EARLy PLEISTOCENE AGE OF FLUVIAL SEDIMENT IN THE 
STARá GARDA CAVE REVEALED By 26Al/10Be BURIAL DATING: 
IMPLICATIONS FOR GEOMORPHIC EVOLUTION OF THE MALé 
KARPATy MTS. (WESTERN CARPATHIANS)
ZGODNJA PLEISTOCENSKA STAROST FLUVIALNIH 
SEDIMENTOV V JAMI STARá GARDA, KI JO JE DALA 26Al/10Be 
DATACIJA: UPORABNOST ZA GEOMORFNI RAZVOJ NIZKIH 
KARPATOV (ZAHODNI KARPATI)
Michal ŠUJAN1,*, Alexander LAčNÝ1,2, Régis BRAUCHER3, Peter MAGDOLEN4 & ASTER Team5
1 Department of Geology and Paleontology, Faculty of Natural Sciences, Comenius University in Bratislava, Ilkovičova 6, 842 15 
Bratislava, Slovakia, e-mail: miso@equis.sk, lacny@fns.uniba.sk; 
2  State Nature Conservancy of Slovak Republic, Little Carpathians Protected Landscape Area, Štúrova 115, 900 01, Modra, 
Slovakia
3 Aix-Marseille Université, CEREGE, CNRS UM 34, F-13545 Aix-en-Provence, France, e-mail: braucher@cerege.fr
4  Department of Organic Chemistry, Faculty of Natural Sciences, Comenius University in Bratislava, Ilkovičova 6, 842 15 
Bratislava, Slovakia, e-mai: magdolen@fns.uniba.sk
5  ASTER Team (Georges Aumaître, Didier Bourlès, Karim Keddadouche), Aix-Marseille Université, CEREGE, CNRS UM 34, 
F-13545 Aix-en-Provence, France.
Received/Prejeto: 27.06.2017
COBISS: 1.01
ACTA CARSOLOGICA 46/2−3, 251–264, POSTOJNA 2017
Abstract UDC  551.435.84(234.372.3)
Michal Šujan, Alexander Lačný, Régis Braucher, Peter Mag-
dolen & Aster Team: Early Pleistocene age of fluvial sediment 
in the Stará Garda Cave revealed by 26Al/10Be burial dating: 
implications for geomorphic evolution of the Malé Karpaty 
Mts. (Western Carpathians)
Assessment of vertical movements of tectonically bounded 
blocks is crucial for determination of geohazards in densely 
inhabited zones, such as the border zone of western Slovakia 
and eastern Austria. The morphostructure of the Malé Kar-
paty Mts. divides the Vienna and Danube basins in the West-
ern Carpathian – Eastern Alpine junction, and its neotectonic 
activity is of high importance. This study was focused on 
26Al/10Be burial dating of fluvial sediment in the Stará Garda 
Cave, located in the central part of the mountains. The struc-
tural research revealed predisposition of forming of horizontal 
passages in low angle to subhorizontal bedrock stratification 
together with low-grade metamorphic foliation. Fluvial origin 
of the passages was inferred from mezoscale erosional features 
on the bedrock as well as from facies character of the well pre-
served sedimentary profile. Cave sediment was according to 
petrographic analysis derived from a watershed comparable 
to recent one of the Stupavský Potok Stream. Three analysed 
dating samples provided low values of isotopic concentrations, 
allowing us only to calculate the minimum burial age of the 
deposit of 1.72 Ma. Assuming the low position of the cave 
above recent surface streams, resulting maximum incision rate 
of 26 m/Ma indicates very low uplift of the mountains horst 
during the quaternary. The slow incision of the river network 
Izvleček UDK  551.435.84(234.372.3)
Michal Šujan, Alexander Lačný, Régis Braucher, Peter Mag-
dolen & Aster Team: Zgodnja pleistocenska starost fluvialnih 
sedimentov v jami Stará Garda, ki jo je dala 26Al/10Be data-
cija: uporabnost za geomorfni razvoj Nizkih Karpatov (Za-
hodni Karpati)
Ocena vertikalnih premikov tektonsko omejenih blokov je 
ključna za določitev geohazardov v gosto naseljenih območjih. 
Morfostruktura Malih Karpatov deli Dunajski in Donavski ba-
zen na stičišču Zahodnih Karpatov – Vzhodnih Alp in njegova 
neotektonska aktivnost je zelo pomembna. Študija se je posve-
tila 26Al/10Be dataciji fluvialnih sedimentov v jami Stará Garda 
v osrednjem delu gorovja. Strukturna raziskava je raz krila pre-
dispozicijo oblikovanja vodoravnih jamskih rovov pod nizkim 
kotom v odvisnosti od subhorozontalne stratifikacije kamnine 
ter tudi z nizko stopnjo metamorfne foliacije. Na fluvialno 
poreklo rovov smo sklepali iz srednje velikih erozijskih oblik na 
njihovih stenah kot tudi iz lastnosti faciesov dobro ohranjen-
ega sedimentnega profila. Glede na petrografske ana lize jamski 
sediment izhaja iz povodja, ki je primerljiv z recentnim pov-
odjem potoka Stupavský. Trije analizirani vzorci so nam dali 
nizke vrednosti koncentracij izotopov, ki so nam omogočile 
le izračun najnižje pokopne starosti sedimenta, ki je znašala 
1,72 Ma. če upoštevamo, da leži jama nizko nad recentnimi 
vodnimi tokovi, dobimo maksimalno hitrost vrezovanja dolin 
samo 26 m/Ma, kar kaže na zelo majhen tektonski dvig v času 
kvartarja. Počasno vrezovanje rečne mreže se dobro ujema s 
široko ohranjenim uravnanim površjem, imenovanim »Sred-
njegorska uravnava«. V nasprotju pa so sorazmerno visoke 
ACTA CARSOLOGICA 46/2–3 – 2017252
MICHAL ŠUJAN, ALEXANDER LAčNÝ, RéGIS BRAUCHER, PETER MAGDOLEN & ASTER TEAM
is in good agreement with a widespread preservation of the 
planation surface called "Mid-mountain level". In contrast are 
relatively high values of palaeodenudation rates inferred from 
isotopic concentrations. Generally, our results indicate that the 
Malé Karpaty Mts. horst underwent relatively intense but short 
uplift in the Early Pleistocene, followed by very moderate uplift 
up to the recent.
Key words: Western Carpathians, Malé Karpaty Mts., fluvial 
cave sediment, burial dating, Early Pleistocene, neotectonics.
vrednosti hitrosti paleodenudacije, ki izhajajo iz koncentracij 
izotopov. Na splošno naši rezultati kažejo, da je bil horst Nizkih 
Karpatov podvržen relativno močnemu, toda kratkemu dvigo-
vanju v spodnjem pleistocenu, ki mu je sledil zmeren dvig do 
sedanjosti.
Ključne besede: Zahodni Karpati, Nizki Karpati, fluvialni 
jamski sedimenti, pokopna datacija, starejši pleistocen, neotek-
tonika.
INTRODUCTION
Malé Karpaty Mts., located in the western Slovakia, em-
body a pre-Cenozoic morphostructure on the western-
most margin of the Western Carpathians (e.g., Hók et al. 
2014). The horst divides the Danube and Vienna basins 
filled with successions of mainly Neogene age, which are 
characteristic by ongoing accumulation during the qua-
ternary (Maglay et al. 1999, 2009; Beidinger & Decker 
2011). This is an indication of a possible neotectonic 
activity of the area. However, neotectonic history of the 
Malé Karpaty Mts. is still not well known, and this miss-
ing piece of information may play a major role for pres-
ence of geohazards in this highly inhabited area.
Fluviokarst levels form usually in response to cycles 
of developing incision of a stream following a base level 
fall and its stabilisation. Hence, study of timing of their 
formation could provide a strong proxy for determining 
vertical movements (e.g., Granger et al. 2001; Wagner 
et al. 2010; Calvet et al. 2015). Presence of allochthonous 
sediment deposited by a sinking stream is essential for 
dating of a cave level formed by fluvial processes.
This study was focused on the Stará Garda Cave, lo-
cated in the southern part of the Malé Karpaty Mts. The 
cave contains fluviokarst levels and a fluvial sedimentary 
profile, which was the subject to facies analysis and cos-
mogenic burial dating, with aim to determine timing of 
its formation prior to vertical movements of the Malé 
Karpaty horst. Considering the geometry of the cave sys-
tem and its position within the mountains, implications 
for the Pleistocene geomorphic development of the area 
were given. 
GEOLOGICAL AND GEOGRAPHICAL SETTING
The Malé Karpaty Mts. represent the westernmost ex-
posed segment of the Internal Western Carpathians 
(Fig. 1a), composed of Tatric, Fatric and Hronic tectonic 
nappe units. The Tatric unit consists of crystalline base-
ment and its latest Paleozoic to Mesozoic sedimentary 
cover, while the Fatric and Hronic units are thin skinned 
nappes comprising latest Paleozoic to Mesozoic sedi-
mentary sequences individualised in the Palaeoalpine 
tectonic phase (e.g., Hók et al. 2014). The area borders 
with the contact zone of the Eastern Alps and Western 
Carpathians, which is covered by the Neogene sedimen-
tary sequences of the Vienna Basin. 
The morphostructure of the Malé Karpaty Mts. 
underwent slow exhumation during the Paleogene to 
middle Miocene times (Králiková et al. 2016). Its tec-
tonic individualisation was connected with a synrift sub-
sidence phase of the Vienna and Danube basins in the 
middle Miocene, since accumulation of several kilome-
tres thick sequences was associated with activity of faults 
bounding the Malé Karpaty Mts. from SE and NW (e.g., 
Kováč 2000). Its present elevated shape is considered to 
be formed during the Pleistocene (Minár et al. 2011), 
accompanied by deposition of thick quaternary succes-
sions on their both sides (Maglay et al. 1999, 2009).
The Borinka Succession crops out in the north-
western part of the Malé Karpaty Mts. and consists of 
Jurassic marine clastic carbonates deposited in front of 
an active overthrust (Fig. 1b). The Stará Garda Cave was 
formed in Prepadlé Formation of the Lower Jurassic age, 
which comprises gray, massive to thick bedded, occa-
sionally laminated fine-grained carbonates. The cave sys-
tem assigned to Borinka Karst (Majko 1962; Liška 1982; 
Mitter 1983; Magdolen 2004; Hochmuth 2008) could 
be observed in a very specific geological setting, since it 
rims a thrust of the Tatric crystalline complexes of the 
Bratislava nappe over the Borinka succession (Fig. 1b). 
ACTA CARSOLOGICA 46/2–3 – 2017 253
EARLy PLEISTOCENE AGE OF FLUVIAL SEDIMENT IN THE STARá GARDA CAVE REVEALED By 26Al/10Be BURIAL DATING: ...
The contact of both units could be tracked in the gener-
ally NE−SW direction (Polák et al. 2012).
The area recently belongs to a watershed of the Stu-
pavský Potok Creek (Fig. 1c), but it was proposed that the 
fig. 1: Location of the study area. a) general location of the southern part of the Malé karpaty Mts. b) geological map of the study area 
according to Polák et al. (2012), simplified. c) topography of the southern Malé karpaty Mts. with stream network. The extent of the 
"Mid-mountain level" planation surface is according to Urbánek (1992).
recent river basin configuration resulted from a stream 
capture and the NNE−SSW oriented valley parallel to 
the mountain axis was previously drained by the Vydri-
ca Creek (Lukniš 1955; Urbánek 1992; Sládek & Gajdoš 
ACTA CARSOLOGICA 46/2–3 – 2017254
2014). Morphology of the central part of the mountains 
is dominated by a well preserved planation surface called 
the "Mid-mountain level" (Fig. 1c; Urbánek 1992; 2014).
Evolution of the Malé Karpaty Mts. during the qua-
ternary was until now poorly examined taking into ac-
count their vertical movements, what mainly emerged 
from scarcity of proper geochronological data. This issue 
was discussed using morphostratigraphy of river terrac-
es on the south-western margin of the mountains (e.g., 
Šajgalík 1958; Halouzka & Minaříková 1977) and by cor-
relation with planation surfaces (e.g., Lukniš 1964; Jákal 
1983; Dzurovčin 1994; Orvoš 2015), but only applying 
relative dating.
The Stará Garda Cave was discovered by a team of 
professional cavers led by Ján Majko in February 1958 
after a one month excavating of debris from a sinkhole. 
The entrance was buried soon after the early recon-
naissance by rock blocks in April, the same year. The 
re-discovery of the cave happened in June 1991 and 
during the next 20 years some new passages were at-
tached along with continuation at the very end. The key 
advance was done in 2011, when extensive horizontal 
labyrinth was reached and the cave was connected with 
two other near-by caves thus creating the Borinka Cave 
System.
METHODS
CAVE SURVEy: MAPPING, STRUCTURAL 
RESEARCH AND SEDIMENTOLOGy
The survey of the cave was done in the years 2003–2004 
by the members of speleological club Speleo Bratislava. 
Individual geodetic points were assayed by the mine sur-
veying method using a hanging compass, mine inclinom-
eter and steel or fibreglass measuring tape. All values of 
bearings were measured two times (both in forward and 
back orientations). The plan of the cave was generated 
using polyline that connects all geodetic points and sta-
tion points as well. The side projection was constructed 
in the same way using calculated coordinates of all sta-
tion points.
Structural investigations were carried out by the 
classic field-based methods of structural analysis. The 
fundamental structural elements (bedding, brittle dis-
continuities) were measured during the field work and 
visualized with the software for structural geology Open-
Stereo (Grohmann & Campanha 2010). 20 structural el-
ements were measured in the Stará Garda Cave and near 
surface.
Analysis of lithofacies is based on principles of flu-
vial sedimentology (Miall 2000; 2006) with emphasis 
on specifics related to depositional processes in caves 
(e.g., Bosch & White 2004; White 2007; Farrant & Smart 
2011). A detailed vertical lithological log was construct-
ed with aim to record temporal changes in depositional 
processes. The sandy material of grain size 0.5–1.0 mm 
was subject to petrological analysis in two thin sections 
using polarisation microscope. Erosional features of pas-
sage walls were interpreted according to Bretz (1942), 
Curl (1966), Bögli (1980), Lauritzen (1981), Ford & Wil-
liams (2007), Palmer (2007), Klimchouk (2007) and Far-
rant & Smart (2011).
26Al/10Be BURIAL DATING PRINCIPLES
The 26Al/10Be burial dating method was applied to three 
sandy samples taken from vertical succession of the stud-
ied sedimentary log. The dating is based on assumption, 
that clastic material containing quartz grains was exposed 
at the ground surface to cosmic rays in the source area 
and then transported in a stream followed by a burial in 
a cave. Interaction of cosmic rays with quartz material 
causes production of radionuclides 26Al and 10Be by nu-
clear reactions with a stable spallation production ratio 
of 1:6.75. After deposition in a cave passage, the quartz 
material is shielded from cosmic rays and the 26Al/10Be 
ratio will decrease due to radioactive decay of the two el-
ements (e.g., Goose & Phillips 2001; Granger & Muzikar 
2001). The measured ratio can thus be used to determine 
the minimum burial age. This age can also be considered 
to the minimum age of the cave formation, providing that 
cave was formed by fluvial processes and dated sediment 
could be clearly interpreted as allogenic and deposited by 
a stream. Assuming that no post production occurred af-
ter deposition, the data also allow determining the maxi-
mum denudation rate that prevailed at surface before 
burial (von Blanckenburg 2005). Coordinates of studied 
cave, which were applied in calculations, are following: 
Lon – 17.13365; Lat – 48.27864; Alt – 442 m. The studied 
sedimentary profile appears in the depth of 58 m.
TREATMENT OF THE BURIAL  
DATING SAMPLES
Three samples of sand were taken from vertical succes-
sion. Samples of purified quartz were sieved to fraction 
0.25–1 mm and ca. 70 g of material underwent sequen-
tial leaching in HF for decontamination of the grains 
from atmospheric 10Be. The pure decontamined quartz 
MICHAL ŠUJAN, ALEXANDER LAčNÝ, RéGIS BRAUCHER, PETER MAGDOLEN & ASTER TEAM
ACTA CARSOLOGICA 46/2–3 – 2017 255
was spiked with ~100 µl of a (3025±9) ppm of 9Be car-
rier solution and totally dissolved in HF. An aliquot for 
ICP-OES measurements of concentrations of stable alu-
minium was taken after evaporation of the solution. Al 
and Be were separated using standard procedures of ion 
exchange chromatography (Merchel & Herpers 1999). 
Beryllium and aluminium hydroxides were oxidized and 
cathoded with metal powder (Niobium for Be and Silver 
for Al) for AMS measurements, which were performed 
at French national facility ASTER (CEREGE, Aix-en-
Provence).
RESULTS
GEOMETRy OF THE BORINKA CAVE SySTEM 
AND THE STARá GARDA CAVE
The Borinka Cave System consists of four caves, from 
which three are connected (Fig. 2). Active stream occupy 
several levels and leaves the system at the elevation of 
343 m a.s.l. (Stará Garda Cave) or 335 m a.s.l. (Jubile-
jná Cave). A connectivity to the resurgence located ca. 
2.5 km to the SWW on the elevation of 299 m a.s.l. was 
proved by a tracer test. Hence, the studied sedimentary 
profile in the Stará Garda Cave is located approximately 
45 m above the modern piezometric level recently occu-
pied by a recent stream.
The uppermost passage of the Stará Garda Cave is 
reached by an artificial shaft 6 m deep (Fig. 3). A gen-
tly dipping hall is followed by a network of vertical 2 to 
5 m deep wells with vertical levels arranged in a spiral 
framework. These passages reach the Chamber of Bats 
in the depth of 50 m. Here appears a horizontal passage 
oriented to the east with inflow of a stream. The hori-
zontal passage is after 15 m modulated by a vertical 7 m 
deep shaft and opens to a spacious N−S oriented hall 
containing rockfall material. The Fragment of Meander 
Passage follow on its end, which is 1.5 to 2 m high and 
1 to 1.5 m wide and was originally completely filled by 
fluvial deposits. The passage is accessible in a length of 
20 m thanks to excavation works. The main passage con-
tinues from the Chamber of Bats by a vertical shaft on 
the level of 60 m depth, where it branches to two sink-
ing fissure passages. Than the Stará Garda Cave connects 
towards the north to the extensive complex of passages 
of the Borinka Cave System. Original Stará Garda Cave 
follows the western direction and opens to the most spa-
cious segment – the Great Chamber. Narrow fissure pas-
sages continue from the bottom of the hall to the lower-
most level of the Satrá Garda Cave in the depth of 96 m 
(343 m a.s.l.). The cave terminates here by a narrow, low 
and impassable passage, were is located an outflow of the 
stream.
STRUCTURAL PREDISPOSITION OF  
THE STARá GARDA CAVE
Orientation of the cave passages in the Stará Garda Cave 
appears as parallel to major planar discontinuities. These 
are mostly primary stratification planes and planes of 
fissures associated with faults. Measurements of orienta-
tion of stratification S0 directly in the cave as well as on 
the surface in close vicinity shows their orientation to 
W–NW and E–SE with dip reaching 20–35° (Fig. 4a, c). 
fig. 2: Schematic section of the Borinka Cave System depicting its position related to topography and recent stream network.
EARLy PLEISTOCENE AGE OF FLUVIAL SEDIMENT IN THE STARá GARDA CAVE REVEALED By 26Al/10Be BURIAL DATING: ...
ACTA CARSOLOGICA 46/2–3 – 2017256
While the orientation of bedding planes is in accordance 
with the data gained in general geological mapping of the 
area (Polák et al. 2012), steeper dipping of the Borinka 
Succession is much more common in the Malé Karpaty 
Mts. than observed low angle inclination. A low grade 
metamorphic foliation S1 connected with the overthrust 
of the Bratislava nappe was observed as sub-parallel to 
stratification S0. Abovementioned planar inhomogenei-
ties S01 affected formation of horizontally oriented domes 
and passages present in lower altitudes of the cave, such 
as the passage with studied sedimentary profile.
Subvertical to vertical fissures S2 represent another 
observed system of major plane discontinuities, oriented 
generally in ESE–WSW direction (Fig. 4b, c). These fis-
sures played a major role during corrosive to fluvial ero-
sive processes of forming of passages in the upper part of 
the cave up to depth of 40 m, what is well observable on 
the map view on Fig. 3. Similar structures were consid-
ered as important for origin of several other caves of the 
Borinka Karst (Magdolen & Sliva 2003).
The planes S01 are inclined towards W–NW and 
E–SE, forming limbs of folds. Plašienka (1987) declared, 
that original geometry of S01 planes was overprinted by 
subsequent Palaeoalpine transpressive event, which led 
to a mezo- and macroscale symmetric and slightly asym-
metric folding. Foliation associated with this event rep-
resent a cleavage of subvertical fold axial planes, which 
are common feature in the area, but were not observed 
directly in the studied cave. Movement of the dextral 
SW-NE oriented transpressional zone caused rotation of 
fold axes not only on dextral Riedel Shears R1, but also 
on sinistral shears R2 in a counter clockwise direction 
(Plašienka 1987). This rotation is expected to be respon-
sible for the present orientation of folds of S01 planes as 
well as of S2 fissures.
MEZOSCALE EROSIONAL FEATURES OF THE 
CAVE BEDROCK MORPHOLOGy
The surface morphology of the bedrock carbonate in front 
of the passage with studied sedimentary profile shows 
horizontal erosional zones (Fig. 5a), which are consid-
ered as indications of notching process. These developed 
by corrosion during episodes of nearly static water body 
in a vadose passage with an open channel. Several zones 
of notches in vertical arrangement mirror gradual filling 
of the passage with sediment (aggradation) and conse-
quent rising of a water table (Farrant & Smart 2011). In 
contrast, spoon-shaped scoops are present just on oppo-
site side to the sedimentary profile (Fig. 5b), which are 
comparable to scallops. Scallops are formed by dissolu-
tion in a turbulent flow (Bretz 1942; Curl 1966; Ford & 
Williams 2007). Another erosional features of sub-verti-
cal orientation observable on Figure 5c are interpreted as 
half tubes or as wall grooves (Bögli 1980; Lauritzen 1981; 
Ford & Williams 2007; Palmer 2007; Klimchouk 2007). 
These develop typically by dissolution under phreatic 
conditions by vertically flowing water in a passage, that 
has become filled by sediment, what leads to upwards 
fig. 3: ground plan and side view of the Stará garda Cave with indication of main structural elements of the bedrock. 
MICHAL ŠUJAN, ALEXANDER LAčNÝ, RéGIS BRAUCHER, PETER MAGDOLEN & ASTER TEAM
ACTA CARSOLOGICA 46/2–3 – 2017 257
orientation of dissolution (Ford & Williams 2007; Klim-
chouk 2007). Combination of these structures indicates 
alternating of highly turbulent stream with standing water 
conditions, and presence of mostly vadose but also phreatic 
setting during formation of the passages.
STRATIGRAPHy OF THE CAVE FLUVIAL INFILL
Description
The sedimentary profile in the Fragment of Meander pas-
sage contains several distinct lithotypes, depicted on the 
log on Fig. 6. Fine grained lithotype is represented by mud 
and muddy sand, which mostly occurs in 0.5 to 1 cm thin 
laminae, in lower part of the log reaching 2–3 cm. Mud is 
usually laminated and forms continual layers, which divide 
sandy units. Boundaries are mostly sharp and planar, in 
several levels scoured (105 and 122 cm), indicating erosion 
fig. 4a: Example of the bedrock stratification plane associated with 
metamorphic foliation (S01). b) Example of fissure S2 related to 
transpressive event. c) Stereographic projection summarizing orien-
tation of S01 and S2 discontinuities. (Photo: A. Lačný).
fig. 5: Erosional features on the cave bedrock surface. a) horizontal 
erosional zones, which represent notching during process presence 
of nearly static open channel water body. b) Spoon-shaped scoops 
formed by turbulent flow. c) half tubes/wall grooves formed by ver-
tically flowing water under phreatic conditions (ford & Williams 
2007; klimchouk 2007; Photos: N. filipčíková and t. Lanczos).
EARLy PLEISTOCENE AGE OF FLUVIAL SEDIMENT IN THE STARá GARDA CAVE REVEALED By 26Al/10Be BURIAL DATING: ...
ACTA CARSOLOGICA 46/2–3 – 2017258
preceding their deposition. Wavy laminae were deposited 
above positive sandy forms, which may represent current 
ripples (Fig. 7b).
Fine to medium sand appears as massive. Com-
monly overlies muddy laminae and continuously passes 
upward to coarse sand. Coarse sandy layers could be ob-
served either as weakly stratified or massive individual 
layers 5–10 cm, up to 20 cm thick, or together with fine 
to medium sands in upward coarsening units (Fig. 7b). 
These layers locally contain gravel reaching 0.5 cm in di-
ameter (intervals 32–52 cm; 137–144 cm). Coarse sands 
fig. 6: Photomosaic of the studied 
sedimentary section in the frag-
ment of Meander passage with 
corresponding lithological log, 
its interpretation and position of 
burial dating samples. Since the 
passage is narrow, relative di-
mensions of layers are affected by 
compilation of photographs.
fig. 7a: Side view of the sedimen-
tary profile with marked stratifi-
cation and main bounding sur-
faces. b) Detail of the lithofacies 
with presence of upward coars-
ening units and muddy lami-
nae of wavy shape. (Photos: N. 
filipčíková and t. Lanczos).
MICHAL ŠUJAN, ALEXANDER LAčNÝ, RéGIS BRAUCHER, PETER MAGDOLEN & ASTER TEAM
ACTA CARSOLOGICA 46/2–3 – 2017 259
could be found with internal muddy laminae of planar 
or wavy shape. 
Two major erosional surfaces appear in the log on 
52 and 69 cm, marked by angular contacts between lay-
ers (Fig. 7a). The succession in interval 0–52 cm is sub-
horizontally arranged with general upward coarsening 
trend. Interval in 52–69 cm is inclined with dip of 25° 
towards the west. The above situated layers up to 105 cm 
form a lenticular convex horizon with slightly upward 
decrease in grain size (Fig. 7a). Topmost part is char-
acteristic with wavy boundaries and generally coarse 
grained appearance.
Interpretation of depositional processes
Dominantly sandy layers were deposited by an unidirec-
tional traction current in a channel, what is implied by 
character of sorting as well as by geometry of the strata 
(e.g., Bosch & White 2004). Variable grain size (hetero-
lithic pattern) resulted from frequent change in the flow 
transport capacity. Common presence of continual mud-
dy laminae arose from significant decrease in transport 
capacity leading to deposition from suspension. These 
events could represent episodes of slackwater deposition, 
when the passage was fully water-filled (Bosch & White 
2004; White 2007).
Two main angular contacts in the sedimentary pro-
file are of erosional origin, indicating high dynamics of 
the stream. The inclined strata in 52 to 69 cm of the log, 
reaching up to 70 cm in thickness towards the left side 
(west), could be considered as a channel bar. Thus, the 
dip direction towards the west indicates palaeoflow di-
rection. Overlying cross-stratified coarse sand together 
with the strata up to 105 cm is of lenticular convex shape 
and probably represents cross section of a point bar. 
Several ca. 6–8 cm thick units with upward-coarsening 
character resulted from pulses of increased flow strength. 
Despite the variation in a transport capacity, the flow was 
relatively perennial, what is indicated by generally stable 
upper limit of gain size, good sorting and organization of 
strata into channel bars without presence of gravity flow 
deposits.
PETROLOGy AND PROVENANCE OF  
THE DATED SEDIMENT
Petrology of the sands from samples SG1 and SG3 was 
studied in thin sections. Percentual content of each ob-
served clast type is summarized in the Tab. 1. Mineral 
clasts are represented by quartz, K-feldspar, microcline, 
muscovite, sericitized biotite and sericitized plagioclase 
(Fig. 8a-h). Lithoclasts of carbonates, shales and gran-
ites showed relatively high abundance, while sandstone 
lithoclasts were less common. Most of the mineral clasts 
were poorly rounded (Fig. 8a, b), while higher roundness 
was observed in shale lithoclasts (Fig. 8e, f). Percentage 
content of individual clast types does not differ signifi-
cantly between SG1 and SG3 samples.
All mineral clasts and granite lithoclasts are ex-
pected to be derived from granitic rocks, which form 
the recent drainage basin of the Stupavský Potok Creek. 
An exception could represent some well-rounded quartz 
clasts, which could originate from shales. Lithoclasts of 
shales were most probably sourced from erosion of Low-
er Jurassic of the Borinka Succession, while fine grained 
sandstones are present in the Lower-Middle Jurassic of 
the succession. Summarizing the mentioned informa-
tion, sources of all documented clast types are present in 
the recent drainage basin of the Stupavský Potok Creek 
and their appearance indicate short transport. Mate-
rial of metamorphic rocks, which crop out more to the 
north, was not observed.
BURIAL DATING, INCISION AND 
PALAEODENUDATION RATES
Lithofacies analysis proved fluvial origin of the profile in 
question. Moreover, study of morphological features of 
erosional origin on cave passage walls imply that stream 
corrosion and dissolution were main processes control-
ling origin of the passages in the lover part of the cave. 
Thus, burial dating of samples taken from this profile 
should mirror age of the cave formation.
All three measured samples provided relatively 
low concentrations of both 10Be and 26Al (Tab. 2). Con-
sidering the low 26Al/27Al sample ratios (ranging from 
3.3 x 10−15 to 4.58 x 10−15) compared to the processional 
blank (2.2 ± 1.92) x 10−15 the most rigid approach was 
applied with taking into account only the upper limit for 
the 26Al concentrations. This will thus yield to minimum 
burial ages.
Resulting minimum burial age of sedimentary pro-
file is 1.72 Ma, since sample SG3 is on the top of the pro-
tab. 1: Percentage content of clast types observed in thin sections 
of samples Sg1 and Sg3. 
Clast type SG1 [%] SG3 [%]
Quartz 25.5 22
K-feldspar 14 12
Microcline 9.5 7
Muscovite 4 6
Sricitized plagioclase 3 7.5
Sericitized biotite 8.5 5
Carbonate lithoclast 6 11.5
Shale lithoclast 18 10.5
Granite lithoclast 8.5 13
Sandstone lithoclast 3 5.5
EARLy PLEISTOCENE AGE OF FLUVIAL SEDIMENT IN THE STARá GARDA CAVE REVEALED By 26Al/10Be BURIAL DATING: ...
ACTA CARSOLOGICA 46/2–3 – 2017260
file. The cave infill was deposited most probably during 
the Gelasian age of the Early Pleistocene.
Incision rate could be inferred according to posi-
tion of the Stará Garda Cave in the Borinka cave system 
(Fig. 2). The position of the dated profile ca. 45 m above 
the lowermost cave level occupied by an active stream 
imply average maximum incision rate ~26 m/Ma during 
the last 1.72 Ma.
Obtained concentrations yielded catchment-aver-
aged maximum palaeodenudation rates ranging from 
fig. 8: Most common clast types observed in thin sections. Upper photos represent plane polarized light, lower photos cross polarized 
light. Abbreviations: Qtz – quartz; Mc – microcline; Pl-Ser – sericitized plagioclase. Mica represents altered biotite. Shale, granite and 
sandstone indicate lithoclasts.
tab. 2: Upper limit of 26Al concentrations, 10Be concentrations, calculated minimum burial ages and maximum denudation rates for the 
3 studied samples from the Stará garda Cave. 
Sample 26Alupper limit (kat/g)
10Be  
(kat/g)
26Alupper limit /
10Be Minimum burial age  (Ma)
Maximum denudation rate  
(m/Ma)
SG1 18.74 5.075 ± 0.53 3.69 1.35 475.42
SG2 18.68 3.831 ± 0.42 4.88 0.77 840.70
SG3 21.17 6.994 ± 0.70 3.03 1.72 281.18
281.2 to 840.7 m/Ma. These values are very approxi-
mate due to high uncertainty in 26Al concentrations. It is 
worth nothing to mention, that palaeodenudation rates 
represent only a few tens of thousands of years long time 
slice, during which is quartz grain exposed to cosmic 
rays, eroded, transported and deposited in a cave pas-
sage (von Blanckenburg 2005).
MICHAL ŠUJAN, ALEXANDER LAčNÝ, RéGIS BRAUCHER, PETER MAGDOLEN & ASTER TEAM
ACTA CARSOLOGICA 46/2–3 – 2017 261
The obtained dating result of the Stará Garda Cave al-
lochthonous fluvial sediment proves, that the Malé Kar-
paty Mts. horst was in elevated morphological position 
similar to recent already during the Early Pleistocene and 
river incision into carbonate complexes of the Borinka 
Succession was already active. Calculated maximum 
incision rate of ~26 m/Ma in the southern part of the 
Malé Karpaty Mts. represent significantly lower value 
comparing with case studies focused on the quater-
nary incision rates in the Transdanubian Range Mts. 
(60–160 m/Ma; Ruszkiczay-Rüdiger et al. 2016) or in the 
Eastern Alps (~100 m/Ma; Wagner et al. 2010). The value 
of 30–40 m/Ma implied by the results of Bella et al. (2014) 
for the Internal Western Carpathians is much closer to 
presented study. The southern Malé Karpaty Mts. are 
characteristic by moderate relief with low average slope 
inclination ranging in 6–14°, indicating minor intensity 
of recent erosion (Polák et al. 2012; Urbánek 2014). The 
highest flat-shaped parts of the relief were considered to 
be remnants of the pre-Pliocene initial planation surface 
called "Mid-mountain level" (e.g., Mazúr 1976; Minár 
et al. 2011) and are well preserved across the area (Fig. 1c; 
Urbánek 1992; 2014). Our results imply, that uplift of the 
Malé Karpaty Mts. reached low intensity during the qua-
ternary, what led to moderate incision of streams and 
wide preservation of the planation surface.
Although the obtained palaeodenudation rates are 
very approximate, they provide important insight into 
topographic conditions of the Malé Karpaty Mts. during 
the Early Pleistocene. The values are an order of magni-
tude higher comparing with other case studies focused 
on mountain cave systems in the Europe (e.g., Wagner 
et al. 2010; Calvet et al. 2015 and reviewed data therein). 
Moreover, obtained values are two orders of magnitude 
higher than 26Al/10Be result from Internal Western Car-
pathians (Bella et al. 2014) and calculations based on 10Be 
depth profiles in the Transdanubian Range (Ruszkiczay-
Rüdiger et al. 2016). On the other hand, studies of 10Be 
concentrations in recent river sediments in Apennines, 
Southern and Eastern Alps revealed denudation rates 
ranging from 150 to 550 m/Ma in watersheds not affect-
ed by Pleistocene glaciations (Norton et al. 2011; Witt-
mann et al. 2016). However, all these localities exhibit 
much higher relief than the Malé Karpaty Mts. Thus, the 
increased denudation rates during the Early Pleistocene 
might have resulted from a short episode of increased 
uplift related to forming of recent morphostructure of 
the mountains.
The beginning of quaternary is characteristic by 
significant cooling and shift to continental climate with 
high seasonality and oscillations in mean annual tem-
peratures and precipitation in the Central and Eastern 
Europe (e.g., Meyers & Hinnov 2010; Kahlke et al. 2011). 
The climate change resulted in increased intensity of ero-
sion processes, what probably affected the relatively high 
Early Pleistocene denudation rates observed in the stud-
ied area. A more detailed study is needed to determine a 
precise history of denudation rates in the Malé Karpaty 
Mts., as well as to examine their major control factors.
Low measured isotopic concentrations are expected 
to be a consequence of fast erosion and transport to the 
cave passage, with short time of exposure. The cave sedi-
ment was according to petrographic analysis transported 
to a short distance and probably derived from the area 
comparable to the recent drainage basin of the Stupavský 
Potok Creek. Absence of the metamorphic minerals in 
the cave sediment suggest, that the palaeo-watershed did 
not exceed further to the north. Thus, river basin pattern 
remained generally unchanged in the studied locality. 
Low uplift rate left the valley in the central part of the 
Malé Karpaty Mts. relatively unaffected by the headward 
erosion.
DISCUSSION
CONCLUSIONS
The study revealed fluvial origin of lower passages of 
the Stará Garda Cave (Malé Karpaty Mts.), considering 
mezoscale morphological erosional features on the bed-
rock surface and facies of the sedimentary infill. Analysis 
of 26Al and 10Be concentrations from three fluvial sedi-
ment samples provided low isotopic values, allowing us 
only to calculate minimum burial age of 1.72 Ma. Low 
concentrations of both isotopes probably resulted from 
short transport and exposition. A short transport of the 
sandy material in a river basin of extent comparable to 
actual one of the Stupavský Potok Creek is indicated by 
petrographic character of the cave sediment. The dated 
sedimentary profile is located only ca. 45 m above the 
river bed of the recent stream network, what imply a slow 
incision rate lower than 26 m/Ma. This value together 
with the widespread preservation of the "Mid-mountain 
level" planation surface was interpreted as a result of slow 
uplift of the mountains and associated low base level fall 
EARLy PLEISTOCENE AGE OF FLUVIAL SEDIMENT IN THE STARá GARDA CAVE REVEALED By 26Al/10Be BURIAL DATING: ...
ACTA CARSOLOGICA 46/2–3 – 2017262
REFERENCES
Beidinger, A. & K. Decker, 2011: 3D geometry and kine-
matics of the Lassee flower structure: Implications 
for segmentation and seismotectonics of the Vienna 
Basin strike-slip fault, Austria.- Tectonophysics, 
499, 1−4, 22−40. DOI: https://doi.org/10.1016/j.
tecto.2010.11.006.
Bella, P., Braucher, R., Holec, J. & M. Veselský, 2014: Da-
tovanie pochovania alochtónnych fluviálnych sedi-
mentov v hornej časti Dobšinskej ľadovej jaskyne 
(IV. vývojová úroveň systému Stratenej jaskyne) 
pomocou kozmogénnych nuklidov [in English: 
Cosmogenic nuclide dating of the burial of alloch-
thonous fluvial sediments in the upper part of the 
Dobšinská Ice Cave (IVth evolution level of the 
Stratenská cave system), Slovakia].- Acta Carsologi-
ca Slovaca, 52, 2, 101−110. 
Bögli, A., 1980: karst hydrology and Physical Speleology.- 
Springer-Verlag, pp. 284, Berlin.
Bosch, R.F. & W.B. White, 2004: Lithofacies and trans-
port of clastic sediments in karstic aquifers.- In: 
Sasowsky, I.D., & Mylroie, J.E. (eds.) Studies of 
cave sediments.- Kluwer Academic/Plenum Pub-
lishers, pp. 1−22, New york. DOI: https://doi.
org/10.1007/978-1-4419-9118-8_1.
Bretz, J.H., 1942: Vadose and phreatic features of lime-
stone caves.- Journal of Geology, 50, 675−811.
Calvet, M., Gunnell, y., Braucher, R., Hez, G., Bourlès, 
D., Guillou, V. & M. Delmas, 2015: Cave levels as 
proxies for measuring post-orogenic uplift: Evi-
dence from cosmogenic dating of alluvium-filled 
caves in the French Pyrenees.- Geomorphol-
ogy, 246, 617−633. DOI: https://doi.org/10.1016/j.
geomorph.2015.07.013.
Curl, R.L., 1966: Scallops and flutes.- Transactions of the 
Cave Research Group of Great Britain, 7, 121−160.
Dzurovčin, L., 1994: Príspevok k poznaniu procesov a 
časového priebehu zarovnávania slovenských Kar-
pát – ich vzťah k neotektonickým fázam a paleo-
geografickému vývoju v Paratethýde (in English: A 
contribution to knowledge of processes and timing 
of planation in the Slovakian Carpathians – its re-
lationship to neotectonic phases and palaeographic 
development in the Paratethys).- Mineralia slovaca, 
26, 2, 126−143.
Farrant, A.R. & P.L. Smart, 2011: Role of sediment in 
speleogenesis; sedimentation and paragenesis.- 
Geomorphology, 134, 79−93. DOI: https://doi.
org/10.1016/j.geomorph.2011.06.006
Ford, D. & P.D. Williams, 2007: karst hydrogeol-
ogy and geomorphology.- John Wiley & Sons 
Ltd, pp. 576, Chichester. DOI: https://doi.
org/10.1002/9781118684986.
during the quaternary. High palaeodenudation values 
calculated from isotopic concentrations indicate episode 
of intense uplift during the earliest Pleistocene, when the 
river network incised into the planation surface to eleva-
tion level of the studied sedimentary profile in the Stará 
Garda Cave. The vertical movement was negligible since 
the early quaternary uplift episode up to recent.
ACKNOWLEDGMENT
This work was supported financially by the Slovak Re-
search and Development Agency under the contracts 
APVV-0099-11, APVV-14-0118, APVV-15-0575, 
APVV-16-0121, APVV-16-0146 and SK-FR-2015-0017 
as well as by the Scientific Grant Agency of the Ministry 
of Education, Science, Research and Sport of the Slovak 
Republic and the Slovak Academy of Sciences (VEGA) 
within the project 1/0602/16. Authors wish to express 
their gratitude to Tomáš Lanczos and Nela Filipčíková 
for their help during the field work. Katarína Šarinová 
is thanked for her kind assistance during petrographic 
analysis. ASTER AMS national facility (CEREGE, Aix 
en Provence) is supported by the INSU/CNRS, the ANR 
through the "Projets thématiques d’excellence" program 
for the "Equipements d’excellence" ASTER-CEREGE ac-
tion and IRD. Prof. Pavel Bosák and an anonymous re-
viewer are thanked for their constructive suggestions, 
which improved the manuscript.
MICHAL ŠUJAN, ALEXANDER LAčNÝ, RéGIS BRAUCHER, PETER MAGDOLEN & ASTER TEAM
ACTA CARSOLOGICA 46/2–3 – 2017 263
Gosse, J.C. & F.M. Phillips, 2001: Terrestrial in situ cos-
mogenic nuclides: theory and application.- quater-
nary Science Reviews, 20, 1475−1560. DOI: https://
doi.org/10.1016/S0277-3791(00)00171-2.
Granger, D.E. & P.F. Muzikar, 2001: Dating sediment 
burial with in situ-produced cosmogenic nuclides: 
theory, techniques, and limitations.- Earth and 
Planetetary Science Letters, 188, 269−281. DOI: 
https://doi.org/10.1016/S0012-821X(01)00309-0.
Granger, D.E., Fabel, D. & A.N. Palmer, 2001: Pliocene–
Pleistocene incision of the Green River, Kentucky, 
determined from radioactive decay of cosmogenic 
26Al and 10Be in Mammoth Cave sediments.- Geolog-
ical Society of America Bulletin, 113, 825−836. DOI: 
10.1130/0016-7606(2001)113<0825:ppiotg>2.0.co;2.
Grohmann, C.H. & G.A.C. Campanha, 2010: OpenSte-
reo: open source, cross-platform software for struc-
tural geology analysis.- Presented at the AGU 2010 
Fall Meeting, San Francisco, CA.
Halouzka R. & D. Minaříková, 1977: Stratigraphic corre-
lation of Pleistocene deposits of the river Danube in 
the Vienna and Komárno Basin.- Sborník geolog-
ických věd, Antropozoikum, 11, 7−55.
Hochmuth, Z., 2008: Krasové územia a jaskyne Sloven-
ska (in English: Carst areas and caves of Slovakia).- 
Geographia Cassoviensis, 2, 2, 1−210.
Hók J., Šujan M. & F. Šipka, 2014: Tectonic division of 
the Western Carpathians: an overview and a new 
approach.- Acta Geologica Slovaca, 6, 2, 135−143.
Jákal, J. 1983: Krasový reliéf a jeho význam v geomor-
fologickom obraze Západných Karpát (in English: 
Carst relief and its importance in a geomorphologi-
cal character of the Western Carpathians).- Geogra-
fický časopis, 35, 2, 160−183.
Kahlke, R.-D., García, N., Kostopoulos, D.S., Lacom-
bat, F., Lister, A.M., Mazza, P.P.A., Spassov, N. & 
V.V. Titov, 2011: Western Palaearctic palaeoenvi-
ronmental conditions during the Early and early 
Middle Pleistocene inferred from large mammal 
communities, and implications for hominin dis-
persal in Europe.- quaternary Science Reviews, 30, 
11−12, 1368−1395. DOI: https://doi.org/10.1016/j.
quascirev.2010.07.020.
Klimchouk, A.B., 2007: Hypogene speleogenesis: hydro-
geological and morphogenetic perspective.- Special 
Paper of the National Cave and Karst Research In-
stitute, Carlsbad, 1, 1−106.
Kováč, M., 2000: geodynamický, paleogeografický a 
štruktúrny vývoj karpatsko- panónskeho regiónu v 
miocéne: Nový pohľad na neogénne panvy Slovenska 
(in English: geodynamical, paleogeographical and 
structural development of the Carpathian-Pannonian 
region in Miocene. New view on Slovak Neogene ba-
sins).- Veda, pp. 202, Bratislava.
Králiková, S., Vojtko, R., Hók, J., Fügenschuh, B. & M. 
Kováč, 2016. Low-temperature constraints on 
the Alpine thermal evolution of the Western Car-
pathian basement rock complexes.- Journal of 
Structural Geology, 91, 144−160. DOI: https://doi.
org/10.1016/j.jsg.2016.09.006.
Lauritzen, S.-E., 1981: Simulation of rock pendants – 
small scale experiments on plaster models.- Pro-
ceedingsof the 8th International Congress of Spele-
ology, Kentucky, 407−409.
Liška, M., 1982: Výskum Borinského krasu a jeho ochra-
na (in English: Research of the Borinka Karst and 
its protection).- Výskumné práce z ochrany prírody, 
4, 3−73.
Lukniš, M., 1955: Správa o geomorfologickom a kvarté-
rne-geologickom výskume Malých Karpát (dolina 
Vydrice) (in English: A report about geomorpho-
logical and quaternary-geological research in the 
Malé Karpaty Mts. – the Vydrica Stream valley).- 
Geografický časopis, 7, 1, 65− 80.
Lukniš, M., 1964: Pozostatky starších povrchov zarovná-
vania v československých Karpatoch (in Eng-
lish: The remnants of older planation surfaces in 
the Czech-Slovakian Carpathians).- Geografický 
časopis, 15, 3, 289−298.
Magdolen, P., 2004: O Starej garde (in English: About the 
Stará Garda Cave).- Spravodaj SSS, 35, 1, 77−82.
Magdolen, P. & Ľ. Sliva, 2003: Jaskyňa Veľké Prepadlé 
P-2 v Malých Karpatoch (in English: The Veľké Pre-
padlé Cave P-2 in the Malé Karpaty Mts.).- Acta 
Carsologica Slovaca, 41, 83−90.
Maglay, J., Halouzka, R., Baňacký, V., Pristaš, J. & J. 
Janočko, 1999: Neotektonická mapa Slovenska v 
mierke 1 : 500 000 (in English: Neotectonic map of 
Slovakia in the scale 1 : 500 000). Ministry of envi-
ronment of the SR, State Geological Survey of Di-
onýz Štúr, Bratislava.
Maglay, J., Pristaš, J., Kučera, M. & M. ábelová, 2009: 
quaternary geological map of Slovakia – quaterna-
ry cover thickness, scale 1:500 000.- State Geologi-
cal Survey of Dionýz Štúr, Bratislava.
Majko, J., 1962: Borinský kras v prieskume (in English: 
Borinka Karst in research).- Krásy Slovenska, 39, 
10, 375−377.
Mazúr, E., 1976: Morphostructural features of the West-
ern Carpathians.- Geografický časopis, 28, 2, 
101−112.
EARLy PLEISTOCENE AGE OF FLUVIAL SEDIMENT IN THE STARá GARDA CAVE REVEALED By 26Al/10Be BURIAL DATING: ...
ACTA CARSOLOGICA 46/2–3 – 2017264
Merchel, S. & S.U. Herpers, 1999: An update on ra-
diochemical separation techniques for the de-
termination of long-lived radionuclides via ac-
celerator mass spectrometry.- Radiochimica 
Acta, 84, 215−219. DOI: https://doi.org/10.1524/
ract.1999.84.4.215.
Meyers, S.R. & L.A. Hinnov, 2010: Northern Hemi-
sphere glaciation and the evolution of Plio-Pleisto-
cene climate noise.- Paleoceanography, 25, PA3207, 
doi:10.1029/2009PA001834.
Miall, A.D., 2000: Principles of Sedimentary Basin Analy-
sis. Third edition.- Springer, pp 616, Berlin.
Miall, A.D., 2006: The geology of fluvial deposits: Sedi-
mentary facies, basin analysis, and petroleum geol-
ogy. fourth edition.- Springier, pp. 584, Berlin.
Minár, J., Bielik, M., Kováč, M., Plašienka, D., Barka, I., 
Stankoviansky, M. & H. Zeyen, 2011: New mor-
phostructural subdivision of the western Carpathi-
ans: an approach integrating geodynamics into 
targeted morphometric analysis.- Tectonophysics, 
502, 1−2, 158−174. DOI: https://doi.org/10.1016/j.
tecto.2010.04.003.
Mitter, P., 1983: Geomorfologická rajonizácia krasu 
Malých Karpát (in English: Geomorphological 
regionalization of the Malé Karpaty Mts. Karst).- 
Slovenský kras, 21, 3−34.
Norton, K.P., von Blanckenburg, F., DiBiase, R., 
Schlunegger, F. & P.W. Kubik, 2011: Cosmogenic 
10Be-derived denudation rates of the Eastern and 
Southern European Alps.- International Journal of 
Earth Sciences, 100, 5, 1163−1179. DOI: https://doi.
org/10.1007/s00531-010-0626-y.
Orvoš, P., 2015: Zarovnané povrchy a ich tektonická 
diferenciácia v podmienkach výzdvihu pohorí (in 
English: Planation surfaces and their tectonic dif-
ferentiation in mountains).- Geografický časopis, 
67, 2, 169−180.
Palmer, A.N., 2007: Cave geology.- Cave Books, 454 pp, 
Dayton.
Plašienka, D., 1987: Lithological, sedimentological and 
paleotectonic pattern of the Borinka Unit in the Lit-
tle Carpathians.- Mineralia Slovaca, 19, 3, 217−230.
Polák, M., Plašienka, D., Kohút, M., Putiš, M., Bezák, V., 
Maglay, J., Olšavský, M., Filo, I., Havrila, M., Buček, 
S., Elečko, M., Fordinál, K., Nagy, A., Hraško, Ľ., 
Németh, Z., Malík, P., Liščák, P., Madarás, J., Slav-
kay, M., Kubeš, P., Kucharič, Ľ., Boorová, D., Zlin-
ská, A., Siráňová, Z. & K. Žecová, 2012: Explanatory 
notes to the geological map of the Malé karpaty Mts. 
in scale 1 : 50 000.- State Geological Survey of Di-
onýz Štúr, pp. 287, Bratislava.
Ruszkiczay-Rüdiger, Z., Braucher, R., Novothny, á., Csil-
lag, G., Fodor, L., Molnár, G. & B. Madarász, 2016: 
Tectonic and climatic control on terrace formation: 
Coupling in situ produced 10Be depth profiles and 
luminescence approach, Danube River, Hungary, 
Central Europe.- quaternary Science Reviews, 
131, 127−147. DOI: https://doi.org/10.1016/j.
quascirev.2015.10.041.
Šajgalík, J., 1958: Pokryvné útvary juhovýchodnej časti 
Devínskej brány (in English: Cover sequences of 
the southeastern part of the Devín Gate).- Acta 
Geologica et Geographica Universitatis Comenia-
nae, Geologica, 1, 197−211.
Sládek, J. & V. Gajdoš, 2014: The morphotectonic view 
of Vydrica valley evolution and its sedimentological 
response.- In: Marek T. et al. (eds.) geomorphologi-
cal proceedings 12: proceedings and excursion guide 
of the conference State of geomorphological research 
in 2014.- Univerzita Jana Evangelisty Purkyně, pp. 
62−63, Ústí nad Labem.
Urbánek, J., 1992: Vývoj dolín v južnej časti Malých Kar-
pát (in English: Evolution of valleys in the south-
ern part of the Malé Karpaty Mts.).- Geografický 
časopis, 44, 2, 162−173.
Urbánek, J., 2014: Malé karpaty – príbeh pohoria (in 
English: Malé karpaty Mts. – a story of mountains).- 
Veda, pp. 144, Bratislava.
von Blanckenburg, F., 2005: The control mechanisms 
of erosion and weathering at basin scale from cos-
mogenic nuclides in river sediment.- Earth and 
Planetary Science Letters, 237, 462−479. DOI: 
https://doi.org/10.1016/j.epsl.2005.06.030.
Wagner, T., Fabel, D., Fiebig, M., Häuselmann, P., Sahy, 
D., Xu, S. & K. Stüwe, 2010: young uplift in the non-
glaciated parts of the Eastern Alps.- Earth and Plan-
etary Science Letters, 295, 159−169. DOI: https://
doi.org/10.1016/j.epsl.2010.03.034.
White, W.B., 2007: Cave sediments and paleoclimate.- 
Journal of Cave and Karst Studies, 69, 76−93.
Wittmann, H., Malusà, M.G., Resentini, A., Garzanti, E. 
& S. Niedermann, 2016: The cosmogenic record of 
mountain erosion transmitted across a foreland ba-
sin: Source-to-sink analysis of in situ 10Be, 26Al and 
21Ne in sediment of the Po river catchment.- Earth 
and Planetary Science Letters, 452, 258−271. DOI: 
https://doi.org/10.1016/j.epsl.2016.07.017.
MICHAL ŠUJAN, ALEXANDER LAčNÝ, RéGIS BRAUCHER, PETER MAGDOLEN & ASTER TEAM