E-ISSN : 2541-5794  

P-ISSN : 2503-216X  

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

 

 
Sidek, A. & Hamzah, U./ JGEET Vol 03  No 02/2018 69 

 

Structural Analysis of Northwest Sabah Basin by 2D 
Reconstruction of Seismic Sections 

Akhmal Sidek
 1,

, Umar Hamzah
2
  

1
 Petroleum Engineering Department, Institute for Oil and Gas, FCEE, Universiti Teknologi Malaysia 
2 Geology Programme, PPSSA, Faculty of Science and Technology, Universiti Kebangsaan Malaysia. 

 
* Corresponding author : makhmal@petroleum.utm.my 

Received: 2 Apr, 2018. Revised : 26 Apr 2016, Accepted: 7 May, 2018, Published: 1 June 2018  
DOI : 10.24273/jgeet.2018.3.2.1413 

 
Abstract 
The tectonic evolution of thrust-fold belt and thrust sheet zone in Northwest Sabah basin was described based on balanced 
reconstruction of seismic sections representing Mid-Miocene to Recent deposits. The study area is located at the center of a 
wide crustal deformational zone bordered by the Sunda Shelf on the northeast, Sulu Sea in the southwest and the South 
China Sea in the northwest. Balancing cross section can be applied after the deformed geological structure geometry is 
accurately determined from seismic sections and 7 seismic stratigraphic unit from 15 Ma until Recent is consecutively 
restored. There are four steps involved in retro-deformation processes beginning with removing all faults displacements 
followed by unfolding the folds, isostasy correction and finally the removal of each compacted layer parts or decomposition. 
Wider fold wavelengths with least thrust faults were observed from south to north in the seismic sections ranging from 12 
to 4 km with an average of about 7 km, while smaller fold wavelengths and more thrust faults were observed in the north 
based on the same seismic sections. In general, the reconstructed cross sections revealed compressional tectonic deformation 
activity as shown by shortening strain trending NW-SE. Measurement of total shortening shows that thrust fold belt is 
imbalance by an exceeds of 14.7 km and more active compared to thrust sheet zone which has only 0.9 km. Results of the 
study also indicate facies destruction due to shortening which is decreasing towards Pliocene or younger deposits. 
 
Keywords: 2D Reconstruction, NW Sabah Basin, 2D Seismic Profiles, Retro-deformation 

 

 

1. Introduction  

NW Sabah Basin, which is also generally known 
as Sabah-Brunei basin, Northwest Borneo basin or 
Baram-Balabac basin proposed by Cullen (2010) is 
bordered in its east-west to major part of the North 
Sarawak Basin. These two basins are separated by a 
steep slope sea bed of West Baram lineament which 
is connected to NW-SE trending Tinjar strike slip 
fault (Mazlan Madon, 1999;  Tan & Lamy, 1990) 

Sabah Basin is a trench associated basin or 
sometimes is called as fore-arc basin (Levell 1987). 
Based on previous gravity, depositional history and 
sequence stratigraphy studies, this basin is 
expanding as a foreland basin followed by collision 
of continents below the South China Sea and West 
Sabah (Hazebroek et al. 1994; Noor Azim Ibrahim 
1994; Milsom et al. 1997). Sabah basin is also 
formed by thinning of continental crust layer due to 
dispersion of South China Sea (Tjia & Mohd Idrus 
Ismail, 1994).  

The Sabah Basin is considered as a compressional 
dynamic tectonic zone of northwest-southeast 
trend. There are some variations in previous study 
on the tectonic activity of Sabah basin where Abdul 
Manaf & Wong (1995), Mohd Idrus et al. (1995) and 
Hamilton (1979) reported that the study area was in 
passive condition without any earth movement and 

seafloor spreading during early Eocene. But this 
hypothesis was rejected due to the discovery of 
highly compressional deformation in the Miocene 
to recent sedimentary rocks as well as evidence 
from tensional movements measurement by global 
positioning system (GPS) technique (Ingram et al. 
2004; Simons et al. 2007; King et al. 2010).  

King et al. (2010) used 2D Dynel computer 
software for structural reconstruction of Southern 
Sabah Basin only. Results of their study show a 
decrease in crustal shortening towards the north 
into Baram Delta. The subject of crustal mobility 
and the mechanism to enhance the formation of 
Sabah Basin is still under discussion until today. It is 
hoped that the study of structural reconstruction 
based on seismic data and well in the area of thrust 
fold belt and thrust sheet by using latest 2DMOVE 
computer software would resolve some of the 
problems. In this study we used the same technique 
to propose some crustal restoration and 
reconstruction by using seismically derived cross 
sections or profiles in the thrust fold and thrust 
sheet zones.  

The analysis is hoped to optimize the use of 
seismic sections in increasing the understanding 
related to the tectonic mechanism that is 
controlling the formation of folds and thrust faults 



 
70  Sidek, A. & Hamzah, U./ JGEET Vol 03  No 02/2018  
 

in the study area by using 2DMOVE computer 
software. 

 
1.1. Geological Setting 

Sabah Basin constitutes of 85% marine or 
offshore deposits towards the South China Sea 
while the rest covered along the west coast of 
western Sabah and north of western Sarawak. The 
basin is about 350 km length and 140 km width 
trending along northeast-southwest covering an 
area of about 47075 km squares with thickness of 
about 10 km of mostly Tertiary siliciclastic 
sediments (CCOP, 1991)  

Bol & Hoorn (1980) studied the structural style 
across NW Sabah continent and basically found out 
that the structural style along northwest to 
southeast was dominated by compressional 
deformation with minor early tensional stage. In 
some of the area, the structural pattern was 
dominated by tensional activity with some 
compressional effect. The third structural style was 
mainly compressional with thrust belt due to 
gravitational sliding and subduction or both.  

Tan & Lamy (1990) and Hazebroek et al. (1994) 
has identified six structural regions namely Inboard 
Belt, Outboard Belt, Sabah Trough, Dangerous 
Ground, Thrust Sheet Zone and active delta (Baram 
Delta) thrust-fold based on the structural style 
differences and depositional history. The study area 
covers the whole region of geologically complex 
tectonic structure of NW Sabah Basin (Fig. 1).  

In terms of depositional history, the siliciclastic 
sediment of shelf slope was deposited pro-
gradationally towards the sea during early Miocene 
after the early phase of deep sea deposition. The 
depositional processes were interrupted by several 
episodes of tectonic activities leading to formation 
of regional unconformities which have been used to 
divide the Sabah basin into several stages. These 
stages were separated by major unconformities 

resulted from tectonic movements and uplifted 
towards the southeast near the basin boundary.  

The most major regional unconformity in the 
study area is the deep regional unconformity (DRU) 
which is separating the underlying post-mid 
Miocene deep marine rock sequence from the top 
mid Miocene to Quaternary slope-shelf sediments. 

2. Methodology 

A total of 10 seismic sections basically 
representing nine sequence boundaries divide the 
Quaternary sediment overlying the basement. 
These seismic sections were then traced and 
divided into 2DMOVE polygonal shapes for 
structural interpretation and fold types 
classification. Sequences 1 to 6 represent post-rift 
Mid-Miocene episodes while sequences 7 and 8 
represent depositional units formed during the 
rifting processes taken place in lower Miocene. 
These sequences (7 and 8) are also both considered 
to be the top surface of shale basement or the base 
of thrust faults (Fig. 2) as refer to previous work by 
Akhmal Sidek et al. (2015).  

Cross section restoration or sometime known as 
retro-deformation process is carried out for 
reconstructing the formation of structural geometry 
deformation or to bring back the original 
sedimentary layers before they are being deformed 
by tectonic process. The reconstruction process 
includes removing the effect of faulting and folding. 
There are four sequential algorithms involved in the 
retro-deformational processes to generate the 
algorithmic cross sectional model resulting from 
the deformational phases. The algorithmic 
sequence begins with removing the faults 
displacement, unfolding of folds, isostatic 
correction and lastly is removing the layer which 
has been compacted by compression during the 
deformation to its original position (de-
compaction).  

 

 
 

Fig.1. Tectono-stratigraphic provinces of Sabah Basin and location of seismic lines. (After Hutchison, 2004) 



 
Sidek, A. & Hamzah, U./ JGEET Vol 03  No 02/2018 71 

 

 
The assumption made during the processes is no 

input and output movement must originate from 
the sedimentary layer during the tectonic 
deformation (Midland Valley 2012). The correct 
algorithm is determined by the horizon mechanic of 
each layer and the boundary situation. 
Nevertheless, the restored model is not necessarily 
representing the correct pre-deformed geometry or 
the structural evolution movement. Suitable 
algorithmic model selection in the study is 
concentrated to tri-sheared technique for fault shift 
algorithm while the sliding technique is used in the 
algorithm for unfolding the folds. These techniques 
are particularly used to resolve both types of 
tectonic regimes represented by compressional 
thrust-fold belt and tensional inboard belt observed 
in northwest Sabah basin.  

The measurement for isostasy correction 
depends on the loading dimension acted upon the 
sediment layer plus the rigidness of lithospheric. In 
this respect the elastic thickness has to be assumed 
as fixed and constant in time and space even though 
it has different lithospheric rigidity (Watts & 
Talwani, 1974) The elastic thickness value (Te) and 
the average wavelength (ʎ) is about 8 km and 6 km 
respectively (Braitenberg et al. 2004). These 
parameter values are used in general for subduction 
analysis in South China Sea and the values are 
constant for the whole process of kinematic model 
development. Parameters used for isostasy 
modelling in this study are given in Table 1.  

 
Table 1. Parameters for 2DMOVE kinematic modelling in 
NW Sabah Basin. 

Layer model unit Bulk 
density, 

kg/m
3
 

Young 
Modulus, 

GPa 
U1 (Late Pliocene-recent) 2.24 1.12 

U2 (Early Pliocene) 2.28 1.90 

U3 (Late Miocene) 2.30 2.11 

U4 (Mid-Miocene) 2.34 2.35 

U5 (Mid-Miocene) 2.37 2.50 

U6 (Early Miocene) 2.40 2.85 

Sea water 1.03 - 

Mantle 3.33 - 

 
Kinematic model in this study is a kind of inverse 

modeling since its purpose is to analyze retro-
deformational process involving thrust fold and 
normal fault structures. It is also meant for 
predicting fault development, kinematic analysis 
and layer length in designing the pre-deformed 
structural architecture. Kinematic modelling 
analysis in this study is carried out with the aim of 
measuring the percentage and rate of layer model 
total shortening. Shortening percentage represents 
qualitative value of compressional tectonic process 
experienced by the area. 

2DMOVE is used in kinematic model 
development for geometrical interpretation in line 

with the geological concept. All seismic sections in 
SEGY format were imported into the software for 
analysis involving five complete stages. In stage 1, 
structural geometry or faults positions, footwall and 
hanging wall blocks were identified from the 
seismic sections. Selection of fault shifting 
algorithm by tri-shear technique is carried out in 
the following stage 2 and clearing the fault shift by 
downward movement along the dip direction is 
accomplished in stage 3. Selection of algorithm for 
unfolding the fold by flexural slip technique, 
completing the restoration process for upper 
section and calculation of shortening length are 
carried out in stage 4.  

Finally, the restored upper section is cleared 
from the model for de-compaction process and 
isostasy correction in stage 5. Shortening 
percentage is calculated after the fault shifting 
algorithm and fold unfolding for every layer section 
or balanced restoration is completed. The equations 
for the shortening percentage length is L = Pin1  
Pin2 where L is the distance in meter between Pin1 
and Pin 2. Pin 1 is fixed while Pin 2 is moved during 
the restoration process. The differen
= L (Final)  L (Initial) where L (Final) is the section 
length after restoration and L (Initial) is the length 
before restoration. The equation for calculating the 
total of shortening percentage is Σ

length of each section. 
 The uncertainty for each shortening magnitude 

calculation is about 15 % considering the 
uncertainty in seismic depth-time conversion, error 
in horizon picking during the interpretation and 
uncertainty in the restoration processes. 

 

3. Result  

Structural fold in the study area are closely 
related to thrust faulting and classified as gentle to 
open. It can be observed in many seismic sections 
within thrust fold belt and only few in Sabah Trough 
as well as in thrust plate. Maximum and minimum 
fold wavelengths in the NW Sabah Basin is 12 km 
and 4 km respectively.  

The maximum fold wavelength is observed in 
the south of study area along seismic line LSD while 
the minimum fold wavelength is observed in 
seismic line LSL located in the north of study area.  

Average fold wavelength is about 7 km and the 
fold type is considered as low angle based on its size 
calculated between fold wings. The calculated 
average value is not very far different from what has 
been reported by Morley et al. (2011). They found 
that the average fold wavelength in NW Borneo is 
about 10 km.  



 
72  Sidek, A. & Hamzah, U./ JGEET Vol 03  No 02/2018  
 

 
Fig. 2. Example of seismic section (a) polygonal model and sequences (b) determination of inter-limb angle and fold 

 
 

 
 

Fig.3. Schematic cross section traced from seismic line LSA representing south of study area illustrating structural 

restoration from mid-Miocene (6) to Recent (1).wavelength (c) fold type classifications (d). 



 
Sidek, A. & Hamzah, U./ JGEET Vol 03  No 02/2018 73 

 

 
The restoration processes began with layer unit 

of recent to Mid-Miocene in age (15 Ma) numbered 
as 1 representing the youngest age to 6 for the 
oldest one. Fig.s 3 to 5 are examples of kinematic 
models representing south to north of the study 
area. 

 

 
 
Fig. 4. Schematic kinematic model for seismic line LSF 
representing the center of study area. 

 

 

Fig. 5. Schematic kinematic model for seismic line LSL 
representing north of study area. 

 
Overall, the restored cross sections show 

compressional deformation tectonic activities 
displayed by shortening strain that striking from 
northwest to southeast. This deformation is 
interpreted to be related to thrust faulting activities 
within thrust-fold belt and all normal faults in the 
shelf slope.  

4. Discussion 

Thrust faults in the study area were originated 
from compressional tectonic while all the normal 
faults were from tensional zone. Based on total 
shortening calculation, structures in deep water 
northwest Sabah basin is dominated by 
compressional activity. The value of total 
shortening percentage is calculated along 230 km 
length from seismic line LSA to LSL as shown in Fig. 
6.  

The plotted curves include uncertainty limit 
with total shortening length of 0.9 km to 14.7 km. 
The curves also record the age of each reconstructed 
layer unit during the formation of sequence 
stratigraphy unit 6 to unit 1. The lowest value of 
total shortening (0.9 km) is observed in the north 
along seismic line LSL while the highest value (14.7 
km) is calculated in the south along seismic line LSB. 
Length of total shortening is found increasing from 
11.6 km in south seismic line (LSA) to 14.7 km in 
northern seismic line (LSB) and then decreased 
again to 6.5 km along seismic line LSC. The 
significant decrease in total shortening in seismic 
line LSC may probably be due to error during the 
seismic interpretation process. Most likely the 
complete image of thrust fault structures were 
failed to be identified due to the quality of available 
seismic sections.  

Total shortening is increased from 7.7 km along 
seismic line LSD to 9.4 km along seismic line LSE and 
then started to decrease towards the north from 5.7 
km in LSF to 3.6 km along seismic line LSH. A very 
small total shortening of 3.2 km is observed in 
seismic line LSI, 1.6 km along LSK and eventually the 
shortest shortening of 0.9 km is observed in seismic 
line LSL.  

The major shortening with a magnitude of about 
14.4 km was observed in restoring unit 3  along 
seismic line LSB (Fig. 6). It can be interpreted as due 
to thick sediment supply from the continental shelf 
into the slope occurs during 7 to 8.5 Ma (million 
years) in the southern part of the study area. The 
rate of shortening is relatively decreasing in 15 Ma 
to recent. 

Fig. 7 shows the difference rate of total thrust-
fold belt by previous researchers and in this study. 
Hesse et al. (2010) reported similar study in 
structural restoration based on a total of 6 seismic 
sections in the same thrust-fold belt. Four of the 
seismic sections overlapped with LSA, LSB, LSD and 
LSF and in conclusion they divided the sections into 
5 sedimentary sequences as opposed to 7 sequences 
that found in this study.  



 
74  Sidek, A. & Hamzah, U./ JGEET Vol 03  No 02/2018  
 

 
Fig. 6.  Curves showing the shortening values against distance of seismic lines with uncertainties bars from mid-Miocene 

(15 Ma) until Pliocene (4 Ma). 

Hesse et al. (2010) also observed crustal total 
shortening (8-13 km) in the thrust-fold belt from 
recent to Miocene. Shortening of about 5 to 7 km for 
each layer was observed in recent to Pliocene unit 
sequence while a much smaller shortening of 2-4 
km was observed in the Early to Late Pliocene 
sequences. A shortening of approximately 3 km was 
calculated in layer sequence of early Pliocene to 
Miocene in age. In general, the rate of shortening in 
sedimentary sequence is found decreasing from 
older towards younger. Basically their findings are 
not so much in difference from the results of this 
study where the major shortening was reported in 
the southwest particularly along seismic line LSB.  

Based on seismic line positions, major tectonic 
compression was towards NW-SE which is almost 
similar to what was reported by King et al.(2010) 
that obtained the tectonic trend by investigating a 
total of about 200 wells in Baram thrust-fold belt 
and in some part of Sabah Basin thrust-fold. 

5. Conclusion 

The seismic cross sections used in the structural 
reconstruction of the study area are considered as 
effective for estimating the rate of crustal 

shortening. The tectonic compressional activity 
which is considered as the main factor to cause the 
shortening and destroying the sedimentary 
depositional facies from parallel to chaotic seismic 
facies as observed in several seismic sections within 
the thrust-fold belt and thrust sheet.  

The values of total shortening measured in 
thrust-fold belt and thrust sheet zones indicate that 
both areas are not in equilibrium and had different 
rate of tectonic intensities. Exceeding balanced 
about 0.9 km and 14.7 km lengths were observed in 
crustal shortening of thrust-fold belt and thrust 
sheet zone both representing compressional area.   

This study is only completed if the value of 
crustal shortening is also measured from seismic 
lines representing the extensional zones located in 
shallow bathymetry (<200 m) area of Sabah Basin. 
The reconstruction system is balanced when the 
rate of crustal shortening observed in 
compressional and extensional zones are equal. 
Higher rate of crustal shortening indicates higher 
degree of compressional tectonic suffered by that 
particular crustal area resulting to formation of 
many thrust fault structures. 



 
Sidek, A. & Hamzah, U./ JGEET Vol 03  No 02/2018 75 

 

 

Fig.7. Comparison of structural reconstruction results by previous researchers and in this study. Comparison based on 

seismic lines (a) and comparison based on rose diagrams (b). 

Acknowledgements 

Authors would like to thank PETRONAS 
especially Petroleum Resource Exploration (PREx) 
and Petroleum Management Unit (PMU) for 
providing the subsurface data in this study area. The 
Kingdom Suite 8.8 and 2DMOVE software was used 
in interpreting seismic lines and retro-deformation. 
This study was supported by Malaysian 
Government under Fundamental Research Grant 
Scheme (FRGS) vot: R. J130000.7846.4F954 and 
Potential Academic Staff (PAS) vot: Q. 
J130000.2746.02K90.   

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	1. Introduction
	1.1. Geological Setting

	2. Methodology
	3. Result
	4. Discussion
	5. Conclusion
	Acknowledgements
	References