E-ISSN : 2541-5794  
   P-ISSN : 2503-216X  

Journal of Geoscience,  
Engineering, Environment, and Technology 
Vol 03 No 02 2018 

 

 
128  Cahyaningsih, C. et al./ JGEET Vol 03  No 02/2018  

 

Lithofacies And Depositional Analysis Environment of West 
Section Kolok Nan Tuo, Sawahlunto, West of Sumatera 

Catur Cahyaningsih
1
, Anjas Latif Ritonga

1
, Shaury Aldila

1
, Zulhikmah

1
 

1
Department of Geological Engineering, Universitas Islam Riau, Pekanbaru-Riau, 28284, Indonesia 

 
* Corresponding author : caturcahyaningsih@eng.uir.ac.id 
Tel.:+81-72-867-1686 

Received: 2 June, 2017. Revised : 24 May,  2018, Accepted: 30 May, 2018, Published: 1 June 2018 
DOI: 10.24273/jgeet.2018.3.2.340 
 

Abstract 
Study areas were located to the west of Kolok Nan Tuo Village. Geographically this area is located at coordinates 00° 36' 
57,85'' - 00° 37' 56,89'' latitude and 100°42' 10,08 '' 100°43' 47,28" longitude. The methods used in research is geological 
mapping. Based on the results of stratigraphic research area is divided into three units: Crystalline Limestone Unit (SBGK) 
consisting Crystalline Limestone of and mudstone lithofacies, Conglomerate Units (SK) consists of polymic conglomerate 
and sandstones greywacke lithofacies while claystone Unit (SBL) lithofacies consists of claystone with sedimentary flake 
structures. Result of research suggested that depositional environment based on type of lithofacies include of grain size, 
sedimentary structures and content of fossils. SBGK interpreted as basement of basin, SK depositional environment was 
debris unit limestones, which can be seen from fragments of conglomerates that consist of crystalline limestones and 
mudstone that deposited in alluvial fan (deposition surface). Clay lithologies where mudstone generally deposited in 
current flow that form flake structures and calcareous, that interpreted deposited in neritic environment. 

 
Keywords: Ombilin basin, geological mapping, lithofacies, Kolok Nan Tuo 

 

 

1. Introduction 

The Geological process is a process associated 
with the formation of the earth regarding both 
tectonic and regarding its constituent rocks. While 
the field study conducted by researchers intend to 
map the distribution of rocks in the West Section 
of Kolok Nan Tuo (Fig. 1), which will be grouped 
based on the lithology of their respective 
characteristics and the depositional environment is 
also different. So that the results of these studies 
will produce a geological map.  

2. Basic Theory 

 Many experts define different facies. However, 

they generally agree that the facies is characteristic 

of sedimentary rock units. According to Selley 

(Walker, 1985 and James 1992) facies sediments is 

a body of rock that can be identified and 

differentiated from other rock units by geometry, 

lithology, sedimentary structures,  fossils, and the 

pattern of their ancient stream. Armed with the 

physical, chemical, and biological environments 

can be reconstructed in the deposition of 

sedimentary rock sequences and are called facies 

analysis. While Lithofacies based on characteristics 

of the composition, physical, and chemical at a 

rock. 

Geologically of study area, West Section of 

Kolok Nan Tuo belongs to the Ombilin Basin. 

Ombilin basin is divided into several formations 

which are distinguished by lithofacies  and the 

depositional environments (Koesomadinata and 

Matasak, 1981): 

 
Fig. 1. Administrative map of study area 



  

 
Cahyaningsih, C. et al./ JGEET Vol 03  No 02/2018 129 

 

2.1. Pre-Tertiary rocks 

The Pre-Tertiary rock is a rock the underlying 
basin Ombilin. These rocks are exposed at the 
western and eastern parts of basin. Pre-Tertiary 
rocks exposed in the western part of the basin 
consists of (Koesomadinata and Matasak, 1981): 
- Silungkang Formation, composed of coral 
limestone lithology of volcanic rocks. Rock consists 
of andesitic volcanic lava, as well as the basaltic 
tuffs. Age formations are the Pleistocene-Carbon 
content of fossil Fussulinid in limestone. 
- Tuhur Formation, consisting of lithology slate, 
Shale Members and Limestone Members. This 
formation was Triassic Age. 
 
2.2. Tertiary rock 

2.2.1 Brani Formation 

Brani Formation consists of conglomerates with 
fresh color is purplish brown, grain size is gravel, 
with a wide variety of fragments such as andesite, 
limestone, slate, argillite, granite, quartzite, arkose 
with coarse-grained, massive and generally not 
plated. This age formation is based on relationship 
with Sangkarewang Formation which allegedly 
Paleocene to Eocene.  The formation was deposited 
as a precipitate Brani estimated alluvial fan 
(Koesomadinata and Matasak, 1981). 

2.2.2 Sangkarewang Formation 

According Koesomadinata and Matasak (1981), 
consists of shale formations Sangkarewang layered 
thin dark gray-brown to black, plastic, containing 
calcareous carbon material, mica, pyrite, and the 
rest of the plant. These formations have inserts in 
the form of layers of sandstone with thick are 
generally less than 1 m, there are fragments of 
quartz and feldspar, calcareous gray to black, clay 
matrix disaggregated mica and carbon-containing 
material and the presence of slump structures. 
Inset These sandstones show a pattern fining 
upwards. Based on pollen analysis estimated age of 
this formation or pre-Eocene Eocene. Formation 
Sangkarewang estimated deposited at lake 
environment. 

2.2.3 Sawahlunto Formation 

According to Koesomadinata and Matasak 
(1981), this formation consists of shale sequences 
gray-brown, silty shale and siltstone with quartz 
sandstone inserts gray-brownish and characterized 
by the presence of coal. Generally carbonaceous 
shale. Sandstone has a characteristic sequence of 
fining upwards, has a layered sedimentary 
structures cross- maze, ripple lamination and firm 
base erosion that shows a sequence of point bar. 
Coal Interspersed with the generally gray siltstone 
and carbonaceous clays. This Sawahlunto 
Formation Eocene based on the analysis of pollen 
shows Paleocene to Eocene age. The presence of 
carbonaceous shale, coal, particularly sandstone-
type point bar shows the depositional environment 

of formation. This is a floodplain with a winding 

river where coal is deposited. 

3. Methodology 

The research method used is the analysis of 
maps and field studies (mapping).  Map analysis is 
used to determine the state of the landscape and 
slope (Putra and Choanji, 2016;  Suryadi, 2016) as 
supporting activities to facilitate field research 
activities. 

The field research aimed at obtaining more field 
data according to research materials to be 
analyzed. At this stage, do some work done, 
including determining the location of the 
observations and the observations of outcrops.  

At every outcrop, observations do plotting 
observation station location on the map and 
delineate the megascopic framework outcrop. 
Outcrop observations include: 

 Measurement outcrop dimensions, 
Fig.graphs, and sketches. 

 Description lithology, strike-dip, coating 
thickness, and sedimentary structures. 

 Sampling. 
After the field data obtained is then performed 

the data analysis stage so characteristic lithological 
types and lithologies in the study area can be 

determined. 

4. Result 

Based on field data, the rocks in the study area 
can be classified into three rock units: 

 Limestone Crystalline Unit 

 Conglomerate Unit 

 Claystone Unit 
Lithologies as each have a different lithofacies, 

crystalline limestones facies units composed of 
limestone crystalline and mudstone, conglomerate 
unit consists of a conglomerate facies and facies 
greywacke sandstone and mudstone facies units 
consist of claystone facies which sometimes 

contained in the form of thin layered sandstones. 

5. Discussion 

Based on the results of the analysis of field data, 
lithologies in the area of research can be grouped 
into three lithologies. 

5.1 Crystalline Limestones Unit 

Unit crystalline limestones located in the 
Eastern part of the study area. Crystalline 
limestones unit is composed of crystalline 
limestone and limestone. Mudstone referring to 
the regional geology, rock units is comparable to 
the old Silungkang Formation Permian-Carbon era. 
Crystalline limestones unit is marked in blue on a 
geological map of the study area. Lithology on this 
unit are: 

 
 
 



  

 
Cahyaningsih, C. et al./ JGEET Vol 03  No 02/2018 130 

 

5.1.1 Crystalline Limestone Facies 

Crystalline Limestones facies are dominant in the 
Eastern part of the study area. Description detailed 
crystalline limestones have weathered gray color 
and a fresh color white whitish-grey. With 
component binder matrix deposition and grains 
have crystallized so that no fossils of both types of 
macro and micro. (Fig. 1) 

 

 

Fig. 1. Crystalline limestones with directions N65°E 

5.1.2 Limestone Mudstone Facies 

Limestone mudstone facies are dominant in the 
Southeast area of research. Description limestone 
mudstone a detailed have weathered blue-white 
color and a fresh color bluish grey because it is a 
carbonate rock. According to the classification of 
this rock called Dunham, mudstone because it has 
granules of less than 10% and this rock was not 
found fossilized. The texture of this rock is non-
crystalline, amorphous because the constituent 
mineral crystal and type of compactness is quite 
loud. (Fig. 2). 

5.2. Greywacke Sandstone Facies 

Facies lithic sandstones greywacke dominant is 
in the Southern part of the study area. In the flow 
of the river, Malakutan discovered sedimentary 
layering structure.  
Description sandstones greywacke lithic in detail 
which has a color weathered gray dark and fresh 
colors gray, grain size medium kind of Well 
rounded, medium sorted, permeability moderate, 
compactness bit loud, for component grains were 
observed in macroscopic using loops consist of 40% 

quartz, 30% feldspar and debris 30%.  Matrix 
percentage is more than 15%. (Fig.. 4) 

 

 

Fig. 2. Limestone mudstone with directions N84°E - 
 

 

Fig. 3. Conglomerates with fragments of limestone 
crystalline and limestone mudstone with direction 
N246ºE 

 



  

 
Cahyaningsih, C. et al./ JGEET Vol 03  No 02/2018 131 

 

 

Fig. 4. Greywacke lithic sandstones with Fig. directions 
N125°E 

For classifying the sandstone use classification of 
Pettijohn, 1986. (Fig. 5). Facies sediment may have 
formed tectonically unstable when appointed by 
poorly sorted, and sedimentary structures indicate 
that the slow lorises rock units are the result of the 
Silungkang Formation debris deposited on the 
environment precipitation inland. (Fig 6). 
 

 

 
 
Fig. 5. Triangular sandstone classification (Pettijhon, 
1975) 
 

 

 

Fig. 6. An illustration of formation of conglomerate rock 
units as a result of debris and forming alluvial fan. 

 

5.3 Claystone  

Unit claystone is in the Central part of the study 
area that spreads from North to South. These 

lithologies of claystone and sometimes there is a 
fine sandstone insert. Members of this unit 
included into the Lower Formation Ombilin old 
when Late Oligocene-Early Miocene. This unit is 
marked in green on a geological map of the study 
area. The lithofacies  on this unit are: 

5.3.1 Mudstone Facies 

Clay facies predominantly located in the southern 
part of the study area. Description claystone 
detailed flake has weathered grey color and a fresh 
color grey-brown, clay 1/256 mm grain size, very 
well rounded, closed containers, thin laminated 
sedimentary structures, low permeability, well 
sorted, indicating that environmental carbonate 
deposition on this rock is in the form of land 

environment, the type of soft compactness. (Fig.. 7) 

 

Fig. 7. Claystone unit with flakes structures with photo 
directions N 125°  E  N 305°E 

For facies sedimentary depositional environments 

is deposited in neritic environment which can be 

seen from flake structure of the sediment, 

indicating that the current relatively quiet and 

nature carbonate facies sediments showed that the 

sedimented on the marine environment. (Fig. 8). 

6. Conclusion 

In Kolok Nan Tuo area there are five lithofacies  

are: crystalline limestone, mudstone limestone,   

conglomerates,  sandstones greywacke lithic, and 

claystone that can be grouped into three 

lithologies are limestone lithologies crystalline 

which is a basement in the basin the conglomerate 

unit formed on alluvial fan and it is resulted 



  

 
Cahyaningsih, C. et al./ JGEET Vol 03  No 02/2018 132 

 

 

Fig. 8. An illustration of the state of environmental 

change precipitation to claystone unit 

from debris unit of limestone crystalline which can 
be seen on the number of fragments of limestone 
crystalline and limestone mudstone in facies 
conglomerates which deposited on terrestrial 
environments (fluvial) as an alluvial fan. clay 
lithologies interpret deposited in neritic condition 
which can be seen from the content of which is the 
identifier sediment carbonate marine environment 
on clay facies. (Fig. 4.) 

 

 

 
 

Fig. 9. Geological Map of the study area  

 

Acknowledgment 

Thanks to Laboratory of Geological 

Engineering Department, Faculty of Engineering, 

Universitas Islam Riau who has helped the data 

collection and analysis in finish writing this 

article.  

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	1. Introduction
	2. Basic Theory
	2.1. Pre-Tertiary rocks
	2.2. Tertiary rock
	2.2.1 Brani Formation
	2.2.2 Sangkarewang Formation
	2.2.3 Sawahlunto Formation


	3. Methodology
	4. Result
	5. Discussion
	5.1 Crystalline Limestones Unit
	5.1.1 Crystalline Limestone Facies
	5.1.2 Limestone Mudstone Facies

	5.2. Greywacke Sandstone Facies
	5.3 Claystone

	6. Conclusion
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