Late Quaternary evolution of the sedimentary environment in 
Modrejce near Most na Soči (Soča Valley, Julian Alps)
Poznokvartarni razvoj sedimentacijskega okolja v Modrejcah pri Mostu na Soči  
(Posočje, Julijske Alpe) 
Petra JAMŠEK RUPNIK
1
, Manja ŽEBRE
1,2 
& Giovanni MONEGATO
3
1
Geološki zavod Slovenije, Dimičeva ul. 14, SI-1000 Ljubljana, Slovenia; e-mail: petra.jamsek-rupnik@geo-zs.si 
2
Aberystwyth University, Department of Geography and Earth Sciences, Llandinam Bldg, Penglais,  
Aberystwyth SY23 3DB, United Kingdom
3
Italian National Research Council CNR, Institute of Geosciences and Earth Resources IGG,  
Via G. Gradenigo 6, 35131 Padova, Italy
Prejeto / Received 19. 5. 2020; Sprejeto / Accepted 13. 11. 2020; Objavljeno na spletu / Published online 7. 12. 2020
Key words: glaciation, glaciofluvial deposition, glaciolacustrine deposits, till, Soča Glacier, Quaternary, Soča 
Valley
Ključne besede: poledenitev, glaciofluvialna sedimentacija, glaciolakustrični sedimenti, til, Soški ledenik, 
kvartar, Posočje
Abstract
Geomorphological and geological mapping have long been used to study the glacial history of the Slovenian 
Alps, but many uncertainties remain regarding the time and extent of Pleistocene glaciations there. Glacial 
landforms and undisturbed glacial deposits are rare in the areas of the former glacier terminus, especially in the 
Soča Valley, where large discrepancies in the interpretation of the extent of the former Soča Glacier have been 
reported. Early studies proved inconclusive as to whether one or two glaciations extended into the Soča Valley as 
far as Most na Soči. In order to answer this question, the Quaternary sedimentary succession and landforms in 
the Modrejce Valley near Most na Soči were investigated. New geological and geomorphological field data allow  
the interpretation of the sedimentary environment and the stratigraphic relationships between different units.
In response to glacial dynamics, the sedimentation developed from glaciofluvial and glaciolacustrine to fully 
glacial environments, followed by slope deposition. At higher altitudes lateral moraines are preserved, while 
the staircase-like slope below has been carved into older glacial, glaciofluvial and glaciolacustrine deposits by 
glacial and post-glacial processes, including fluvial erosion and slope dynamics. We conclude that the succession 
studied here was deposited over the course of two different glacial advances – LGM and pre-LGM. Our study 
thus suggests that the Soča Glacier extended as far as the area of Most na Soči twice over the course of the late 
Quaternary.
Izvleček
Geomorfološke in geološke raziskave zgodovine poledenitev v Slovenskem Alpskem prostoru imajo dolgo 
tradicijo, kljub temu pa še vedno ostaja več nejasnosti o obsegu in času pleistocenskih poledenitev v tem 
prostoru. Ledeniške geomorfne oblike in nepredelani ledeniški sedimenti so redko ohranjeni na območjih 
nekdanjih ledeniških čel, kar še posebej velja za Posočje, za katero so bile poročane različne interpretacije obsega 
nekdanjega Soškega ledenika. Pretekle študije niso uspele ugotoviti, ali je ena ali morda več poledenitev segalo 
tako daleč po Posočju, da je doseglo Most na Soči. Da bi raziskali to vprašanje, smo svojo študijo usmerili na 
kvartarno sedimentacijsko zaporedje in geomorfne oblike v Modrejcah pri Mostu na Soči. Novi terenski geološki 
in geomorfološki podatki omogočajo interpretacijo sedimentacijskega okolja in stratigrafskih odnosov med 
različnimi enotami. V povezavi z ledeniško dinamiko se je sedimentacijsko okolje razvilo iz glaciofluvialnega 
in glaciolakustričnega v ledeniškega, kateremu je sledilo odlaganje pobočnega materiala. Bočne morene so 
ohranjene na višjih legah, medtem ko je stopničasto pobočje vrezano v starejše ledeniške, glaciofluvialne in 
glaciolakustrične sprijete sedimente. Vrezovanje je rezultat delovanja mlajših ledeniških procesov in procesov 
po umiku ledenika, kot so rečna erozija in pobočna dinamika. Sklepamo, da je bilo preučeno sedimentacijsko 
zaporedje odloženo med dvema različnima napredovalnima fazama; v zadnjem poledenitvenem višku in v enem 
izmed prejšnjih. Naša študija tako nakazuje, da je Soški ledenik v poznejšem delu kvartarja dvakrat segal do 
območja Mosta na Soči. 
GEOLOGIJA 63/2, 295-309, Ljubljana 2020
https://doi.org/10.5474/geologija.2020.022
© Author(s) 2020. CC Atribution 4.0 License

296 Petra JAMŠEK RUPNIK, Manja ŽEBRE & Giovanni MONEGATO
Introduction 
The glacial history of the southeastern Alps 
covers multiple glaciations, which were first es-
tablished by Penk & Brückner (1901–1909). Im-
provements in dating methods allowed for bet-
ter characterization of the chronology of the last 
glacial cycle (Monegato & Ravazzi, 2018), es-
pecially for the Last Glacial Maximum (LGM), 
which is best preserved due to its young age 
(about 26–19 ka, e.g., Monegato et al., 2007; Ivy-
Ochs et al., 2008; Ivy-Ochs, 2015; Monegato et al., 
2017). In the Alps, deposits related to older gla-
ciations are difficult to date (e.g., Dehnert et al., 
2012; Lowick et al., 2015; Rades et al., 2016) and 
their relative chronologies are inferred through 
their stratigraphic relationship with the alluvi-
al-coastal stratigraphy (Fontana et al., 2010) or 
through analysis of their boundaries, which are 
sometimes characterized by paleosoils or peat 
layers (Gianotti et al., 2015). 
The Alps in Slovenia hosted three large val-
ley glaciers – the Soča, Sava Dolinka and Sava 
Bohinjka glaciers – as well as small cirque and 
valley glaciers in the Kamnik-Savinja Alps and 
the Karavanke Mountains (Bavec & Verbič, 2011) 
(Fig. 1). Small ice caps independent from the 
major Alpine valley glaciers were present in the 
Northern Dinaric sector (Žebre et al., 2013, 2016). 
Although the glacial history of the Slovenian ter-
ritory has been studied since the late 19th cen-
tury, many uncertainties remain about the tim-
ing and extent of Pleistocene glaciations in the 
Slovenian Alps (Bavec & Verbič, 2011; Ferk et al., 
2017). This is especially true for the Soča moun-
tain basin, where spatially incomplete records 
on landforms and lack of geochronological data 
still do not allow us to make any thorough re-
constructions of former ice limits. In fact, earlier 
studies suggested that during the Würm (sensu 
Chaline & Jerz, 1984) the Soča Glacier extended 
southwards out of the Julian Alps down to Tol-
min and even further, to Most na Soči (Brückner, 
1891; Tellini, 1898; Penck & Brückner, 1901–1909; 
Feruglio, 1925; Winkler, 1931; Melik, 1954; Šifrer, 
1965). On the other hand, more recent findings 
suggest that the Soča Glacier did not even reach 
Fig. 1. LGM glacier extent 
in southeastern European 
Alps. The extent of the mo-
delled LGM glacier driven 
by the EPICA paleo-tem-
perature record and paleo-
-precipitation correction is 
after Seguinot et al. (2018), 
while the geomorphologi-
cal reconstruction of the 
extent of the LGM glacier is 
modified from Ehlers et al. 
(2011). The digital terrain 
model is from SRTM data 
(Shuttle Radar Topography 
Mission), accessible from 
EarthExplorer (https://
earthexplorer.usgs.gov/).

297 Late Quaternary evolution of the sedimentary environment in Modrejce near Most na Soči (Soča Valley, Julian Alps)
beyond the Bovec Basin, which is located more 
than 30 km upstream from Most na Soči (Bav-
ec et al., 2004). Such large discrepancies are the 
result of sparse landform records as well as the 
overprinting of glacial evidence by subsequent 
glacier re-advances and late- to post-glacial 
slope processes. Moreover, the most up-to-date 
model-based simulations of the LGM ice extent 
in the Eastern Alps, including the Slovenian Alps 
(Seguinot et al., 2018) (Fig. 1), are not in accord-
ance with the roughly defined geomorphological 
ice limits, which makes interpretation of the ex-
tent of paleo-glaciers here even more questiona-
ble and in need of new data. 
In the past, glacial and proglacial sediments 
in the Soča Valley were studied using geological 
and geomorphological methods to constrain the 
extent of the glacier and interpret its dynamics 
(Šifrer, 1964/1965; Kuščer et al., 1974; Kunaver, 
1975, 1980; Bavec et al., 2004). Glacial deposits 
from the last and penultimate glaciations were 
dated in the Bovec Basin (Bavec et al., 2004). 
Quaternary deposits in the Most na Soči area 
have been studied previously by Šifrer (1965) and 
more recently mapped by Buser (1987) as part of 
the basic 1:100.000 geological map. According to 
Šifrer (1965) the distribution of till and proglacial 
deposits suggests that the Soča Glacier was divid -
ed into two ice lobes south of Tolmin. Although 
glacial landforms and deposits in this area have 
been identified and described very precisely, it 
is unclear whether they were deposited over the 
course of one or several glaciations. Any reliable 
absolute dating that could reveal the age of gla-
cial deposits around Most na Soči is still missing. 
This study focuses on late Quaternary deposits 
in the Modrejce Valley located between Tolmin 
and Most na Soči (Fig. 2), where steep cliffs pro -
vide good exposures for the study of stratigraph-
ic relationships among the sedimentary units. 
Fig. 2. Distribution of 
Quaternary deposits in 
the Tolmin and Most na 
Soči areas (updated af-
ter Šifrer, 1965 and Buser 
1987). Shaded relief is 
derived from LiDAR ba-
sed DEM (Ministry of the 
Environment and Spatial 
Planning, Slovenian 
Environment Agency, 
2011).

298 Petra JAMŠEK RUPNIK, Manja ŽEBRE & Giovanni MONEGATO
Using geological and geomorphological mapping 
and sedimentological analysis we investigated 
the landforms and deposits, interpreted their 
sedimentary environments, and established their 
relative chronological relationships. This enabled 
us to reconstruct the late Quaternary sedimenta-
ry evolution of this area in relationship to glacial 
advances and slope dynamics.
Methods
Quaternary landforms and deposits in the 
Modrejce Valley were studied using geomorpho-
logical and geological mapping, as well as sed-
imentological facies analysis. A map of Quater-
nary deposits in the wider Tolmin area (Fig. 2) 
was summarized from Šifrer (1965), Buser (1987) 
and our GIS- and field-based geomorphological 
and geological mapping. A detailed map of Qua-
ternary landforms in the selected area of Modre-
jce (Fig. 3A) was prepared by means of field-
based geomorphological and geological mapping 
along with a stacked cross-section (Fig. 3B) and 
description of landforms (Figs. 4 and 5) and de-
posits (Fig. 6). 
Geomorphological mapping was based on Li-
DAR data with a relative horizontal and vertical 
accuracy of 0.30 and 0.15 m, respectively (Min-
istry of the Environment and Spatial Planning, 
Slovenian Environment Agency, 2011). The Li-
DAR-based DEM with 1 m resolution was used 
to generate a shaded relief map, a slope degree 
map, a slope aspect map and contour lines with 
an equidistance of 1 m. These various topograph-
ic representations helped to distinguish different 
geomorphic characteristics associated with Qua-
ternary sedimentation and erosion (e.g. terraces, 
cliffs, moraines, colluvial fans). 
Quaternary deposits were documented using 
field sedimentological logging. Each unit was 
described according to its lithology using clas-
sifications by Wenthworth (1922) and Folk et al. 
(1970) and according to its various sedimentary 
characteristics described by Tucker (2011). The 
lithology of the units is described based on mac-
roscopic observations. The lithological composi-
tion of the clasts is given qualitatively. Facies are 
summarized according to Eyles et al. (1983) and 
Miall (2006) codes respectively for glacigenic and 
alluvial/deltaic deposits (Table 1) and into faci-
es associations as in Miall (2006) and Benn and 
Evans (2010). This approach enabled us to gather 
the data necessary to interpret the depositional 
environment, its evolution and clast provenance.
Quaternary deposits in the Soča Valley 
around Tolmin and Most na Soči 
The Soča Valley floor around Tolmin and 
Most na Soči is mainly covered with glaciofluvi-
al, fluvial and alluvial fan deposits (Fig. 2). Two 
units of fluvial deposits were distinguished: the 
younger fluvial deposits represent the Holocene 
thalweg of the Soča River, and the older fluvial 
and glaciofluvial deposits are terraced. The ter-
races have risers that vary in size from several 
meters to more than 50 meters. In several places 
the terraces are covered by alluvial fans related 
to small tributaries of the Soča River. Based on 
relative elevation, landform preservation, sed-
iment characteristics, pedogenesis and cemen-
tation, the terraces are assumed to be Middle to 
Late Pleistocene in age, while the alluvial fans 
are assumed to be Late Pleistocene (Šifrer, 1965). 
Lacustrine and glacial sediments are also 
present in the valley, whereas scree deposits are 
Table 1. Facies codes used in this study are summarized from Eyles et al. (1983) and Miall (2006). 
Facies code Facies Sedimentary structures
Gcm Clast-supported, massive gravel /
Gmm Matrix-supported, massive gravel Weak grading
Gh Clast-supported, crudely bedded gravel Horizontal bedding, imbrication
Gp Gravel, stratified Planar cross-beds
Gt Gravel, stratified Trough cross-beds
Sm Sand, fine to coarse Massive, or faint lamination
Sh Sand, very fine to coarse, may be pebbly Horizontal lamination
Sr Sand, very fine to coarse Ripple cross-lamination
Fl Sand, silt, mud Fine lamination, very small ripples
Fsm Silt, mud Massive 
Dmm Matrix-supported, massive diamict /
Dms Matrix-supported, stratified diamict Stratification more than 10 % of unit thickness
Dcm Clast-supported, massive diamict /
Dcs Clast-supported, stratified diamict Stratification more than 10 % of unit thickness
Dcg Clast-supported, graded diamict Vertical grading in clast content

299 Late Quaternary evolution of the sedimentary environment in Modrejce near Most na Soči (Soča Valley, Julian Alps)
abundant on the toe of valley slopes. Lacustrine 
sediments are laminated and well-consolidated 
muds, silts to sands. Their stratigraphic relation 
to the glaciofluvial succession places their dep-
osition into glaciation (Šifrer, 1965). Glacial de-
posits are spread on the saddle that closes the 
Modrejce Valley to the west (Fig. 2) up to about 
280 m a.s.l. and form morainic ridges, whose out-
crops show loose glacial deposits. Here, a thin 
soil (about 10 cm) developed on them and the de -
posit lacks any considerable sign of weathering. 
The shape of these moraines indicates they are 
well preserved, and their minimal weathering 
is similar to that of the LGM glacial deposits in 
Fig. 3. Quaternary landforms and deposits of the Modrejce Valley. A - Geomorphic map. B – Stacked cross-section of landforms 
and facies associations. Note that in order to capture all units, the topographic profiles of individual landforms were projected 
into stacked cross-sections from different parts of the map. The points at the surface are the actual projected vertices taken 
from the LiDAR DEM every 5 m across the terrace-like landforms. Topographic contours 1 m equidistant from each other are 
derived from LiDAR based DEM (Ministry of the Environment and Spatial Planning, Slovenian Environment Agency, 2011).

300 Petra JAMŠEK RUPNIK, Manja ŽEBRE & Giovanni MONEGATO
the nearby area (Monegato et al., 2007; Žebre et 
al., 2013; Colucci et al., 2014), suggesting a com-
parable young age. Cemented and weathered 
glacial deposits are also present within the suc-
cession and at different elevations up to about 
500 m a.s.l.; they were likely deposited in differ-
ent phases of glacial advance during the LGM or 
earlier (Šifrer, 1965).
Fig. 4. Three-dimensional view of the Modrejce Valley with main landforms from the Fig. 3 (M – moraine, T4, T5S and T10S 
– terraces) and locations of the photos from Fig. 5. Digital orthophoto (Public Information of Slovenia, the Surveying and 
Mapping Authority of the Republic of Slovenia, DOF, 2011) is draped over LiDAR-based DEM (Ministry of the Environment 
and Spatial Planning, Slovenian Environment Agency, 2011).
Fig. 5. Field photos of the Modrejce Valley landforms. A – Moraine, terraces and colluvial fan on the NE slopes of the valley. B – 
Moraines on both sides of the valley (photo taken from the NE side). C – Talus slope with corresponding scree deposits outcrop -
ping in a quarry on the NE slopes. D – Talus slopes above the moraine on the NE side. See Fig. 4 for locations of the photos.

301 Late Quaternary evolution of the sedimentary environment in Modrejce near Most na Soči (Soča Valley, Julian Alps)
Quaternary deposits and landforms  
of the Modrejce Valley
The Modrejce Valley is a tributary valley of the 
Soča Valley, running between the Bučenica and 
Mrzli vrh hills northwest of Most na Soči (Fig. 2). 
The Modrejce Creek runs through the valley. The 
bedrock on the NE slopes consists of platy Volče 
limestone with chert (Upper Cretaceous; Coni-
acian – Campanian), which is separated by the 
dextral strike-slip Idrija Fault from the coarse-
grained limestone breccia with intercalations of 
flysch (Upper Cretaceous; Maastrichtian) build-
ing the bedrock on the SW slopes (Buser, 1987). 
The valley hosts glacial sediments, as well as gla -
ciofluvial and scree deposits (Šifrer, 1965). 
Ten terrace-like surfaces separated by steps 
and cliffs were mapped on the hillslopes of the 
Modrejce and Soča valleys between 170 and 250 m 
a.s.l. (Figs. 3 and 5A). These surfaces are tens of 
meters wide and are not flat like common terrac-
es; they instead slope gradually (5–15°) towards 
the valley bottom, in contrast to the steep slope of 
the valley flanks. The related deposits are partial -
ly covered by colluvial fans and aprons. Moraines 
are present at higher elevations (250–280 m a.s.l.) 
and characterize the saddle closing the Modrejce 
Valley to the west (Figs. 3 and 4). Talus is present 
at even higher elevations (Figs. 3A and 5C, D). 
The cliffs expose a complex series of Quater-
nary clastic deposits of mostly sandy conglom-
erates to gravels (Gh, Gp, Gt, Gcm) intercalated 
with layers of sandstones, sands (Sm, Sh, Sr) and 
silts (Fl, Fsm) (Fig. 6A-I). Local clast-supported 
to matrix-supported coarse breccias (Dcs, Dcm, 
Dcg) are interbedded. Matrix-supported diamic-
ton (Dmm, Dms) characterizes some thick layers. 
The prevailing lithology of the clasts is limestone, 
whereas other lithologies occur including chert, 
cherty limestone, red marly limestone (Scaglia 
Rossa Formation), sandstone with mica, green 
marl and dolostone. Layers are mostly sub-hori-
zontal; in some outcrops the bedding gently dips 
SE, WNW or SWS. Cross-bedding dips W to SW, 
indicating the transport from E and NE. 
The mapped deposits in the Modrejce Valley 
can be divided into five facies associations (FA) 
(Fig. 3B) according to their lithologic properties 
and their stratigraphic relations. 
The FA-A consists of horizontal- to cross-bed -
ded sandy gravels (Gh, Gp) with beds of crude-
ly bedded gravels (Gcm) (Fig. 6A-B). Clast-size 
ranges from fine grained pebble to cobble and 
even small boulders occur. Gravels are poorly 
sorted and clast-supported; they are mostly ce-
mented but with some loose gravel layers. Clasts 
are sub-angular to rounded, mostly sub-rounded 
clasts prevail, some layers of prevailing rounded 
or sub-angular clasts occur. Lenses of massive 
silt and sand (Fsm, Sm) are interbedded.
The FA-A can be associated with fluvial dep-
osition. The sedimentary structure with horizon-
tal- and cross-bedding is typical for braided riv-
er deposits (Miall, 2006); however, the variation 
in roundness between subangular and rounded 
clasts stands in contrast to the fluvial environ-
ment typical of the Soča River during a warm 
period. The Soča River flows along its valley for 
about 60 km before reaching the investigated lo-
cation, and its Holocene gravels are well round-
ed. Cross bedding in outcrops below T10 and T4 
indicates the sediments were mostly deposited 
from E, NE and SE, which points to the Soča 
Valley. Also, the lithological composition of clasts 
indicates paleo-Soča provenance. Local sedi-
mentation by the Modrejce Creek is therefore ex-
cluded. Based on the roundness of the clasts and 
the largely poorly sorting we interpret the FA-A 
as glaciofluvial, related to the outwash stream of 
the Soča Glacier close to the valley slope. 
FA-B is represented by a coarsening upward 
succession from laminated or massive silt (Fl, 
Fsm) to cross-bedded conglomerates (Gp), out-
croppi ng on both sides of the Mod rejce Val ley ( F ig. 
3B). Thick lenses of horizontal- and cross-lami-
nated sands (Sh, Sr) and silts (Fl) with angular to 
sub-rounded dropstones up to 10 cm in size (Fig. 
6D) occur below T4. Sand ripples (Sr) are visible 
in some parts of these layers. A succession con-
sisting of horizontal-laminated silt to sand (Fl, 
Sh) up to 2 m thick crops out in the cliff below 
T10 on both sides of the Modrejce Valley (Fig. 6E-
G). There, silts and sands occasionally include 
sub-angular to rounded dropstones up to 2 cm in 
size. Laminas of sandstone with sand ripples (Sr) 
are locally present within loose sand. The suc-
cession shows reverse gradation from silts at the 
bottom to fine and coarse sands towards the top. 
Although not continuously exposed, the lateral 
extent of this succession can be followed in the 
southern cliff for some 150 m. The fine-grained 
succession is overlain with fine grained conglom -
erates (Gp, Gh), followed by coarser grained con-
glomerates (Gp, Gh), with angular to sub-round-
ed clasts. The cross-bedding dips about 30° to the 
SW (Fig. 6H). 
The finer layers of laminated silt and sand with 
dropstones and sand ripples (FA-B) intercalated 
within the FA-A are interpreted as lacustrine to-
esets and bottomsets. Since they occur within the 
glaciofluvial succession and include dropstones 

302 Petra JAMŠEK RUPNIK, Manja ŽEBRE & Giovanni MONEGATO
they are likely related to a glaciolacustrine en-
vironment. Moreover, the thicker succession of 
reverse grading silts and sands in the cliff be-
low T10S followed first by cross-bedded sandy 
conglomerates dipping towards the SW and then 
horizontal- to cross-bedded sandy conglomerates 
likely indicate toeset to foreset transition in a 
Gilbert-type delta succession (e.g. Nemec, 1990) 
at the margin of the glacier in a southwestward 
progradation during glacial advance. 
FA-C consists of layers of sandy breccia (Dcs, 
Dcm) occasionally present as interbedded layers 
within sandy conglomerates of FA-A. The sandy 
breccia is poorly sorted and clast supported, with 
angular to sub-rounded clasts, where sub-angu-
lar clasts prevail (Fig. 6C). In one case, we found 
facies of boulder size breccia without matrix 
(Dcg), filling the depression in FA-A in a cliff 
below T4. This breccia is massive, clast-support-
ed, cemented and normally graded (Fig. 6J). The 
Fig. 6.

303 Late Quaternary evolution of the sedimentary environment in Modrejce near Most na Soči (Soča Valley, Julian Alps)
clasts are angular to rounded, while sub-angular 
clasts prevail. Clasts range in size from 10 cm to 
more than 1 m.
Layers of sandy breccia may be interpret-
ed either as facies of glaciofluvial deposits or as 
slope deposit. In some cases, the dipping of lay-
ers towards S (towards the bottom of the val-
ley) suggests deposition from the slopes. Facies 
of boulder-size breccia without matrix (Dcg) is 
peculiar in the system in view of the large size 
of the clasts and the absence of matrix. Due to 
the normal grading and roundness of the clasts 
we assume these deposits were formed by slope 
redeposition. The slope material likely originated 
from older glacial or periglacial sediment higher 
on the slopes, since some clasts within this FA 
are sub-rounded. Therefore, short gravity slope 
material was likely mixing with glaciofluvial 
material. 
Fig. 6.

304 Petra JAMŠEK RUPNIK, Manja ŽEBRE & Giovanni MONEGATO
FA-D is a complex association consisting of 
prevailing sandy breccia (Dcm, Dcs, Dmm, Dms) 
interbedded with sandy conglomerates (Gh, 
Gcm). Alternating stratified (prevailing; Dcs, 
Dms, Gh) and massive facies (Dmm, Dcm, Gmm, 
Gcm) occur and clast-supported (prevailing; 
Dcm, Dcs, Gcm, Gh) and matrix-supported fa-
cies (Dmm, Dms, Gmm) are present (Fig. 6K-N). 
Sandy breccia is poorly sorted, clast supported, 
with angular to rounded clasts, where angular 
to sub-angular clasts prevail. In parts, it con-
sists of horizontally-bedded sandy breccia with 
fine-grained horizons (average clast size 2–8 mm, 
maximum 1 cm) and coarse-grained ones (aver-
age clast size 2 cm, maximum 15 cm) (Fig. 6K). In 
other parts, the sandy breccia is massive (Dcm), 
clast supported, with fine grained gravel and 
sand as a matrix and chaotically oriented angu-
lar clasts of up to 50 cm in size (Fig. 6L). Boulders 
more than 1 m occur locally within the breccia. 
Occasionally, the breccia is replaced by massive 
to stratified, poorly sorted and clast supported 
sandy conglomerates (Gh, Gcm), with angular 
to rounded clasts, with sub-rounded clasts pre-
vailing (Fig. 6M). Interbedding between prevail-
ing stratified and less often massive structure, 
clast- and matrix-supported structure, breccia 
and conglomerates, continues through this part 
of the Modrejce succession. The prevailing li-
thology of the clasts is limestone, whereas marls 
and limestone with chert are also common, and 
other lesser lithologies include red marly lime-
stone (Scaglia Rossa Formation), sandstone with 
mica, green marl and dolostone. Layers are most -
ly sub-horizontal, with occasional SE dipping 
layers also outcropping. The deposits of this FA 
Fig. 6. Outcrops visible on the cliffs of the Modrejce Valley (A-D and J: cliff below terrace T4; E-I: cliff below terrace T10S; 
K-O: cliff below moraine; P: top of moraine). A – Silt and sand (Fsm, Sm) interbedded with cemented sandy gravel (Gcm, 
Gh). B – Sandy conglomerate with cross-bedded structure (Gp). C – Sandy breccia (Dcm). D – Horizontally laminated silt to 
sand with dropstones (Fl, Sh). E – Horizontally laminated silt (Fl) to sand (Sh, Sr) overlaid with sandy conglomerate (Gcm). 
F – Sand with scattered pebbles (Sm). G – Laminated sandstone (Sh) overlaid with sandy conglomerate (Gh). H - Horizontally 
laminated sand (Sh) overlaid with cross-bedded sandy conglomerate (Gp). I – Vertical coarse grading of horizontal- and cross-
-bedded sandy conglomerate (Gh, Gp). J – Boulders without matrix filling the depression over sandy conglomerate (Dcg). K 
– Horizontally-bedded coarse sandy gravels (Gh). L – Massive sandy breccia with chaotically oriented angular clasts (Dcm). 
M – Massive sandy conglomerate (Gcm). N – Contact between sandy breccia below (Dms) and sandy conglomerate (Gh) on top. 
O and P – Matrix supported, massive diamicton (Dmm).

305 Late Quaternary evolution of the sedimentary environment in Modrejce near Most na Soči (Soča Valley, Julian Alps)
are cemented, and clasts, which are composed of 
clastic rocks partially weathered in otherwise 
not pedogenized deposits. 
The mixing association FA-D crops out in the 
cliff below the moraines and indicates a contin-
uous change in the depositional mechanism from 
glacial (massive, matrix-supported sandy breccia 
to conglomerate with chaotically oriented clasts) 
to glaciofluvial (stratified, clast supported, poor -
ly sorted conglomerates), where the glaciofluvi-
al may be related to the proglacial or subglacial 
streams.
FA-E consists of facies of massive and ma-
trix-supported silty to sandy diamicton (Dmm) 
with boulders (Fig. 6O), with local lenses of mas-
sive sand (Sm) and gravels (Gmm). This diamic-
ton has angular to rounded clasts, some of which 
are striated and polished. The deposit is nor-
mally- to over-consolidated towards the bottom. 
Clasts have not developed weathering rings, and 
deep weathering structures are absent, with only 
a thin layer of soil (roughly 10 cm) developed on 
these deposits.  
The FA-E characterizes the uppermost depos-
its, which are interpreted as a glacial till and are 
morphologically represented by lateral moraines 
present at 250–280 m a.s.l. in the Modrejce Val-
ley; these belonged to the sedimentation by the 
two lobes of the Soča Glacier surrounding Mount 
Bučenica (Fig. 2). 
Our interpretations of the depositional en-
vironments of FA-A, FA-B, FA-D and FA-E are 
consistent with earlier interpretations by Ši-
frer (1965). At several points in the Soča Valley, 
between Tolmin and Most na Soči, Šifrer also 
noted that certain terraces include sediments 
with different genesis and that these sediments 
do not correspond to the individual terrace as 
a landform, since the terrace landforms are cut 
into older sediments. Likewise, geomorphologi-
cal evidence indicates that terrace-like surfaces 
T4-T10 in the Modrejce Valley are not related to 
glaciofluvial deposits exposed in the cliffs. The 
studied glaciofluvial succession was deposited 
from the bottom of the valley upwards, regard-
less of the terrace levels, as suggested by a gla-
ciolacustrine layer 2 m thick outcropping in the 
cliff below T10S on the southern side, and below 
T7 on the northern side of the valley. In contrast, 
fill terraces would each be composed of mate-
rial of the same sedimentary facies origin and 
the uppermost terraces would include the old-
er deposits. This suggests that the terrace-like 
surfaces T4-T10 in Modrejce are likely erosional 
landforms. 
Since glaciofluvial deposits were overrun by 
the glacier, terrace-like landforms were proba-
bly cut into glaciofluvial and glaciolacustrine de -
posits by subglacial erosion and mostly by sub-
sequent post-glacial fluvial erosion, additionally 
reshaped by ongoing slope processes. Any sedi-
ments related to glacial and post-glacial fluvial 
erosion processes were not preserved in the ex-
posed cliffs below terrace-like surfaces, except 
for the glacial deposits in the uppermost flat area 
(FA-E). However, they could be present on top 
of the terrace-like surfaces, but due to the lack 
of outcrops there, this cannot be verified with-
out invasive research techniques. Furthermore, 
any sediments from this period would be bur-
ied near the slopes by the younger colluvial fans 
and aprons visible in the geomorphology (Fig. 3). 
Based on the geomorphological evidence alone, 
it could be speculated that post-glacial erosion 
may have created two paired and eight unpaired 
terrace-like surfaces. Their relationships are not 
clear due to the complex depositional and ero-
sional history of the valley. The erosional pro-
cesses were likely partly impacted by the lith-
ological changes between glaciolacustrine and 
glaciofluvial deposits, promoting steep slopes in 
coarse-grained cemented units. 
The lowermost terraces T0-T3 were not sub-
jected to detailed sediment mapping. Based on 
spatial distribution, T1-T3 landforms are more 
likely fluvial terraces. T0 is one of a few broader 
Soča terraces (Šifrer, 1965).
Evolution of Quaternary sedimentary 
environment in the Modrejce Valley
The stratigraphic architecture of the Modre-
jce Valley deposits suggests that several phases of 
deposition and erosion occurred during the late 
Quaternary. The glaciofluvial environment (FA-
A) related to the Soča Glacier was occasionally 
mixing with short-period (glacio)lacustrine (FA-
B) and the slope deposition environment (FA-C). 
Towards the top of this succession, the glaciola-
custrine delta deposits (FA-B) indicate the close 
proximity of the glacier. The succession continues 
with the glacial deposition in exchange with the 
glaciofluvial one (FA-D). The overall succession 
was buried by glacial deposits (FA-E). The sub-
sequent incision of the Modrejce Valley was char-
acterized by slope deposition, which continues to 
this day. The entire studied succession, except for 
the covering slope deposits, was therefore depos-
ited during cold phases and recorded fluctuations 
in the glacier terminus position around Tolmin 
and Most na Soči. Phases of glacial advance and 

306 Petra JAMŠEK RUPNIK, Manja ŽEBRE & Giovanni MONEGATO
retreat were already proposed in this area by Ši-
frer (1965), based on geomorphic and sedimento-
logical records in the Soča Valley (Fig. 2). 
The sedimentological and geomorphic records 
presented in this study show that the succession 
was likely deposited over the course of at least 
two different glacial phases (Fig. 7). In the later 
glacial phase, FA-E was deposited. Its degree of 
weathering (shallow soil, absence of deep weath-
ering structures such as deep soil or cryoturba-
tion and no weathering rings on clasts), the ab-
sence of cementation and the preservation of 
landforms (moraines present, with no erosion fea -
tures developed on their surfaces) in the Modre-
jce saddle point to the LGM age. Similar type of 
landforms that have been clearly attributed to the 
LGM remain preserved in the south-eastern Al-
pine valleys (e.g., Pellegrini et al., 2005; Ravazzi 
et al., 2012; Colucci et al., 2014). One of the mod-
eled extents of the LGM glaciation by Seguinot et 
al. (2018) also nearly reached Tolmin and is thus 
roughly in agreement with our estimation. In an 
Fig. 7. Reconstruction of sedimentary phases showing the unique situation in the Modrejce Valley.

307 Late Quaternary evolution of the sedimentary environment in Modrejce near Most na Soči (Soča Valley, Julian Alps)
earlier glacial phase, FA-A to FA-C were deposit-
ed during the glacier retreat phase and FA-D de -
posited during the following glacier advance into 
the Modrejce Valley. In view of the overall cemen -
tation of FA-A to FA-D, the presence of partly 
weathered clasts of clastic rocks in otherwise not 
pedogenized glacial diamicton (Dmm) in FA-D 
and the absence of related landforms it is likely 
that deposition of these successions occurred be-
fore the LGM and that successions were subse-
quently covered by lodgment till deposits (e.g., Re -
itner and Draxler, 2002). The succession of FA-A 
to FA-D was then eroded during the subsequent 
interglacial/interstadial phase and carved by 
the Soča Glacier during the last glacial advance, 
when moraines (FA-E) were settled all along the 
flat areas of the Modrejce Valley. During the Late 
Glacial, the succession was eroded again as a re-
sult of post-glacial processes; small flat surfaces 
were shaped into a staircase-like slope. During 
the Holocene, a final slope/scree deposition was 
established and continues to this day. 
Similar slope developments as in Modrejce 
Valley can be observed in post-glacial incisions 
in Alpine valleys (e.g. Ravazzi et al., 2012; Reitner 
et al., 2016). However, it is a rare case that older 
deposits have been preserved in such abundance 
after the interglacial / interstadial erosion phase 
and the subsequent glacial accumulation and 
erosion phase. The conservation capacity of older 
loose and poorly cemented sediments during gla-
cial erosion is negligible, everywhere in similar 
environments in the Alpine region. The excep-
tional case in our study could be due to the shel-
tered position of Modrejce Valley in the passage 
between the hills Bučenica and Mrzli vrh, which 
was located outside the two main erosion corri-
dors of the Soča Glacier, which split and encased 
around Bučenica (Fig. 2). Our interpretation of 
the depositional records thus represents a new 
and original contribution to the understanding of 
glacial and post-glacial landscape development. 
Our reconstruction implies that the last, as 
well as one of the earlier glaciations reached 
the Most na Soči area, as suggested by Šifrer 
(1964/1965) and even earlier studies (Brückner, 
1891; Tellini, 1898; Penck & Brückner, 1901–1909; 
Feruglio, 1925; Winkler, 1931; Melik, 1954). Since 
our provisional age estimates are based on com-
parisons of qualitative data, further quantitative 
chronological indications are needed to better 
narrow and constrain the age of these glacial ad-
vances, which information would cast new light 
on the geomorphological evolution of the Most na 
Soči valley knot.
Conclusions
Our study of the Quaternary deposits in the 
Modrejce Valley offers new insights into the ex-
tent of glaciation in the Slovenian Alps, espe-
cially in the Soča Valley. The Quaternary sedi-
mentary environment in this area developed in 
response to glacial dynamics from glaciofluvial, 
glaciolacustrine and slope intercalation to gla-
cial deposition. Depositional records of glacio-
fluvial, glaciolacustrine and glacial sedimen-
tation in the Modrejce Valley are related to the 
Soča Glacier and show that the glacier reached 
the Most na Soči area twice in the late Quater-
nary. The investigated succession was deposited 
over the course of two different glacial periods, 
which we interpreted as LGM and pre-LGM gla-
ciation. The glacial and glaciofluvial deposits 
from the earlier phase are abundant, despite the 
subsequent glacial overflow in the LGM. This 
is probably due to the unique sheltered position 
of Modrejce Valley, which was outside the main 
erosional path of the Soča Glacier. Such sites are 
of crucial importance for the study of alpine gla-
cial history. Further work with absolute dating 
methods is necessary to narrow the age of these 
glacial advances.
Acknowledgements
The study was carried out as part of program P1-
0011, Regional Geology, and as a preliminary study 
for project J1-2479, Past climate change and glaciati-
on at the Alps-Dinarides junction, both funded by the 
Slovenian Research Agency (ARRS). This work forms 
the basis for the ongoing structural investigation of 
the area. We would like to thank Jernej Jež from the 
Geological Survey of Slovenia for his field assistan-
ce and constructive comments during the preparati-
on of the manuscript. Two anonymous reviewers are 
acknowledged for their comments on the manuscript, 
which have contributed to the improvement of the 
manuscript.  
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