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

Journal of Geoscience,  
Engineering, Environment, and Technology 
Vol 04 No 01 2019 

 

 
22  Syahputra, R., et al./ JGEET Vol 04 No 01/2019   

 
 

RESEARCH ARTICLE 
 

Correlation Between Fracture Azimuth, Surface Lineaments and 
Regional Tectonics: A case study from Belik District, Central 

Java, Indonesia 

Reza Syahputra
 1,

*, Felix M. H. Sihombing
1
, Octria A. Prasojo

1
  

1
 Geology Study Program, Universitas Indonesia, Kampus UI Depok, Depok, West Java, 16424, Indonesia. 

 
* Corresponding author : syahputra.reza@sci.ui.ac.id  

Tel.:+62-87883917464 
Received: Nov 6, 2016; Accepted: Nov 20, 2016. 
DOI: 10.25299/jgeet.2019.4.1.2294 

 
Abstract 

Two major strike-slip faults with northeast-southwest and northwest-southeast orientation have shifted the southern 
Central Java, including Belik District.  Consequently, many smaller faults that have the same direction as the major faults and 
west-east direction folding systems were emerged. The orientation of these geologic structures could be observed from 
morphological features such as ridge and river. A quantitative approach was carried out to unravel the impacts of those geologic 
structures on the geomorphology of the study area, which is located between Slamet Mountain and Sindoro Mountain, Central 
Java province. The method used in this research was the structural geology analysis, including the interpretation of ridge and 
river lineament, the distribution of fractures, and statistical analysis. The research location is divided into four different segments 
based on its lineament and morphology. The lineament that has similar characteristics was tested using normality test of 
Kolmogorov-Smirnov. The Spearman test was used to obtain the correlation between surface lineament and fracture azimuth. 
All fracture azimuth, ridges and rivers tend to have northwest-southeast and northeast-southwest direction. These results show 
similar direction with strike-slip regional structural pattern. The statistical calculation and field observation indicate the 

landform. 
 
Keywords: Fracture Azimuth, Lineament, Spearman, Belik 
 
 

 

1. Introduction  

The morphology of Central Java tends to have 
indentation. It is interpreted as the cause of major right 
and left lateral faults movement in that area (Satyana, 
2005, 2006, 2009).  It is also considered to be 
intensively affected by tectonics (Widagdo, et al, 2018). 
On the other hand, the condition of the outcrop is 
sometimes highly affected by weathering and erosion 
which make the tectonic features   difficult to be 
observed.  

The research location is situated  between 109
0
 

- 109
0
 

0
  7

0
 

South Latitude, which is in the Central Java Province 
(Fig. 1). It is bordered by Purbalingga district on the 
south, Paninggaran on the east side, and Mount Slamet 
at the west side. Djuri et al. (1996) divided the 
stratigraphy of the study area from the youngest to the 
oldest into Late Pliocene Lava of Mount Slamet, Early 
Miocene of Rambatan Formation, and Middle to Late 
Miocene of Halang Formation. He stated that the 
Rambatan Formation consist of shale and marl 

alternates with light grey calcareous sandstone, while 
the Halang Formation have interlaminated sandstone 
and shale. The Central Java Province was influenced by 
wrench fault systems from Late Cretaceous to 
Paleogene, where it cut each other with left-lateral 
fault from northeast to southwest in Muria-Kebumen 
and right-lateral fault from northwest-southeast in 
Cilacap-Pamanukan (Satyana, 2005). 

According to fault kinematic ellipsoid, the Muria-
Kebumen and Cilacap-Pamanukan faults may provoke 
other strike-slip fault and foldings around the research 
area (McClay, K. R., 1991). Most folds between these 
two strike-slip faults have west-east direction.  The 
lineament from Mount Slamet, Sindoro, Sumbing and 
Merbabu also showed the same direction with the 
folding (Pacey, et al, 2013).  

The geologic structures can be observed with 
several different techniques including the direct 
observation in the field and laboratorial analysis and 
interpretation. The landscape morphology can be 
affected by endogenic process such as plate tectonic 
deformation or local geological structure. The 

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Syahputra, R., et al./ JGEET Vol 04 No 01/2019 23 

 
 

structural geology evidence in   a tropical country like 
Indonesia, is difficult to observe because of the high 
weathering rate (BNPB, 2010). Hence, laboratorial 
analysis and interpretation become crucial in the 
identification of the deformation process.  

 

 
Fig. 1. Map showing the research location. The strike-slip fault cut each 
other in the opposite slip and trend. Modified from Satyana (2005). 

 
We propose a combination approach, employing 

field acquisition and statistical analysis to study 
geologic structures. A Combination of these methods 
may increase the chance of having a better result and 
eliminate the uncertainty. Many successful cases have 
applied statistics to determine the landscape 
morphology evolution related with tectonics (Zadeh, et 
al, 2013; Vannametee et al., 2014; Yudhicara, et al, 
2017).  

This research employs the bivariate analysis to 
evaluate the relationship between the fracture azimuth 
and the surface lineament direction. This method was 
chosen because of its efficiency and effectiveness to 
decipher the main factors that affect their 
development.  This statistical analysis must be 
supported by other geological evidence in order to 
minimize or eliminate the error and misinterpretation.  

The landscape morphology in Central Java Province 
tend to emerge by following the folding direction, 
which shows the west-east direction parallel to the 
folding direction. This research aims to unravel the 
influence of tectonics process on the formed landscape 
morphology  and to determine which processes were 
more dominant compare to other geological processes. 

  
1.1 Regional Geology 

Tectonic pattern from Neogene Central Java sub 
basin on the northern part is a part of back-arc basin.  It 
is formed between magmatic arc on the south 
(Southern Java) and the Sundaland on the north as a 
result of subduction between Eurasia and Indo-
Australian plate. 

The research area which is located in Besuki 
Majenang High is part of North Serayu Mountain Zone. 
The mountainous zone extends from west to east with 
the width ranging from 30 to 50 kilometers (van 
Bemmelen, 1949) 

Situmorang et al. (1976) postulated the faulting 
mechanism in Java based on Riedel shear concept. 
Furthermore, he explained it was resulted from the 
collision between Eurasia and Indo-Australia plate in 
the Middle Cretaceous and then formed specific fault 
and fold pattern. Kusumayudha (1994) explained that 
the meridional fracture system or west to east 

structural orientation was affected by the 
compressional force from North to South (N 350

0
 E). 

The wrench faults which were resulted on the left and 
right of the folding system lead to 45

0
 to its 

compressional force. Hence, Java is divided into three 
blocks. The first one is positioned higher than the 
second and third block. Each of blocks is bordered by a 
couple of strike-slip fault with northwest-southeast 
direction between the first and the second and 
northeast-southwest direction between the first and 
the third one. All the structural from the main 
compressional force are categorized as a R1 and R2 
system in Riedel shear model. 

The North Serayu Mountain experienced three 
episodes of tectonics activity: (1) Miocene to Pliocene, 
(2) Pliocene to Pleistocene, and (3) Holocene (van 
Bemmelen, 1949; N. Ratman and G. Robinson,1996). 

2. Methodology 

This research attempted to support field 
observation with statistical analysis. Basic geological 
mapping was first carried out to check the lithology and 
structural geology evidence. These parameters then 
used to help the statistic calculation. 

The research area was divided into several 
segments based on its morphology before the 
lineament was drawn. It was conducted by manual 
interpretation and aimed to have precise lineament 
trend that fit with its group, so it can represent the 
direction of actual alignment. 

The lineament from ridge and river were calculated 
thoroughly. They were resulted from the topographic 
map and the satellite imagery. To better signify the 
intensity the length of lineaments is put into 
consideration in statistical calculation using weighting 
method. The result then compared with fracture 
measurements in the field to find out the correlation. 

The fracture azimuth and lineament were 
compared based on its segments. For example, we 
compare the fracture from segment 1 to ridge and river 
in the same segment and others. Then we considered to 
calibrate the lineament with the main regional 
tectonics force in each segment. 

Before each data compared to each other, all 
lineaments and fractures data were tested whether the 
data distribution has a normal trend or not using 
Kolmogorov-Smirnov test.  

We use bivariate analysis to test correlation 
between fracture and lineament. Pearson test was used 
when data distribution is normal, while Spearman test 
was u
distribution. R value is expressing magnitude of the 
correlation, while p value is expressing level of 
significance. 

The statistical results were managed using SPSS 
software (Statistical Product for Social Science) © 
version 25.0. 

The result was interpreted by combining the 
geological condition (such as geomorphology, 
lithology, and drainage pattern) with the statistical 
calculation. A good match between those parameters 



 
24  Syahputra et al./ JGEET Vol xx No xx/20xx  
 
 

lead to a better understanding of the endogenic and 
exogenic processes in the past. 

 
2.1 Data Availability 

The lithology, the morphometry, and the fracture 
azimuth were acquired through field mapping. The 
lithology distribution has been confirmed with 33 
macroscopic observation sites and 10 petrographic 
analysis (Fig.2). The morphometry was obtained using 
slope analysis (Van Zuidam, 1985) (Eqn. 1) and 
reconfirmed by field visit. More than four hundred of 
fracture azimuth were measured to determine its main 
direction. 

 
 

(1) 
 

Where: 
s : slope (%) 
n  : the number of contours cutting by a line 
CI : contour interval (meters) 
d : the distance between the highest and the lowest  
   contour (meters) 
Sp  : scale on the map 

 
The drainage pattern was obtained through the 

studio analysis and combined with the calculation of 
river order from Strahler (1952). The first order which 
crosses into each other result in the second order, and 
if the first order runs into the second one, it remains the 
second order. The river order was conducted to analyze 
the river stages, whether it was young or old enough to 
be influenced by a geological process.  

The lineament data were obtained from ridge and 
river using satellite imagery and topography map, 
respectively. We used channel 4, 5, and 7 in this 
satellite imagery to see the lineament trend and the 
drainage pattern, and successfully gained more than 
hundreds of lineaments. These data were then used to 
reconfirm the field data. 

 

3. Results 

3.1. Lithology 

There are four lithology in the research location that 
can be simply distinguished by their texture and 
composition (Fig.2). More than 15 % lithology in the 
research area is covered by Andesitic lava flow from 
Slamet Mountain. The research area is also dominated 
by 30 % of Feldspathic Wacke Sandstone from Halang 
Formation and 50 % of shale from Rambatan Formation. 
Some Diorite intrusion was covered only 5 % on the 
western part of the research area. 

It can be concluded from field observation  that the 
Andesitic lava from Mount Slamet always covers the 
lowest part of  the research area with 0  7 % of slope, 
filled in the nearby valleys and rivers. It is dark or black 
in color and has a porphyritic texture and vesicular 
structure. Besides, the Feldspathic Wacke Sandstone 
usually lies on the higher ground between 200  1,150 

meters with 10  20 % of slope which has the 
interlaminated sandstone and mudstone characteristic. 
Most of the sandstone has a stiff rock strength. It 
proved by the hammer when was used to take the 
sample which brought out fire sparks.  The shale of 
Rambatan Formation is overlapped with the sandstone 
from Halang Formation in between 100  850 meters. 
And the Diorite intrusion has located on the 650  1,000 
meters elevation with 20  50 % of slope. 
 

 
Fig. 2. Field photographs (left) and photomicrographs (right) of 
representative samples from research location. All photomicrographs 
originated from the outcrop on the left and were taken using x-nicol. 
(A- -basalt lava flow from Mt. Slamet; (B-
Rambatan Fm.; (C- -

Granodiorite intrusion. (K-Fs=K-Feldspar; Pl=Plagioclase; Px=Pyroxen; 
Qz=Quartz) 
 

3.2. Morphology 

The elevation of the research area varies from 100 
m to 1,000 m above sea level. The topography is 
grouped into five slope classes, namely flat (0 % - 1.8 %), 
slightly sloping (3.6 %  5.4 %), sloping (7.1 % - 14 %), 
slightly steep (16 % - 20 %), and steep (16 % - 41 %). The 
sloping topography is covering 55 %, and the the 
slightly steep slope covering 30 % of northeast and 
south part of research area in, and the other classes are 
scattered evenly. 

Most slopes are consisted of Rambatan and Halang 
Formation, except for flat and steep slope which 
consisted of andesitic lava and granodiorite intrusion, 
respectively. The valley is categorized as dull to sharp 
v-shape and dull u-shape.  

According to the elevation and slope classification 
of van Zuidam, R., A, (1985), 90 % of research area 
assigned into a hilly landform and the other 10 % was 

%100
).1(







Spd

Cln
s



 
Syahputra, R., et al./ JGEET Vol 04 No 01/2019 25 

 
 

categorized into mountainous and valley landform on 
southwest. 

 
3.3. Drainage Pattern 

The drainage pattern has been categorized into 
three different group based on topographic map, river 
order, and observation in the field. They were then 
compared with basic and modified drainage pattern 
(Howard, 1967). They are classified into sub-parallel, 
parallel, and dendritic.  

The sub-parallel covered around 70 % of the 
research area. The lithology in sub-parallel is 
dominated by mudstone from Rambatan Formation. On 
the other hand, the parallel pattern is in the long and 
continuous mountainous landform with steep slope 
area. The lithology is dominated by sandstone from 
Halang Formation, which is more resistant than 
Rambatan Formation.  The summit of the mountain act 
as a water divided, and the river run from south to 
north. And the last one is dendritic pattern that covered 
the southeast and southwest of research area (Fig. 3).  

 

 
 

Fig. 3. Interpreted drainage pattern and river order. 

 
The river order was categorized into five order. The 

smaller order represents the earliest stage of river 
development and becomes mature as the order 
escalate. Most river is dominated by first and second 
order. The third, fourth, and fifth order have the total of 
20, 9, and 1, respectively. The river run along in two 
directions. The river on the south side is dominated by 

the river which run from north to south while the rest 
flow from south to north (Fig. 3). 

 
3.4. Structural Geology  

The folding is composed of two synclines 
(Mendelem and Majakerta) and two anticlines 
(Gombong and Karangmanggu). Most of the folding 
relatively extending from west to east except for 
Majakerta syncline which has a northwest-southeast 
direction. 

The fault in the research location can only be 
observed from the map or satellite imagery. The fault 
interpretation was helped by the regional structural 
geology. It was interpreted that there are two local 
right-lateral fault. However, there was no slicken-side 
evidence in the field except the fractures. (one of the 
fractures is documented on Fig. 2C)  

 

 
 

Fig. 4. Ridge lineament interpretation from satellite imagery has been 
divided into four segments. The fracture azimuth only available at the 
segment 1 and 3.  

 
The fracture azimuth has been collected from 14 

different stations in the southwest and northeast side 
of the study area (Fig. 4). But we were not able to 
measure the fracture azimuth in other area because the 
weathering rate was intensively occurred. Most of the 



 
26  Syahputra et al./ JGEET Vol xx No xx/20xx  
 
 

fractures are located  on the  sandstone and no fracture 
was found on shale and igneous rocks. Field 
observation showed the direction of the fracture 
azimuth in two different dominant orientation, which 
are northeast-southwest and northwest-southeast. The 
fracture from the stereographic projection interpreted 
that it was dominated by the intermediate principle 
stress (Fig. 5). Then we assumed that the fracture found 
as shear component. However, in few stations we also 
found the tensional fractures. 

 

 
 

Fig. 5. Both principal stress from segment 1 and 3 interpreted as a result 
of strike-slip fault. The slicken-side has not been found in the field, only 
small displacement in the outcrop located at K13. 

 
The fracture azimuth showed that the data 

distribution can not be represented in normal. The 
statistical calculation of the fracture azimuth direction 
is also represented by the same direction by field 
observation (Table 1).   

 
3.5. The Lineament Trend 

The lineament was mapped by utilizing the ridge 
and the river lineament from the satellite imagery and 
topographic map. Based on normality test of 
Kolmogorov-Smirnov, the lineament azimuth is not 
categorized into normally distributed data set.  

The ridge lineament was drawn by considering a 
continuous morphological which formed by specific 
geological processes. Some of the ridge had a distinct 
shape but some hadnot. The differences acknowledge 
trough the color and the shadow from satellite imagery.  

The mode of ridge lineament in each segment 
showed four different trends. Then the research area 
was divided into four different segments. Segment 1 is 
dominated by N 174

0
 E (northeast-southwest) while 

segment 2 is dominated by two different orientation, N 

57
0
 E and N 121

0
 E (northeast-southwest and 

northwest-southeast). Segment 3 is directed into 
different trend direction, which is N 150

0
 E (northwest-

southeast). And segment 4 was dominated by N 91
0
 E 

trend (west-east) (Fig. 6). 
 

Table 1. Descriptive analysis of lineament and fracture azimuth. 

Segmented 
of research 

area 

Lineamen
t and 
Fracture 

Trend 

n Median Mode 
Std. 
deviati

on 

Segment 1 
Ridge 104 147 174 49,55 
River 424 293 302 113,23 
Fracture 258 205,50 205 79,32 

Segment 2 
Ridge 144 104,50 57; 121 27,31 
River 439 154 69 63,48 

Segment 3 
Ridge 142 74 150 42,19 
River 289 135 157 44,94 

Fracture 169 140 140 92,46 

Segment 4 

Ridge 88 90 91 28,78 
River 

124 131 
67; 
103; 
200 

81,74 

 
The river lineament composed of two kinds set of 

data, longer and shorter. The longer river was located 
on several main river while the shorter one came with 
a great deal of number and dominated the river 
branching (Fig. 6). Most river lineament is dominated 
by the same pattern direction with the ridge in each 
segment and while the rest show opposite direction. 
 

 
Fig. 6. River lineament and structural feature 

 



 
Syahputra, R., et al./ JGEET Vol 04 No 01/2019 27 

 
 

3.6. Correlation between fracture azimuth, ridge and 
river lineament 

All data set are not normally distributed, then the 
Spearman test performed. We found that there were 
plenty of which had different correlation, even if it was 
in the same segment. 

In segment 1 we found that there was statistically 
significant correlation between fracture azimuth and 
ridge, and the correlation strength was  categorized 
into medium. It also had the same significant 
correlation between ridge and river lineament, but it 
was the weak one.  

In segment 2 there was only ridge and river 
lineament which compared to each other. They showed 
a meaningful correlation, but it was very weak. 

Different with segment 1 and 2, the fracture and 
river lineament in segment 3 has a negative correlation 
and there was no correlation between fractures and 
ridge lineament in this segment. 

Segment 4 was almost the same with segment 2, 
which only has ridge and river lineament to be 
compared. It showed no statistical correlation were 
found between these parameters. 

We also compared fractures from segment 1 and 3 
with the ridge and river lineament from outside this 
segment. But the result showed no significance, except 
the correlation between fracture in segment 3 with 
ridge in segment 4 which showed the negative 
correlation. 

The correlation was also compared with fractures 
and corrected lineament. It was corrected to the main 
tectonic force angle, which was interpreted came from 
the north side of Java. After reducing the lineament 
with the main tectonic force, we got no significant 
changes using this method. Some of data which had no 
correlation remain the same. However, the negative 
correlation between fracture in segment 3 and ridge 
lineament in segment 4 become not significant.  

 
Table 2. The correlation between segment. (Fr=fracture; Rd=Ridge; 
Rv=River. The number indicate the segment). *p < 0.05 and R (+) = 
Significant and linear correlation; **p < 0.05 and R (-) = Significant and 
opposite correlation; ***p > 0.05 = Not significant 

Correlation intra 
and between 

segment 

P (significant 
level) 

R (Correlation Strength) 

Fr1-Rd1 * 0.0 0.436 

Fr1-Rv1 *** 0.882 0.09 

Rd1-Rv1 * 0.03 0.293 

Fr1-Rd2 *** 0.112 -0.133 

Fr1-Rv1 *** 0.233 -0.74 

Rd2-Rv2 * 0.001 0.278 

Fr3-Rd3 *** 0.602 0.044 

Fr3-Rv3 ** 0.0 -0.324 

Rd3-Rv3 *** 0.906 -0.10 

Fr3-Rd4 ** 0.0 -0.409 

Fr3-Rv4 *** 0.13 -0.222 

Rd4-Rv4 *** 0.187 0.142 

4. Discussion 

Regional tectonic at research location was 
interpreted between Paleocene and recent. Martodjojo 
(1994) grouped tectonic deformation in the research 
area into the Meratus and Sumatra trend which formed 
between Late Cretaceous and Paleocene. The oldest 
stratigraphy at research location was deposited from 
Middle to Late Miocene, which indicates that the 
fractures and lineaments must be younger than those 
regional strike-slip. We presumed that even there was 
time gap between regional strike-slip and geologic 
structures at the research location, the dominant 
lineament and fracture azimuth showed a similar 
pattern with right-lateral Cilacap-Pamanukan fault 
(northwest-southeast) and left-lateral Muria-Kebumen 
fault (northeast-southwest).  

The main tectonic force tends to come from north, 
created a synthetic (R1) Muria-Kebumen and antithetic 
(R2) Cilacap-Pamanukan shear fault according to Reidel 
shears model. The principle stress from fractures 
(segment 1 and 3) showed that the intermediate stress 
was the dominant force which affected fractures 
direction. This result also had the same direction with 
the Indian oceanic subduction from the Late Cretaceous 
to the present. 

Field observation has succeeded to classify the 
morphology based on its lithology. We found that most 
resistant rocks (sandstone from Halang Formation and 
granodiorite intrusion) are located on the mountainous 
landform at altitude more than 500 meters above sea 
level with sloping and slightly steep slope. However, 
some of the sandstone still can be found at the hilly 
landform together with mudstone from Rambatan 
Formation. This distribution showed that the 
weathering rate in the research location is increasing 
downward. The valley shape become an indicator for 
weathered rocks. Most sandstone and intrusion 
landform showed a sharp v-shaped valley (vertically 
eroded). Except for intrusion, the sandstone from the 
Halang Formation were distributed in a long and 
continuous mountain. On the other hand, the landform 
with mudstone and andesitic lava dominated by the u-
shaped valley (horizontally eroded). 

The statistical descriptive showed that most of the 
lineament and the fracture azimuth assembled into the 
second quadrant. However, several lineament and 
fractures fall into the first and third quadrant (see mode 
in Table 1). According to this information the lineament 
has two major direction, which are northwest-
southeast and northeast-southwest.  The fracture 
azimuth also has the same direction with the 
lineament.  The fractures direction in segment 1 is 
represented by northeast-southwest direction, while 
the fracture from segment 3 dominated by northwest-
southeast direction.  

In segment 1 the river and ridge lineament tend to 
have northwest-southeast direction while the fracture 
has the northeast-southwest. The opposite direction 
between these parameters were caused by the less 
dominant of fracture azimuth direction (northwest-
southeast). It was proved by the coefficient correlation 



 
28  Syahputra et al./ JGEET Vol xx No xx/20xx  
 
 

that falls into medium category. However, the fracture 
might not the main influence because the slope is 
slightly steep, and the drainage pattern is sub-parallel, 
which means external factor could possibly have a role 
in this segment. 

In the segment 2 and 4, neither the ridge nor the 
river has a correlation with the fracture from segment 
1 and 3. Most likely the formation of ridge and river 
were controlled by the denudational process. We 
interpreted this was due to the absence of fractures. 
Moreover, the slope is categorized into sloping and the 
drainage pattern is dominated by sub-parallel.  

The ridge, river, and fractures in segment 3 have the 
same direction. However, the significant correlation 
only resulted between fractures and river lineament. 
The fracture possibly less affected the formation of the 
river because the coefficient correlation has negative 
value, thus it might be not fully controlled by fractures 
or the fracture was not greater than external factors 
such as weathering. Insignificant correlation between 
fractures and ridge proved the lithology and external 
factor could possibly control the morphology in 
segment 3. Otherwise, the ridge could be influenced by 
less dominant fracture orientation, which was 
northeast-southwest. We were able to interpret this 
because one of the correlations between fracture and 
lineament still meaningful. However, if both of 
lineament do not have meaningful correlation to the 
fracture then no correlation will be significant 
statistically. 

The correlation between calibrated and non-
calibrated lineament showed no significance 
difference. This could possibly happen because the 
main tectonic force has only small angle value, thus the 
changes could not be significantly detected. 

Our research limitation includes the absence of 
morphometric characteristic such as Bifurcation Ratio, 
Drainage Density, etc. It occurs since our research area 
was not big enough to discuss about the catchment 
area. Other factors that may become the limitation of 
our study are the absence of fault evidence that may 
affect the landform changes. 

5. Conclusion 

The regional fault in central Java compare to the 
lineament and fracture azimuth have the same 
direction with the research area, which is northwest-
southeast and northeast-southwest. However, they 
have different dominant direction in each segment.  

The lineament in segment 3, especially the river, 
was probably controlled by the Cilacap-Pamanukan 
fault. However, the negative correlation and field data 
showed that the weathering process also had a role on 
this lineament. 

There is orientation difference between the fracture 
and lineament in segment 1. However, the correlation 
between ridge and river in this segment is weak and 
linear. The weak correlation showed that there might 
be another fault mechanism which affected the ridge 
and river lineament.  Since the position of this research 
area in the middle of two strike-slip regional fault, 

there is a possibility that the landform was built with 
different lineament orientation. The direction possibly 
caused by another regional fault which is Muria-
Kebumen fault. 

Based on statistical calculation, the morphology of 
the research area was not probably fully controlled by 
the regional fault. Evidence in the field also showed the 
external factors such as erosion as the factor of changes 
in landform (proved by weathered shale of Rambatan 
Formation from Fig. 2B). 

The river order is dominated by lower order, which 
characterizes the younger rivers. The vertical erosion 
dominated the weathering processes, indicated by the 
great number of lower river order. The drainage pattern 
also showed less significant effect to be affected by the 
fault. Observation from the field showed that only three 
synclines and two anticlines that were probably 
affecting the landform change. 

 

Acknowledgement 

The greatest contribution gave to Dr. Radhiyatam 
Mardhiyah and Dr. Charlie H. Wu who gave much 
better understanding in statistical calculation. We 
would also like to thank the Geological Agency for the 
provided map and satellite imagery. 
 

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	Correlation Between Fracture Azimuth, Surface Lineaments and Regional Tectonics: A case study from Belik District, Central Java, Indonesia 
	1. Introduction
	1.1 Regional Geology

	2. Methodology
	2.1 Data Availability

	3. Results
	3.1. Lithology
	3.2. Morphology
	3.3. Drainage Pattern
	3.4. Structural Geology
	3.5. The Lineament Trend
	3.6. Correlation between fracture azimuth, ridge and river lineament

	4. Discussion
	5. Conclusion
	Acknowledgement
	References