Organic Matter Distribution and Characteristics among Rock Formations in Malaysia: Implications on Hydrocarbon Generation Potential

Abstract

Numerous studies have been done to determine the hydrocarbon potential of Malaysia’s formations and basins due to the need to identify more conventional or unconventional hydrocarbon resources. Due to the fact that none of these investigations were carried out with any prior knowledge in the relevant regions with hydrocarbon potential, some of them did not, however, yield the expected results. This study aims to provide researchers with all the necessary information about potential hydrocarbon-producing areas in Malaysia and the various lithologies connected to them by analyzing all earlier studies carried out in Malaysia. This was accomplished by determining patterns in the distribution of organic matter and characteristics of the formations in Malaysia. Total Organic Carbon (TOC), Generic Potential (GP), Vitrinite Reflectance (R_o), and Hydrocarbon Yield (S2) were the most important hydrocarbon generation potential indicators discussed. A heat map was created using a statistical weight ranking with a weight of 45% for the TOC value and 30%, 15%, and 10% for the GP, S2, and R_o values, respectively. According to the data, the Bintulu, Pinangah, Begrih, Liang, and Tanjong formations have the highest potential to generate hydrocarbons in Malaysia, while the Kroh, Setap, Kalabakan, Temburong, and Belaga have the least potential. Majority of formations with high hydrocarbon potential are tertiary in age and consist primarily of coal and carbonaceous shale formations. The most promising formations are mostly immature, with type II or type III kerogen quality. It is recommended that critical exploration activities be focused on the tertiary-aged formations, particularly those in East Malaysia, in order to increase Malaysia’s hydrocarbon production.

1. Introduction

Like most Asian countries, Malaysia’s economy depends mainly on oil and gas produced from its current reserves [1]. Most of Malaysia’s hydrocarbon is produced from its petroleum-bearing sedimentary basins, like those in the onshore West Baram Province of North-west Borneo, Neogene Sandakan Formation of North-east Sabah, and the coal-bearing sequence at Batu Arang, and Western Sabah Basin [2,3,4]. Generally, Malaysia’s Western Peninsular area has been least explored for hydrocarbons, compared to the Eastern region, however, all possible petroleum yielding areas should be given much attention due to the decline in conventional resources. Also, due to the decline in hydrocarbon production from conventional reservoirs, more focus has been placed on unconventional reservoirs for hydrocarbon generation [5,6,7].

Currently, in Malaysia, there is a burning and active desire or aim to explore the potential for hydrocarbon production in the eastern and western Malaysia areas, and to discover new conventional and unconventional hydrocarbon basins. Such studies have mainly focused on the known major sedimentary basins, including Penyu, Malay, Sabah, Sarawak, Sandakan, and some parts of the Tarakan basins [8,9,10,11]. There are several stand-alone studies on the source rock potentials of several basins or formations in east and west Malaysia [8,9,12,13,14,15,16]. However, they all fail to provide a holistic insight into Malaysia’s key hydrocarbon generation potential. Therefore, systematic review studies are needed to provide useful state-of-the-art knowledge on the potential of these basins and formations in Malaysia. This would provide new future directions and recommendations toward the discovery of new conventional and unconventional reservoirs.

To fully understand the hydrocarbon potential of formations, it is important to characterize them using geochemical techniques [17,18]. This includes determining the entire amount of organic matter available in the sediments (Source richness), thermal maturity level, and, finally, the type of organic matter (Source quality) [17,19,20]. Source richness deals with the amount of organic matter present in the rocks capable of generating hydrocarbons [19]. According to Ronov [21], the capacity of a rock to generate hydrocarbons depends heavily on the quantity of organic matter available. It is deemed to be a sign of the sediment’s capacity for hydrocarbon generation and not just a measurement of the quantity of organic matter present [19]. Source quality indicates the types of organic matter present in the sediment, giving an idea of the type of hydrocarbons the sediment can generate [19]. As burial depth increases, there is increasing pressure and temperature which cooks the sediments and causes them to lithify and this transforms the organic matter in them to kerogen [22]. Therefore, the thermal maturity parameter indicates the stages of hydrocarbon generation the sediment has undergone [23,24,25]. These three main parameters were used to classify the formations analyzed. It is important to combine several analytical techniques for a more precise source rock evaluation [17]. The analytical techniques often used are Total Organic Carbon (TOC) analysis, Rock-Eval Pyrolysis, and Vitrinite Reflectance analysis [17,25,26,27].

This review reports on almost all the articles in the literature on the source rock potentials in the east and west Malaysia, by systematically providing insight and details on the TOC, generic potential (GP), hydrocarbon yield (S2) and vitrinite reflectance (R_o) of Malaysian formations/basins. For simplicity, the paper categorizes the source rock potential parameters according to the basins’ geographical locations: Peninsula, Sabah, and Sarawak. The findings in this article encourage the discovery of new conventional and unconventional hydrocarbon resources in Malaysia. The data provided in review tables could be used for basin hydrocarbon modeling in Malaysia. Potential green or less studied areas or basins in Malaysia are also discussed in this paper as future research prospects.

2. Geological Setting and Study Area

2.1. Geology of Malaysia

In this study, the formations discussed are scattered across Malaysia. As stated before, Malaysia is generally divided into two main regions, Peninsular Malaysia and East Malaysia. Peninsular Malaysia occupies a total land area of 130,268 km² [28]. It has a length of 750 km and a breadth of 330 km. It is also known to be elongated in a NNW–SSE direction [28,29]. The Johor Strait and the Straits of Malacca separate Peninsular Malaysia from Singapore Island to its south and western Sumatra Island, respectively (Figure 1). Peninsular Malaysia is a vital part of the Eurasian Plate and it is located at Sunderland, the Southeastern Asian part [28,29]. The Peninsula was formed in the Cenozoic era, and it is known to be tectonically steady, with only a few tectonic activities, like uplifts, movement of faults, tilting, and local gentle down warps [30]. Peninsular Malaysia is divided into three belts: the Eastern belt, the Western belt, and the Central belt. The division is based on the belts’ different geological characteristics [31,32,33]. The Central and Eastern belts of Peninsular Malaysia are split up by the Bentong–Raub suture zone [31,34,35].

The Upper Paleozoic rocks can be seen in the three belts of the Peninsular, while the Lower Paleozoic rocks can only be seen in the Western part of the Peninsular [28]. The following studied rock formations/basins are all located in Peninsular Malaysia; Belata, Semanggol, Kroh, Semantan, Batu Arang, Batu Gajah and the Penyu. All the formations mentioned are in the Western belt of Peninsular Malaysia, except for the Penyu basin, which is in the Central belt (Figure 1). The ages of the formations studied range from the Silurian to the Tertiary periods (Figure 2).

The geology of East Malaysia is divided into two main areas, the Sabah region, and the Sarawak region. Sarawak is subdivided into three tectonostratigraphic zones representing the decreasing stratigraphic and structural complexity towards the east [36,37,38]. The three zones are the Kuching, Sibu, and Miri zones [39,40,41]. The Kuching zone is located in the westernmost Sarawak, west of Batang Lupar [42]. The Kuching zone is thought to be a marginal part of the West Borneo basement, which spreads southwards into Kalimantan [36,43]. The Sibu Zone is located in the center of Sarawak, and it is predominately composed of thick shale–sandstone turbidite sequences accumulated in the oceanic crust [44,45]. The Miri zone is the youngest of the three zones and it is located in the northeast [36]. The Tatau-Mersing line acts as a boundary between the Sibu and Miri zones. The following studied rock formations are all located in the Sarawak region: Bintulu, Belaga, Nyalau, Begrih, Liang, Balingian, Mukah, Lambir, Miri, and Tukau (Figure 1). The ages of the formations studied range from the Middle Cretaceous to Tertiary periods, with most of the formations found in the Miocene epoch (Figure 3a).

Sabah occupies an area of about 76,115 km² in the northern part of Borneo Island [46,47,48]. It lies next to actively moving plates in the southeast Asia region [49]. The area’s topography is considered rough, particularly on the west coast. Sabah is mainly composed of thick, folded, Upper Cretaceous to Tertiary marine sedimentary rocks, lavas and plutonites, and subordinate Mesozoic metamorphic rocks [46,50,51]. Near the west coast is a distinct mountain range that includes the Palaeogene Crocker formation and other older rock units. It rises to between 3000 to 4000 m above sea level, culminating in the Late Neogene Kinabalu granodiorite intrusion, which peaks at 4101 m [49,50,51]. The following studied rock formations are all located in the Sabah region: Ganduman, Sebahat, Tanjong, Sandakan, Temburong, Pinangah, Beliat, Meligan, West Crocker, Setap, Kapilit, and Kalabakan (Figure 1). All the formations studied in Sabah are found in the Tertiary period, with most of the formations found in the Miocene epoch (Figure 3b).

2.2. Study Area

The study area for this review consisted of all areas in Malaysia where rock formations have been evaluated to determine their potential to generate hydrocarbons. Out of the one hundred and fifty-nine (159) formations in Malaysia, a total of twenty-nine (29) formations from both Peninsular and East Malaysia were analyzed in this study, representing 18% of all the formations in Malaysia. Of the studied formations, 76% were conducted in East Malaysia, while the remaining 24% were in Peninsular Malaysia (Figure 1). Out of the twenty-two formations in East Malaysia, twelve (12) of the formations analyzed were from the Sabah region, and the remaining ten (10) were from Sarawak (

Table 1. List of various formations studied, and the references associated with these formations.

No.	Formation/Basin	Region	Location (s)	Coordinates	Period/Age	Author (References)
1	Belata	Peninsular Malaysia (PM)	Sungai Gumut/Kg. Air Panas/Junction to Kg. Sg Jang/Kuala Kubu town/Kuala Kubu Bharu	03°36′25″,101°35′18.3″/ 03°36′27″, 101°35′49.2″/ 03°34′31.6″, 101°36′55.9″/ 03°33′20.3″, 101°38′25.2″/ 03°33′15″, 101°38′41″	Carboniferous	[8]
2	Semanggol	Peninsular Malaysia (PM)	Gunung Semanggol/Bukit Merah/Nami		Late Permian to Early Triassic	[13,14,52]
			Nami/Taiping	N 06°04′38.10″, E 100°43′52.90″/ N 04°56′38.20″, E 100°41′40.20″
			Taiping/Bukit Merah/Nami
3	Kroh	Peninsular Malaysia (PM)	Kg Lalang/Kelian Intan/Near Kg Puloh/Felda Nenering/Kg. Lalang to Air Panas/Baling border	05°35′43′′0.6, 101°04′9′′0.18/ 05°36′6′′0.96, 101°01′8′′0.45/ 05°36′9′′0.49, 101°01′8′′0.04/ 05°40′34′′0.1, 101°01′8′′0.3/ 05°38′30′′0.3, 101°05′24′′0.9/ 05°39′16′′0.1, 101°05′45′′0.5/ 05°43′14′′0.6, 100°58′53′′0.8	Silurian & Devonian	[53]
4	Semantan	Peninsular Malaysia (PM)	Kuala lipis/Benta/Kota Kelanggi/Karak/Thermos shale/Maran/Temerloh/Bahau/Gemas/Tenang/Ayer Hitam	04°03′43.5″, 101°59′05.8″/ 03°53′39.4″, 102°27′38.9″/ 03°11′26.2″, 102°24′06.2″/ 02°34′53.7″, 102°36′44.9″/ 02°27′17.7″, 102°58′38.6″/ 01°53′44.0″, 103°12′38.6″/ 03°28′05.4″, 102°03′03.5″/ 03°43′13.8″, 103°03′00.0″/ 03°35′00.0.2″, 102°46′44.6″/ 03°26′24.4″, 102°25′10.5″/ 04°11′16.8″, 102°03′45.1″	Triassic	[13,52]
			Ayer Hitam/Yong Peng/Labis/Bukit Jeram Padang Ridge/Temerloh/Toll Plaza/Benta/Kuala Lipis
5	Batu Arang	Peninsular Malaysia (PM)	Selangor		Eocene-Oligocene	[54]
	Batu Arang	Peninsular Malaysia (PM)	Selangor	N 3°19′22.01″, E 101°28′30.03″	Eocene-Oligocene	[55]
6	Penyu	Peninsular Malaysia (PM)	Chenor, Pahang	N 3°29′16.64′’, E 102°44′1.65′’	Tertiary	[56]
7	Batu Gajah	Peninsular Malaysia (PM)	Baju Gajah		Devonian	[57]
8	Ganduman	Sabah/East Malaysia	Dent Peninsula	05°20.6540, 119°07.312 05°16.2640, 119°05.490 05°16.4130, 119°06.403 05°16.8790, 119°08.231 05°08.5620, 119°06.102 05°20.6560, 119°10.751 05°10.7570, 119°10.524 05°18.6370, 119°00.550 05°19.1070, 119°02.679 05°20.4030, 119°05.977 05°11.6560, 119°10.984 05°18.3000 119°00.000 05°18.630’, 119°00.150 05°18.4330, 119°08.532 05°18.4320, 119°08.531 05°19.3420, 119°08.763	Pliocene	[58]
9	Sebahat	Sabah/East Malaysia	Dent Peninsula	05°08.133, 119°01.833 05°13.617, 118°58.950 05°09.067, 118°58.800 05°09.700, 118°54.650 05°09.733, 118°54.900 05°09.067, 119°00.000	Upper Mioceneto Pliocene	[58]
9	Sebahat	Sabah/East Malaysia	Dent Peninsula	05°17.283, 118°59.867 05°20.217, 119°00.733 05°08.826′119°00.314 05°08.825′119°02.855′ 05°08.463, 119°01.802 05°09.196, 119°00.602 05°13.817, 118°58.210 05°13.748, 118°59.006 05°23.363, 119°14.317 05°05.473, 118°51.761	Upper Miocene to Pliocene	[58]
10	Tanjong	Sabah/East Malaysia	Pinangah area		Miocene	[59]
	Tanjong	Sabah/East Malaysia	Sabah	N 04°30′58.0′′ E 117°14′32.0′′	Oligocene to Early Miocene	[55]
	Tanjong	Sabah/East Malaysia	Southern Sabah		Middle Miocene to Late Early Miocene	[60]
11	Sandakan	Sabah/East Malaysia	Sandakan		Middle to Late Miocene	[61]
12	Temburong	Sabah/East Malaysia	Tenom		Miocene	[62]
	Temburong	Sabah/East Malaysia	Sipitang-Tenom	N 04.58147, E 115.42054/ N 04.58124, E 115.42801	Paleogene to early Miocene	[15]
13	Pinangah coalfield	Sabah/East Malaysia	Sandakan		Early to middle Miocene	[63]
14	Beliat	Sabah/East Malaysia	Batu Luang	N 05.52415, E 115.52573/ N 05.52365, E 115.52520/ N 05.52350, E 115.52475	Late Miocene	[15]
	Beliat	Sabah/East Malaysia	Kuala Penyu		Miocene	[64]
15	Meligan	Sabah/East Malaysia	Sipitang	N 05.02157, E 115.32355/ N 05.00651, E 115.33254	Early Miocene	[15]
16	West Crocker	Sabah/East Malaysia	Sipitang	N 05.02376, E 115.30998/ N 04.59835, E 115.35441/ N 05.46563, E 116.01333	Paleogene	[15]
17	Setap	Sabah/East Malaysia	Beaufort		Miocene	[64]
18	Kapilit	Sabah/East Malaysia	Eucalyptus camp		Early to Middle Miocene	[65]
	Kapilit	Sabah/East Malaysia	Southern Sabah		Early to Middle Miocene	[60]
19	Kalabakan	Sabah/East Malaysia	Southern Sabah		Early Miocene	[60]
20	Bintulu coalfields	Sarawak/East Malaysia	Bintulu		Oligocene	[63]
21	Belaga	Sarawak/East Malaysia	Jalan Sri Aman–Sarikei/Jalan Sibu–Bintulu/Jalan Sibu–Sarikei		Late Cretaceous to Late Eocene	[12]
22	Begrih	Sarawak/East Malaysia	Mukah	N 2°45′27.47″ E 112°20′34.98″	Lower Pliocene	[55]
23	Nyalau	Sarawak/East Malaysia	Bintulu	N 3°11′32.98″E 113°5′17.62″	Oligocene-Miocene	[55]
	Nyalau	Sarawak/East Malaysia	Bintulu		Oligocene-Miocene	[66]
	Nyalau	Sarawak/East Malaysia	Bintulu		Oligocene-Miocene	[4]
24	Liang	Sarawak/East Malaysia	Mukah	N 02°40′11.41″ E 112°20′22.56″	Lower to Upper Pliocene-	[55]
25	Balingian	Sarawak/East Malaysia	Sarawak	N 02°47′98.40″ E 112°23′19.41″	Late Miocene	[55]
	Balingian	Sarawak/East Malaysia	Sarawak		Upper Miocene	[63]
26	Mukah coalfield	Sarawak/East Malaysia	Sarawak		Upper Miocene	[63]
27	Lambir	Sarawak/East Malaysia	Sarawak	4°11.271’ N,114°2.437’ E/ 4°11.230’ N, 114°2.399’ E/ 4°11.215’ N, 114°2.410’ E/ 4°11.190’ N, 114°2.195’ E	Middle Miocene	[67]
28	Miri	Sarawak/East Malaysia	Sarawak	4°11.618’ N, 113°50.778’ E/ 4°12.718’ N, 113°53.661’ E/ 4°15.193’ N, 113°54.227’ E	Middle to Late Miocene	[67]
29	Tukau	Sarawak/East Malaysia	Sarawak	4°15.519’ N, 114°2.156’ E	Late Miocene	[67]

). These formations were chosen based on the studies already done to determine the hydrocarbon generation potential of the said formations. Most of these formations fall under the Tertiary period with the majority under the Miocene epoch. The age of the formations range from the Silurian to Tertiary. The majority of the twenty-nine (29) studied formations were primarily composed of carbonaceous shales and coals. Some of the formations were also composed of mudstone, coaly sandstone, and carbonaceous sandstones.

3. Methodology

Published data on TOC analysis, Rock-Eval Pyrolysis, and Vitrinite Reflectance analysis of the twenty-nine formations (29) in Malaysia were accumulated and analyzed to determine the formations’ characteristics and potentials to generate hydrocarbons. Retrieved data on TOC, GP, S2, and R_o from the analysis mentioned was used for this analysis.

The average of all the data provided by different authors on a particular formation was used to analyze the formation as a whole. Some of the formations without Vitrinite Reflectance (R_o) values from the data accumulated were calculated using the formula [R_o = (0.0149 × Tmax) − 5.85] according to Wust [68]. Even though the R_o formula has limitations, because it may not objectively reflect the actual situation of the various regions within the scope of the study, the formula has been widely used to calculate R_o when no experiment was conducted to determine the actual R_o. In addition, other scholars, such as Ahmed, Shoieb and Owusu [8,12,53], have used it to estimate the R_o of formations in Malaysia. Therefore, this formula sufficed since it is only an estimation of the maturity. Other values, such as HI, PI, and OI, that were not available were calculated using their corresponding formulae [69,70].

Justification for Heat Map

Finally, a heat map was generated to give an idea of all the formations’ hydrocarbon generation potentials using the average weight of the formations’ TOC, GP, S2, and R_o values. A weighted statistical ranking method was used to create the heat map with Forty-five percent weight for TOC value, and thirty, fifteen, and ten for GP, S2, and R_o values, respectively. The weighted ranking percentages were assigned according to the order of importance of the parameters. The weighted statistical ranking score was estimated using the equation below:

$$R{S}_n=\frac{{{\displaystyle \sum }}_{i=1}^{n}xw}{{{\displaystyle \sum }}_{i=1}^{n}w}$$

(1)

where RS is the weighted statistical ranking score for n variable (TOC, GP, S2, and R_o values), x is the hydrocarbon generation potential indicator variables values, and w is the assigned weighted ranking percentages for each variable.

TOC was allocated 45% because it is arguably the most important parameter to consider in source rock evaluation. This is due to the fact that any prospective source rock should have a high TOC [17]. TOC measures the organic richness of sedimentary rocks by totaling the organic matter quantity available in the rock [21,24]. The TOC analysis is the first analysis conducted to have a fair idea of the hydrocarbon potential of a formation [25,71]. Even though TOC is an important parameter, it should not be used alone; according to Tissot [72], some organic matter can generate hydrocarbons while others cannot generate anything because of their inert nature. TOC analysis cannot differentiate between inert and productive organic matter; it quantifies all the organic matter in the rock [17]. This can result in inaccurate results. Moreover, TOC also reacts to the maturity of organic matter; Daly [73] noticed that the amount of TOC in a rock reduced as hydrocarbons were generated and forced out. Due to these reasons, there is also a need to consider the formations’ hydrocarbon yield (S2) and generic potential (GP).

The GP received 30% of the allocation since it is the closest to TOC in estimating the potential of source rocks. GP represents the hydrocarbons that a source rock can generate if subjected to sufficient temperature [74,75,76]. It is the summation of S1 and S2, with S1 representing the already generated hydrocarbon and S2 representing the hydrocarbon generating potential remaining in the sediment’s kerogen [75,76]. This makes the GP superior to the S2, so a higher statistical weight is given to GP than to S2.

Hydrocarbon yield (S2) was assigned 15% because it represents the hydrocarbon generating capacity remaining in the sediment’s kerogen after a portion of the organic matter has already formed hydrocarbons [75,76].

Finally, the R_o was given the least statistical weight (10%) because even though thermal maturity is essential to the capacity of organic matter to generate hydrocarbons, formations with extraordinarily high organic matter and low thermal maturity can still produce hydrocarbon through thermal cracking [77]. Potential source rocks, according to Waples [78], are immature sedimentary rocks capable of generating and expelling hydrocarbons if their maturity level is higher. As a result, immature formations can still be considered potential source rocks.

4. Hydrocarbon Potential of formations in Malaysia

4.1. Organic Geochemical Characteristics of Formations in Peninsular Malaysia (PM)

4.1.1. Source Richness of Formations in PM

Generally, the formations in Peninsular Malaysia had very good TOC values, ranging from 1.33% to 41.23% wt%, according to the classification of TOC values by Peter [79].

Table 2. Interpretation of average TOC values of formations in Peninsular Malaysia according to Peter [79].

No.	Formation	Avg TOC (wt%)	Interpretation after Peter [79]	Reference(s)
1	Belata	3.32	Very good	[8]
2	Semanggol	2.85	Very good	[13,14,52]
3	Kroh	2.21	Very good	[53]
4	Semantan	2.68	Very good	[13,52]
5	Batu Arang	41.23	Very good	[54,55]
6	Penyu	15.84	Very good	[56]
7	Batu Gajah	1.33	Good	[57]

provides the classification of TOC values. The Batu Gajah shale formation has the lowest average TOC of 1.33 wt%, which was still good for hydrocarbon generation according to the Peter [79] interpretation of TOC values. The lower the organic content in the rock, the lower its TOC value, and the lower the TOC value, the lower the chance of generating hydrocarbon. The Batu Arang formation and the Penyu basin had the highest TOC values at 41.23% and 15.84 wt%, respectively, as shown in Table 2. The high values of Batu Arang formation and the Penyu basin could be attributed to the formations being primarily composed of coals, and black shales, which contain very high organic content, especially the coals [80,81,82]. The other formations, such as Belata, Semanggol, Kroh, and Semantan, had very good TOC values, ranging from 2.21 to 3.32 wt% (Table 2). The formations with the highest TOC values in Peninsular Malaysia were predominantly composed of coals and oil shales which supported claims made by Pashin, Rullkotter and Speight [83,84,85] that these sedimentary rock types contain high amounts of organic matter. Organic richness measures the amount of organic matter in the sediment capable of generating hydrocarbon, not just the amount of organic matter itself [19]. For this reason, it is not advisable to use TOC alone to determine the quantity of hydrocarbon a rock can generate, as suggested by Dembicki [17]. This is because there are different types of organic matter in sediments, with some generating hydrocarbons while some are also inert and do not generate any hydrocarbon [72]. The increasing maturity of organic matter also causes TOC to decrease [17,73]. As the organic matter matures, the relative inert kerogen content of the organic matter increases as the reactive organic matter is used up in hydrocarbon generation [73]. Therefore, it is key to combine TOC with other analyses, such as Rock-Eval Pyrolysis to make accurate predictions of TOC [17]. Figure 4 shows the combined analysis of TOC and S2 of the formations in Peninsular Malaysia. According to Figure 4, the Batu Arang formation and Penyu basin had the highest chance of producing hydrocarbons. This was demonstrated by the high amount of organic matter present in the formations, as confirmed by their high S2 values. The hydrocarbon generation potentials of these formations are promising and require further research for economic considerations. The lower S2 values in the Belata, Semanggol, Kroh, and Semantan formations indicated that the organic matter in these formations had already been generated, because S2 stands for the residual organic matter in the formations.

4.1.2. Source Quality

Rock-Eval pyrolysis is the most reliable analytical technique to provide information about kerogen type [19,69,86]. The analyzed dataset from the Rock-Eval allows the derivation of HI and OI, which is equivalent to the H/C atomic ratio and O/C atomic ratio, respectively [69,79,86]. The average OI values of the Belata, Semanggol, Kroh, Semantan, and Batu Arang formations ranged from 2.03 to 31.50 mgCO₂/g, and their average HI values ranges from 0.02 to 347.38 mg HC/g (

Table 3. Average OI and HI values of formations in PM.

No.	Formation	Av OI (mg CO2/g)	Av HI (mg HC/g)	Reference(s)
1	Belata	2.03	0.02	[8]
2	Semanggol	30.16	22.89	[13,14]
3	Kroh	5.82	1.42	[53]
4	Semantan	31.50	26.18	[13,52]
5	Batu Arang	22.06	347.38	[55]

). The Belata and Kroh formations had very low HI and OI values, making it difficult to get a good reading from the plot in Figure 5. There were indications that the samples in both the Semantan and Semanggol formations were of type IV kerogen (Figure 5). However, according to Dembicki [17] the Semantan and Semanggol formations appear gas-prone because type IV kerogen is basically inert and does not really influence S2, but contributes to the TOC, which lowers the HI. The similarities in the kerogen type of both the Semantan and Semanggol formations could be associated with part of both formations being formed in the Triassic period.

To evaluate the kerogen type of the Batu Arang formation and Penyu basin, Tmax and HI values were used, due to limitations on the availability of OI data for those formations in the open literature. The average Tmax of the Batu Arang formation and Penyu basin was 416.86 °C and 416.35 °C, respectively, and the average HI was 463.43 and 434.80, respectively (

Table 4. Average Tmax and HI values of Batu Arang and Penyu formations in PM.

No.	Formation	Av Tmax (°C)	Av HI (mg HC/g)	Reference(s)
1	Batu Arang	416.86	463.43	[54]
2	Penyu	416.35	434.80	[56]

). The Batu Arang formation and Penyu basin have type II and type I kerogen types, respectively (Figure 6). This shows that the organic matter from the Penyu basin originated from algal material deposited in lacustrine environments, thereby producing mostly waxy oil [17]. The Batu Arang having type II organic matter gives the impression that it originated from autochthonous organic matter deposited under reducing conditions in marine environments. As a result, it primarily produces naphthenic oil [17].

The classification by Peter [79] (

Table 5. Source quality interpretation of formations in PM using Peter [79] interpretation.

No.	Formation	Av S2/S3	Av HI (mg HC/g)	Peter [79] Source Quality Interpretation	Reference(s)
1	Belata	0	0.02	Gas	[8]
2	Semanggol	0.36	22.89	Gas	[13,14]
3	Kroh	0.06	1.42	Gas	[53]
4	Semantan	1.06	26.18	Gas	[13,52]

), that uses the HI vs. S2/S3, suggests that the Belata and Kroh formations are type III, which indicates that they generate gas. Furthermore, the organic matter from the Belata and Kroh formations is derived from terrestrial plant debris or aquatic organic matter deposited in an oxidizing environment, and, thus, might mainly produce gas [72]. The Semantan and Semanggol formations were also classified according to Peter [79] classification and indicated type III kerogen, and this confirmed the conclusion that type IV kerogen appears to be gaseous.

4.1.3. Thermal Maturity

Vitrinite Reflectance (R_o) is the principal thermal maturity indicator in hydrocarbon exploration [76,87]. However, not all the formations had vitrinite reflectance analysis done according to the data analyzed. As a result, R_o was calculated for the formations without R_o data, using the Duvernay shale model [R_o = (0.0149 × Tmax) − 5.85] [68]. The range of R_o values of the formations in Peninsular Malaysia was 0.39% to 3.58%, with an average value of 1.38% (

Table 6. Thermal maturity interpretation for formations in PM according to Dow [88] using R_o.

No.	Formation	Av Ro (%)	Dow [88] Thermal Maturity Interpretation	Reference(s)
1	Belata	3.58	Dry gas	[8]
2	Semanggol	1.21	Late oil	[13,14,52]
3	Kroh	1.40	Wet gas	[53]
4	Semantan	1.26	Late oil	[13,52]
5	Batu Arang	0.41	Immature	[54,55]
6	Penyu	0.39	Immature	[56]

). The Belata Formation had the highest R_o, with the Penyu and Batu Arang Formations having the lowest values of 0.39 and 0.41, respectively (Table 6). According to the standard interpretations of the stages of organic matter maturity by Dow [88], the samples from Batu Arang and Penyu were immature (Table 6). The immature nature of the Batu Arang and the Penyu indicated that the organic matter in these formations had not been exposed to deep burial and thermal cracking to generate hydrocarbons. It also indicated that the samples from Semantan and Semanggol formations were in the late oil generation stage. Finally, the interpretation by Dow [88] suggests that the Belata formation samples had generated dry gas, while that of Kroh had also generated wet gas. Tmax vs. PI plots are often used to determine the maturity, and they provided results similar to those obtained from the interpretation based on Dow [88] classification. According to the Tmax vs. PI plots, the samples from Batu Arang and Penyu were immature, while the samples from Semantan and Semanggol were in-between the oil and gas zones. The Belata and Kroh formations had matured to the dry gas stage (Figure 7). According to the HI vs. Tmax plots, the Batu Arang, Kroh, Belata formations, and Penyu basin were in the pre-oil stage, indicating that they were still immature (Figure 8). However, the HI vs. Tmax plots results for the Belata and Kroh formations differed from the R_o and Tmax vs. PI plots. This could have been because of the relatively low HI resulting from the low S2 values. Generally, Tmax values of rocks with very low S2 values (<0.2 mg HC/g rock) can be inaccurate [79,89]. The Semantan and Semanggol formations were in the wet gas/condensate zone indicating higher thermal maturity than the others.

4.1.4. Generic Potential (GP)

GP refers to the quantity of hydrocarbons a rock can generate if subjected to sufficient temperature [76]. The GP represents the summation of the S1 and S2 (GP = S1 + S2). S1 denotes previously generated hydrocarbons, while S2 stands for the remaining hydrocarbon generating potential in the sediment’s kerogen, so combining the two gives an idea of the formation’s potential to generate hydrocarbons [75,76]. The GP values ranged from 0.02 to 143.07 mg HC/g with an average of 38.44 mg HC/g. The Batu Arang had the highest value of 143.07 mg HC/g with the Belata having the lowest value of 0.02 mg HC/g (

Table 7. Interpretation of average GP values of formations in PM according to Hunt [75].

No.	Formation	Generic Potential (GP) S1 + S2 (mg HC/g)	(Hunt, 1995), GP Interpretation	Reference(s)
1	Belata	0.02	Poor	[8]
2	Semanggol	0.21	Poor	[13,14,52]
3	Kroh	0.05	Poor	[53]
4	Semantan	0.84	Poor	[13,52]
5	Batu Arang	143.07	Very good	[54,55]
6	Penyu	86.46	Very good	[56]

). According to the Hunt [75] classification of GP, all the formations had very poor GP, except for the Batu Arang formation and Penyu basin which had very good GP. The low GP values of the Belata, Kroh, Semantan and Semanggol formations could be attributed to the matured nature of those formations. As the maturity of the sediment increases, the S2 reduces, resulting in lower GP.

4.1.5. Hydrocarbon Generation Potential of Rock Formations in PM

The Penyu basin and Batu Arang formation stood the highest chance of generating hydrocarbons from all the formations studied in Peninsular Malaysia. This was due to the high TOC, high GP and high hydrocarbon yield (S2) values, which showed that the formations had high organic matter present. As the samples were still immature, most of the hydrocarbons were still intact and stood a high chance of generating hydrocarbons when subjected to high temperatures. The Penyu basin and Batu Arang formation also generate type I and type II kerogens, respectively. The Semantan and Semanggol formations had a low chance of generating hydrocarbons. These formations had relatively average TOC and low GP and matured organic matter, indicating that most hydrocarbons had already been generated. The Semantan and Semanggol formations generate type III kerogen, which is gaseous in nature.

The Kroh and Belata formations have the least possible chance of generating hydrocarbons among the formations studied in Peninsular Malaysia. This was because of the very mature organic matter in those formations and poor GP as well. The formations’ high maturity and low GP represented low hydrocarbon generation potential. The Belata and Kroh formations also generate type III kerogen. A fair assessment of the Batu Gajah shale was not possible, due to inadequate data for its assessment; however, the formation is known to have good TOC.

4.2. Organic Geochemical Characteristics of Rock Formations in Sabah Region

4.2.1. Source Richness of Rock Formations in the Sabah Region

Rocks in East Malaysia are categorized into two sections: (i) Sabah and (ii) Sarawak. Most of the TOC results from the Sabah region were good, ranging from 0.53 to 68.05 wt%, with an average of 17.63 wt%, which was very good according to Peters [79] classification of TOC values (

Table 8. Interpretation of average TOC values of formations in Sabah according to Peters [79].

No.	Formation	Avg TOC (wt%)	Interpretation after Peters [79]	Reference(s)
1	Ganduman	15.75	Very good	[58]
2	Sebahat	6.51	Very good	[58]
3	Tanjong	52.80	Very good	[55,59,60]
4	Sandakan	19.27	Very good	[61]
5	Temburong	0.53	Fair	[15,62]
6	Beliat	1.64	Good	[15,64]
7	Pinangah	68.05	Very good	[90]
8	Meligan	1.99	Good	[15]
9	West Crocker	3.19	Very good	[15]
10	Setap	0.84	Fair	[64]
11	Kapilit	39.94	Very good	[60,65]
12	Kalabakan	1.03	Good	[60]

). The Pinangah formation had the highest TOC value of 68.05 wt%, with the Temburong formation having the lowest TOC value of 0.53 wt% (Table 8). The very high TOC values of the Ganduman, Tanjong, Sandakan, Pinangah, and Kapilit formations could be associated with their composition of coals and carbonaceous shales or mudstones. Coals and carbonaceous shales are known to contain high organic matter [84,85]. Since TOC alone does not give the actual quantity of organic matter capable of producing hydrocarbons, there was also a need to analyze the quantity of organic matter that would generate hydrocarbons, which could be done by combining TOC with S2. The TOC vs. S2 plot indicated that the Pinangah, Tanjong, and Kapilit formations had a very high chance of generating hydrocarbon. On the other hand, the chances of organic matter being generated from the Sandakan and Ganduman formations was below average. In contrast, the rest of the formations in the Sabah region had a meager chance of generating hydrocarbon, as shown in Figure 9.

4.2.2. Source Quality

The average OI values of the Sandakan, Temburong, Pinangah, Beliat, Meligan, West Crocker, and Setap formations ranged from 3.6 to 88.50, while the HI values ranged from 35.19 to 392.5 (

Table 9. Average OI and HI values of formations in Sabah.

No.	Formation	Avg OI	Avg HI	Reference(s)
1	Sandakan	47.48	76.74	[61]
2	Temburong	17.94	35.19	[15,62]
3	Pinangah	3.60	392.50	[63]
4	Beliat	43.00	56.22	[15,64]
5	Meligan	19.40	36.60	[15]
6	West Crocker	21.20	71.00	[15]
7	Setap	88.50	60.10	[64]

). The Ganduman, Sebahat, Tanjong, Kapilit and Kalabakan formations had HI ranging from 24.69 to 261.78 and Tmax ranging from 372 to 492.7 °C (

Table 10. Average Tmax and HI values of formations in Sabah.

No.	Formation	Avg Tmax (°C)	Avg HI	References
1	Ganduman	372.00	60.75	[58]
2	Sebahat	405.44	24.69	[58]
3	Tanjong	458.33	250.08	[60]
4	Kapilit	434.06	261.78	[60,65]
5	Kalabakan	492.70	39.60	[60]

). The OI and HI plots indicated that almost all the formations were of type III kerogen, except for the Pinangah and Tanjong formations, which were type 1. This suggested that only the Pinangah and Tanjong formations would generate oil, but the rest would generate gas (Figure 10). The Tmax vs. HI plots also indicated that the Tanjong and Kalabakan formations were Type I, and the Kapilit formation was Type III, with the Ganduman and Sebahat formations being Type IV (Figure 11). However, since type IV kerogen is inert and only minimally contributes to the S2 but significantly contributes to the TOC, this lowered the HI, making the source rock appear more gas-prone [17]. The Pinangah and Tanjong formations were type I kerogen, originating from algal material accumulated in lacustrine environments and producing waxy oil [17]. So, the other formations in the Sabah region, except Pinangah and Tanjong, originated from terrestrial plant debris or aquatic organic matter accumulated in an oxidizing environment that generated mainly gas [72].

4.2.3. Thermal Maturity

The R_o values of the studied formations in the Sabah region ranged from 0.30% to 1.35%, with an average value of 0.7% (

Table 11. Thermal maturity interpretation of formations in Sabah according to Dow [88] using R_o.

No.	Formation	Av Ro	Dow [88], Thermal Maturity Interpretation	Reference(s)
1	Ganduman	0.30	Immature	[58]
2	Sebahat	0.35	Immature	[58]
3	Tanjong	0.66	Early Oil	[55,59,60]
4	Sandakan	0.40	Immature	[61]
5	Temburong	1.35	Wet Gas	[15,62]
6	Pinangah	0.56	Immature	[90]
7	Beliat	0.88	Peak Oil	[15,64]
8	Meligan	0.76	Early Oil	[15]
9	West Crocker	0.91	Peak Oil	[15]
10	Setap	0.38	Immature	[64]
11	Kapilit	0.59	Immature	[60,65]
12	Kalabakan	1.30	Late Oil	[60]

). The Temburong formation had the highest R_o, with the Ganduman formation having the lowest R_o value of 0.30%. According to the standard interpretations of the stages of organic matter maturity by Dow [88], the Ganduman, Sebahat, Sandakan, Pinangah, Setap, and Kapilit formations from the Sabah regions were immature. While the others had generated oil in different stages, only the Temburong formation was highly matured to generate gas (Table 11). The Tmax vs. PI plots provided results like the Dow [88] classification. The Temburong and Kalabakan formations had already generated dry gas, while the West Crocker, Meligan, and Beliat formations had generated oil. The rest of the formations were either immature or between the immature and oil stage (Figure 12). According to the HI vs. Tmax plots, the Gaduman, Pinangah, Kapilit, Sebahat, Sandakan, Setap, and Begrih formations were in the pre-oil stage, indicating that they were still immature. The Tanjong, Beliat, and Meligan formations are in the oil window, while the West Crocker formation was in the wet gas/condensate zone. Finally, the Kalabakan and Temburong formations were in the dry gas zone, indicating the two formations’ matured nature (Figure 13).

4.2.4. Generic Potential (GP)

The GP values of the formations in Sabah ranged from 0.12 to 279.69 mg HC/g with an average of 55.19 mg HC/g. The Pinangah formation had the highest value of 143.07, with the Temburong having the lowest value of 0.12 mg HC/g (

Table 12. Interpretation of average GP values of formations in Sabah according to Hunt [75].

No.	Formation	Generic Potential (GP) S1 + S2 (mg HC/g)	(Hunt, 1995), GP Interpretation	Reference(s)
1	Ganduman	21.37	Very good	[58]
2	Sebahat	3.57	Fair	[58]
3	Tanjong	181.29	Very good	[55,59,60]
4	Sandakan	18.84	Very good	[61]
5	Temburong	0.12	Poor	[15,62]
6	Pinangah	279.69	Very good	[90]
7	Beliat	1.75	Poor	[15,64]
8	Meligan	0.92	Poor	[15]
9	West Crocker	4.85	Fair	[15]
10	Setap	0.56	Poor	[64]
11	Kapilit	148.9	Very good	[60,65]
12	Kalabakan	0.45	Poor	[60]

). According to the Hunt [75] classification of GP, the Pinangah, Ganduman, Tanjong, Kapilit and Sandakan formations had very good GP while that of West Crocker and Sebahat were fair (Table 12). The GP of Kalabakan, Meligan, Beliat, and Setap formations are all poor, according to the Hunt [75] classification (Table 12). The low GP values of these formations could be attributed to their low maturity and low organic richness. As the thermal maturity of the sediment increases, the S2 reduces, thereby decreasing the GP. Low thermal maturity and high organic matter could be attributed to the high GP values of the Pinangah, Ganduman, Tanjong, Kapilit, and Sandakan formations.

4.2.5. Hydrocarbon Generation Potential of Rock Formations in Sabah

The Sabah region has many formations that can generate hydrocarbons, probably commercially. The Pinangah, Tanjong, Sandakan, Kapilit, and Ganduman formations can all generate hydrocarbons in commercial quantities. These formations had very high TOC values, high hydrocarbon yield (S2), and very good GP. The Pinangah and Tanjong formations generate type I kerogen, whilst Sandakan, Kapilit and Ganduman formations generate type III kerogen. The Temburong and Setap formations had the slightest chance of generating hydrocarbons in the Sabah region, due to the low TOC nature, poor GP, and the matured nature of the organic matter in the formations. The other formations, such as Sebahat, Beliat, Meligan, West Crocker, and Kalabakan formations, had a moderate to low chance of generating hydrocarbons, due to the relatively average TOC and matured nature of the formations and with some having poor GP.

4.3. Organic Geochemical Characteristics of Formations in Sarawak Region

4.3.1. Source Richness of Rock Formations in the Sarawak Region

The formations in the Sarawak region had TOCs ranging from 0.74 to 97.8 wt% with an average of 38.89 wt% (

Table 13. Interpretation of average TOC values of formations in Sarawak according to Peter [79].

No.	Formation	Avg TOC (wt%)	Interpretation after Peter [79]	Reference(s)
1	Bintulu	70.02	Very good	[90]
2	Belaga	0.74	Fair	[12]
3	Nyalau	36.10	Very good	[55,66]
4	Begrih	97.80	Very good	[55]
5	Liang	93.22	Very good	[55]
6	Balingian	49.71	Very good	[55,63]
7	Mukah	34.83	Very good	[63]
8	Lambir	3.25	Very good	[67]
9	Miri	1.54	Good	[67]
10	Tukau	1.68	Good	[67]

). The Belaga formation had the lowest TOC value, while the Begrih formation had the highest TOC value. Overall, the TOC of the Sarawak region was very good according to Peters [79] classification (Table 13). The high TOC values of the Bintulu, Nyalau, Begrih, Liang, Balingian, and Mukah formations could be attributed to the formations being primarily composed of coals, and black shales, which are high in organic matter, especially the coals, which contain very high organic content [80,81,82]. The TOC vs. S2 plots indicated that the Begrih, Liang and Balingian had a very high chance of generating hydrocarbons due to their high S2 values, as shown in Figure 14.

4.3.2. Source Quality

The average OI values of the formations in Sarawak ranged from 3 to 31 mgCO₂/g and the average HI values ranged from 10.76 to 400.50 mgHC/g, as shown in

Table 14. Average OI and HI values of formations in Sarawak.

No.	Formation	Avg OI (mgCO2/g)	Avg HI (mgHC/g)	Reference(s)
1	Bintulu	3.00	400.50	[63]
2	Belaga	26.04	10.76	[12]
3	Nyalau	12.23	259.22	[55,66]
4	Begrih	31.00	234.50	[55]
5	Liang	26.75	253.35	[55]
6	Balingian	25.71	200.83	[55,90]
7	Mukah	23.45	210.40	[90]
8	Lambir	27.00	81.80	[67]
9	Miri	30.20	88.70	[67]
10	Tukau	25.50	84.20	[67]

. The OI and HI plots indicated that most of the formations were of type II and III kerogen, except for the Belaga and Begrih, which were of type IV kerogen, and the Bintulu formation, which was of type I kerogen (Figure 15), originating from algal material accumulated in lacustrine environments, producing waxy oil [17]. The Liang, Nyalau, Mukah, and Balingian formations were of type II kerogen (Figure 15). Type II kerogen originates from autochthonous organic matter accumulated in reducing conditions in marine environments, and this mainly produces naphthenic oil. The Tukau, Miri, and Lambir formations were of type III kerogen. They originated from terrestrial plant debris and/or aquatic organic matter accumulated in an oxidizing environment, and this mainly produces gas. The Belaga and Begrih were Type IV kerogen and appeared gas-prone because, according to Dembicki [17], type IV kerogen is basically inert and does not really influence S2 but contribute to the TOC, which lowers the HI. As a result, the rock appears more gas-prone. So, therefore, the Belaga and Begrih mainly generate gas.

4.3.3. Thermal Maturity

The R_o values of the formations in the Sarawak region ranged from 0.37% to 2.39%, with an average value of 0.65% (

Table 15. Thermal maturity interpretation for formations in Sarawak according to Dow [88] using R_o.

No.	Formation	Av Ro (%)	Dow [88], Thermal Maturity Interpretation	Reference(s)
1	Bintulu	0.58	Immature	[63]
2	Belaga	2.39	Dry Gas	[12]
3	Nyalau	0.54	Immature	[55,66]
4	Begrih	0.45	Immature	[55]
5	Liang	0.44	Immature	[55]
6	Balingian	0.40	Immature	[55,63]
7	Mukah	0.37	Immature	[63]
8	Lambir	0.42	Immature	[67]
9	Miri	0.44	Immature	[67]
10	Tukau	0.43	Immature	[67]

). The Belaga formation had the highest R_o, with the Mukah formation having the lowest R_o value of 0.37% (Table 15). Except for the Belaga formation, the average R_o for all the other formations was below 0.60. According to the standard interpretations of the stages of organic matter maturity by Dow [88], all the formations studied in the Sarawak region were immature, apart from the Belaga formation, which was matured to the extent of generating dry gas (Table 15). The Tmax vs. PI plots provided results like the Dow [88] classification. All the nine (9) other formations studied in the Sarawak region were in the immature zone, with only the Belaga formation in-between the wet gas and dry gas window (Figure 16). According to the HI vs. Tmax plots, all the formations studied were in the pre-oil stage, apart from the Belaga formation which is in the dry gas zone (Figure 17). Therefore, the results from all the three classifications for thermal maturity used were in line with one another.

4.3.4. Generic Potential (GP)

The GP values of the formations in Sawarak ranged from 0.1 to 289.37 mg HC/g with an average of 115.58 mg HC/g. The Bintulu formation had the highest value of 289.37, with the Belaga having the lowest value of 0.1 mg HC/g (

Table 16. Interpretation of average GP values of formations in Sarawak according to Hunt [75].

No.	Formation	Generic Potential (GP) S1 + S2 (mg HC/g)	(Hunt, 1995), GP Interpretation	Reference(s)
1	Bintulu	289.37	Very good	[63]
2	Belaga	0.1	Poor	[12]
3	Nyalau	131.06	Very good	[55,66]
4	Begrih	231.75	Very good	[55]
5	Liang	232.57	Very good	[55]
6	Balingian	187.06	Very good	[55,63]
7	Mukah	78.03	Very good	[63]
8	Lambir	2.86	Fair	[67]
9	Miri	1.47	Poor	[67]
10	Tukau	1.48	Poor	[67]

). According to the Hunt [75] classification of GP, the Bintulu, Nyalau, Begrih, Liang, Balingian, and Mukah formations had very good GP, while that of the Lambir formation was fair (Table 16). The GP of Belaga, Tukau and Miri formations were all poor, according to the Hunt [75] classification (Table 16). The low GP values of these formations could be attributed to their low maturity and low organic richness. Low thermal maturity and high organic matter were probably the cause of high GP values in most formations.

4.3.5. Hydrocarbon Generation Potential of Rock Formations in Sarawak

For Sarawak, the Begrih, Liang, Balingian, and Bintulu formations had the highest chance of generating hydrocarbons, due to their high TOC, high hydrocarbon yield (S2), and high GP. These formations were immature, indicating that there was still a chance of generating hydrocarbons in huge quantities when subjected to high temperatures. The Belaga formation had the slightest chance of generating hydrocarbons in the Sarawak region due to the very mature nature of the hydrocarbons and poor GP. The significantly matured nature of the Belaga formation indicated that it had already generated to its total capacity; therefore, there was little chance of further generating hydrocarbons. The other formations had a moderate to low probability of generating hydrocarbons, due to their relatively satisfactory TOC and S2 and fair to poor GP. Most of the formations in the Sarawak region generate type II and type III kerogen.

5. Generative Potential of Malaysia

A heat map was generated using the ranking of the formations’ TOC, GP, S2, and R_o values. A statistical weight ranking method was used for the heat map with Forty (40) percent weight for TOC value and thirty (30), fifteen (15), and ten (10) for GP, S2, and R_o values, respectively. The weighted ranking percentages were provided, given the parameters’ order of importance. The ranking indicated that the Bintulu, Pinangah, Begrih, Liang and Tanjong were the top five formations with the highest potential to generate hydrocarbons (Figure 18). Conversely, the Kroh, Setap, Kalabakan, Temburong, and the Belaga formations had the lowest generation potential among all the formations studied (Figure 18). It can be deduced from the heat map that the formations in Sarawak had the highest potential to generate hydrocarbons, followed by the formations in Sabah and then, finally, the formations in Peninsular Malaysia (Figure 18).

6. Prospects and Recommendations

• The coaly formations, such as Bintulu, Batu Arang, Penyu, Tanjong, Sandakan, Pinangah, Nyalau, Balingian, and Mukah, can serve as unconventional resources, such as for coal bed methane (CBM), and also conventional liquid hydrocarbons.
• Due to the abundance of coal formations, there is a need to find more uses for these coals to exploit the resource fully.
• More exploration works for hydrocarbon generation potential of rocks should be focused on formations in the tertiary and, more importantly, the tertiary formations in Sarawak and Sabah regions.
• Most of the formations with high potential to generate hydrocarbons are immature, indicating that there is a probability that the offshore equivalents might be matured enough to generate hydrocarbons, because they are buried deeper, and they are subjected to higher temperatures deep down.

7. Conclusions

Based on the findings of this review, the following conclusions are drawn:

• The formations in Sarawak have the highest potential to generate hydrocarbons, followed by the formations in Sabah and then, finally, the formations in Peninsular Malaysia.
• The formations with the highest potential to generate hydrocarbons among the formations analyzed are primarily coal and carbonaceous shale formations.
• The hydrocarbon generation potentials in Malaysian formations are mostly high in the younger formations, compared to the older ones.
• Most of the formations with high potential to generate hydrocarbons have immature organic matter, which is probably because those formations are younger and, thus, have not been buried for long.
• Most formations with the highest potential to generate hydrocarbons, such as Bintulu, Pinangah Tanjong, and Batu Arang, are of type 1 kerogen, indicating that the organic matter in these rock formations originated from algal material deposited in lacustrine environments and so produces mostly waxy oil.