ISSN 1408-7073
MATERIALS and GEOENVIRONMENT
MATERIALI in GEOOKOLJE
RMZ - M&G, Vol. 66, No. 3 pp. 139-210 (2019)
Ljubljana, December 2019
RMZ - Materials and Geoenvironment RMZ - Materiali in geookolje
ISSN 1408-7073
Old title/Star naslov
Mining and Metallurgy Quarterly/Rudarsko-metalurški zbornik ISSN 0035-9645, 1952-1997
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Boštjan Markoli
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Cosovic, Vlasta , University of Zagreb, Croatia
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Falkus, Jan, AGH University of Science and Technology, Poland
Gojic, Mirko, University of Zagreb, Croatia
John Lowe, David, British Geological Survey, United Kingdom
Jovičic, Vojkan, University of Ljubljana, Slovenia/IRGO Consulting d.o.o.,
Slovenia
Kecojevic, Vladislav, West Virginia University, USA Kortnik, Jože, University of Ljubljana, Slovenia Kosec, Borut, University of Ljubljana, Slovenia Kugler, Goran, University of Ljubljana, Slovenia Lajlar, Bojan, Velenje Coal Mine, Slovenia
Malbašic, Vladimir, University of Banja Luka, Bosnia and Herzegovina
Mamuzic, Ilija, University of Zagreb, Croatia
Moser, Peter, University of Leoben, Austria
Mrvar, Primož, University of Ljubljana, Slovenia
Palkowski, Heinz, Clausthal University of Technology, Germany
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Pelizza, Sebastiano, Polytechnic University of Turin, Italy
Ratej, Jože, IRGO Consulting d.o.o., Slovenia
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Šmuc, Andrej, University of Ljubljana, Slovenia
Terčelj, Milan, University of Ljubljana, Slovenia
Vulic, Milivoj, University of Ljubljana, Slovenia
Zupančič, Nina, University of Ljubljana, Slovenia
Zupanič, Franc, University of Maribor, Slovenia
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Table of Contents Kazalo
Original scientific paper Izvirni znanstveni članki
Analysis of Chemical Composition Homogeneity in the Cross-section of the Rods	139
Produced from Alloys of 6xxx Group
Analiza homogenosti kemijske sestave po preseku litih drogov izdelanih iz zlitin iz skupine 6xxx
Maja Vončina, Peter Cvahte, Ana Kračun, Tilen Balaško, Jožef Medved
Review of Studies on Corrosion of Steel by CO2, Focussed on the Behaviour of API Steel	149
in Geological CO2 Storage Environment
Pregled korozije jekla s CO2, osredotočen na obnašanja jekel API v okolju geološkega shranjevanja CO2
Wilmer Emilio García Moreno, Gabriela Gonçalves Dias Ponzi, Ângelo Abel Machado Pereira Henrique, Jairo José de Oliveira Andrade
Petrochemistry and petrogenesis of the Precambrian Basement Complex rocks around	173
Akungba-Akoko, southwestern Nigeria
Petrokemija in petrogeneza predkambrijskih kamnin podlage na območju Akungba-Akoko, JZ Nigerij
Abimbola Chris Ogunyele, Oladotun Afolabi Oluwajana, Iyanuoluwa Queen Ehinola, Blessing Ene Ameh, Toheeb Akande Salaudeen
Heavy Mineral Distribution in the Lokoja and Patti Formations, Southern Bida Basin,	185
Nigeria: Implications for Provenance, Maturity and Transport History
Razširjenost težkih mineralov v formacijah Lokoja in Patti: poreklo, zrelost in zgodovina transporta
Bankole, S. I., Akinmosin, A., Omeru, T. and Ibrahim, H. E.
Assessment of Hydrogeological Potential and Aquifer Protective Capacity of Odeda,	199
Southwestern Nigeria
Hidrogeološki potencial in ocena zaščitnih zmogljivosti vodonosnika na območju Odeda v Nigeriji
J.O. Aina, O.O. Adeleke, V. Makinde, H.A. Egunjobi, P.E. Biere
Historical Review Zgodovinski pregled
Instructions to Authors Navodila avtorjem
Historical Review
Zgodovinski pregled
More than 90 years have passed since the University Ljubljana in Slovenia was founded in 1919. Technical fields were united in the School of Engineering that included the Geologic and Mining Division, while the Metallurgy Division was established only in 1939. Today, the Departments of Geology, Mining and Geotechnology, Materials and Metallurgy are all part of the Faculty of Natural Sciences and Engineering, University of Ljubljana. Before World War II, the members of the Mining Section together with the Association of Yugoslav Mining and Metallurgy Engineers began to publish the summaries of their research and studies in their technical periodical Rudarski zbornik (Mining Proceedings). Three volumes of Rudarski zbornik (1937, 1938 and 1939) were published. The War interrupted the publication and it was not until 1952 that the first issue of the new journal Rudarsko-metalurski zbornik - RMZ (Mining and Metallurgy Quarterly) was published by the Division of Mining and Metallurgy, University of Ljubljana. Today, the journal is regularly published quarterly. RMZ - M&G is co-issued and co-financed by the Faculty of Natural Sciences and Engineering Ljubljana, the Institute for Mining, Geotechnology and Environment Ljubljana, and the Velenje Coal Mine. In addition, it is partly funded by the Ministry of Education, Science and Sport of Slovenia.
During the meeting of the Advisory and the Editorial Board on May 22, 1998, Rudarsko-metalurski zbornik was renamed into "RMZ - Materials and Geoenvironment (RMZ - Materiali in Geookolje)" or shortly RMZ - M&G. RMZ - M&G is managed by an advisory and international editorial board and is exchanged with other world-known periodicals. All the papers submitted to the RMZ - M&G undergoes the course of the peer-review process. RMZ - M&G is the only scientific and professional periodical in Slovenia which has been published in the same form for 60 years. It incorporates the scientific and professional topics on geology, mining, geotechnology, materials and metallurgy. In the year 2013, the Editorial Board decided to modernize the journal's format.
A wide range of topics on geosciences are welcome to be published in the RMZ - Materials and Geoenvironment. Research results in geology, hydrogeology, mining, geotechnology, materials, metallurgy, natural and anthropogenic pollution of environment, biogeochemistry are the proposed fields of work which the journal will handle.
Že več kot 90 let je minilo od ustanovitve Univerze v Ljubljani leta 1919. Tehnične stroke so se združile v Tehniški visoki šoli, ki sta jo sestavljala oddelka za geologijo in rudarstvo, medtem ko je bil oddelek za metalurgijo ustanovljen leta 1939. Danes oddelki za geologijo, rudarstvo in geotehnologijo ter materiale in metalurgijo delujejo v sklopu Naravoslovnotehniške fakultete Univerze v Ljubljani. Pred 2. svetovno vojno so člani rudarske sekcije skupaj z Združenjem jugoslovanskih inženirjev rudarstva in metalurgije začeli izdajanje povzetkov njihovega raziskovalnega dela v Rudarskem zborniku. Izšli so trije letniki zbornika (1937, 1938 in 1939). Vojna je prekinila izdajanje zbornika vse do leta 1952, ko je izšel prvi letnik nove revije Rudarsko-metalurški zbornik - RMZ v izdaji odsekov za rudarstvo in metalurgijo Univerze v Ljubljani. Danes revija izhaja štirikrat letno. RMZ - M&G izdajajo in financirajo Naravoslovnotehniška fakulteta v Ljubljani, Inštitut za rudarstvo, geotehnologijo in okolje ter Premogovnik Velenje. Prav tako izdajo revije financira Ministrstvo za izobraževanje, znanost in šport.
Na seji izdajateljskega sveta in uredniškega odbora je bilo 22. maja 1998 sklenjeno, da se Rudarsko-metalurški zbornik preimenuje v RMZ - Materiali in geookolje (RMZ -Materials and Geoenvironment) ali skrajšano RMZ - M&G. Revijo RMZ - M&G upravljata izdajateljski svet in mednarodni uredniški odbor Revija je vključena v mednarodno izmenjavo svetovno znanih publikacij. Vsi članki so podvrženi recenzijskemu postopku.
RMZ - M&G je edina strokovno-znanstvena revija v Sloveniji, ki izhaja v nespremenjeni obliki že 60 let. Združuje področja geologije, rudarstva, geotehnologije, materialov in metalurgije. Uredniški odbor je leta 2013 sklenil, da posodobi obliko revije.
Za objavo v reviji RMZ - Materiali in geookolje so dobrodošli tudi prispevki s širokega področja geoznanosti, kot so: geologija, hidrologija, rudarstvo, geotehnologija, materiali, metalurgija, onesnaževanje okolja in biokemija.
Glavni urednik
Editor-in-Chief
139
Original scientific paper	Received: Dec 03, 2019
Accepted: Dec 16, 2019 DOI: 10.2478/rmzmag-2019-0018
Analysis of Chemical Composition Homogeneity in the Cross-section of the Rods Produced from Alloys of 6xxx Group
Analiza homogenosti kemijske sestave po preseku litih drogov izdelanih iz zlitin iz skupine 6xxx
Maja Vončina1*, Peter Cvahte2, Ana Kračun2, Tilen Balaško1, Jožef Medved1
1	Faculty of Natural Sciences and Engineering, Department for Materials and Metallurgy, University of Ljubljana, Ljubljana, Slovenia
2	Impol Group, Partizanska 38, 2310 Slovenska Bistrica, Slovenia * maja.voncina@omm.ntf.uni-lj.si
Abstract
The alloys from Al-Mg-Si system provide an excellent combination of mechanical properties, heat treatment at extrusion temperature, good weldability, good corrosion resistance and formability. Owing to the high casting speed of rods or slabs, the solidification is rather non-equilibrium, resulting in defects in the material, such as crystalline segregations, the formation of low-melting eutectics, the unfavourable shape of inter-metallic phases and the non-homogeneously distributed alloying elements in the cross-section of the rods or slabs and in the entire microstructure. The inhomoge-neity of the chemical composition and the solid solution negatively affects the strength, the formability in the warm and the corrosion resistance, and can lead to the formation of undesired phases due to segregation in the material. In this experimental investigation, the cross-sections of the rods from two different alloys of the 6xxx group were investigated. From the cross-sections of the rods, samples for differential scanning cal-orimetry (DSC) at three different positions (edge, D/4 and middle) were taken to determine the influence of inhomogeneity on the course of DSC curve. Metallographic sample preparation was used for microstructure analysis, whereas the actual chemical composition was analysed using a scanning electron microscope (SEM) and an energy dispersion spectrometer (EDS).
Key words: casted rods for extrusion, homogeneity of chemical composition, DSC analysis, microstructure.
Povzetek
Zlitine iz sistema Al-Mg-Si zagotavljajo odlično kombinacijo mehanskih lastnosti, toplotno obdelavo pri temperaturi ekstruzije, dobro varivost, dobro korozijsko odpornost in preoblikovalnost. Zaradi visoke hitrosti ulivanja drogov ali bram je strjevanje dokaj neenakomerno, kar ima za posledico nastanek napak v materialu, kot so kristalne segregacije, tvorba niz-kotaljivih evtektikov, neugodna oblika intermetalnih faz in nehomogena porazdelitev legirnih elementov po preseku drogov ali bram in v celotni mikrostrukturi. Nehomogenost kemične sestave in trdne raztopine negativno vpliva na trdnost, preoblikovalnost v toplem ter korozijsko odpornost, poleg tega pa lahko vodi do tvorbe nezaželenih faz zaradi segregacije v materialu. V tej eksperimentalni preiskavi smo preučili preseka drogov dveh različnih zlitin iz skupine 6xxx. Vzorci za diferencialno vrstično kalorimetrijo (DSC) so bili odvzeti iz prečnega prereza droga na treh različnih mestih (rob, D/4 in sredina), z namenom ugotavljanja vpliva nehomogenosti na potek DSC krivulje. Za analizo mikrostrukture smo uporabili metalografski vzorec, medtem ko smo dejansko kemijsko sestavo analizirali z energijsko disperzijskim spektrometrom (EDS) na vrstičnem elektronskem mikroskopu (SEM).
Ključne besede: liti drogovi za ekstrudiranje, homogenost kemične sestave, DSC analiza, mikrostruktura.
8 Open Access. © 2019 Voncina M., Cvahte P., Kracun A., Balasko T., Medved J., published by Sciendo.	This work is licensed
under the Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 License.
140
Introduction
Aluminium alloys from the group 6xxx have good mechanical properties, good formability and corrosion resistance. Alloyed elements affect weldability corrosion resistance, corrosion cracking, electrical conductivity and density. Alloying magnesium and silicon to aluminium alloys from the group 6xxx takes place in the appropriate ratio (Mg/Si = 1.73] to form the Mg2Si phase [1]. In practice, alloys of the 6xxx system produced by casting techniques containing excess silicon or magnesium. Excess silicon results in higher strength and increases their transformability but reduces corrosion resistance. Excess magnesium increases corrosion resistance but reduces transformability and strength [2, 3].
The presence of iron in alloys of the 6xxx system results in the formation of phases such as ALFe, ALFe,Si, ALFeMgSr and ALFe, which
3	o 2	o	*-,3 6	6
may be detrimental to the properties of these alloys [4]. Iron reduces ductility and toughness by forming coarse components with aluminium and other alloying elements. It also reduces strength, corrosion resistance and fatigue resistance. The alloying elements of chromium and manganese correct the shape and size of iron phases and its compounds in alloys of the 6xxx system. The presence of manganese not only increases the temperature of recrystallisation and corrosion resistance but also allows dispersion hardening and ageing [2]. Although alloys from the group 6xxx have lower strength than alloys from the groups 2xxx and 7xxx, they have advantages such as good formability and corrosion resistance. Bismuth and lead can also be added for better machining by cutting. These alloys are used for profiles for doors, windows, ladders, walls and fences. They are used for the manufacture of frames for motors and cabinets of electric motors, heating and cooling pipes, office equipment, etc. [5]. The production of products from the alloys of the group 6xxx begins with the continuous or semi-continuous casting of the rods, followed by homogenisation. With a higher degree of homogenisation, better formability properties can be expected, which are crucial for further processing. Homogenisation annealing is the process by which crystal segregations and
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low-melting eutectics are eliminated, the shape of intermetallic phases is changed and small precipitates are formed. The homogenisation process achieves a uniform distribution of the alloying elements throughout the entire microstructure. The inhomogeneity of the solid solution can adversely affect the corrosion/oxidation resistance, strength, working temperature (consequence of artificial reduction of melting point in interdendritic spaces] and formability in a warm, and can cause undesired phases due to segregation [6, 7]. Thus, by means of homogenisation annealing, the formability of bars, ingots and other cast semi-finished products is improved; in this case, casted rods made of aluminium alloys, since they have non-homoge-neously distributed alloying elements throughout the microstructure [8-10]. The uneven distribution of alloying elements inside the dendritic microstructure is a feature of high cooling rates. These differences increase with increasing cooling rates and greater differences in the composition between the melt and the solid phases at the beginning of crystallisation, which in some alloys can only be equated with long-term homogenisation as a result of solid-phase diffusion processes [11-13]. Owing to the non-equilibrium solidification, in the solid state, eutectic can be obtained, which according to the theoretical phase diagram should not form. Lowering the temperature at which incipient fusion started is so called a non-equilibrium solidus (NRS]. In order to avoid local incipient fusion, each heat treatment must be carried out below the NRS temperature. Local incipient fusion may result in the formation of porosity resulting from the dissolution of non-equilibrium phases. The cracks formed during the forming can be the result of a molten eutectic phase that does not dissolve. The degree of inhomogeneity is influenced by several different factors. The wider interval of solidification of the individual alloy in practical and theoretical aspects contributes to greater non-homogeneity. The increase in non-homogeneity is also influenced by the difference in the size of the solvent atoms and dissolved atoms, and their crystalline structure [5, 11]. The homogenisation annealing of cast structures to improve the formability was developed on the basis of empirical methods for determin-
Vončina M., Cvahte P., Kračun A., Balaško T., Medved J.
141
ing the time and temperature of the annealing. One of the determining factors is diffusion. In the empirical determination of the time and temperature of the annealing, the diffusivity of the local chemical composition must be taken into account. The diffusion of individual particles can be used to approximately determine the diffusion time, for which the following expression (1] can be used: [8, 10].
In this equation x is the diffusion path and represents half of the space between the secondary dendritic arms. Therefore, the process of homogenisation is more effective if the grains are smaller, since the elements need to take a shorter path. D represents the diffusivity given in the following equation, whereas D0 represents diffusion constant; Q is the activation energy for the diffusion; R is a gas constant and T is the temperature at which diffusion takes course.
D = A>exp g)	(2)
According to this equation, the temperature has an exponential influence on the diffusion and consequently also on the time and temperature of homogenisation. By homogenisation annealing, only micro-segregation can be influenced. By the solidification of large castings, macro-segregations may occur, which may also be one metre high and could not be affected by homogenisation annealing [11]. In Table 1, the calculation of the diffusion coefficients of the various elements and the time needed at the certain temperature at which the element travels 50 mm (the hypothetical half-distance between the secondary dendritic arms) are given. Table 1 shows that the time drastically reduces with the rising temperature. Among the selected elements, the longest diffusion times are for manganese, where at a temperature of 600°C, the homogenisation annealing should last as much as for 567.3 h. Among other elements, only iron is also more difficult, which requires 21.6 h at the same temperature, while for other elements, the diffusion at a distance of 50 mm takes place in 2.2 h (Cu), 2.1 h (Al - self - diffusion), 0.7 h (Si), 0.5 h (Mg) and 0.3 h (Zn) [14-17].
Table 1: Diffusion of elements in aluminium at temperatures 550,600 and 650°C at a distance of 50 mm [14-17],
Element	T [°C]	D [cm2/s]	t [h]
	550	9.64E-10	7.2
Al	600	3.32E-09	2.1
	650	9.98E-09	0.7
	550	6.70E-11	103.6
Fe	600	3.22E-10	21.6
	650	1.30E-09	5.3
	550	3.21E-09	2.2
Si	600	1.04E-08	0.7
	650	2.95E-08	0.2
	550	4.30E-09	1.6
Mg	600	1.31E-08	0.5
	650	3.55E-08	0.2
	550	2.01E-12	3461.6
Mn	600	1.22E-11	567.3
	650	6.14E-11	113.1
	550	9.83E-10	7.1
Cu	600	3.15E-09	2.2
	650	8.88E-09	0.8
	550	7.30E-09	1.0
Zn	600	2.00E-08	0.3
	650	4.92E-08	0.1
Owing to all the factors listed earlier, which influence the quality of the production of cast rods, the process of homogenisation and further processing of rods, two cross-sections of the rods from two different alloys of the 6xxx group, were analysed in this study. From the cross-sections of the rods, samples for differential scanning calorimetry (DSC] were taken at three locations in order to determine the effect of inhomogeneity on the DSC curve. The samples after the DSC analysis were, furthermore, metallographically prepared and microstructure was analysed, where the actual chemical composition was analysed using a scanning electron microscope (SEM) and an energy dispersion spectrometer (EDS].
Analysis of Chemical Composition Homogeneity in the Cross-section of the Rods Produced from Alloys of 6xxx Group
142
Materials and Methods
Based on the chemical composition of investigated alloys, which correspond to the EN AW-6008 and EN AW-6060 standards given in Table 2, a simulation of the thermodynami-cally non-equilibrium solidification according to Scheil was performed using the Thermo-Calc software and the TCAL6 database.
In addition, DSC analysis was performed in order to determine the temperature changes and the thermal effects that occur during heating/melting and cooling/solidification of the investigated alloys. Experiments were carried out using the STA Jupiter 449C device from Netzsch by placing two identical corundum crucibles on the platinum sensor. In one crucible, the investigated sample, and in the other, a comparative (inert] sample was placed. The
Table 2: Chemical composition of investigated alloys according to EN-AW standards in wt.%. Alloy Si	Fe	Cu Mn Mg	Cr Zn Ti	V	Al
6008 0.50-0.90 0.35 0.30 0.30 0.40-0.70 0.30 0.20 0.10 0.05-0.20 Rest
6060 0.30-0.60 0.10-0.30 0.10 0.10 0.35-0.60 0.05 0.15 0.10	-	Rest
system was heated in a furnace according to the pre-programmed temperature program up to 720°C. At this temperature, it was kept for 10 minutes. Heating and cooling stages were carried out at a constant rate of 10 K/min. The test was performed in a protective atmosphere of argon Ar 6.0. During the measurement, the apparatus measured the temperature, the difference in temperatures between the investigated and the comparative samples and the time. DSC analysis was carried out on cast samples taken from the centre, on D/4 and on the edge of the cross-section of the rod. The samples were cut from the cross-section of the rod and turning at a diameter of 4.5 mm and a height of 4 mm, which were inserted into the device where analysis was performed. After the measurements, the heating and cooling DSC curves were plotted; the characteristic temperatures were determined from heating and cooling DSC curves, and the influence of the sampling site on the characteristic temperatures was analysed. After the DSC analysis, the samples were metallographically prepared and photographed using a BX61 light microscope with the purpose of analysing the influence of the sampling site from the cross-section of the rod on the formation and distribution of microstructural components. Furthermore, using the SEM Jeol JSM-7600F and EDS analyzer NCA Oxford 350 EDS SDD, the chemical composition
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of all samples after DSC analysis was analysed, and the homogeneity of the chemical composition in the intersection of the rod was analysed.
Results and Discussion
Figure 1a shows the calculated cooling curve of the alloy EN AW-6008 (Scheil's model], with the dotted line showing the course of equilibrium solidification. In this alloy, according to the calculation, in the microstructure, the primary a-Al, eutectic a-Al + Al15Si2M4 and eu-tectic a-Al + Al15Si2M4 + Al9Fe2Si2 phases can be expected, while at a lower temperature (approximately 568°C), the eutectic phases Al18Fe2Mg7Si10 and Mg2Si can solidify. Non-equilibrium solidification begins at 654°C and ends at 558°C. In the following, the Scheil's model of non-equilibrium solidification taking into account the large diffusion coefficients of the elements of silicon and magnesium is calculated (Figure 1b]. In this case, only three phases are obtained: a-Al, eutectic a-Al + Al15Si2M4 and eutectic a-Al + Al8Fe2Si. The solidification starts at Tl = 654°C and ends at TS = 603°C. Figure 2 shows the calculated cooling curve of the alloy EN AW-6060 (Scheil's model]. In this alloy, the primary crystals of a-Al, eutectic a-Al+AL ,Fe„ and eutectic a-Al + AL ,Fe„ + ALFe,Si
134	1348 2
can be found in the microstructure; the phase
Vončina M., Cvahte P., Kračun A., Balaško T., Medved J.
143
Figure 1: The cooling curve of the non-equilibrium solidification of the alloy EN AW-6008 without considering the diffusion (a) and taking into account the larger diffusion coefficients of the elements of silicon and magnesium (b).
Figure 2: The cooling curve of the non-equilibrium solidification of the alloy EN AW-6060 without considering the diffusion (a) and taking into account the larger diffusion coefficients of the elements of silicon and magnesium (b).
Al8Fe2Si is transformed into the phase Al9Fe2Si2; also at a lower temperature, the eutectic phases Al18Fe2Mg7Si10 and Mg2Si can solidify. Non-equilibrium solidification begins at 656°C and ends at 557°C. Figure 2b shows Scheil's model of non-equilibrium solidification taking into account the large diffusion coefficients of silicon and magnesium. In this case, only three phases are obtained in the non-equilibrium curve: a-Al, eutectic a-Al + Al13Fe4 and eutectic a-Al + Al13Fe4 + Al8Fe2Si. The solidification starts at Tl = 656°C and ends at Ts = 616°C.
At the heating DSC curve, the Al3Ti and AlMg-0 phases at the temperature of 233.2°C and 282.4°C, respectively, presumably precipitate (Figure 3b), which was verified by thermodynamic calculations/simulations of equilibrium solidification and is a consequence of the supersaturated solid solution of the pre-hardened alloy. At 601.0°C, the eutectic a-Al + Al0Fe2Si melts, which represents a sol-idus temperature, and at a temperature of 609.6°C, the eutectic a-Al + Al15Si2M4 melts with respect to the Scheil's calculation in Figure 1. Furthermore, at 646.8°C, melting of primary
Analysis of Chemical Composition Homogeneity in the Cross-section of the Rods Produced from Alloys of 6xxx Group
144
Figure 3: Heating (blue) and cooling (green) DSC curves of the samples 6008_centre (a), 6008_D/4 (b) and 6008_edge (c) with marked characteristic temperatures and corresponding microstructure images.
a-Al crystals is observed. During cooling, at a temperature of 648.6°C, the primary a-Al solidifies; at a temperature of 599.0°C, eutectic a-Al + Al15Si2M4 and at a temperature of 572°C, eutectic a-Al + Al8Fe2Si. At 551.8°C, most likely the Si2V eutectic phase solidifies (named as CrSi2 in the TC calculation). Similar transitions are also observed on DSC curves of samples taken from the centre and
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edge of the cross-section of the rod, except that the temperatures slightly differ (Figure 3a and c). When comparing the curves, distinct differences are observed, which probably suggests an inhomogeneous chemical composition in the cross-section of the rod (Figure 4). This is also confirmed by microstructural images after DSC analysis at various sites. The density of microstructural components is much higher
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Figure 4: Comparison of heating (a) and cooling (b) DSC curves of EN AW-6008 alloy from different places of the rod: centre (blue), D/4 (green) and edge (red).
Figure 5: Heating (blue) and cooling (green) DSC curves of the sample 6060_centre (a), sample 6060_D/4 (b) and sample 6060_ edge (c) with marked characteristic temperatures and corresponding microstructure images.
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DSC /(mW/mg)
T exo
Temperature l°C
Figure 6: Comparison of heating (a) and cooling (b) DSC curves (blue), D/4 (green) and edge (red).
/(mW/mg) T exo
Temperature /°C '-6060 alloy from different places of the rod: centre
6008-S	6008-D	600S-R
Figure 7: EDS analysis of samples from the alloy EN AW-6008 taken from the cross-section of the rod at D/4, centre and edge after the DSC analysis.
6060-S	6060-D	6060-R
-Me -Si -Mn -Fe
Figure 8: EDS analysis of samples from the alloy EN AW-6060 taken from the cross-section of the rod at D/4, centre and edge after the DSC analysis.
in the sample 6008_centre than in the sample 6008_edge, whereas the distribution of microstructure phases is most uniform in the sample 6008_D/4.
Figure 5 shows the heating and cooling DSC curves of samples from the EN AW-6060 alloy taken at three different locations with the accompanying microstructural images. At 574.5°C, the eutectic a-Al + Al8Fe 2Si begins to melt (according to the Scheil's calculation in Figure 2b), which represents the solidus temperature, and at a temperature of 624.1°C, the eutectic a-Al + Al13Fe4 melts. Furthermore, at 642.1°C, the melting of the primary crystals of a-Al is observed. On the basis of the TC calculations of the equilibrium solidification, it can be concluded that the heating DSC curve leads to the precipitation of the phases Al15Si2M4 and Mg2Si at a temperature of 242.4°C and 371.2°C, respectively. During cooling, the primary a-Al (liquidus) solidifies at a temperature of
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649.7°C and eutectic with Fe phase (Al13Fe4 or Al8Fe2Si) solidifies at a temperature of 602.8°C, depending on the ratio between Fe and Si. Similar changes are also observed on DSC analyses of samples taken from the centre (Figure 5a) and the edge (Figure 5c) of the cross-section of the rod, except that the temperatures differ slightly from one another. When comparing the heating (Figure 6a) and cooling (Figure 6b) of the DSC curves, it is observed that the curves are generally very similar, which indicates better homogeneity of the chemical composition across the cross-section of the rod. The higher homogeneity of the chemical composition and, consequently, of the microstructural components indicated by the results of the DSC analysis was confirmed also by the microstructural images shown next to the corresponding DSC analysis.
Figures 7 and 8 show the results of the EDS analysis on the samples after the DSC experi-
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ments confirming the preliminary conclusions; however, only the fluctuation of certain chemical elements is presented since the actual chemical composition of the investigated alloys could not be revealed. It can be seen that the chemical composition is not homogeneous in the cross-section of the cast rod. The largest deviations in the EN AW-6008 alloy are found in a silicon concentration, which varies by more than 0.5 wt.%. Minor deviations are also found in concentrations of magnesium, vanadium, manganese and iron, which can be eliminated by appropriate homogenisation annealing. Minor fluctuations in the chemical composition are shown by EDS analysis of the alloy EN AW-6060 (Figure 8), which was assumed already after the DSC analysis, where the DSC curves are very similar. The concentrations of magnesium, silicon, manganese and iron are slightly increased from the centre to the edge. EN AW-6060 alloy rods are fairly homogeneous in chemical composition already in the cast state.
Conclusion
The aim of this investigation was analysis of chemical composition homogeneity in the cross-sections of the rods produced from alloys of the 6xxx group. DSC analysis indicated non-homogeneity of the experimental alloys, whereas four reactions in case of EN AW-6008 alloy and two reactions in case of EN AW-6060 alloy could be expected, which corresponds to the Scheil's non-equilibrium calculations, where larger diffusion coefficients of the elements of silicon and magnesium were taken into account.
On the basis of the results presented earlier, it can be concluded that the alloy EN AW-6060 is already quite homogeneous in the cast state through the cross-section of the rod. The concentration of some elements slightly increases from the centre to the edge. From the results of the analysis of the cross-section of the rod from the EN AW-6008 alloy, it is evident that the chemical composition is not homogeneous in the cross-section of the cast rod. The greatest deviations are observed in the concentration of silicon, which also fluctu-
ates by more than 0.5 wt.%. Minor deviations are also found in concentrations of magnesium, vanadium, manganese and iron, which can be eliminated by appropriate homogenisation annealing.
Acknowledgements
The work was co-financed by the Republic of Slovenia; the Ministry of Education, Science and Sport and the European Regional Development Fund. The work was carried out in the framework of the project Modelling of thermo-mechAnical pRocessing of The alumlNium alloys for high quality products (MARTIN, Grant No.: C3330-18-952012).
References
[1]	Zhong, H., Rometsch, P.A., Cao, L., Estrin, Y. (2016): The influence of Mg/Si ratio and Cu content on the stretch formability of 6xxx aluminium alloys. Materials Science and Engineering: A, 651, pp. 688-697.
[2]	Mukhopadhyay, P. (2012): Alloy Designation, Processing, and Use of AA5XXX Series Aluminium Alloys. ISRN Mettalurgy, 2012, pp. 1-16, doi: 10.5402/2012/165082.
[3]	Jakobsen, J.V. (2016): Microstructure and Mechanical Properties of welded AA6082 Aluminum Alloys. Master Thesis. Trondheim, 89 p.
[4]	Sha, G., O'Reilly, K., Cantor, B., Worth, J., Hamerton, R. (2001): Growth related metastable phase selection in a 6xxx series wrought Al alloy. Materials Science and Engineering: A, Elsevier, 304-306, pp. 612-616.
[5]	Substances and Technologies [online]. SubsTech [cited 7/28/2012]. Available on: https://www.goo-gle.si/#q=SubsTech.+Classification+of.
[6]	Zhong, H., Rometsch, P.A., Estrin, Y. (2014): Effect of alloy composition and heat treatment on mechanical performance of 6xxx aluminum alloys. Transactions of Nonferrous Metals Society of China, 24(7), pp. 2174-2178.
[7]	Totten, G.E., Mackenzie, D.S. (2016): ASM Handbook vol. 4E; Heat Treating of Nonferrous Alloys. ASM International, pp. 32-37.
[8]	Kammer, C. (1999): Aluminium handbook vol. 1: Fundamentals and Materials. Aluminium-Zentrale e.V.: Germany, 718 p.
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[9] Mackenzie, A.S., Totten, G.E. (2003): Handbook of Aluminium vol. 1: Physical Metallurgy and processes. Marcel Dekker, Inc.: New York, 1310 p.
[10]	Van Horn, K.R. (1967): Aluminium vol. 1: Properties, physical metallurgy and phase diagrams. Metals Park: American Society for Metals, 2521p.
[11]	Tohru, A., Gordon Baker, M. (1991): Handbook, A.S.M. Volume 4, Heat Treating. ASM International, 1960 p.
[12]	Zolotorevsky, V.S., Glazoff, M.V., Belov, N.A. (2007): Casting aluminium alloys. Elsevier: Oxford, pp. 184-185.
[13]	Lise Dons A. (2001): The Alstruc homogenization model for industrial aluminum alloys. Journal of light Metals 1, pp. 133-149.
[14]	Gale, W.F., Totemeier T.C. (2004): Smithells Metals Reference Book: Eighth Edition, Elsevier.
[15]	Hood, G.M. (1969): The Diffusion of Iron in Aluminium. Chalk River Nuclear Laboratories, pp. 305-328.
[16]	Hood, G.M., Schultz, R.J. (1970): The Diffusion of Manganese in Aluminium. Chalk River Nuclear Laboratories, pp. 1479-1489.
[17]	Paccagnella, A., Ottaviani, G., Fabbri, P., Ferla, G., Que-irolo, G. (1985): Silicon Diffusion in Aluminium. Thin Solid Films, 128(3-4), pp. 217-232.
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Original scientific paper
Received: Sep 12, 2019 Accepted: Dec 10, 2019 DOI: 10.2478/rmzmag-2019-0017
Review of Studies on Corrosion of Steel by CO2, Focussed on the Behaviour of API Steel in Geological CO2 Storage Environment
Pregled korozije jekla s CO2, osredotočen na obnašanja jekel API v okolju geološkega shranjevanja CO2
Wilmer Emilio Garcia Moreno1*, Gabriela Gonçalves Dias Ponzi1, Ângelo Abel Machado Pereira Henrique1, Jairo José de Oliveira Andrade2
1	Graduation Programme in Materials Engineering and Technology, Pontifical Catholic University of Rio Grande do Sul (PGTEMA/PUCRS), Brazil
2	Pontifical Catholic University of Rio Grande do Sul (PGTEMA/PUCRS), Brazil * wilgm93@gmail.com
Abstract
The world energy demand has become higher with the growing population, which has translated into an increase in emission of greenhouse gases into the atmosphere. For this reason, CO2 capture and storage has been undertaken to purify the atmosphere. For storing this CO2 it is necessary to have wells to inject it (deeper than 800 m); moreover, these wells need to have stability over time, and one of the stability aspects is the protection of steel against corrosion. Considering this aspect, the most common steels (focussed on American Petroleum Institute [API] steels) that can be used in an injector well were studied. The best performance was obtained using a high alloy content of Cr and Ni. Furthermore, the most important parameter analysed when corrosion is studied is the test time, which was modelled to stabilise the corrosion rates. The experiments were undertaken after a general review of different studies that investigated the corrosion of steel when in contact with CO2 in the vapour phase and under supercritical conditions.
Povzetek
Z naraščanjem števila prebivalcev se povečujejo tudi energetske potrebe, kar se odraža na povečanju emisij toplogrednih plinov v atmosfero. Zaradi tega se z namenom čiščenja ozračja izvaja zajem in skladiščenje CO2. Za skladiščenje CO 2 so potrebne injekcijske vrtine (globlje od 800 m), ki morajo imeti potrebno časovno stabilnost. Eden od stabilnostnih vidikov je ohranjanje jekla proti korozijskim napadom. Zaradi tega so bile opravljene raziskave najbolj pogostih jekel (osredotočeno na API jekla), ki se jih lahko uporablja v injekcijskih vrtinah. Najboljše rezultate so pokazala jekla z visokim deležem Cr in Ni. Pri raziskavah korozije ima pomembno vlogo čas, zato je bil upoštevan pri model-skih analizah. Članek temelji na splošnem pregledu različnih raziskav, v katerih so se avtorji ukvarjali s korozijo jekla v stiku s CO2 v pari in v superkritičnih pogojih.
Ključne besede: stopnja korozije, API jeklo, faza CO2, vsebnost Cr-Ni-Mo
Key words: corrosion rate, API steel, CO2 phase, Cr-Ni-Mo content
9 Open Access. © 2019 Moreno W.E.G., Dias Ponzi G.G., Machado Pereira Henrique A. A., de Oliveira Andrade J.J., published by Sciendo. |feciThis work is licensed under the Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 License.
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Introduction
Mechanism of CO Corrosion
The economic growth and increasing population have influenced energy demand, causing the latter's cumulative growth, specifically in terms of the use of fossil fuels as a means to supply this demand. This has had repercussion on the global average greenhouse gas concentrations, having CO2 as the principal component [1]. The biggest challenge in this context is reduction of CO2 emissions into the atmosphere, with the alternative use of diverse energy sources, such as natural gas, ethanol, nuclear energy, etc. [1].
To reduce the CO2 level in the atmosphere, CO2 capture and storage has been planned and used, this CO2 being stored, mostly, in depleted oil and gas reservoirs; however, some other places have also been considered, such as saline aquifers and coal seams. Some examples of these projects are RECOPOL (coal seam in Poland], Allison Unit (enhanced coal bed methane in Mexico], Selipner (gas field in Norway], Salah gas (project launched by British Petrochemicals and Statoil in Algeria], Ketzin field (enhanced gas recovery in Germany] and some others [2]. According to the Intergovernmental Panel on Climate Change (IPCC] (2007], to have success in CO2 storage, capacity, injectivity and confinement are required; therefore, well stability is really important, and due to some leakage, a path could be created through the well. Hence, to guarantee the wellbore integrity, some authors have established a lifetime of 1000 years [4-7]. CO2 is injected in the supercritical condition (>31 °C and 7.38 MPa and stored deeper than 800 m] [2] and reacts with the steel and cement, bringing about damages. When these wells are not designed for injecting CO2 [3], cement car-bonation, microannulus opening and casing corrosion may possibly occur [4]. The objective of this work is to present a general review of the effect of CO2 corrosion in different kinds of steels used as casing, aiming to know the best options to guarantee the casing stability.
Relation Between Corrosion and Well Integrity
When well stability is talked about, an important topic is corrosion (of either steel or cement]. However, in this paper, the focus is on steel corrosion. It is important to mention that every completion in wells requires metallic components (wellhead, Christmas tree, tubing, casing, packer, etc.], which - in most of the cases (not always] - are made of some form of steel that have metallic alloy elements, i.e. chromium [5].
A CO2 injector well can suffer corrosion in every component, from the wellhead to the down-hole completion components and, therefore, to achieve large success in the CO2 storage project, the wells must bear the highest impact of corrosion [2]; thus, to know how to resist corrosion, it is necessary to know how it attacks. CO2is stable, inert and non-corrosive as a gas; however, when it is in the presence of water (either in the aqueous or vapour CO2 phase], dissolution occurs, with subsequent hydration, forming H2CO3 (carbonic acid], which is the principal agent attacking steels [6]; the principal corrosion products are FeCO3 (iron carbonate] and Fe3C (iron carbide] [7] but, to understand this mechanism better, analysing how it proceeds step by step is required.
Chemical Reaction of CO2 and H2O
Following Table 1, first the CO2 is hydrated by dissolving in water, forming carbonic acid (H2CO3], which is a weak acid because the CO2 is partly dissociated in water. As carbonic acid is diprotic, it dissociates in two steps, which is considered the main source of acidity. The resulting pH is a function of the CO2 partial pressure. In the first dissociation of carbonic acid, the bicarbonate is obtained (HCO3], which, later on, dissociates into carbonate (CO3] [6, 8].
Chemical Interaction of Fe with Environment
Knowing how CO2 reacts in the presence of water, we can see that Fe also reacts with its environment (Table 2]. Initially, Fe reacts with carbonic acid, yielding ferrous bicarbonate (Fe(HCO3]2]; after this, the precipitation
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Table 1: Reaction of CO2 andH2O, Reaction name	Reaction
Carbon dioxide hydration	C02 + h2o ^ h2co3
Carbonic acid dissociation	H2C03 ~ H+ + HC03
Bicarbonate anion dissociation	HCO- ~ H+ + C02
Table 2: Reaction of Fe with the environment, Reaction name	Reaction
Iron-carbonic acid reaction	Fe + 2H2C03 ^ Fe2+ + 2HC03 + H2
Iron-bicarbonate reaction	Fe2+ + 2HC03 ^ Fe(HC03)2
Iron carbonate precipitation	Fe(HC03)2 ^ FeC03 + C02 + H20
	Fe2+ + COi- ^ FeC03
of iron carbonate occurs, in two ways. First, when the concentrations of Fe2+ and CO2- ions reach the maximum solubility limit, they combine forming iron carbonate (FeCO3), with a consequent increase in pH [9]. Second, when the ferrous bicarbonate dissociates, it forms FeCO3 + CO2 + H2O; this water could react with the resultant carbon dioxide, yielding, again, carbonic acid and, in this way, it could result in a cycle of corrosion.
The case when CO2 and water are present has been explained, but, normally, water can have different kinds of ions, such as Cl-, Na+, Ca+, SO2-, etc., which can affect the equilibrium of CO2 and the resulting pH [6]. On the other hand, the presence of FeCO3 could lead to a reduction in the corrosion rate because it is formed on the steel surface [10]. Moreover, this protective film is dependent on low temperatures and high supersaturation of Fe2+ and CO2-; however, this protective film could grow without having any protective property, but, when it does have the property, it could reduce the corrosion rate between 5 and 100 times [8]. Adversely, even when the iron carbonate is precipitated, if it is not compacted on the surface, it cannot prevent the corrosion [10]. Therefore, some analyses have been performed, showing that at low temperatures, the FeCO3 film gets dissolved continuously and the corrosion rate increases [11]. The precipitation kinetics of FeS is almost two
Review of Studies on Corrosion of Steel by CO2, Focussed on the Behaviour of API Steel in Geological CO2 Storage Environment
Figure 1: CO corrosion on a pipe [14],
orders of magnitude faster than that of FeCO3 at the same conditions [12]; moreover, FeCO3 was formed after 60 days, and even when there was a reduction in corrosion rate, there was still corrosion [13]. In addition, as shown in Figure 1, it is noted that the electrochemical dissociation of iron leads to surface corrosion. Finally, although the Fe2+ ion could react later to form the protective film, this could lead to study the corrosion rate and rate of formation of protective film to know whether FeCO3 is having a positive or negative effect, because as mentioned earlier [11-13], there is still corrosion on steel.
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3	" ' i
Figure 2: Well configuration. Taken from [18].
Different Kinds of Steels
CO2 can affect the different materials in CO2 injector wells. Therefore, the metallurgical selection (as well as the type of cement] plays an important role [15] because the casing steel and other parts of the well can be subject to corrosion when they are exposed to CO2 or formation fluids (or both] (Figure 2]. This corrosion can be controlled by using corrosion-resistant alloys (CRAs) [16]. Furthermore, if a CRA is improperly selected, it can lead to mistakes in the future,
affecting the performance; hence, taking care of the specific properties of the steels is required because a group of CRAs can be resistant at one temperature; however, this does not guarantee that the CRAs will work with the same performance in a different environment [17]. Casing and tubing play an important role in wells; so, ensuring their integrity is essential. Therefore, the American Petroleum Institute (API] has standardised some grades of steels, which are differentiated by groups, content of
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Table 3: Required chemical composition [21],
Chemical composition in mass fraction (%)
C Mn Mo Cr Ni Cu P S	Si
Group Grade Type -
Min Max Min Max Min Max Min Max Max Max	Max	Max	Max
H40 - -- -- -- - -- -	0.03	0.03	-
J55 - -- -- -- - - --	0.03	0.03	-
K55 - -- -- -- - -- -	0.03	0.03	-
1 -
N80 1- -- -- -- -- -	0.03	0.03	-
N80Q------- -- -	0.03	0.03	-
R95 - - 0.45 - 1.90 - - - - - -	0.03	0.03	0.45
M65 - -- -- -- - - --	0.03	0.03	-
L80 1 - 0.43 - 1.90 - - - - 0.25 0.35	0.03	0.03	0.45
L80 9Cr - 0.15 0.30 0.60 0.90 1.10 8.00 10.00 0.50 0.25	0.02	0.01	1.00
2	L80 13Cr 0.15 0.22 0.25 1.00 - - 12.00 14.00 0.50 0.25	0.02	0.01	1.00 C90 1 - 0.35 - 1.20 0.25 0.85 - 1.50 0.99 -	0.02	0.01	-T95 1 - 0.35 - 1.20 0.25 0.85 0.40 1.50 0.99 -	0.02	0.01	-C110 - - 0.35 - 1.20 0.25 1.00 0.40 1.50 0.99 -	0.02	0.005	-
3	P110 - -- -- -- - - --	0.02	0.03	-
4	Q125 1 - 0.35 - 1.35 - 0.85 - 1.50 0.99 -	0.02	0.01	-
chemical compounds, manufacturing processes and mechanical properties [19], giving the API steel grade; different names are obtained, qualified by a number that represents the minimum yield strength and a letter chosen arbitrarily, without meaning. Therefore, they have been divided into four groups, categorised by resistance to sulphide stress cracking and working pressure [20]:
-	Group 1: H-40, J-55, K-55, N-80, R-95;
-	Group 2: M-65, L-80, C-90, C-95, T-95, C-110;
-	Group 3: P-110;
-	Group 4: Q-125.
Furthermore, they can be divided by product specification level (PSL):
—	PSL-1: Common application casing (H-40, J-55, K-55, M-65, N-80, R-95];
—	PSL-2: Corrosion-resistant casing (L-80, C-90, T-95, C-110);
—	PSL-3: Deep well casing (P-110, Q-125).
However, each carbon API steel has the following specific characteristics:
—	H40: It is an API steel that is not generally used as tubing, due to its yield strength and
the saving in terms of cost is minimum compared to J55 [19],
—	J55: This kind of steel is used for most wells if it meets the design criteria. Moreover, when subjected to a CO2 environment, it is recommended that it is normalised and tempered, as it is used for maximum 9000 ft and 4000 psi in land wells [19].
—	N80: It should be either normalised or normalised and tempered [21]. Furthermore, it shows susceptibility to H2S, and it is recommended for sweet wells [19].
—	L80: Tempered at 620 °C, it has 9Cr and 13Cr steels, being anticorrosive in a CO2 environment; these types should be used at partial pressure of H2S <1.5 psi [19],
—	T95: It is divided into two types, the first one being used in sour facilities [19].
—	C110: This C-steel has maximum minimum yield strength. If necessary, the product can be cold-rotated, straightened and subsequently stress-relieved at temperatures between 30 °C and 55 °C below the final specified tempering temperature, or hot-rotated and straightened at temperatures not >165 °C [21].
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Table 4: Required mechanical properties [22].						
Group	Grade	Type		Yield strength (MPa)		Minimum tensile strength
				Min	Max	(MPa)
	H40	-	0.50	276	552	414
	J55	-	0.50	379	552	517
1	K55	-	0.50	379	552	655
	N80	1	0.50	552	758	689
	N80	Q	0.50	552	758	689
	R95	-	0.50	655	758	724
	M65	-	0.50	448	586	586
	L80	1	0.50	552	655	655
	L80	9Cr	0.50	552	655	655
2	L80	13Cr	0.50	552	655	655
	C90	1	0.50	621	724	689
	T95	1	0.50	655	758	724
	C110	-	0.70	758	828	793
3	P110	-	0.60	758	965	862
4	Q125	1	0.65	862	1034	931
—	P110: This type is restricted to quench-and-tempered heat treatment and is used in deep and sweet wells with high pressures. Even though it has more yielding strength, it is cheaper than C90 and T95 [19].
—	Q125: Gag-press straightening or hot-rotating straightening can be performed for straightening, but the temperature at the end of the rotary straightening process should not be <400 °C. However, if this method cannot be used, the product can also be cold-rotated and straightened, but the stress relief must be performed at 510 °C (950 °F) after straightening [21].
These products must comply with the required chemical composition (Table 3), tensile properties and thickness, as presented in Table 4.
Cr-Steel
Onoyama et al. [23] investigated the corrosion resistance of three different compositions of duplex stainless steel. They evaluated the first two in National Association of Corrosion Engineers (NACE) solution at 80 °C for 100 h to get the effect, in percentage, of different compositions of the alloying elements in the steel, finding that it
is desirable to reduce the Si percentage (<0.5%), leading to the amount of Ni becoming 10% and increasing the resistance; moreover, Mo and N improve the steel and, Sn and Sb have to be correctly added, neither in excess or nor in lower amount, with the best values being 0.05% Sn and 0.15% Sb. On the other hand, duplex steel was tested in 2.8 x 10-2 mol/L NaCl solution saturated with CO2 and N2 at 260 °C for 100 h at 0.10 and 0.05 MPa, obtaining the maximum value around 8.5 x 10-3 mm/yr at 0.10 MPa of pressure and around 3 x 10-3 mm/yr at 0.05 MPa of pressure.
Kimura et al. [24] studied the effect of CO2 corrosion in 13Cr steel, modifying the chemical composition of Cu, Ni and Mo, at 3 MPa and 180 °C, inside an autoclave with 20% of NaCl solution saturated with CO2 gas, for 7 days, evaluating the weight loss rate. When there was no addition of Cu, Ni and Mo, the corrosion rate was 1.71 mm/yr, but when these elements were part of the chemical composition, the corrosion rate was <0.3 mm/yr. Moreover, with the increase in Mo content at the same Ni percentage, the corrosion rate decreased. On the other hand, the addition of Cu did not affect the corrosion rate and- the effect of Ni-Cu was not clear.
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Another study was carried out by Leth-Olsen [25], which compared carbon-steel, 13Cr and super 13Cr (S13Cr) in a potassium solution with CO2(g) in the liquid and vapour phases, finding an excellent performance of S13Cr, with an average of 0.01 mm/yr, compared to 13Cr, which had a maximum value of 0.7 mm/yr and 0.3 mm/yr (in the liquid phase]. Furthermore, the values of maximum corrosion were noted when the dummies were exposed in the liquid phase, the rates of corrosion in the vapour phase being 0.2 mm/yr for carbon-steel and 0.05 mm/yr for 13Cr; no corrosion was seen in S13Cr.
In 2008, the erosion-corrosion of 22Cr steel was analysed, compared with that of an X65 pipeline under the same conditions. This experiment was evaluated using sand grains under three special conditions. First, by varying the temperature from 20 to 70 °C at a sand concentration of 200 ppm and a CO2 flow of 20 m/s, a constant corrosion rate of around 5 mm/yr was obtained for 22Cr, while X65 showed an increase from 12.25 to 43.5 mm/yr. Second, the solid particle concentration was varied from 30 to 200 ppm, with a temperature of 20 °C and flow velocity of 20 m/s; although having the same tendency, the corrosion rate for 22Cr increased from 0.1 to 2.4 mm/yr approximately, while for X65, it changed from 9 to 12 mm/yr. The last was the variation of velocity from 7 to 20 m/s, maintaining the temperature at 20 °C and concentration of sand particles at 100 ppm; the corrosion rate in 22Cr increased from 0.2 to 0.8 mm/yr, while for X65, it varied from 2.4 to 5.9 mm/yr approximately [26]. Then, it is important to note that an important parameter is considered in this study, namely, the solid particles.
Xu et al. [7] simulated the 3Cr steel used in the well casing in the Huizhou oilfield, with the same formation water composition to get the effect of CO2 corrosion at different temperatures (45, 65, 85 and 105 °C), measuring every structure in a CO2 environment, comparing the result in terms of temperature and CO2 partial pressure (0.5 and 0.2 MPa). They concluded that by increasing the temperature and pressure, it is possible to gain higher corrosion rates. They observed a corrosion rate of 4.5 mm/yr at CO2 partial pressure of 0.5 MPa and 100 °C; the
highest value obtained at CO2 partial pressure of 0.2 MPa was 1.14 mm/yr at 65 °C and approximately 1 mm/yr at 105 °C.
Group 1 (J-55, K-55, N-80) Cui et al. [27] evaluated the CO2 corrosion at supercritical conditions (80 °C and 8.274 MPa] in J55, N80 and P110, at different water cuts (30, 50, 70, 90 and 100%), obtaining an increase in corrosion rate with higher water cut amount. Furthermore, N80 and J55 showed similar behaviour (7 and 4 mm/yr] and, at the same time, were better than P110 (9 mm/yr). Furthermore, Lin et al. [28] compared the three steels mentioned herein at ion concentrations (g/l) of 19.0 Cl-, 1.14 SO4-, 0.6 HCO3 , 1.05 Mg+, 0.39 Ca2, 11.99 Na+ and 0.12 CO3 . First, the pressures (6.89 and 10.34 MPa) were varied at 90 °C; the following values were obtained for the corrosion rate of N80, P110 and J55 steels: 1.752 mm/yr, 2.403 mm/yr, 1.854 mm/yr, 0.922 mm/yr, 1.054 mm/yr and 1.105 mm/yr, respectively. Furthermore, when the pressure was maintained constant (between 1.38 and 2.07 MPa CO2 partial pressure), the corrosion peak was at 100 °C and, after that, it was lower, the best steels being N80 followed by J55. Some studies have been carried out to compare J-55 and N-80. One on these studies was by Li et al. [29], who analysed the effect of temperature at 5 MPa of partial pressure and varied the partial pressure at 80 °C over a period of 72 h. Furthermore, these two kinds of steel were compared with carbon steel P110: when pressure is varied, the best result was obtained using J55; however, on varying the temperature, sometimes, the best result was obtained using N80.
When this group of steels is talked about, another important steel item referred to is K55. A study was carried out by Elramady [30], in which a piece was subjected in formation water with CO2 at 40 psi (0.276 MPa) at ambient temperature, obtaining a rate varying from 0.4 to 0.74 mm/yr. On the other hand, Pehlke [31] used brine, CO2, H2S and N at 1000 kPa and 170 °C, obtaining a corrosion rate between 0.188 and 0.243 mm/yr for K55 steel. Furthermore, when corrosion by CO2 is studied, there are other acids that can affect the well apart from the carbonic acid. Jingen et al. [32]
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analysed the effect of the ratio of CO2 partial pressure to H2S partial pressure (10, 100, 200 and 400 MPa] in formation water, for N80 steel, at 90 °C and pCO2 equal to 0.4 MPa, having a flow rate of 1.7 m/s; they found that when H2S is not present, the corrosion rate is 1.689 mm/yr, while the ratio is 10; the rate is 0.172 mm/yr, changing to 0.789, 0.621 and 0.511 mm/yr for the subsequent ratios. Additionally, another work studied N80 steel at the same temperature, but at 4 MPa in the present of acetic acid with CO2 in brine. A value of 0.55 mm/yr was obtained in the absence of the acid, but when solid particle concentration was increased to 1000, 3000 and 5000 ppm, the corrosion rate was 1.25, 3.55 and 4.95 mm/yr approximately [33].
Group 2 (L-80, T-95, C-110) In this group, one of the most commonly used steels is L80. One of the studies on L80 was by Choi et al. [34], where the temperature was set at 65 and 90 °C and the CO2 pressures used were 4 MPa (gaseous phase] and 8 and 12 MPa (supercritical phase], in a saline solution of 25% HCl; at 65 °C, the corrosion rate
was 8.7, 9.9 and 11 mm/yr, respectively, while at 90 °C, the corrosion rate was 6.1, 3.4 and 4.8 mm/yr, respectively. A similar study was done by Lopes et al. [35], which analysed the steel at 15 and 30 MPa in brine at 50 °C, obtaining 3.534 mm/yr at 15 MPa after 7 days, but 0.375 mm/yr after 30 days and 2.774 mm/yr at 30 MPa after 7 days.
The corrosion process could be affected by other factors, such as sulphur and water. Qiu et al. [36] studied corrosion at three temperatures -60, 90 and 150 °C - and 0.1 MPa of H2S partial pressure and 0.5 MPa of CO2 partial pressure, varying the sulphur content (2 and 4%] and the water content (30 and 70%]; the results are shown in Table 5. When the chromium composition of this steel is varied, the corrosion rate changes too, and an example of this is the work by da Silva [37], which used three different CO2 partial pressures (0.1, 0.3 and 0.65 MPa] at 20 °C with 2, 3 and 5% of NaCl for 72 h, having 0.82% of Cr in twocoupons of L-80 steel (Table 6].
Two other steels in this group are T95 and C110, which were investigated by Elgadd-afi [38], where they varied the H2S concen-
Table 5: Corrosion rates [36].
T (°C) PH2S (MPa) PCO2 (MPa) Cl- (g/l) S (%) H2O (%) Rate (mm/yr) 60	0.1	0.5	0.13	2	30	1.56
90	0.1	0.5	0.13	2	30	1.06
150	0.1	0.5	0.13	2	30	1.39
60	0.1	0.5	0.13	4	30	1.47
90	0.1	0.5	0.13	4	30	0.78
150	0.1	0.5	0.13	4	30	2.08
60	0.1	0.5	0.13	2	60	1.15
90	0.1	0.5	0.13	2	60	0.94
150	0.1	0.5	0.13	2	60	0.98
60	0.1	0.5	0.13	4	60	1.10
90	0.1	0.5	0.13	4	60	0.68
150	0.1	0.5	0.13	4	60	1.00
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Table 6: Corrosion rates [37]. P (bar)
NaCl (%)
Rate (mm/yr)
CQ1
CQ2
	2	0.56	0.49
1.0	3	0.45	0.52
	5	8.89	0.29
	2	1.29	0.71
3.0	3	1.26	0.80
	5	1.13	0.82
	2	1.66	1.11
6.5	3	1.57	0.96
	5	1.61	0.92
tration (0, 10, 50 and 150 ppm) at 38 °C and 41.37 MPa; for T95, the CO2 corrosion rate was 15, 20, 17 and 17.5 mm/yr, while for C110, the values were 13, 14.5 and 9 mm/yr (there was no test for 150 ppm of H2S).
Groups 3 and 4 (P-110, Q-125)
The last two groups contain only two steels, which are used for deep well casing. Regarding the studies on P110, the first corresponds to analysis at 100 and 160 °C with a pressure of 4 MPa in a brine solution for 120 h, obtaining a marked contrast in corrosion rate, with values of 6.1843 and 0.8754 mm/yr [39]. Similarly, Guan [40] - at 90 °C and 4 MPa - obtained a corrosion rate around 0.8261 mm/yr; at 110 °C with the same pressure, the rate was 0.2489 mm/yr. On the other hand, if the pressure was varied (0.1, 2, 4 and 6 MPa), maintaining the same temperature (100 °C) for 168 h, the results were 0.64, 0.76, 0.91 and 0.83 mm/yr, respectively [41]. The other steel is Q125. This steel was studied in a CO2 environment, in a brine solution simulated from the Jinlin Oil Field at 1 MPa and 30 °C and a flow of 1 m/s having a corrosion rate of 1.012 mm/yr [42]. Furthermore, varying the temperature (30, 60, 90 and 120 °C) and keeping the pressure at 2 MPa, using formation water from an oilfield, the values obtained were 0.9, 2.8, 3.6 and 2.4 mm/yr [43]. Giving continuity to the investigation from Elgadd-afi [38], increasing the H2S concentration, the corrosion rates were approximately 3.2, 9.5, 10 and 10 mm/yr.
Analysis of CO2 Corrosion Studies
In this section, the corrosion rates in different kinds of API steels obtained by different studies are analysed. The principal objective was gathering not only the corrosion rate but also data on the chemical composition of chromium, nickel and molybdenum, pressure, temperature, duration of experiment, the phase of CO2 and the kind of steel. Every detail was collected and summarised in the Appendix.
Dependency of Corrosion Rates on the Test Time
The different values of corrosion rates indicate that corrosion could be dependent on the test time. Hence, these values were plotted against the days on linear (Figure 3) and semi-log (Figure 4) scales to get better information. There is
Corrosion rate along the test time
1
b
a U
									
s									
•• »									
i.									
									
> y									
.•I»1. Ii	•								
0 10 20 30 40 50 60 70 80 90 Days
Figure 3: Corrosion rate against time on a linear scale.
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Figure 4: Corrosion rate against time on a semi-log scale.
a clear tendency versus the time in the graphs;
in Figure 4, four regions were identified:
—	From 0 to 3 days, which could be fast growth in corrosion rate, which could be produced by the formation of FeCO3 film.
—	From 3 to 25 days, in which there is a continuous reduction of the corrosion rate.
—	From 25 to 45 days, stabilisation of the corrosion rates is initiated, with observation of exponentially reducing rates.
—	From 45 days onwards, the rates of corrosion are stabilised; there is a plateau, with
a corrosion rate of 0.008 mm/yr; however, this value is only an approximation.
With the already-identified four zones of the corrosion mechanism, the tendency was modelled, yielding two curves; the first equation shows a slightly better fit in the initial region, and the second equation is the best simplified tendency approximation along time (blue dotted curve).
45
y = 0.0088 + —
3 /2./xntime\ -time-Xo
1 v 0 »e-3- (1): Better curve fit
time
time
y = 0.0088 + 6.8e 4.5
(2): The best simplified curve approximation
Stabilised Corrosion Rates To analyse the long-term corrosion rates, these have to be in their plateau; it means, they have to be stabilised. Therefore, every rate with a test
time below 45 days was stabilised by the mean of the tendency in Eq. (2) (because it is simpler and well fitted). Furthermore, they were separated by the CO2 phase (vapour and supercrit-
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Steel
Figure 5: Stabilised corrosion rates for different kinds of steels in the CO2 vapour phase.
C^ Q^ V^ ^ ^	^ fP ^
Steel
Figure 6: Stabilised corrosion rates for different kinds of steels in the CO2 supercritical phase.
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Table 7: Classification of corrosion rates by steels.		
Category	Steels in CO2 vapour phase	Steels in CO2 supercritical phase
	P110, 13Cr, Q125, 3Cr, N80, J55, 1Cr, K55	P110, N80, J55,13Cr, 22Cr
Low	and	and
	22Cr	20Cr-25Ni
Moderate	-	T95, C110, Q125 and L80
High	L80	-
Figure 7: Effect of chromium content in steels, for each CO phase.
ical). Then, to conclude the results observed in both graphs (Figures 5 and 6), it is necessary to refer to the NACE corrosion category, which defines the corrosion rate as low if the value is <0.025 mm/yr, moderate if it ranges between 0.025 and 0.15 mm/yr and high if the value is from 0.16 to 0.25 mm/yr. Thus, the steels could be classified as in Table 7, and in general, the corrosion rate is lower in the supercritical condition, which is the phase of CO2 when it is injected, and higher in the vapour when it goes through the cement paste.
Effect of Chemical Composition of Steels
Addition of chemicals to form steel alloys permit better response against corrosion, especially when chromium is added (it forms stainless steel] and, furthermore, the quantity of nickel and molybdenum could help to prevent CO2 corrosion. The effect of these elements when they are added to steels was analysed (Figures 7-9]. There is a clear effect of chromium as a corrosion-protective element. Only its presence in steel reduces corrosion significantly, and at a percentage >20%, it presents a plateau but has a very low corrosion rate. When nickel is added, the rate reduces faster, helping the chro-
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15 20 25 30 35 Percentage of Cr + Ni
Figure 8: Effect of chromium and nickel content in steels, for each CO2 phase.
15 20 25 30 35 40 Percentage of Cr + Ni + Mo
Figure 9: Effect of chromium, nickel and molybdenum content in steels, for each CO2 phase.
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Figure 10: Corrosion rate against the pressure.
Figure 11: Corrosion rate versus the temperature.
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mium as a protective element; however, the molybdenum has no significant effect, showing the same tendency as when it is not added. This is in the supercritical condition, because when the vapour phase is observed, the effect is not as high as in the supercritical condition.
Effect of Pressure and Temperature Studying the effect of these two factors is difficult, because the idea is to analyse by varying one of them and maintaining the other one constant; to observe the effect, however, it was decided to graphically represent them as separate parameters (Figures 10 and 11). Then, varying the pressure (>7.38 MPa is supercritical condition), the lowest corrosion rates are found in the supercritical conditions, and as the pressure becomes higher, lower rates are obtained. However, when the temperature is evaluated, it is difficult to get a tendency probably because different values of pressure could be studied at one temperature.
Conclusion
It is known that different factors could affect the corrosion rates. First, the time of tests has to be considered because a test spreading over 3 days should not be used for determining awell's stability in CO2-rich conditions, because, as earlier mentioned, for a warranty of stability for >100 years, the corrosion rates must be the lowest as possible. On the other hand, the wall thickness is a factor to be considered in the front side corrosion rates, because the walls could be as thick as 12 mm to >25 mm. Thus, a corrosion rate of 0.06 mm/yr could corrode half the thickness of a wall of 12 mm in 100 years; hence, warrantying the lowest corrosion rates is extremely important and required.
Alternatively, having a steel with high yield strength, such as C110, T95 or P110, is not a warranty for having good corrosion protection, but the chemical elements can help. Furthermore, ensuring good corrosion protection during the injection of CO2 can have the highest effect on the life of the casing and tubing along the well, because, besides the corrosion, the steel can be affected by erosion due to the flow
of CO2 along the tubing. Additionally, if the well presents good stability along its injection path, the next important section has to be the cement paste stability, which will be the wall between the casing and the stored CO2. Furthermore, the only steel that presented a relatively worse behaviour was L80, but in the vapour phase of CO2. Finally, by ensuring a corrosion rate around 0.01 mm/yr, in 1000 years, it will corrode 10 mm; but for this to happen, the CO2 has to be in contact with the casing. It means an injectivity spanning 1000 years or breaking through the cement paste after storing.
Acknowledgements
First, thanks are due to the Pontifical Catholic University of Rio Grande do Sul (PUCRS] because without the university, this work could not have been completed. Furthermore, we thank CAPES and Petrobras, for the award of scholarships, which let us work at PUCRS.
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RMZ - M&G | 2019 | Vol. 66 | pp. 149-172 Moreno W.E.G., Dias Ponzi G.G., Machado Pereira Henrique A. A., de Oliveira Andrade J.J.
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Appendix
Steel	CO2 phase	P (MPa)	T (°C)	Rate (mm/yr)	Reference	Time (days)	C	Cr	Ni	Mo
3Cr	Vapour	0.2	45	0.45	[7]	7	0.22	2.94	0.3	0.3
3Cr	Vapour	0.2	65	1.03	[7]	7	0.22	2.94	0.3	0.3
3Cr	Vapour	0.2	85	1	[7]	7	0.22	2.94	0.3	0.3
3Cr	Vapour	0.2	105	0.99	[7]	7	0.22	2.94	0.3	0.3
3Cr	Vapour	0.5	40	0.2	[7]	7	0.22	2.94	0.3	0.3
3Cr	Vapour	0.5	60	0.7	[7]	7	0.22	2.94	0.3	0.3
3Cr	Vapour	0.5	80	3.45	[7]	7	0.22	2.94	0.3	0.3
3Cr	Vapour	0.5	100	4.5	[7]	7	0.22	2.94	0.3	0.3
13Cr	Vapour	3	180	1.71	[24]	7	0.025	13		
13Cr	Vapour	3	180	0.225	[24]	7	0.025	13	4	1
13Cr	Vapour	3	180	0.18	[24]	7	0.025	13	4	2
13Cr	Vapour	3	180	0.23	[24]	7	0.025	13	5	1
13Cr	Vapour	3	180	0.15	[24]	7	0.025	13	5	2
13Cr	Vapour	3	180	0.26	[24]	7	0.025	13	4	1
13Cr	Vapour	3	180	0.18	[24]	7	0.025	13	4	2
13Cr	Vapour	1.14	130	0.05	[25]	49	0.02	13	0.4	0.09
13Cr	Vapour	1.14	130	0.005	[25]	49	0.02	12.24	5.73	2.1
J55	Supercritical	8.274	80	0.5	[27]	4	0.19	0.19	0.017	0.092
J55	Supercritical	8.274	80	0.9	[27]	4	0.19	0.19	0.017	0.092
J55	Supercritical	8.274	80	7	[27]	4	0.19	0.19	0.017	0.092
J55	Supercritical	8.274	80	10.5	[27]	4	0.19	0.19	0.017	0.092
J55	Supercritical	8.274	80	12.2	[27]	4	0.19	0.19	0.017	0.092
N80	Supercritical	8.274	80	0.7	[27]	4	0.24	0.036	0.028	0.021
N80	Supercritical	8.274	80	1	[27]	4	0.24	0.036	0.028	0.021
N80	Supercritical	8.274	80	7.2	[27]	4	0.24	0.036	0.028	0.021
N80	Supercritical	8.274	80	11	[27]	4	0.24	0.036	0.028	0.021
N80	Supercritical	8.274	80	12.8	[27]	4	0.24	0.036	0.028	0.021
P110 Supercritical		8.274	80	1	[27]	4	0.26	0.15	0.012	0.01
P110 Supercritical		8.274	80	1.7	[27]	4	0.26	0.15	0.012	0.01
P110 Supercritical		8.274	80	10	[27]	4	0.26	0.15	0.012	0.01
P110 Supercritical		8.274	80	11.2	[27]	4	0.26	0.15	0.012	0.01
P110 Supercritical		8.274	80	14.4	[27]	4	0.26	0.15	0.012	0.01
J55	Vapour	6.89	90	1.854	[28]	4	0.19	0.19	0.017	0.092
J55	Vapour	1.725	80	0.827	[28]	4	0.19	0.19	0.017	0.092
J55	Vapour	1.725	100	0.949	[28]	4	0.19	0.19	0.017	0.092
J55	Vapour	1.725	120	0.894	[28]	4	0.19	0.19	0.017	0.092
J55	Vapour	1.725	140	0.275	[28]	4	0.19	0.19	0.017	0.092
J55	Vapour	1.725	160	0.64	[28]	4	0.19	0.19	0.017	0.092
J55	Vapour	1.725	180	0.351	[28]	4	0.19	0.19	0.017	0.092
J55	Vapour	1.725	200	0.636	[28]	4	0.19	0.19	0.017	0.092
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J55	Supercritical	10.34	90	1.105	[28]	4	0.19	0.19	0.017	0.092
N80	Vapour	6.89	90	1.752	[28]	4	0.24	0.036	0.028	0.021
N80	Vapour	1.725	80	0.681	[28]	4	0.24	0.036	0.028	0.021
N80	Vapour	1.725	100	1.053	[28]	4	0.24	0.036	0.028	0.021
N80	Vapour	1.725	120	0.814	[28]	4	0.24	0.036	0.028	0.021
N80	Vapour	1.725	140	0.272	[28]	4	0.24	0.036	0.028	0.021
N80	Vapour	1.725	160	0.191	[28]	4	0.24	0.036	0.028	0.021
N80	Vapour	1.725	200	0.322	[28]	4	0.24	0.036	0.028	0.021
N80	Vapour	1.725	180	0.204	[28]	4	0.24	0.036	0.028	0.021
N80	Supercritical	10.34	90	0.922	[28]	4	0.24	0.036	0.028	0.021
P110	Vapour	6.89	90	2.403	[28]	4	0.26	0.15	0.012	0.01
P110	Vapour	1.725	80	0.948	[28]	4	0.26	0.15	0.012	0.01
P110	Vapour	1.725	100	1.609	[28]	4	0.26	0.15	0.012	0.01
P110	Vapour	1.725	120	0.862	[28]	4	0.26	0.15	0.012	0.01
P110	Vapour	1.725	140	0.41	[28]	4	0.26	0.15	0.012	0.01
P110	Vapour	1.725	160	0.353	[28]	4	0.26	0.15	0.012	0.01
P110	Vapour	1.725	180	0.422	[28]	4	0.26	0.15	0.012	0.01
P110	Vapour	1.725	200	0.95	[28]	4	0.26	0.15	0.012	0.01
P110 Supercritical		10.34	90	0.922	[28]	4	0.26	0.15	0.012	0.01
J55	Vapour	5	20	0.7	[29]	3	0.19	0.049	0.026	0.007
J55	Vapour	5	40	6	[29]	3	0.19	0.049	0.026	0.007
J55	Vapour	5	60	8	[29]	3	0.19	0.049	0.026	0.007
J55	Vapour	5	80	3.9	[29]	3	0.19	0.049	0.026	0.007
J55	Vapour	5	100	0.85	[29]	3	0.19	0.049	0.026	0.007
J55	Vapour	2	80	0.1	[29]	3	0.19	0.049	0.026	0.007
J55	Supercritical	8	80	5.2	[29]	3	0.19	0.049	0.026	0.007
J55	Supercritical	10	80	7.2	[29]	3	0.19	0.049	0.026	0.007
J55	Supercritical	12	80	6.2	[29]	3	0.19	0.049	0.026	0.007
N80	Vapour	5	20	0.7	[29]	3	0.24	0.22	0.028	0.018
N80	Vapour	5	40	5	[29]	3	0.24	0.22	0.028	0.018
N80	Vapour	5	60	9	[29]	3	0.24	0.22	0.028	0.018
N80	Vapour	5	80	3.1	[29]	3	0.24	0.22	0.028	0.018
N80	Vapour	5	100	2	[29]	3	0.24	0.22	0.028	0.018
N80	Vapour	2	80	0.1	[29]	3	0.24	0.22	0.028	0.018
N80	Supercritical	8	80	5.2	[29]	3	0.24	0.22	0.028	0.018
N80	Supercritical	10	80	7.2	[29]	3	0.24	0.22	0.028	0.018
N80	Supercritical	12	80	6.2	[29]	3	0.24	0.22	0.028	0.018
P110	Vapour	5	20	0.8	[29]	3	0.265	0.958	0.042	0.35
P110	Vapour	5	40	5	[29]	3	0.265	0.958	0.042	0.35
P110	Vapour	5	60	10	[29]	3	0.265	0.958	0.042	0.35
P110	Vapour	5	80	4.5	[29]	3	0.265	0.958	0.042	0.35
P110	Vapour	5	100	1.3	[29]	3	0.265	0.958	0.042	0.35
P110	Vapour	2	80	0.2	[29]	3	0.265	0.958	0.042	0.35
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P110	Vapour	8	80	5.7	[29]	3	0.265	0.958	0.042	0.35
P110	Vapour	10	80	7.75	[29]	3	0.265	0.958	0.042	0.35
P110	Vapour	12	80	6.4	[29]	3	0.265	0.958	0.042	0.35
P110 Supercritical		8	80	5.7	[29]	3	0.265	0.958	0.042	0.35
P110 Supercritical		10	80	7.75	[29]	3	0.265	0.958	0.042	0.35
P110 Supercritical		12	80	6.4	[29]	3	0.265	0.958	0.042	0.35
K55	Vapour	1	170	0.29	[31]	7				
N80	Vapour	0.4	90	1.689	[32]	3	0.24	0.036	0.028	0.021
N80	Vapour	0.4	90	0.172	[32]	3	0.24	0.036	0.028	0.021
N80	Vapour	0.4	90	0.789	[32]	3	0.24	0.036	0.028	0.021
N80	Vapour	0.4	90	0.621	[32]	3	0.24	0.036	0.028	0.021
N80	Vapour	0.4	90	0.511	[32]	3	0.24	0.036	0.028	0.021
N80	Vapour	4	90	0.55	[36]	5	0.42	0.051	0.005	0.18
N80	Vapour	4	90	1.25	[36]	5	0.42	0.051	0.005	0.18
N80	Vapour	4	90	3.55	[36]	5	0.42	0.051	0.005	0.18
N80	Vapour	4	90	4.95	[36]	5	0.42	0.051	0.005	0.18
L80	Vapour	4	65	8.5	[34]	2	0.3	0.85		
L80	Supercritical	8	65	9.9	[34]	2	0.3	0.85		
L80	Supercritical	12	65	11	[34]	2	0.3	0.85		
L80	Vapour	4	90	6.1	[34]	2	0.3	0.85		
L80	Supercritical	8	90	3.4	[34]	2	0.3	0.85		
L80	Supercritical	12	90	4.8	[34]	2	0.3	0.85		
L80	Supercritical	15	50	0.375	[35]	30	0.315	0.04	0.01	0.11
L80	Supercritical	15	50	3.534	[35]	7	0.315	0.04	0.01	0.11
L80	Supercritical	30	50	2.774	[35]	7	0.315	0.04	0.01	0.11
L80	Vapour	0.5	60	1.5568	[36]	30	0.22	1.2	0.5	
L80	Vapour	0.5	90	1.0627	[36]	30	0.22	1.2	0.5	
L80	Vapour	0.5	150	1.3941	[36]	30	0.22	1.2	0.5	
L80	Vapour	0.5	60	1.467	[36]	30	0.22	1.2	0.5	
L80	Vapour	0.5	90	0.7794	[36]	30	0.22	1.2	0.5	
L80	Vapour	0.5	150	2.0835	[36]	30	0.22	1.2	0.5	
L80	Vapour	0.5	60	1.1466	[36]	30	0.22	1.2	0.5	
L80	Vapour	0.5	90	0.9401	[36]	30	0.22	1.2	0.5	
L80	Vapour	0.5	150	0.9807	[36]	30	0.22	1.2	0.5	
L80	Vapour	0.5	60	1.0967	[36]	30	0.22	1.2	0.5	
L80	Vapour	0.5	90	0.6833	[36]	30	0.22	1.2	0.5	
L80	Vapour	0.5	150	1.0032	[36]	30	0.22	1.2	0.5	
L80	Vapour	0.1	20	0.56	[37]	3	0.17	0.81	0.014	0.003
L80	Vapour	0.1	20	0.49	[37]	3	0.21	0.82	0.015	0.031
L80	Vapour	0.1	20	0.45	[37]	3	0.17	0.81	0.014	0.003
L80	Vapour	0.1	20	0.52	[37]	3	0.21	0.82	0.015	0.031
L80	Vapour	0.1	20	0.89	[37]	3	0.17	0.81	0.014	0.003
L80	Vapour	0.1	20	0.29	[37]	3	0.21	0.82	0.015	0.031
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L80	Vapour	0.3	20	1.29	[37]	3	0.17	0.81	0.014	0.003
L80	Vapour	0.3	20	0.71	[37]	3	0.21	0.82	0.015	0.031
L80	Vapour	0.3	20	1.26	[37]	3	0.17	0.81	0.014	0.003
L80	Vapour	0.3	20	0.8	[37]	3	0.21	0.82	0.015	0.031
L80	Vapour	0.3	20	1.13	[37]	3	0.17	0.81	0.014	0.003
L80	Vapour	0.3	20	0.82	[37]	3	0.21	0.82	0.015	0.031
T95	Supercritical	41.37	38	15	[38]	7	0.33	1.01	0.03	0.79
T95	Supercritical	41.37	38	20	[38]	7	0.33	1.01	0.03	0.79
T95	Supercritical	41.37	38	17	[38]	7	0.33	1.01	0.03	0.79
T95	Supercritical	41.37	38	17.5	[38]	7	0.33	1.01	0.03	0.79
Q125 Supercritical		41.37	38	3.2	[38]	7	0.26	0.91	0.04	0.26
Q125 Supercritical		41.37	38	9.5	[38]	7	0.26	0.91	0.04	0.26
Q125 Supercritical		41.37	38	10	[38]	7	0.26	0.91	0.04	0.26
Q125 Supercritical		41.37	38	10	[38]	7	0.26	0.91	0.04	0.26
C110 Supercritical		41.37	38	13	[38]	7	0.3	1.01	0.01	0.78
C110 Supercritical		41.37	38	14.5	[38]	7	0.3	1.01	0.01	0.78
C110 Supercritical		41.37	38	9	[38]	7	0.3	1.01	0.01	0.78
P110	Vapour	4	100	6.1843	[39]	5	0.19		0.028	0.028
P110	Vapour	4	160	0.8754	[39]	5	0.19		0.028	0.028
P110	Vapour	4	90	0.9394	[40]	3				
P110	Vapour	4	110	0.4491	[40]	3				
P110	Vapour	0.1	100	0.64	[41]	7	0.26		0.028	0.028
P110	Vapour	2	100	0.76	[41]	7	0.26		0.028	0.028
P110	Vapour	4	100	0.91	[41]	7	0.26		0.028	0.028
P110	Vapour	6	100	0.83	[41]	7	0.26		0.028	0.028
Q125	Vapour	1	30	1.012	[42]	7	0.2	1.03	0.2	0.3
Q125	Vapour	2	30	0.9	[43]	7	0.15	0.46	0.2	0.15
Q125	Vapour	2	60	2.8	[43]	7	0.15	0.46	0.2	0.15
Q125	Vapour	2	90	3.6	[43]	7	0.15	0.46	0.2	0.15
Q125	Vapour	2	120	2.4	[43]	7	0.15	0.46	0.2	0.15
20Cr-25Ni	Supercritical	9.5	50	0.0003	[44]	4	0.02	20	25	4.5
20Cr-25Ni	Supercritical	13	80	0.001	[44]	4	0.02	20	25	4.5
20Cr-25Ni	Supercritical	16	110	0.0001	[44]	4	0.02	20	25	4.5
20Cr-25Ni	Supercritical	18.2	130	0.00005	[44]	4	0.02	20	25	4.5
20Cr-25Ni	Supercritical	9.5	50	0.00006	[44]	4	0.02	20	25	4.5
20Cr-25Ni	Supercritical	13.5	80	0.00009	[44]	4	0.02	20	25	4.5
20Cr-25Ni	Supercritical	17	110	0.00011	[44]	4	0.02	20	25	4.5
20Cr-25Ni	Supercritical	21.5	130	0.00005	[44]	4	0.02	20	25	4.5
13Cr Supercritical		9.5	50	0.003	[44]	4	0.195	13		
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13Cr Supercritical		13	80	0.0038	[44]	4	0.195	13		
13Cr Supercritical		16	110	0.009	[44]	4	0.195	13		
13Cr Supercritical		18.2	130	0.003	[44]	4	0.195	13		
13Cr	Supercritical	9.5	50	0.00033	[44]	4	0.195	13		
13Cr	Supercritical	13.5	80	0.0006	[44]	4	0.195	13		
13Cr	Supercritical	17	110	0.0008	[44]	4	0.195	13		
13Cr	Supercritical	21.5	130	0.0004	[44]	4	0.195	13		
22Cr	Supercritical	9.5	50	0.0007	[44]	4	0.03	22	5	3
22Cr Supercritical		13	80	0.0008	[44]	4	0.03	22	5	3
22Cr Supercritical		16	110	0.0004	[44]	4	0.03	22	5	3
22Cr Supercritical		18.2	130	0.0001	[44]	4	0.03	22	5	3
22Cr Supercritical		9.5	50	0.00006	[44]	4	0.03	22	5	3
22Cr Supercritical		13.5	80	0.0001	[44]	4	0.03	22	5	3
22Cr Supercritical		17	110	0.00014	[44]	4	0.03	22	5	3
22Cr Supercritical		21.5	130	0.00006	[44]	4	0.03	22	5	3
13Cr	Vapour	0.1	60	0.002	[45]	29.167	0.46	13.39	0.13	0.03
13Cr	Vapour	6	60	0.0002	[45]	29.167	0.46	13.39	0.13	0.03
1Cr	Vapour	0.1	60	0.0059	[45]	29.167	0.43	1.05	0.04	0.22
1Cr	Vapour	6	60	0.0015	[45]	29.167	0.43	1.05	0.04	0.22
13Cr	Vapour	0.2	50	0.1	[46]	90	0.029	12.78	5.12	2.23
22Cr	Vapour	0.2	50	0.01	[46]	90	0.23	22.91	5.65	3.21
P110	Vapour	0.2	50	0.18	[46]	90	0.25	1.06	0.025	0.65
J55	Supercritical	9.5	70	0.1	[47]	12.5				
J55	Supercritical	9.5	70	0.1	[47]	12.5				
N80	Supercritical	9.5	70	0.1	[47]	12.5				
N80	Supercritical	9.5	70	0.1	[47]	12.5				
J55	Supercritical	9.5	70	2	[47]	4.67				
J55	Supercritical	9.5	70	0.2	[47]	4.67				
N80	Supercritical	9.5	70	1.15	[47]	4.67				
N80	Supercritical	9.5	70	0.2	[47]	4.67				
J55 Vapour 0.5 65	3.3	[48]	2 0.36 0.051 0.009
J55 Vapour	1	65	6.7	[48]	2	0.36	0.051	0.009
J55 Vapour	1.5	65	5.9	[48]	2	0.36	0.051	0.009
J55 Vapour	2.5	65	4.7	[48]	2	0.36	0.051	0.009
J55 Vapour	3	65	3.5	[48]	2	0.36	0.051	0.009
J55 Vapour	5	65	3.95	[48]	2	0.36	0.051	0.009
J55 Vapour	7	65	5.2	[48]	2	0.36	0.051	0.009
J55	Supercritical	9	65	5.2	[48]	2	0.36	0.051	0.009
J55	Supercritical	11	65	5.2	[48]	2	0.36	0.051	0.009
J55	Supercritical	13	65	5.2	[48]	2	0.36	0.051	0.009
J55	Supercritical	15	65	5.2	[48]	2	0.36	0.051	0.009
J55 Vapour	5	30	0.09	[49]	3	0.38	0.09
J55 Vapour	5	48	0.088	[49]	3	0.38	0.09
Review of Studies on Corrosion of Steel by CO2, Focussed on the Behaviour of API Steel in Geological CO2 Storage Environment
172
J55	Vapour	5	55	0.13	[49]	3	0.38	0.09		
J55	Vapour	5	65	0.148	[49]	3	0.38	0.09		
N80	Vapour	0.5	50	6.5	[50]	2	0.33	0.013	0.026	0.016
N80	Vapour	1	50	9.5	[50]	2	0.33	0.013	0.026	0.016
N80	Vapour	2	50	12	[50]	2	0.33	0.013	0.026	0.016
N80	Vapour	3	50	9.5	[50]	2	0.33	0.013	0.026	0.016
N80	Vapour	4	50	9	[50]	2	0.33	0.013	0.026	0.016
N80	Vapour	5	50	3.8	[50]	2	0.33	0.013	0.026	0.016
N80	Supercritical	10	50	1.8	[50]	2	0.33	0.013	0.026	0.016
N80	Supercritical	10	65	8.4	[50]	2	0.33	0.013	0.026	0.016
N80	Supercritical	10	80	11.8	[50]	2	0.33	0.013	0.026	0.016
N80	Vapour	0.15	100	0.75	[51]	3	0.26	0.148	0.028	0.028
N80	Vapour	0.6	100	1.15	[51]	3	0.26	0.148	0.028	0.028
N80	Vapour	1	100	2.25	[51]	3	0.26	0.148	0.028	0.028
N80	Vapour	4	100	7.2	[51]	3	0.26	0.148	0.028	0.028
N80	Vapour	0.1	80	4.65	[52]	3	0.19	0.55		0.14
3Cr	Vapour	0.1	80	2.9	[52]	3	0.1	3.75		0.25
3Cr	Vapour	0.1	80	3.25	[52]	3	0.11	3.3		0.21
N80	Vapour	8	45	0.056	[53]	32	0.29	0.24	0.08	0.09
L80	Vapour	1	25	0.2334	[54]	2	0.22	0.013		
L80	Vapour	4	25	0.3905	[54]	2	0.22	0.013		
L80	Vapour	6	25	0.4044	[54]	2	0.22	0.013		
L80	Vapour	1	25	0.254	[54]	2	0.22	0.013		
L80	Vapour	4	25	0.347	[54]	2	0.22	0.013		
L80	Vapour	6	25	0.4681	[54]	2	0.22	0.013		
L80	Vapour	0.1	80	0.13	[55]	5	0.43		0.25	
L80	Vapour	0.1	80	0.13	[55]	5	0.43	0.95	0.25	
L80	Vapour	0.1	80	0.3	[55]	5	0.11	3.4	0.15	0.6
C110 Supercritical		10.8	120	0.55	[56]	7	0.27		0.04	0.72
P110	Vapour	5	90	1.12	[57]	15	0.25	0.15	0.032	0.27
P110	Vapour	5	90	1.08	[57]	15	0.26	2.99	0.043	0.19
P110	Vapour	5	90	1.57	[57]	15	0.25	5.11	0.041	0.21
P110	Vapour	0.5	120	0.03	[58]	1	0.26			0.01
P110	Vapour	1.5	120	2.23	[58]	1	0.26			0.01
P110	Vapour	3	120	1.1	[58]	1	0.26			0.01
N80	Vapour	0.5	120	0.03	[58]	1	0.24			0.021
N80	Vapour	1.5	120	1.5	[58]	1	0.24			0.021
P110	Vapour	0.1	90	4.2	[59]	5	0.22	0.18	0.01	0.03
RMZ - M&G | 2019 | Vol. 66 | pp. 149-172 Moreno W.E.G., Dias Ponzi G.G., Machado Pereira Henrique A. A., de Oliveira Andrade J.J.
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Original scientific paper	Received: Nov 14, 2019
Accepted: Dec 09, 2019 DOI: 10.2478/rmzmag-2019-0036
Petrochemistry and petrogenesis of the Precambrian Basement Complex rocks around Akungba-Akoko, southwestern Nigeria
Petrokemija in petrogeneza predkambrijskih kamnin podlage na obmocju Akungba-Akoko, JZ Nigerij
Abimbola Chris Ogunyele*, Oladotun Afolabi Oluwajana, Iyanuoluwa Queen Ehinola, Blessing Ene Ameh, Toheeb Akande Salaudeen
Department of Earth Sciences, Adekunle Ajasin University, PMB 001 Akungba-Akoko, Ondo State, Nigeria * abimbola.ogunyele@aaua.edu.ng
Abstract
Field, mineralogical and petrochemical studies of the Precambrian Basement Complex rocks around Akung-ba-Akoko were carried out with the aim of determining their petrology, petrochemical characteristics and petrogenesis. The petrology of Akungba-Akoko area comprises migmatite, granite gneiss and biotite gneiss intruded by biotite granite, charnockite and minor fel-sic and basic rocks. Seventeen representative samples of the granite gneiss, biotite gneiss, biotite granite and charnockite were collected during field geological mapping of the area for petrographic and geochemical analyses. Modal mineralogy revealed that the granite gneiss, biotite gneiss and granite have assemblages of quartz + feldspar + mica + hornblende + opaques and are granitic in composition. The charnockite is characterized by anhydrous mineral assemblage of quartz + feldspar + biotite + hornblende + pyroxene + opaques. Petrochemical data of the rocks revealed that they are moderately to highly enrich in SiO2, sub-alkaline, per-aluminous, magnesian to ferroan and calcic and have K/Rb < 283. The geochemical characteristics and discrimination of the rocks indicated that the granite gneiss and biotite gneiss are orthogneisses formed by metamorphism of igneous protoliths of granitic composition and the biotite granite and charnockite are of igneous/magmatic origin. The biotite granite, charnockite and the igneous protoliths of the biotite gneiss are I-type granitoids formed from crustal igne-ous-sourced melt(s), while the igneous protoliths of the granite gneiss is a S-type granitoid probably derived
Povzetek
Z namenom določitve petrologije, petrokemičnih značilnosti in petrogeneze so bile na območju Akungba-Akoko izvedene terenske, mineraloške in petrokemične raziskave predkambrijskih kamnin podlage. Petrologijo območja Akungba-Akoko sestavljajo migmatit, granitni gnajs in biotitni gnajs, intrudirani z biotitnim granitom, charnokitom in manjšimi felsičnimi in bazičnimi kamninami. Med terenskim geološkim kartiranjem območja je bilo zbranih sedemnajst reprezentativnih vzorcev granitnega gnajsa, biotitnega gnajsa, biotitnega granita in charnokita za petrografske in geokemične analize. Modalne mineraloške preiskave so pokazale da granitni gnajs, biotitni gnajs in granit vsebujejo kremen + glinence + sljudo + rogovačo + neprozorne minerale in so granitni v kompoziciji. Charnokit je karakteriziran kot nehidriran mineral sestavljen iz kremena + glinavca + biotita + rogovače + piroksena + neprozornega minerala. Petrokemični podatki kamnin kažejo, da so srednje do visoko bogate z SiO2, sub-alkalne, peraluminaste, magnezijske do železove, kalcijske in imajo razmerje K/Rb < 283. Geokemične karakteristike in diskriminacije kamnin kažejo, da so granitni gnajsi in biotitni gnajsi ortognajsi, nastali s preobrazbo magmatskih protolitov granitne kompozicije in da so biotitni graniti in charnokiti magmatskega nastanka. Biotitni granit, charnokit in magmatski protoliti biotitnih gnajsov so granitoidi I-tipa, nastali s taljenjem skorje, medtem ko so magmatski protoliti granitnih gnajsov granitoidi S-tipa, verjetno nastali iz taljenja plitve skorje ali sedi-mentov. Tektonska diskriminacija kamnin prikazuje, da
9 Open Access. © 2019 Ogunyele A.C., Oluwajana O.A., Ehinola I.Q., Ameh B.E., Salaudeen T.A., published by Sciendo. |feciThis work is licensed under the Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 License.
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from shallow crustal or sedimentary-sourced melt(s). Tectonic discrimination of the rocks indicated that they were formed during a phase of magmatic activity related to collision and subduction.
Keywords: granitoids, mineralogy, orthogneisses, pe-trogenesis, petrochemistry
so nastale med stopnjo vulkanske aktivnosti povezane s trkom in subdukcijo.
Ključne besede: granitoidi, mineralogija, ortognajsi, petrogeneza, petrokemija
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Ogunyele A.C., Oluwajana O.A., Ehinola I.Q., Ameh B.E., Salaudeen T.A.
175
Introduction
The Precambrian Basement Complex rocks of Akungba-Akoko area form a part of the southwestern Nigerian Basement Complex (Figure 1]. The Nigerian Basement Complex lies within the reactivated Pan-African mobile belt extending between the West African Craton in the west and the Congo Craton in the southeast [1, 2]. It comprises three major lithological units: the Migmatite-Gneiss Complex, the Schist Belts and the Older Granites, which intrude the former two units [3].
The petrology, mineralogy, geochemical characteristics, structure, petrogenesis (origin] and other features of the Basement Complex
rocks of Nigeria, particularly the Schist Belts, have been studied to considerable details by several researchers [4-10]. However, there are still more work to be done, particularly on the Migmatite-Gneiss Complex and the Pan-African granitoids (Older Granite suite and charnockitic rocks], in order to determine their petrogenesis (origin] and possible evolutionary models, tectonics, ages and correlation with similar rock groups in other parts of the world [1, 11, 12]. In view of the above, this paper presents field, mineralogical and petrochemical data of the Migmatite-Gneiss Complex rocks and granitoids around Akungba-Akoko and discusses their petrology, mineralogy and petrochemical characteristics and petrogenesis.
Figure 1: (a) Regional geological map of Nigeria within the Pan-African mobile belt between the West African and Congo Cratons and (b) outline geological map of Nigeria showing Akungba-Akoko in the southwestern Nigerian Basement Complex (modified after [3]).
Methods
Geological mapping of Akungba-Akoko area on a scale of 1:20,000 was carried out to determine the rock types occurring in the area and their structural relationships. Seventeen fresh representative rock samples comprising five granite gneiss, four biotite gneiss, four biotite
granite and four charnockite were collected for petrographic and geochemical analyses. Thin sections of seven samples were prepared and studied, and modal compositions were determined using a transmitted light microscope at the Department of Geology, University of Ibadan, Nigeria. Major and trace element geo-chemical analyses of ten rock samples were
Petrochemistry and petrogenesis of the Precambrian Basement Complex rocks around Akungba-Akoko, southwestern Nigeria
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carried out using the Energy Dispersive X-Ray Fluorescence (ED-XRF) machine (PANalytical model] at the National Geosciences Research Laboratory, Kaduna, Nigeria. The samples were crushed and pulverised to <63 |im. About 15 g of the pulverised samples were used to make glass beads and pressed pellets, which were slotted into the computerised ED-XRF spectrometer for major and trace elemental analyses, respectively. The laboratory results were interpreted using discrimination diagrams to determine their petrochemical characteristics and petrogenesis.
Results and Discussion
Petrology and Mineralogy
The petrology of Akungba-Akoko area comprises mainly Migmatite-Gneiss Complex rocks intruded by Pan-African granitoids (Figure 2]. The Migmatite-Gneiss Complex rocks occurring in the area are migmatite, granite gneiss and bi-otite gneiss. Granite gneiss is the predominant rock type covering more than 85% of the area. The granite gneiss is intruded by biotite granite, which trends NE-SW from the central to the northeastern end of the area. In the north-central part of the area, a core of charnockite and
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Figure 2: Geological map and schematic cross-section of Akungba-Akoko area, southwestern Nigeria.
an enclave (large xenolith] of biotite gneiss occur within the granite gneiss. This lithologic association suggests that the charnockite is intrusive into the granite gneiss; hence, it is younger than the latter and the biotite gneiss is proba-
bly older than the granite gneiss. Field photographs and modal compositions of the various lithologies are shown in Figure 3 and Table 1, respectively.
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Figure 3: Field photographs showing (a) granite gneiss intruded by pegmatites (folded and faulted), (b) folded biotite gneiss, (c) biotite granite containing massive melanocratic segregations and (d) boulders of charnockite in Akungba-Akoko.
Table 1: Average modal mineralogical compositions of Akungba-Akoko Basement Complex rocks.
Minerals (vol.%)	GGN1b	GGN2b	BGN1b	BGN2b	BG1b	BG2b	Ch1b
Quartz	29.40	26.60	26.40	26.40	25.30	21.40	22.30
K-feldspar	28.60	23.30	21.60	23.40	22.30	18.00	18.30
Plagioclase feldspar	34.50	35.20	31.00	33.20	32.00	28.30	32.30
Biotite	6.10	8.40	10.10	10.20	14.90	25.40	8.40
Hornblende	-	3.30	8.50	5.10	3.20	5.10	6.00
Muscovite	0.90	2.50	1.40	1.20	2.00	1.00	5.30
Opaque	0.60	0.70	0.90	0.60	0.80	0.90	0.40
Pyroxene	-	-	-	-	-	-	7.70
Total	100.10	100.00	99.90	100.10	100.50	100.10	100.70
GGN - granite gneiss, BGN - biotite gneiss, BG - biotite granite, Ch - charnockite.
The granite gneiss of Akungba-Akoko area (Figure 3a] is weakly to moderately foliated, light grey and medium to coarse grained with a megacrystic (blastoporphyritic to porphy-roblastic] fabric. It is composed of alternating bands of light- and dark-coloured minerals,
most of which are folded. The light-coloured bands are quartz and feldspar rich, while the dark-coloured bands are rich in biotite, hornblende and other ferromagnesian minerals. Quartz and feldspar are the porphyroblasts in the gneiss, and they often have an augen
Petrochemistry and petrogenesis of the Precambrian Basement Complex rocks around Akungba-Akoko, southwestern Nigeria
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Figure 4: QAP diagrams for classifying (a) the gneisses and biotite granite (after [14]) and (b) charnockite (after [15]) of Akungba-Akoko.
(eye-like) shape. The granite gneiss, in some locations, contains garnets and quartzitic inclusions. The rock mainly trends WNW-ESE to ENE-WSW with moderate to steep dips to the south. Pegmatites, vein quartz, quartz lenses, basic dykes and sills are abundant in the granite gneiss, sometimes giving the gneiss a migmatit-ic appearance.
Biotite gneiss occurs in the northern part of the area forming mountains/ridges, which extends northwards to Ikare-Akoko area and beyond. [5, 13] referred to this rock as grey gneiss. The rock is composed essentially of quartz, feldspar and biotite (Table 1) and is dark grey, medium grained and strongly foliated with thin alternating bands of light- and dark-coloured minerals (Figure 3b). A ridge of migmatite composed of granite gneiss, biotite gneiss, granite, aplite, pegmatite and vein quartz extends from the southwestern part of Akungba to Supare-Akoko area in the ENE-WSW direction. The rock is highly deformed with the component rocks being intricately mixed and folded. Ptygmatic folds, faults and joints trending in different directions are abundant in this rock. The biotite granite intruding granite gneiss in Akungba-Akoko is very rich in biotite and hornblende giving it a very dark colour. The granite
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is medium to coarse grained; rich in quartz, feldspar, biotite and hornblende (Table 1) and contains massive melanocratic segregations of biotite, hornblende and iron (Figure 3c). The coarse-grained, dark-coloured charnockite (Figure 3d) with a shining appearance occurring in the granite gneiss is pyroxene-bearing (Table 1) and rich in quartz, feldspar, bio-tite and muscovite. The charnockite occurs as boulders, some of which are weathered. Minor rocks occurring in the area include pegmatite, vein quartz, aplite, and basic dykes and sills are often found as intrusives within the gneisses and migmatite. The QAP diagrams of [14, 15] revealed that the granite gneiss, biotite gneiss and biotite granite are granitic in composition (Figure 4a) and the charnockite is a true char-nockite (Figure 4b).
Petrochemistry and Petrogenesis
Petrochemical data of the basement rocks around Akungba-Akoko (Tables 2 and 3) revealed that the rocks have moderate to high SiO2 contents: granite gneiss (73.86-74.58 wt.%), biotite gneiss (67.80-73.62 wt.%), biotite granite (59.83-60.06 wt.%) and charnockite (57.50-59.70 wt.%). Based on silica contents, the gneisses are classified as acidic rocks, while
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Table 2: Major element compositions (in wt.%) of the Basement Complex rocks of Akungba-Akoko.
Major	Granite gneiss	Biotite gneiss Biotite granite	Charnockite
oxides	GGN1	GGN2	GGN3	BGN1	BGN2	BG1	BG2	Ch1	Ch2	Ch3
SiO2	74.40	73.86	74.58	73.62	67.80	60.06	59.83	57.50	58.72	59.70
TiO2	0.18	0.23	0.32	0.50	0.69	1.00	1.03	1.09	0.98	0.88
Al2O3	13.40	13.84	13.52	12.60	14.63	16.77	17.04	17.90	16.78	15.20
F®2°3	3.26	3.83	3.68	3.58	5.33	6.66	6.68	6.70	6.68	6.73
MnO	0.03	0.06	0.04	0.05	0.04	0.13	0.15	0.25	0.26	0.13
MgO	0.27	0.32	0.21	0.76	1.00	3.02	2.92	2.41	3.02	3.11
CaO	3.00	2.89	2.04	3.01	4.18	5.54	6.05	7.11	6.93	7.02
Na2O	2.01	1.75	1.80	1.62	2.06	0.84	0.67	0.86	0.72	0.70
«2°	2.40	2.59	3.00	3.63	2.54	2.29	2.39	2.35	2.37	3.03
P2O5	ND	ND	ND	ND	ND	ND	ND	0.01	ND	0.01
LOI	0.51	0.58	0.71	0.90	1.40	3.25	3.03	2.86	3.15	2.45
TOTAL	99.46	99.95	99.90	100.27	99.67	99.56	99.79	99.04	99.61	98.96
GGN - granite gneiss, BGN		- biotite gneiss, BG - biotite granite, Ch - charnockite.								
Table 3: Trace element compositions (in ppm) of the Basement Complex rocks of Akungba-Akoko.										
Trace	Granite gneiss			Biotite gneiss		Biotite granite		Charnockite		
elements	GGN1	GGN2	GGN3	BGN1	BGN2	BG1	BG2	Ch1	Ch2	Ch3
Ba	300	470	310	510	240	580	684	815	722	814
Co	5	6	4.9	3	1	3	4	3.8	4	2
Cr	0.38	0.3	0.28	0.2	0.27	1	2	2	2	1
Nb	7	5	4	2	2	1	2	3	3	2
Ni	8	7	6	3	12	6	9	7	5	4
Rb	82	90	122	100	130	120	100	98	120	116
Sc	2	3	3	1	1	1	1	3	1	-
Sr	110	90	116	88	40	138	150	14	167	132
Th	18	12	22	16	24	12	13	12	14	10
V	1	12.5	17	2	3	13.7	13	10	12	16
Y	27	14	32	40	14	31	42	40	38	26
Zr	100	66	80	122	70	119	130	110	120	116
K/Rb	242.89	238.82	204.07	301.25	162.15	158.37	198.34	199.00	163.90	216.77
GGN - granite gneiss, BGN - biotite gneiss, BG - biotite granite, Ch - charnockite.
Petrochemistry and petrogenesis of the Precambrian Basement Complex rocks around Akungba-Akoko, southwestern Nigeria
180
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Figure 5: Petrochemical diagrams for discriminating Akungba-Akoko granite gneiss, biotite gneiss, biotite granite and charnockite. (a) K2O + Na2O versus SiO2 plot (after [17]), (b) K2O versus SiO2 plot (after [18]), (c) Al2O/(Na2O + K2O) versus Alpj (CaO + Na2O + K2O) molecular plot (af2er [19]), (d) Al2O/(CaO + Nafi + K<O) versus SiO2 (after [20]), (e) FeOo>ta/(FeOtotal+MgO) versus SiO2 (after [21]) and (f) K O + Na O - CaO versus SiO plot (after [21 ]).
the biotite granite and charnockite are classified as intermediate rocks. Al2O3 in the rocks range from 12.60 to 17.90 wt.%. The moderate to high silica and alumina contents of these
RMZ - M&G | 2019 | Vol. 66 | pp. 173-184
rocks are correctable with their high quartz and feldspar contents (Table 1). Fe2O3 and MgO are relatively higher in the charnockite (Fe2O3: 6.68-6.73 wt.%; MgO: 2.41-3.11 wt.%),
Ogunyele A.C., Oluwajana O.A., Ehinola I.Q., Ameh B.E., Salaudeen T.A.
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Nb + y (ppm)
■ Granite gneiss	Œ Bio+ite gneiss • Biotite granite • Charnockite
Figure 6: Petrochemical diagrams of (a) TiO2 versus SiO2 (after [22]) and (b) Rb versus Nb + Y (after [25]) for determining the petrogenesis and tectonic settings of Akungba-Akoko granite gneiss, biotite gneiss, biotite granite and charnockite.
biotite granite (Fe2O3: 6.66-6.68 wt.%; MgO: 2.92-3.02 wt.%) and biotite gneiss (Fe2O3: 3.585.33 wt.%; MgO: 0.76-1.00 wt.%) compared to the granite gneiss (Fe2O3: 3.26-3.83 wt.%; MgO: 0.21-0.32 wt.%). This is as a result of the higher amount of mafic minerals (biotite + hornblende + pyroxene + opaques) in the charnockite, biotite granite and biotite gneiss relative to the granite gneiss. CaO is relatively higher than Na2O and K2O in almost all the rocks. All the rocks are also characterized by low to moderate Ba and low Cr, Nb and V contents pointing to a felsic to intermediate composition. The average K/Rb ratios of the rocks (granite gneiss: 228.59, biotite gneiss: 231.70, biotite granite: 178.35 and charnockite: 193.22) are less than that of crustal rocks (283) [16], therefore suggesting crustal sources of the rocks. Geochemical discrimination of the rocks in the area using the Na2O + K2O versus SiO2 plot [17] revealed that they are sub-alkaline rocks (Figure 5a). On the K2O versus SiO2 plot [18], the biotite and granite gneisses are essentially medium-K calc-alkaline rocks, while the bio-tite granite and charnockite are high-K calc-al-kaline rocks (Figure 5b). All the rock samples except one charnockite sample are plotted within the peraluminous field of the Al2O3/ (Na2O + K2o) versus Al2O3/(CaO + Na2O + K2O) molecular plot of [19] (Figure 5c). The Al2O3/ (CaO + Na2O + K2O) versus SiO2 plot [20] further distinguished the granite gneiss as S-type
peraluminous granitoid and the biotite gneiss, biotite granite and charnockite as I-type peraluminous granitoids (Figure 5d). The biotite and granite gneisses are ferroan, while the bi-otite granite and charnockite are essentially magnesian (Figure 5e). The magnesian nature of the biotite granite and charnockite is due to low FeOtotal/(FeOtotal + MgO) and SiO2 relative to the gneisses. All the rocks are calcic as shown by the K2O + Na2O - CaO versus SiO2 plot ([21]) (Figure 5f).
The granite gneiss, biotite gneiss, biotite granite and charnockite of the Akungba-Akoko area plot within the igneous field on the TiO2 versus SiO2 discrimination diagram [22] (Figure 6a). This suggests that the granite gneiss and bio-tite gneiss of the area are orthogneisses and are formed by metamorphism of igneous pro-toliths, and the biotite granite and charnockite are of igneous origin. The moderate to high silica contents, K/Rb values (<283), sub-alkalinity and I-type peraluminous nature of the biotite granite, charnockite and biotite gneiss indicate that they are I-type granitoids. This suggests that the biotite granite, the charnockite and the igneous protoliths of the biotite gneiss are formed from crustal igneous-sourced melt(s) [21, 23, 24]. The igneous protoliths of the granite gneiss were probably formed from shallow crustal or sedimentary-sourced melt(s) as indicated by its S-type peraluminous character, occasional appearance of garnets and other
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Al-silicate (especially muscovite] in its mineralogy as well as presence of quartzite inclusions in the rock at some locations. Tectonic discrimination of Akungba-Akoko rocks revealed that they are all volcanic arc granitoids (Figure 6b] suggestive of rocks formed during a phase of magmatic activity related to collision and subduction [20, 25].
Conclusion
This study discussed the petrology, mineralogy, petrochemistry and petrogenesis of the Basement Complex rocks around Akungba-Akoko. The area is underlain mainly by migmatite, granite gneiss, biotite gneiss, biotite granite and charnockite. The gneisses in the area are orthogneisses formed by metamorphism of igneous protoliths of granitic composition. The biotite granite and charnockite are of ig-neous/magmatic origin. The biotite granite, charnockite and the igneous protoliths of the biotite gneiss were formed from crustal igne-ous-sourced melt(s], while the igneous proto-liths of the granite gneiss were probably derived from shallow crustal or sedimentary-sourced melt(s]. These basement rocks are volcanic arc granitoids formed during a phase of magmatic activity related to collision and subduction.
Acknowledgements
The authors wish to thank Mr. Adedibu Sunny Akingboye for his field assistance and comments on the manuscript of this paper. The National Geosciences Research Laboratory, Ka-duna, Nigeria, and the Department of Geology, University of Ibadan, Nigeria, are also appreciated for facilitating ED-XRF and petrographic analyses of the samples, respectively.
References
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Original scientific paper	Received: Dec 31, 2018
Accepted: Feb 26, 2019 DOI: 10.2478/rmzmag-2019-0011
Heavy Mineral Distribution in the Lokoja and Patti Formations, Southern Bida Basin, Nigeria: Implications for Provenance, Maturity and Transport History
Razširjenost težkih mineralov v formacijah Lokoja in Patti: poreklo, zrelost in zgodovina transporta
Bankole, S. I.*, Akinmosin, A., Omeru, T. and Ibrahim, H. E.
University of Lagos, Faculty of Science, Department of Geosciences, Akoka, Lagos, Nigeria *sbankole@unilag.edu.ng
Abstract
Heavy mineral component of 13 samples from the Lokoja and Patti Formations, Bida Basin have been studied for their textural characteristics, compositional abundance, maturity and provenance determinations. The suite of heavy minerals encountered is classified as opaque and non-opaque constituents. The non-opaque components include zircon, tourmaline, rutile, garnet, staurolite, epidote, kyanite, titanite, lawsonite, cassit-erite, sillimanite, hornblende, hypersthene and andalu-site. The assemblage is generally dominated by zircon and tourmaline in the two formations. The constituent heavy minerals identified are dominated by ultra-stable and stable classes, whereas the ZTR indices indicate mineralogical immaturity coupled with textural immaturity of the constituent grains. This suggests the possible dominance of chemical weathering of the source rock. The suites of minerals recovered have been linked to both metamorphic and non-metamorphic crystalline rock origins.
Key words: heavy mineral, zircon, tourmaline, minera-logical analysis
Povzetek
Komponente težkih mineralov trinajstih vzorcev iz formacij Lokoja in Patti v bazenu Bida so bile preiskovane glede na teksturne lastnosti, pogostost, zrelost in določitve porekla. Nabor proučevanih težkih mineralov je razvrščen na neprozorne in prozorne sestavne dele. Prozorne komponente vključujejo cirkon, turmalin, rutil, granat, stavrolit, epidot, kianit, titanit, lavsonit, kasiterit, silimanit, rogovačo, hipersten in andaluzit. V sestavi formacij večinoma prevladujeta cirkon in turmalin. Med težkimi minerali prevladujejo ultra stabilni in stabilni razredi, medtem ko indeksi ZRC izkazujejo mineraloško nezrelost, povezano s teksturno nezrelostjo sestavnih zrn. To nakazuje na mogočo prevlado kemijskega preperevanja matične kamnine. Pridobljeni minerali so povezani tako z metamorfnim kot ne meta-morfnim kristalnim nastankom.
Ključne besede: težki minerali, cirkon, turmalin, mineraloška analiza
9 Open Access. © 2019 Bankole, S. I., Akinmosin, A., Omeru, T. and Ibrahim, H. E., published by Sciendo. |feciThis work is licensed under the Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 License.
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Introduction
The Intracratonic Bida Basin (Nupe or Middle Niger Basin] is one of the inland sedimentary basins of Nigeria [1], located roughly at the mid-central Nigeria (Figure 1]. It is a northwest-southeast trending basin contiguous with the Anambra Basin. It extends from Kontag-ora, Niger State to Dekina, Benue State with a length of about 400 km and a width approximating 160 km [2]. Sediment accumulation in the basin commenced from Campanian and continued through the Maastrichtian [3] with fills ranging between 3.5 and 4.5 km thickness [4, 5] at the central part of the basin. Several research papers have been published on the evolution and stratigraphy of the basin. Rift origin in connection with the aulacogen Benue Trough of Nigeria consequence to the separation of the South American and African continents in the Late Jurassic has been suggested for the Bida Basin [6-8]. This rifting resulted in the generation of series of horst and graben structures that characterizes the floor of the Bida Basin.
On the basis of geographical and lateral facies variation, the basin has been divided into the northern and southern sub-basins (Figure 1]. In the southern Bida sub-basin, the oldest sedimentary unit, lying non-conformably on the Precambrian to Lower Paleozoic crystalline basement complex is the fluviatile Lokoja Formation (Figure 2]. Patti Formation conformably overlies the Lokoja Formation (Figure 3]. Observations at the base of Agbaja Plateau and also at the Ahoko Village mine indicate mixed marine and continental deposition environments for the Patti Formation. Literature accounts revealed that the formation consists of sandstones, siltstones, mudstones and shale in intercalation with bioturbated ironstones [9, 10]. The marine series of the Patti Formation is exposed at an abandoned mine in Ahoko Village along Lokoja-Abuja Highway. This unit, which constitutes part of the shale member of the Patti Formation has been extensively reviewed, described and reported by several authors [8, 10, 11-13]. The Agbaja Ironstone Formation caps the sequence of sediments in the southern Bida Sub-basin. Agbaja Formation is an intercalation of claystones, sandstones and
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Figure 1: Geological map of Nigeria. Box indicates the study area.
Figure 2: Section of the Lokoja Formation exposed at Okumi, along the Lokoja-Abuja Highway.
oolitic/massive ironstones. Ladipo et al. [14] interpreted the sequence of the formation as abandoned channel sands and overbank deposits with marine influence resulting in the formation of the massive concretionary and oolitic ironstones.
In the present study, we report on the distribution and concentration of heavy minerals in the Lokoja and Patti Formations. On the basis of these, attempt is made to infer the provenance, maturity and transport history of the sediments of the formations. Detrital sediments are products of pre-existing igneous, metamorphic and also sedimentary rocks. These rocks are composed of diverse detrital minerals with some being classified as placer minerals. The latter are generally highly mechanically resistant and survive the usual complex transportation processes from source areas to the depocen-
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Figure 3: Section of the Patti Formation exposed near the Agbaja Plateau along Lokoja - Agbaja road. The capping rock (uppermost section) in this outcrop is the lower unit of Agbaja Ironstone Formation.
ters. These characteristics have allowed the use of heavy minerals in the study of sediment provenance, maturity and transport history. This method has been widely applied in fluvial [15, 16], coastal-shallow marine [17, 18], deep marine [19] depositional environments.
Materials and Methods
Materials
In total, 13 sediment samples (six from Lokoja Formation and seven from Patti Formation) were subjected to heavy mineral analysis. The analysis was carried out at the Sedimento-logical Laboratory, Department of Geosciences, University of Lagos, Nigeria.
Methods
Heavy mineral analysis in this study followed the procedure of Suzuki [20] and Mange and Maurer [21] for heavy mineral separation. The heavy liquid, Bromoform (CHBr3) with a density of 2.9 g/cc and viscosity of 0.068 poises was used. The samples were air-dried for a week to dispel
any moisture as they were collected during the rainy season. Thereafter, the sediments were gently disaggregated by squeezing between fingers and filter paper or mortar and pestle in the case of hard samples to liberate individual grains. Each sample of 70 g was weighed and sieved to obtain 62.5-500 microns size grains. The individual sample was then poured into the bromoform and stirred thoroughly to free the samples of air bubbles. The particles were allowed to settle for about 20 minutes, stirring periodically to prevent the particles from adhering to funnel wall. The heavy crop was repeatedly washed in excess acetone and distilled water and air-dried and labelled. In all, 13 permanent mounts were made on slides using coupled resin. Mineral identification on the basis of their optical properties as proposed by Mange and Maurer [21] and Lindholm [22] was conducted on the samples.
More than 100 grains were counted from each slide for statistical analysis. Rock fragments, unidentifiable grains as well as authigenic and opaque minerals were excluded from the total sum to obtain uniform, comparable data on transparent assemblages for the characterization of mineralogical provinces. The sum of transparent minerals was recalculated to a value of 100% and the abundance of each heavy mineral species was scaled accordingly. The "ZTR" index which is the combined percentage of zircon, tourmaline and rutile among the non-opaque heavy minerals, omitting micas and au-thigenic species was calculated using [23] formula below:
Zircon + Tourmaline + Rutile
ZRT index =-x 100
Non — opaque
ZTR index was calculated for the samples to ascertain their mineralogical maturity. According to Hubert [23], ZTR index <75% implies immature to sub-mature sediments and ZTR >75% indicates mineralogically matured sediments.
Results and Discussions
Results
Heavy mineral concentration in the Lokoja and Patti Formations is classified into opaque and
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Implications for Provenance, Maturity and Transport History
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non-opaque constituents. The opaque components generally referred to as iron stained heavy minerals require further chemical analysis to allow investigation under petrographic microscope. This chemical analysis, however, is beyond the scope of the present investigation and no further serious attention apart from statistical consideration is accorded to this class of heavy minerals herein. The recovered non-opaque components common to the two formations include the following: zircon, tourmaline, rutile, garnet, staurolite, epidote, kyanite, titanite, lawsonite, cassiterite, sillimanite, hornblende, hypersthene and andalusite (Plates 1-14). Kyanite, cassiterite, hypersthene, staurolite, hornblende and lawsonite show rare occurrences in the Lokoja Formation, except in a sample (Lok2 S6) that has significant amount of hornblende. Also, Kyanite, titanite, hornblende and garnet show rare occurrences in the Patti Formation, kyanite occurs only in PAT S7 sample. The proportion of heavy mineral recovered to the volume of sediment analysed is generally low and may not support any significant economic prospect. Information on the proportion of the heavy minerals recovered from the two formations is provided in Tables 1 and 2. Also, Tables 3 and 4 show the calculated ZRT% index results.
The summary of the identification/classification criteria and the significant characteristics of each of the recovered heavy mineral are as follow:
Zircon: Zircon grains (Plates 2, 3 and 6) are prismatic, rounded to sub-rounded and sometimes contains fluid and mineral inclusions. Prismatic grains frequently showed zonation identified by fine bands parallel to the crystal boundary (Plate 2). The colourless varieties are more in abundance than the coloured varieties. The grains are easily identifiable owing to their very high relief and they are surrounded by black halo (Plates 2, 3 and 6). They show weak pleochroism and strong birefringence. Tourmaline: Tourmaline grains (Plates 1, 2, 4 and 5) are prismatic, elongated, oval-shaped, spherical, euhedral, sub-hedral to irregular in shapes, with terminations at one or both ends of prismatic variety. Moderate relief, mineral inclusions (Plate 9) and overgrowths were frequently observed (Plate 1). Colours vary from
pale to pink, dark green (Plate 4), pale yellowish, dark brown (Plate 4), very dark (almost opaque, may be iron bearing; Plates 1 and 5) and sometimes colourless. Colour zoning is frequent, pleochroism sharp and distinctive. Varicoloured varieties were also present (one portion of the grain displays striking different shades to the other).
Rutile: Rutiles (Plate 7) appeared as small and sub-rounded slender prisms with well-developed terminations or breakage patterns. A thick halo surrounds the grains because of their extremely high refractive indices. Grains are mostly brownish red to brownish black in colours and show distinct pleochroism (Plate 7). Kyanite: Kyanite grains (Plates 8 and 12) are angular, or prismatic, dominantly colourless, weakly pleochroic (uneven coloured pleochro-ism) and exhibit characteristic cross-fractures and step-like features (Plates 8 and 12). The step-like uneven thickness resulted in a spectacular arrangement of the interference colours appearing in blue and grey on thicker and thinner parts, respectively.
Sillimanites: Sillimanites (Plates 9, 11 and 13) are long, slender, prismatic or irregular in shapes. Sillimanites show distinct cleavage, pleochroic (pale brown to pale yellow), parallel extinction, shows brilliant second- and third-order interference colours with yellow, green and pink as a dominant shades; slight twinkling is noticeable on rotation.
Andalusite: Andalusite (Plates 2-4, 6 and 7), mostly colourless and frequently enclose carbonaceous impurities. The rare manganoan variety, viridine which is green in colour was observed (Plate 4). They occur as prismatic, sub-rounded to angular or of irregular morphology; cleavage traces are poorly displayed. Some grains are non-pleochroic, whereas others display inhomogeneous pattern of pleo-chroism. Due to their irregular shape and uneven thickness, they display disorderly patterned interference colours. Weak interference colours are second-order orange and greenish blue (Plates 2-4, 6, and 7). Garnet: Garnets (Plates 1, 3-6), easily identifiable because of their high relief and isotropic nature are euhedral, rounded, sub-rounded or irregular grains with uneven or conchoidal
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Table 1: Proportion (number of grains) of heavy minerals concentration in the sediments of Lokoja Formation.
Sample Name	S/N	Zrn	Tur	Rt	Grt	St	Ep	Sil	Tt	And	Ky	M	Cst	Hbl	Hyp	Lws	Opq
LOK1 S1	1	4	3	1	4	-	4	-	4	-	-	4	-	-	-	-	22
LOK1 S2B	2	5	13	1	1	-	8	11	2	7	3	9	-	-	-	3	236
LOK1 S4B	3	5	4	3	4	1	2	2	-	5	-	4	-	-	-	-	142
LOK2 S2	4	11	9	3	8	1	5	3	3	1	-	6	-	1	1	-	253
LOK2 S6	5	6	3	4	2	-	3	-	-	3	-	-	4	7	1	-	245
LOK2 S8	6	69	5	12	10	2	10	8	-	3	-	2	-	-	-	3	1560
TOTAL		100	37	24	29	4	32	24	9	19	3	25	4	8	2	6	2458
Note: Zrn = Zircon; Tur = Tourmaline; Grt = Garnet; St = Staurolite; Ep = Epidote; Sil = Sillimanite; Tt = Titanite; And = Andalusite; Ky = Kyanite; Opq = Opaque, Hbl = Hornblende; Hyp = Hypersthene; Cst= Cassiterite; Lst = Lawsonite; M= Mica. S/N: Serial Number.
Table 2: Proportion (number of grains) of heavy minerals concentrations in the sediment samples from Patti Formation.
CODE S/N Zrn Tur Rt Grt St Ep Sil Tt And Ky M Hbl Opq
PAT S1B 1 27 10 1 - 4 2 1 1 3 - - 1 303
PAT S2B	2	13	11	2	-	-	4	-	3	-	-8	3	54
PAT S5B	3	4	4	2	1	6	-	2	-	3	-4	-	201
PAT S7	4	10	9	2	4	13	10	8	4	8	2-	4	1352
PAT S13	5.............												
PAT S16	6............-												
PAT S17B	7	3	4	8	1	-	-	2	-	4	--	-	2420
TOTAL	57 38 15 6 23 16 13 8 18 2 12 8 4330
fractures. Colours vary from pinkish brown, pale red, pale pink to colourless. Titanite: Titanite (Plate 12] grain has a high resinous lustre. Relief shows a slight twinkling on rotation of the stage. The grain has a weak pleochroism and good cleavage. High-order interference colours in golden yellow and yellowish white.
Staurolite: Staurolite (Plates 4, 11 and 14] occurs as irregular or angular grains. Colour
ranges from pale yellow, golden yellow to dark yellowish brown. They exhibit distinct pleo-chroism (colourless to different shades of yellow].
Epidote: Epidote (Plates 2, 6 and 8] occurs as irregularly shaped grains, yellowish green to green coloured with fairly high relief. They exhibit distinct pleochroism (colourless, pale yellow, yellowish green].
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Table 3: ZTR maturity index and individual percentage mineral of the sediment samples of Lokoja Formation.
TOTAL
CODE Zrn Tur Rt Grt St Ep Sil Tt And Ky M Cst Hbl Hyp Lst NON- Z+T+R
OPAQUE
ZTR% INDEX
LOK1 S1	4	3	1	4	-	4	-	4	-	-	4	-	-	-	-	24	8	33.3
LOK1 S2B	5	13	1	1	-	8	11	2	7	3	9	-	-	-	3	63	19	30.2
LOK1 S4B	5	4	3	4	1	2	2	-	5	-	4	-	-	-	-	30	12	40.0
LOK2 S2	11	9	3	8	1	5	3	3	1	-	6	-	1	1	-	52	23	44.2
LOK2 S6	6	3	4	2	-	3	-	-	3	-	-	4	7	1	-	33	13	39.4
LOK2 S8	69	5	12	10	2	10	8	-	3	-	2	-	-	-	3	124	86	69.4
TOTAL	100	37	24	29	4	32	24	9	19	3	25	4	8	2	6	326	161	49.4
%	30.7	11.3	7.4	8.9	1.2	9.8	7.4	2.8	5.8	0.9	7.7	1.2	2.5	0.6	1.8	Individual mineral% abundance		
Average ZTR% Index = 42.8%
Total Opaque = 2458
Total Non-opaque = 326
Total Non-opaque excluding micas = 301
Table 4: ZTR maturity index and individual percentage mineral of the sediment samples of Patti Formation.
TOTAL
CODE Zrn Tur Rt Grt St Ep Sil Tt And Ky M Cst Hbl Hyp Lst NON- Z+T+R
OPAQUE
ZTR% INDEX
PAT S1B	27	10	1	-	4	2	1	1	3	-	--	1-	- 50 38 76.0
PAT S2B	13	11	2	-	-	4	-	3	-	-	8-	3-	- 44 26 59.1
PAT S5B	4	4	2	1	6	-	2	-	3	-	4-	--	- 26 10 38.5
PAT S7	10	9	2	4	13	10	8	4	8	2	--	4-	- 74 21 28.4
PAT S17B	3	4	8	1	-	-	2	-	4	-	--	--	- 22 15 68.2
TOTAL	57	38	15	6	23	16	13	8	18	2	12 -	8 -	216 110 50.9
%	26.4	17.6	6.9	2.8	10.6	7.4	6.0	3.7	8.3	0.9	5.6 -	3.7 -	Individual mineral% abundance
Average ZTR% Index = 54.0%
Total Opaque = 4330
Total Non-opaque = 216
Total Non-opaque excluding micas = 204
Discussion
The percentage proportions of the non-opaque heavy mineral constituents (Figures 4 and 5] in Lokoja and Patti Formations show the domi-
nance of zircon. Tourmaline is the second most abundant of the recovered minerals. Epidote comes next in the Lokoja Formation with stau-rolite in the Patti Formation. Epidote is present
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Figure 4: Overall percentage proportion of each non-opaque heavy mineral in the Lokoja Formation.
Figure 5: Overall percentage proportion of each non-opaque heavy mineral in the Patti Formation.
in all the samples of the Lokoja Formation but only in three (3] samples of the Patti Formation. Staurolite was recovered in three (3] samples each of the Lokoja and Patti Formations. The minerals with the lowest percentage proportion are cassiterite, staurolite, kyanite and hyperst-hene in the Lokoja Formation, whereas the lowest in the Patti Formation is kyanite. Cassiterite, lawsonite and hypersthene are totally absent in the Patti Formation. In the heavy mineral stability index of [24,25], hornblende, hypersthene
and andalusite are classified as unstable, epi-dote, kyanite, garnet, sillimanite, titanite, law-sonite, cassiterite as moderately stable, garnet, staurolite as stable and zircon, tourmaline, rutile as ultra-stable minerals. Consequent to the proportion of the constituent heavy mineral in the studied sections, the sediments of the Lokoja and Patti Formations are considered generally stable as they are dominated by ultra-stable and stable minerals.
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Figure 6: Bar chart of ZTR index of each selected samples of Lokoja Formation.
Figure 7: Bar chart of ZTR index of each selected samples of Patti Formation.
The calculated ZTR% index for the two formations ranges from 30.2% to 69.4% in the Lokoja Formation (Figure 6), whereas in the Patti Formation, it ranges from 28.4% to 76.0% (Figure 7). All, except one sample from the Lokoja Formation, have ZTR% index of <50%. This low ZTR index indicates that the samples of the Lokoja Formation are mineralogically im-
mature. The ZTR index of the Patti Formation shows only slight improvement with two samples having ZTR >50% and three having ZTR% index of <50%. The mean percentage of ZTR index for Lokoja Formation is 42.8%, whereas that of Patti Formation is 54.0%. These show the comparative mineralogical maturity advan-
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tage of the sediments of the Patti Formation over their Lokoja counterparts. Generally, very few rounded grains were encountered in all the samples studied (Plates 1-14). Most of the grains are either angular or sub-angular, suggesting that the sediments are from nearby sources and may not have been transported far away from weathering location. Hence, indicating textural immaturity of the sediments of both formations. The abundance of ultra-stable and stable heavy minerals in an assemblage of texturally immature sediments grains (angular to sub-angular) is suggestive of the prevalence of chemical weathering of the source rocks contributing the heavy minerals to the studied formations. Based on the constituent minerals in the studied sediments, mixed source ranging from high-to low-grade metamorphic and non-metamor-phic sources is suggested. The possibility of contribution from low-grade metamorphic and non-metamorphic sources is indicated with dominance of zircon and tourmaline [26] in the two formations. Mange and Maurer [21] have linked the presence of lawsonite, hypersthene, hornblende, cassiterite, kyanite, andalusite, sil-limanite, titanite, epidote, staurolite, garnet to high-grade metamorphic terrain. Also, Diekmann and Kuhn [27] attributed the dominance of low maturity heavy mineral such as green hornblende and garnet to high-grade metamorphic source. Rutile is generally linked to highgrade metamorphic source.
Conclusion
Heavy mineral analysis of both Lokoja and Patti Formations shows the predominance of non-rounded heavy minerals suites indicating short transport history from the sediment source, probably the southwest and north central Basement Complex terrains. The ZTR indices gave a general evidence of immature sediment suites for the Lokoja and Patti Formations with the latter being more matured than the former. Furthermore, the sediments of both formations are stable as they are dominated by ultra-stable and stable minerals. An assemblage of stable heavy minerals in a suite of texturally immature sediments validates
the prevalence of chemical weathering of the source rocks which contributed to Lokoja and Patti Formations. The source of the sediments from both formations is interpreted to be of igneous and metamorphic terrain as indicated by the dominance of zircon, tourmaline, rutile, mica and opaque components.
References
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[9]	Olugbemiro, R.O., Nwajide, C.S. (1997): Grain size distribution and particle morphogenesis as signatures of depositional environments of Cretaceous (non-ferruginous) Facies in the Bida Basin, Nigeria. Journal of Mining and Geology, 33, pp. 89-101.
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[11]	Idowu, J.O., Enu, E.I. (1992): Petroleum geochemistry of some late Cretaceous shales from the Lokoja Sand-
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[14]	Ladipo, O., Akande, S.O., Mucke, A. (1994): Genesis of ironstones from middle Niger sedimentary basin, evidence from sedimentological, ore microscopic and geochemical studies. Journal of Mining Geology, 30, pp. 161-168.
[15]	Joshua, E.O., Oyebanjo, O.A. (2009): Distribution of heavy minerals in sediments of Osun River Basin, Southwestern Nigeria. Research Journal of Earth Sciences, 1(2), pp. 74-80.
[16]	Sarma, J.N., Chutia, A. (2013): Petrography and heavy mineral analysis of Tipam Sandstones exposed on the Tipam Hill of Sita Kunda area, Upper Assam, India. South East Asian Journal of Sedimentary Basin Research, 1, pp. 28-34.
[17]	Ramasamy, P., Karikalan, R. (2010): Distribution and percentage of heavy minerals in coastal geomorpho-logical landforms in Palk Strait, southeast Coast of India. Middle-east Journal of Scientific Research, 5(1), pp. 49-53.
[18]	Achab, M., Gutierrez Mas, J.M. (2009): Heavy minerals in modern sediments of the Bay Of Cadiz and the adjacent Continental Shelf (Southwestern Spain): Nature and Origin, Journal of Marine Sciences, 25(2), pp. 27-40.
[19]	Grzebyk, J., Leszczynski, S. (2006): New data on heavy minerals from the Upper Cretaceous-Paleogene Fly-sch of the Beskid Slaski Mts. (Polish Carpathians). Geological Quarterly, 50, pp. 265-280.
[20]	Suzuki, T. (1975): Heavy minerals composition of the recent sediments in three different environments in geological survey of Japan, part 1, 501 p.
[21]	Mange, M.A., Maurer, H.F.W. (1992): Heavy Minerals in Colour. London: Chapman and Hall, 147 p.
[22]	Lindholm, R.C. (1987): A Practical Approach to Sedimentology. London: Allen and Unwin, 279 p.
[23]	Hubert J.T. (1962): A Zircon-tourmaline-rutile maturity index and interdependence of the composition of heavy minerals assemblages with the gross composition and texture of sediments. Journal of Sedimentary Petrology, 32, pp. 440-450.
[24]	Pettijohn, F.J., Potter, P.E., Siever, R. (1973): Sand and Sandstone. New York: Springer Verlag, 618 p.
[25]	Morton, A.C. (1985): Heavy Minerals in Provenance Studies. In: Provenance of Arenites, Zuffa, G.G (ed.). Dordrecht: Reidel, pp. 77-249.
[26]	Deer, W.A., Howie, R.A., Zussman, J. (1992): An Introduction to the Rock-Forming Minerals (2nd edition). Essex: Longman, 696 p.
[27]	Diekmann, B., Kuhn, G. (1999): Provenance and dispersal of glacial-marine surface sediments in the Weddell Sea and adjoining areas, Antarctica: ice-rafting versus current transport. Marine Geology, 158(1-4), pp. 209-231.
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Appendix 1a ■
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Implications for Provenance, Maturity and Transport History
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Appendix 1b
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Sample PAT S17B: Andalusite (And), Sillimanite Sample PAT SIB: Staurolite (St), Garnet (Grt), (Sil), Opaque minerals (Opq). Mag. X10	Zircon (Zrn), Opaque minerals (Opq). Mag. X40
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Original scientific paper	Received: Apr 08, 2019
Accepted: Nov 22, 2019 DOI: 10.2478/rmzmag-2019-0015
Assessment of Hydrogeological Potential and Aquifer Protective Capacity of Odeda, Southwestern Nigeria
Hidrogeološki potencial in ocena zaščitnih zmogljivosti vodonosnika na območju Odeda v Nigeriji
J.O. Aina*, O.O. Adeleke, V. Makinde, H.A. Egunjobi, P.E. Biere
Department of Physics, Federal University of Agriculture, Abeokuta, Nigeria * johntemini20@gmail.com
Abstract
Hydrogeological assessment of groundwater resources was carried out with a view to evaluate the potential of the aquifers to provide portable water supply and access the distribution of electrical parameters of hy-drogeologic units in some areas in Odeda, Ogun State, Nigeria. A geophysical survey using vertical electrical sounding (VES) with the Schlumberger electrode array, with half-current electrode spacing (AB/2) varying from 1 to 132 m was carried out at 30 different stations in the study area. The VES data were interpreted qualitatively and quantitatively. Three-to-five sub-surface layers consisting of topsoil, weathered layer consisting of clay, sandy clay, clayey sand and sand layers, and fractured/fresh basement were delineated. Layer resistivities and thicknesses obtained on the curves within the study area showed one main aquifer type, which is the fractured basement. The longitudinal unit conductance (ranging from 0.049720 to 1.4520000 mhos] of the study area aided the protective capacity to be rated into good, moderate and weak. About 33% of the study area falls within the weak protective capacity, 57% falls within the moderate protective capacity and 10% falls within the good protective capacity.
Key words: Groundwater potential, protective capacity, vertical electrical sounding, longitudinal unit conductance, overburden thickness
Povzetek
Raziskava hidrogeoloških podzemnih virov je potekala z namenom ocenitve potenciala vodonosnika za zagotovitev preskrbe z vodo. Pri tem je bila narejena porazdelitev električnih parametrov hidrogeoloških enot na nekaterih območjih kraja Odeda. Uporabljena je bila geofizikalna raziskava z navpičnim električnim sondiranjem (VES) z uporabo Schlumbergerjeve elektrodne postavitve s polovično razdaljo elektrode (AB/2), ki je variirala med 1 in 132 m. Preiskava je bila izvedena na 30 različnih lokacijah. Izmerjeni podatki so bili interpretirani kvalitativno in kvantitativno. Razmejenih je bilo tri do pet podzemnih plasti, ki so jih sestavljale: vrhnja plast, preperela plast (sestavljena iz gline, peščene gline, zaglinjenega peska), peščena plast in razpokana sveža podlaga. Upornost in debelina posameznih plasti kaže na eno glavno vrsto vodonosnika (razpokana podlaga). Glede na vzdolžno prevodnost (v območju med 0.049720 do 1.452000 mhos) raziskovanega območja je mogoče zaščitno zmogljivost vodonosnika razvrstiti v dobro, srednjo in slabo. Okoli 33% raziskovanega območja leži znotraj slabe, 57% znotraj srednje in 10% znotraj dobre zaščitne sposobnosti.
Ključne besede: potencial podzemne vode, zaščitna zmogljivost, navpično električno sondiranje, vzdolžna prevodnost, debelina nadkritja
8 Open Access. © 2019 Aina J.O., Adeleke O.O., Makinde V., Egunjobi H.A., Biere P.E., published by Sciendo. |feciThis work is licensed under the Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 License.
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Introduction
In ensuring livelihood and sustainability across the world, groundwater resources play a major and concrete role. Consumption of groundwater as a feasible source of drinking, domestic, industrial and agricultural needs has proven to be not only safer but also more economical than surface water, as it is commonly unpolluted and available. In recent years, investigation of groundwater sources has become a burning issue and a major concern as groundwater basins are being rapidly stressed due to population explosion, high level of urbanisation, industrialisation and other human activities. Presently, the percentage increase in water usage on a global scale has exceeded twice that of the population [1].
Pores and fractured rock formations in the sub-surface are usually hosts of groundwater. In the basement terrain, groundwater occurs within the overlying unconsolidated material derived directly from weathering of rocks and fractured/faulted bedrock, while in the sedimentary terrain, groundwater occurs within the porous and permeable layer of the saturated zone in the sub-surface [2, 3]. Over the years, groundwater exploration has been carried out using geophysical methods, which include electrical resistivity surveying, electromagnetic techniques and seismic methods, to obtain accurate information about the sub-surface settings, such as aquifer's nature, type and depth of materials (consolidated or unconsolidated], depth of weathered or fractured zone, depth to groundwater, depth to bedrock and salt intrusions into groundwater [4]. Aquifers in the Precambarian basement complex are vulnerable to surface or near-surface contaminants as they commonly occur at shallow depths. Hence, successful exploration of groundwater in a basement terrain requires proper understanding of the hydrogeological characteristics of the aquifer units in relation to their susceptibility to environmental pollution and assessment of their protective capacity [3, 5]. One of the most effective ways of evaluating an environment without interfering with the hydrogeological system is through geophysical studies [6]. Over the years, geophysical survey using the vertical electrical sounding
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(VES] method has been applied in groundwater exploration within the basement complex rocks in Nigeria [7-10].
VES using the Schlumberger array method was carried out at 30 different stations in the study area with the aim to determine the geoelectric parameters, such as resistivities and thicknesses of the sub-surface layers and their hydrogeological properties. This study was also aimed at evaluating the groundwater potential of the area, establishing the aquifer protective capacity of the overlying formations, especially its isolation from contamination, and recommending suitable points for groundwater positioning.
Location and Geology of the Study Area
The study area, as shown in Figure 1, is located between latitudes 7°10'N and 7°12'N and between longitudes 3°23'E and 3°28'E. The study area is characterised by tropical climate with distinct wet and dry seasons. The annual rainfall ranges from 1400 mm to 1500 mm; the mean temperature is 30°C and varies from 25.7°C in July to 30.2°C in February [11]. The study area is underlain by Precambarian basement rocks (Figure 2], which are innately characterised by near-negligible permeability and low porosity. These rocks, according to a previous paper [12], were acknowledged to belong to the youngest of the three major provinces of the West African Craton. These rocks are of Precambarian age to early Palaeozoic age, which extends from the Northeastern part of Ogun State and dips towards the coast [13].
Materials and Methods
The electrical resistivity survey method using the VES method was carried out in the study area. The resistivity data were acquired using Campus Ohmega Terrameter. Thirty VES points were positioned in the study area using Schlumberger electrode configuration with half-current electrode separation (AB/2) ranging from 1 m to 132 m. The apparent resistivity values were obtained as the product of the resistance read from the resistivity meter
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Figure 1: Map of the study area showing the sounding points.
Figure 2: Geological map of Ogun State. Modified after Badmus and Olatinsu [14].
Assessment of Hydrogeological Potential and Aquifer Protective Capacity of Odeda, Southwestern Nigeria
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Table 1: Longitudinal unit conductance/protective capacity rating (source: Oladapo and Akintorinwa [18]).
Total longitudinal unit conductance (mhos) Rating of overburden's aquifer protective capacity
<0.10	Poor
0.1-0.19	Weak
0.2-0.79	Moderate
0.8-4.90	Good
5.0-10.0	Very good
>10.0	Excellent
Table 2: Groundwater potential yield (modified after Bayewu et al. [3]).
Overburden thickness (m)	Reflection coefficient	Groundwater yield
>13	<0.8	High
>13	>0.8	Medium
<13	>0.8	Low
<13	<0.8	Very low
and its corresponding geometric factor (K) for each electrode separation. The apparent resistivity data were then plotted against AB/2 on a bi-logarithm graph as sounding curves. The plotted sounding curves were interpreted manually by partial curve matching using different master curves [15]. The geoelectric parameters from the partial curve matching served as the input model for computer-assisted iteration using WINRESIST.
The values of the longitudinal unit conductance of the overburden rock units in the study area serve as the basis for the characterisation of its aquifer protective capacity. The longitudinal unit conductance gives a measure of the impermeability of the confining clay layer, which has low resistivity and low hydraulic conductivity. The protective capacity of the overburden layers in a particular area is proportional to the longitudinal unit conductance [16]. The longitudinal layer conductance (S) of the overburden at each VES station was obtained as shown in Equation (1) [17].
it
(i)
nal unit conductance were used to classify the areas into good, moderate, weak and poor aquifer protective capacity (Table 1]. This was done using the classification given by Oladapo and Akintorinwa [18].
Olayinka [19] opined that in identifying areas of favourable aquifers within a basement terrain, the resistivity of the basement cannot be exclusively relied upon; hence, one has to consider the basement's reflection coefficient in effectively evaluating groundwater potential in the study area. The degree of fracturing of the underlying basement is shown by the reflection coefficient [3]. The reflection coefficients (r] of the study area were calculated using Equation (2], as given by Bhattacharya and Patra [20] and Loke [21].
r =
(pn -p(n- 1)) (pn + p(n — 1))
(2)
where h. is the layer thickness, p. is the layer resistivity, while the number of layers from the surface to the top of the aquifer varies in the range i = 1, ..., n. The results of the longitudi-
where pn is the layer resistivity of the nth layer and p(n - 1) is the layer resistivity overlying the nth layer.
In a basement terrain, groundwater yield can be grouped into high, medium and low depending on the overburden thickness and/or reflection coefficient (Table 2), as stated by Bayewu et al. [3]. The highest groundwater yield is found in areas where thick overburden overlies the fractured zone [18].
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Results and Discussion
The summary of the geoelectric parameters and inferred lithologies in the study area is presented in Table 3. The curve types obtained after partial curve matching ranges from the three-layer H type (66.7%], A type (3.3%) and K type (3.3%), through the four-layer KH type (23.3%), to the five-layer curve HKH type (3.3%). The predominant H type curve recorded in the study area further affirmed the findings of Oloruntola and Adeyemi [9], who recorded >72% of H curve type in the basement
geological terrain at Abeokuta. Figures 3 and 4 show the typical iterated curves generated from the field measurements. The geoelectric interpretations revealed three to five layers, as follows: topsoil (23-700 Wm); the weathered layer, which is composed of clay/sandy clay and clayey sand/sand (4-790 Wm); underlying this layer are the fractured layer (93-437 Wm) and the fresh basement (532-2106 Wm). The aquifer unit in the study area is basically found in the fractured layer, the yield being dependent on the amount of clay content.
Table 3: Summary of geoelectric parameters and inferred lithologies.
VES no.	No. of layers	Curve types	Resistivity (am)	Thickness (m)	Depth (m)	Reflection coefficient	Inferred lithology
	1		117	2.3	2.3		Topsoil
1	2 3	H	29 437	25.5	27.8	0.876	Clay Fractured basement
	1		211	0.9	0.9		Topsoil
2	2 3	H	110 270	5.0	5.9	0.421	Sandy clay Fractured basement
	1		324	1.3	1.3		Topsoil
3	2 3	H	162 413	13.1	14.4	0.437	Clayey sand Fractured basement
	1		75	2.1	2.1		Topsoil
4	2 3	H	30 352	24.1	26.2	0.843	Clay Fractured basement
	1		100	1.2	1.2		Topsoil
5	2 3	H	5 427	7.2	8.4	0.977	Clay Fractured basement
	1		134	0.6	0.6		Topsoil
	2		35	1.8	2.4		Clay
6	3 4 5	HKH	79 17 318	3.4 8.8	5.8 14.6	0.899	Sandy clay Clay Fractured basement
	1		94	0.8	0.8		Topsoil
7	2 3	H	24 192	4.9	5.7	0.778	Clay Fractured basement
	1		30	1.0	1.0		Topsoil
8	2	H	4	2.0	3.0	0.996	Clay
	3		2106				Fresh basement
	1		94	1.2	1.2		Topsoil
9	2 3 4	KH	120 60 342	6.6 11.8	7.8 19.6	0.701	Sandy clay Clay Fractured basement
	1		109	0.8	0.8		Topsoil
10	2 3	H	32 93	7.2	9	0.489	Clay Fractured basement
	1		26	0.6	0.6		Topsoil
11	2 3 4	KH	655 51 592	5.1 13.1	5.7 18.8	0.841	Sand Clay Fresh basement
	1		161	0.9	0.9		Topsoil
12	2	KH	191	9.1	10	0.315	Clayey sand
	3 4		114 219	8.6	18.6		Sandy clay Fractured basement
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Table 3: Summary of geoelectric parameters and inferred lithologies.
	1		369	2.6	2.6		Topsoil
13	2	H	62	19.7	22.3	0.625	Clay
	3		269				Fractured basement
	1		269	0.7	0.7		Topsoil
14	2	KH	327	3.2	3.9	0.534	Sand
							
	3		198	8.8	12.7		Clayey sand
	4		652				Fresh basement
	1		167	1.2	1.2		Topsoil
15	2	H	66	12.7	13.9	0.576	Clay
	3		245				Fractured basement
	1		700	1.5	1.5		Topsoil
16	2	H	38	8.3	9.8	0.887	Clay
	3		637				Fresh basement
	1		417	1.0	1.0		Topsoil
17	2	H	61	8.7	9.7	0.744	Clay
	3		415				Fractured basement
	1		81	2.3	2.3		Topsoil
18	2	H	27	10	12.3	0.880	Clay
	3		422				Fractured basement
	1		34	0.5	0.5		Topsoil
19	2	KH	790	2.5	3.0	0.761	Sand
							
	3		59	12.6	15.6		Clay
	4		435				Fractured basement
	1		103	1.0	1.0		Topsoil
20	2	KH	146	2.1	3.1	0.615	Clayey sand
	3		40	16.8	19.9		Clay
	4		168				Fractured basement
	1		273	1.7	1.7		Topsoil
21	2	H	35	11.1	12.8	0.702	Clay
	3		200				Fractured basement
	1		329	3.5	3.5		Topsoil
22	2	H	135	35.5	39	0.237	Sandy clay
	3		219				Fresh basement
	1		226	2.0	2.0		Topsoil
23	2	H	42	19.4	21.4	0.921	Clay
	3		1019				Fresh basement
	1		285	0.8	0.8		Topsoil
24	2	H	99	7.8	8.6	0.759	Clay
	3		722				Fresh basement
	1		23	0.8	0.8		Topsoil
25	2	A	49	16.6	17.4	0.777	Clay
	3		391				Fractured basement
	1		63	1.0	1.0		Topsoil
26	2	K	153	16.0	17.0	0.553	Clayey sand
	3		532				Fresh basement
	1		149	1.0	1.0		Topsoil
27	2	H	81	10.4	11.4	0.643	Clay
	3		373				Fractured basement
	1		108	1,6	1.6		Topsoil
28	2	KH	296	6.7	8.3	0.889	Sand
							
	3		82	9.2	17.5		Clay
	4		1391				Fresh basement
	1		161	1.0	1.0		Topsoil
29	2	H	65	10.0	11.0	0.522	Clay
	3		207				Fractured basement
	1		274	2.6	2.6		Topsoil
30	2	H	40	19.6	22.2	0.830	Clay
	3		431				Fresh basement
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Current Electrode Distance (AB/2) [m] Figure 3: Typical VES curve in the study area.
No	Res	Thick Depth
1	117.2	2.3 2.3
2	29.1	25.5 27.9
3	437.2	
RMS-error: 3.5 UFI
0DEDAVES6
	
: I . : I .. . y	W
w LJ ........i ........	.......
10*0	10*1	10*2	10*3
Current Electrode Distance (Afl/2) |m]
Figure 4: Typical VES curve in the study area.
Assessment of Aquifer Protective Capacity
The resistivities and thicknesses of the underground layers were used to compute the longitudinal unit conductance (S) of the layers in the study area. Table 4 shows the calculated longitudinal unit conductance in mhos and the
protective capacity rating for the study area. The longitudinal unit conductance values of the overburden materials in the study area ranged from 0.049720 to 1.452000 mhos. It can be observed that the protective capacity in the study area reveals poor, weak, moderate and good capacity rating. Four VES stations have poor protective capacity, six shows weak protective
Assessment of Hydrogeological Potential and Aquifer Protective Capacity of Odeda, Southwestern Nigeria
206
Table 4: Longitudinal unit conductance and aquifer protective capacity of the study area. VES no. Longitudinal unit conductance (mhos) Overburden's aquifer protective capacity rating
1	0.898968	Good
2	0.049720	Poor
3	0.084877	Poor
4	0.824333	Good
5	1.452000	Good
6	0.616591	Moderate
7	0.212677	Moderate
8	0.533333	Moderate
9	0.264433	Moderate
10	0.232339	Moderate
11	0.287726	Moderate
12	0.128673	Weak
13	0.324788	Moderate
14	0.056833	Poor
15	0.199610	Moderate
16	0.220564	Moderate
17	0.145021	Weak
18	0.398765	Moderate
19	0.231430	Moderate
20	0.444092	Moderate
21	0.323370	Moderate
22	0.273601	Moderate
23	0.470754	Moderate
24	0.081595	Poor
25	0.373558	Moderate
26	0.120448	Weak
27	0.135106	Weak
28	0.149645	Weak
29	0.160057	Weak
30	0.499489	Moderate
the poor/weak overburden protective capacity. About 57% falls within the moderate range, while 10% falls within good overburden protective capacity. The longitudinal unit conductance map of the study area in Figure 5 shows that the northeastern and northwestern parts of the study area are characterised by moderate-to-good protective capacity, and this signifies that there is a little or no infiltration due to precipitation.
Assessment of Groundwater Potential
Figures 6 and 7 show the reflection coefficient and overburden thickness map of the study area. The reflection coefficient in the study area varies from 0.24 to 1.00. The groundwater prospects in the study area are categorised
Figure 5: The longitudinal unit conductance map of the study area.
capacity, 17 show moderate protective capacity, while three show good protective capacity rating, with 33 % of the study area falling within
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Table 5: Groundwater potential across the VES locations. VES Overburden Reflection Groundwater
Figure 6: The reflection coefficient map of the study area.
Figure 7: Isopach map of overburden thickness of the study area.
into high, medium and low potentials. In this study, zones where the overburden thickness is >13 m and the reflection coefficient is <0.8 are considered as zones with high groundwater potential, while zones with overburden thickness <13 m and reflection coefficient <0.8 are considered as zones having very low groundwater potential.
Generally, about 33% of the study area has high groundwater potential, which is restricted mostly to areas underlain by porphyritic granite and porphyroblastic gneiss, as established by a previous paper [22], while 23% of the study area has medium groundwater potential; moreover, 43% of the area has low groundwater potential. This result invariably indicates the significance of detailed groundwater survey and exploration in the study area for locating areas where successful boreholes can be sited.
no.	thickness (m)	coefficient	yield
1	27.8	0.876	Medium
2	5.9	0.421	Very low
3	14.4	0.437	High
4	26.2	0.843	Medium
5	8.4	0.977	Low
6	14.6	0.899	Medium
7	5.7	0.778	Very low
8	3.0	0.996	Low
9	19.6	0.701	High
10	9.0	0.489	Very low
11	18.8	0.841	Medium
12	18.6	0.315	High
13	22.3	0.625	High
14	12.7	0.534	Very low
15	13.9	0.576	High
16	9.8	0.887	Low
17	9.7	0.744	Very low
18	12.3	0.880	Low
19	15.6	0.761	High
20	19.9	0.615	High
21	12.8	0.702	Very low
22	39.0	0.237	High
23	21.4	0.921	Medium
24	8.6	0.759	Very low
25	17.4	0.777	High
26	17.0	0.553	High
27	11.4	0.643	Very low
28	17.5	0.889	Medium
29	11.0	0.522	Very low
30	22.2	0.830	Medium
Conclusion
The geoelectric investigation of the study area has revealed three to five subsurface geoelec-tric layers: top soil, weathered basement and fresh basement rocks. The fractured layer constitutes the sole aquifer unit in the study area. The protective capacity in the study area is more of the moderate type and is therefore not exposed to pollution. About 33% of the study area falls within the high rated groundwater po-
Assessment of Hydrogeological Potential and Aquifer Protective Capacity of Odeda, Southwestern Nigeria
208
tential zone, while the remaining 67% constituted the medium/low groundwater potential zone. Hence, the groundwater potential rating of the area is considered generally as medium/ low. Therefore, areas for locating groundwater should be narrowed to zones of moderate/ good groundwater protective capacity.
Acknowledgement
The authors are grateful to Mr. Afolabi and Mr. Oluwaseun Dada for their support in the collection of data on the field.
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