E-ISSN : 2541-5794 P-ISSN : 2503-216X Journal of Geoscience, Engineering, Environment, and Technology Vol 01 No 01 2017 Suryadi A./ JGEET Vol 1 No 1/2016 1 Fault analysis to Determine Deformation History of Kubang Pasu Formation at South of UniMAP Stadium Hill, Ulu Pauh, Perlis, Malaysia Adi Suryadi 1, * 1 Geological Engineering Program, Faculty of Engineering, Islamic University of Riau Pekanbaru, Riau * Corresponding Author : adisuryadi@eng.uir.ac.id Tel.:+6282283896947 Received: Oct 1, 2016. Revised : 15 Nov 2016, Accepted: Nov 20, 2016, Published: 1 Dec 2016 DOI: 10.24273/jgeet.2016.11.1 Abstract The Kubang Pasu Formation at South of UniMap Stadium Hill has suffered deformation that produced fault with various types and orientations. First deformation (ST1) is southeast northwest were resulted normal, reverse, dextral and sinistral fault. At station 32, Reverse fault (N94 0 E/48 0 ) from ST1 was cut by reverse fault (N48 0 E/40 0 ) result of second deformation (ST2). Another cross cutting fault found at station 108, third deformation (ST3) with stress direction from northeast southwest that produced reverse fault with strike direction N134 0 E and 68 0 of dip angle was cutting the reverse fault (N87 0 E/66 0 ) from second deformation. The youngest deformation (ST4) has stress from east west. At station 110, normal fault (N90 0 E/30 0 ) is representing the youngest deformation was cutting the reverse fault (N154 0 E/52 0 ) from third deformation. Keywords: Deformation, reverse fault, normal fault, dextral fault, sinistral fault, cross cutting. 1. Introduction The study area is located at Bukit Stadium of is bounded by latitude 06 0 28.246' N to 06 0 28.273' N and longitude 100 0 20.923'E to 100 0 (Figure 1). The outcrop is hill-cut at south of Bukit Stadium with extensive approximately 320 m 2 . This area was mapped as Kubang Pasu Formation that consist of clastic sedimentary rock (Gobbet, 1973 and Jones, 1981). History of deformation can be determined by observation of tectonic structure. Study about tectonic structure was carried by Zaiton Harun et al. (1999), Gobbet (1973), and Abdul Hadi et al. (1999) at Kubang Pasu Formation. Relationship between structures can be used to determine the relative age of deformation. Cross cutting law is one of many methods to determine the relative age. Fig 1. Map of the study area 2. General Geology and Stratigraphy Based on geological map of Peninsular Malaysia show that study area is located at Kubang Pasu Formation. The Kubang Pasu Formation is exposed well at north and center of Perlis and extended to north of Kedah (Basir Jasin et al., 2003). Kubang Pasu and Singa Formation at north of Peninsular Malaysia is same age, the typical characteristic of Kubang Pasu is consist of thick quartz sandstone and interbedded with mudstone (Gobbet, 1973). Thickness of Kubang Pasu Formation is more than 1500 m that consist of sandstone and mudstone (Foo, 1983). At Bukit Temiang, there are passage beds from clastic rock of Kubang Pasu Formation become limestone of Chuping Formation. Hassan and Lee (2002) said, sometimes there are pebble and cobble at mudstone and shale layers. The age of Kubang Pasu Formation is determined by fossil that found. Trilobite Cyrtosymbole (Waribole) was found at red and grey shale at Gunung Hutan Aji together with bellerophontide, pelecypode, bacutalitide, brakiopode and crinoid stem. All those fossil represent at Late Devonian till Early Carbon (Kobayashi and Hamada, 1973). Complete sequence of Kubang Pasu Formation exposed at ex-quarry Ladang Cheong Chong Kaw, south of Kampong Panchor and at Kampong Belukar. Bottom part of this formation consist of dark mudstone and dark grey of chert. These layer overlay by interbedded of thin sandstone and thick mudstone. Interbedded of sand stone and mudstone with same thickness is the upper part of Kubang 2 Suryadi A./ JGEET Vol 1 No 1/2016 Pasu Formation (Zaiton Harun and Basir Jasin, 1999). At Kaki Bukit and Gunung Hutan Aji, lower Paleozoic unit (Setul Formation) and upper Paleozoic unit (Kubang Pasu Formation) is exposed adjacent. There is no clear evidence that show unconformity between Paleozoic unit and Devonian unit. Lithostratigraphy of study area are divided into the facies association, they are interbedded of sandstone which is the bottommost sequence, followed by fossiliferous thick mudstone and massive sandstone at the uppermost of the sequence. 3. Structure of Study Area North part of Peninsular Malaysia is associated with Bok Bak mega fault. Bok Bak fault at Bukit Jabi was discussed by Zaiton Harun and Basir Jasin (1999), Mahang formation overlay the Kubang Pasu Formation that younger than it. The boundary between those formations is a milonite zone result of thrust fault caused by Bok Bak fault. Structure geology of study area is show at figure 2. The bedding in this area has two dominants direction that are east west and northeast southwest. The dip ranging from 10 0 - 80 0 toward south and southeast. Furthermore, the dominant structure in the study area is fault. The fault identified in the field are reverse fault, normal fault, sninstral fault and dextral fault. The fault can be identified by presence of mylonite, fault breccias, slickenside, and displacement figure 3. Fig 2. Geological structure map of study area Fig 3. Indication of fault; a. slickenside; b. fault breccia; c. displacement; d. mylonite 3.1 Reverse Fault 34 strike and dip data of reverse fault was taken from the field. All the data plotted to sterionet to get the major reverse fault and the result shown that there are 4 major reverse faults named as Ss1, Ss2, Ss3 and Ss4 (figure 4). All those faults interpreted as pure reverse fault. Besides that, also there is reverse sinistral fault with pitch toward N76 0 E named as SsG. Result of reverse fault analysis represent at Table 1. The result show that there are 4 main stress (compressional stress) which are east-west (Ss1 and Ss4), southeast-northwest (Ss2), north-south (Ss3) and northeast-southwest (SsG). a b c d Suryadi A./ JGEET Vol 1 No 1/2016 3 Fig 4. Sterionet analysis of reverse fault Table 1. Stress analysis result of reverse fault Fault plane Strike and dip Pitch direction Compressional stress σ1 Stress direction Ss1 N7 0 E/70 0 - N97 0 E N277 0 E East-West Ss2 N40 0 E/59 0 - N130 0 E N310 0 E Southeast-northwest Ss3 N86 0 E/42 0 - N176 0 E N356 0 E North-South Ss4 N162 0 E/80 0 - N252 0 E N72 0 E East-West SsG N90 0 E/42 0 N76 0 E N318 0 E N138 0 E Northeast-southwest 3.2 Normal Fault From 47 strike and dip data of normal fault was taken 4 major normal fault labeled as Sn1, Sn2, Sn3 and Sn4 (figure 5). Aside from all those pure normal fault, there are 2 another normal faults found at field. They are normal dextral fault with pitch toward N240 0 E (SnG1) and normal sinistral fault with pitch toward N6 0 E (SnG2). The result of normal fault analysis (Table 2) show that there are 4 extensional stress which are north-south (Sn1), northwest-southeast (Sn2), east-west (Sn3) and northeast-southwest (Sn4, SnG1 and SnG2). 3.3 Dextral Fault 5 major dextral fault plane was got from plotting 18 strike and dip data from field observation. 5 major dextral fault interpreted as pure dextral fault that labeled as Ska1, Ska2, Ska3, Ska4 and Ska5 (figure 6). Data and results of analysis of dextral fault show at Table 3. There are 3 main stress (compressional stress) that generate all of those faults at study area, they are stress from northeast- southwest (Ska1), north-south (Ska2 and Ska3) and northwest-southeast (Ska4 and Ska5). 4 Suryadi A./ JGEET Vol 1 No 1/2016 Fig. 5 Sterionet analysis of normal fault Table 2. Stress analysis result of normal fault Fault plane Strike and dip Pitch direction Extensional stress σ3 Stress direction Sn1 N98 0 E/43 0 - N8 0 E N188 0 E North-south Sn2 N52 0 E/37 0 - N142 0 E N322 0 E Northwest-southeast Sn3 N349 0 E/73 0 - N79 0 E N259 0 E East-west Sn4 N313 0 E/72 0 - N43 0 E N223 0 E Northeast-southwest SnG1 N106 0 E/22 0 N240 0 E N42 0 E N222 0 E Northeast-southwest SnG2 N4 0 E/74 0 N6 0 E N243 0 E N63 0 E Northeast-southwest Fig 6. Stress analysis result of dextral fault Suryadi A./ JGEET Vol 1 No 1/2016 5 Table 3. Stress analysis result of dextral fault Fault plane Strike and dip Compressional stress σ1 Stress direction Ska1 N205 0 E/90 0 N55 0 E N235 0 E Northeast-southwest Ska2 N350 0 E/70 0 N199 0 E N19 0 E North-south Ska3 N322 0 E/65 0 N177 0 E N357 0 E North-south Ska4 N90 0 E/48 0 N292 0 E N112 0 E Northwest-southeast Ska5 N114 0 E/80 0 N325 0 E N145 0 E Northwest-southeast 3.4 Sinistral Fault From 12 strike and dip data of sinistral fault was taken 3 major sinistral fault labeled as Ski1, Ski2 and Ski3 (figure 7). All of them interpreted as pure sinistral fault. Based on analysis of sinistral fault (Table 4), there are 3 main stresses which are north-south (Ski1), northwest-southeast (Ski2) and northeast-southwest (Ski3). Table 4. Stress analysis result of sinistral fault Fault plane Strike and dip Compressional stress σ1 Stress direction Ski1 N27 0 E/90 0 N358 0 E N178 0 E North-south Ski2 N177 0 E/88 0 N150 0 E N330 0 E Southeast- northwest Ski3 N81 0 E/61 0 N55 0 E N235 0 E Northeast- southwest 4. Discussion On the whole, there are 4 main stress that generate fault at study area. All of them are northwest-southeast (ST1), north-south (ST2), northeast-southwest (ST3) and east-west (ST4). Stress from northwest-southeast (ST1) were generated some structures such as Ss2, Sn4, SnG1, SnG2, Ska4, Ska5 and Ski2. Another structure which are Ss3, Sn3, Ska2, Ska3 and Ski1 were generated by stress from north-south (ST2). For stress from northeast-southwest (ST3) were resulted Ss4, SsG, Sn2, Ska1 and Ski3 while stress from east-west (ST4) were caused form Ss1 and Sn1 (Table 5). To determine relative age of all of main stress, cross cutting law was used. At filed, cross cutting between faults were found. At station 32, ST1 that represented by reverse fault with strike N48 0 E and dip 30 0 was cut by reverse fault N94 0 E/48 0 from ST2. That mean ST1 is older than ST2 because it was cut by ST2. Meanwhile at station 108, reverse fault N134 0 E/68 0 that represent ST3 was cutting reverse fault N87 0 E/66 0 that generated by ST2. In other hand, ST 4 that generated normal fault N90 0 E/30 0 at station 110 was cutting 2 reverse fault N154 0 E/52 0 and N160 0 E/36 0 that result of ST3. Based on cross cutting between fault that found at field, the relative age of main stress was determined where the oldest stress is from northwest-southeast (ST1), following by north-south (ST2) and northeast-southwest (ST3). Whilst stress from east-west is the youngest stress at study area (Table 5). Table 5. History of deformation at study area based on analysis of fault Relative age Main Stress Compressional Stress (σ 1) Extensional stress (σ 3) Structures formed Oldest ST 1 Southeast-northwest Northeast-southwest Ss2, Ska4, Ska5, Ski2, Sn4, SnG1 and SnG2 ST 2 North-south East-west Ss3, Ska2, Ska3, Ski1 and Sn3. ST 3 Northeast-southwest Southeast-northwest Ss4, SsG, Ska1, Ski3 and Sn2 Youngest ST 4 East-west North-south Ss1 and Sn1 5. Conclusion 4 type of fault which are reverse fault, normal fault, dextral fault and sinistral fault were identified by indication of slickenside, fault breccias, displacement and presence of mylonite. Analysis of fault indicate that there are 4 main stresses were controlled the deformation at study area. The relative age of main stress was determined by cross cutting evidence between faults that found during observation at field. The oldest main stress is ST1 with the direction from northwest-southeast. The Fig 7. Stress analysis result of sinistral fault 6 Suryadi A./ JGEET Vol 1 No 1/2016 second main stress is from north-south (ST2) and following by third main stress from northeast- southwest (ST3). Meanwhile, the youngest main stress is ST4 with direction from east-west. All the main stresses were represented the history of deformation at study area. Acknowledgements I wish to thank Dr. Zaiton Harun as my supervisor for his guidance and all constructive comments during this study. I would like to thank Mrs. Nazirah Rahman who help me to collect data at field and give me some ideas for this paper. Lastly, thank you very much to all lecturers from geology program, Universiti Kebangsaan Malaysia. References [1] Gobbett, D. J. 1973. Upper Paleozoic. in. Gobbett, D. J. & Hutchison, C. S. (Edt). Geology of the Malay Peninsular: 61-95. New York: John Wiley & Sons, Inc. [2] Jones, C.R. 1981. The geology and mineral resources of Perlis, north Kedah, and Langkawi Island. Geological Survey Malaysia District Memoir 17: 67-84. [3] Zaiton Haron & Basir Jasin. 1999. Implication of the Bok Bak Fault movements on the structure and lithostratigraphy of the Pokok Sena area. Proceeding Mineral and Energy Resource of Southeast Asia: 145- 153. [4] Zaiton Harun & Basir Jasin. 1999. Sempadan litostratigrafi batuan Paleozoik zon baratlaut Semenanjung Malaysia. Dynamic Stratigraphy & Tectonics Of Peninsular Malaysia- Seminar II, The Western Belt & Paleozoic of Peninsular Malaysia: 101- 104 [5] stratification and significance. Dynamic Stratigraphy and Tectonic of Peninsular Malaysia- Seminar II: The Western Belt and Paleozoic of Peninsular Malaysia: 87-100. [6] Abdul Hadi, A. R. 1999. The upper paleozoic Singa- Kubang Pasu mega-sequence: some thoughts on basin initiation, depositional and tectonic hostory. Dynamic Stratigraphy and Tectonic of Peninsular Malaysia- Seminar II: The Western Belt and Paleozoic of Peninsular Malaysia: 58-68 [7] Basir Jasin, Zaiton Harun & Siti Norhajar Hasan. 2003. Black siliceous deposits in Peninsular Malaysia: their occurance and significance. Annual Geological Conference 2003 46: 149-154 [8] Foo, K. Y. 1983. The Paleozoic rocks of Peninsular Malaysia-Stratigraphy and correlation. Proceeding of the Workshopon Stratigraphy Correlation of Thailand and Malaysia 1: 1-19. [9] Hassan, M. H. & Lee, C. P. 2002. Stratigraphy of the Jentik Formation, the transitional sequence from the Setul Limestone to the Kubang Pasu Formation at Guar Sanai, Kampung Guar Jentik, Beseri, Perlis a preliminary study. Geological Society of Malaysia Annual Geological Conference 2002: 169-178. [10]Kobayashi, T. & Hamada, T. 1973. Cyrtosymbolids (Trilobita) from the Langgon Red Beds in Northwest Malaya, Malaysia. Geology & Palaeontology of Southeast Asia 12: 1-28.