1 Introduction
In Southeast Asia, there are two major continental masses, that is, the Indochina Terrane and the Sibumasu Terrane. Sibumasu collided with Indochina after prolonged subduction of the Devonian–Triassic Palaeo-Tethys Ocean [51]. We here recognise two sub-parallel suture zones along the belt of convergence between Sibumasu and Indochina; one wide suture zone representing an extensive accretionary complex of the Palaeo-Tethys (Changning–Menglian and Inthanon sutures), and one narrow suture zone representing a closed back-arc basin (Jinghong, Nan and Sra Kaeo sutures). These two sutures are more or less parallel to each other, with a former island arc in between, stretching from western Yunnan in the north through to Thailand. A new tectonic framework for mainland Southeast Asia is here proposed (Fig. 1).
The Nan and Sra Kaeo sutures in Thailand have traditionally been regarded as representing the Palaeo-Tethys Suture (e.g., [10,34]). However, this interpretation has been questioned by some authors [58,71,72] who have suggested an alternative site for the true Palaeo-Tethys subduction zone to the west, where pelagic cherts of Devonian–Triassic ages are distributed, and instead regarded the Nan and Sra Kaeo sutures as a closed back-arc basin. This view is supported, and is further refined in this paper.
Our new interpretation proposes the existence of an island-arc system and its back-arc basin developed along the western margin of the Indochina Terrane. The distribution patterns and emplacement periods of pre-Cretaceous S- and I-type granitoids support this proposal. Particular attention is paid to the chronostratigraphic occurrence of pelagic or deep-sea sediments in these parallel sutures in order to analyse the age ranges of the two closed seas.
2 Palaeo-Tethys Suture Zone
2.1 Changning–Menglian Suture Zone
The Changning–Menglian Suture Zone corresponds to the widely used term Changning–Menglian Belt. It is generally regarded as the main Palaeo-Tethys Suture Zone in western Yunnan (e.g., [47,75]), and, to the south, it is correlated with the Inthanon Suture Zone in Thailand (Fig. 1). This suture zone contains ophiolitic mélanges, volcanics, shallow-marine carbonates, and deep-sea sedimentary rocks (with substantial pelagic cherts).
Three major ophiolitic mélanges, the Tongchangjia, Shuanggou, and Menglian ophiolites, are known at the northern, central, and southern parts of the suture zone, respectively [83,84]. A series of tightly imbricate thrust sheets are common in mélange matrices [87]. Zhong et al. [87] pointed out that the structural vergence of the thrust sheets is generally west-dipping, appearing opposite to interpreted kinematics of the east-dipping subduction (see below), and they explained this to be a turn over owing to subsequent collisional compression. This requires to be verified.
Some basaltic volcanics range in age from Devonian to Late Permian, and are regarded as seamounts and/or oceanic islands in origin (e.g., [22]). Pure carbonate successions of the Carboniferous–Permian are closely associated with intraplate basalts, and are interpreted as limestone caps to seamounts (e.g., [35,75]).
The deep-sea sediments bear Devonian-Triassic radiolarians (e.g., [26,28,30]), and twenty-two radiolarian assemblage zones are recognised [28]. The oldest deep-sea sediment is represented by the Eoalbaillella lilaensis radiolarian zone (here assigned to the early Middle Devonian) of the Lalei Formation in the Menglian area [25,28]. This sediment, however, is unlikely a true pelagic deposit, because of its turbiditic sedimentary facies and clastic inclusions (Q. Feng, pers. commun., 2005). The Lalei Formation probably represents a hemi-pelagic deposit during the rifting to opening stage when Indochina was split from Gondwana in the Devonian. Unequivocal pelagic sediment of the Changing–Menglian Suture Zone commences with late Middle Devonian cherts with the Entactinia–Entactinisphaera radiolarian assemblage [28]. The youngest pelagic sediment is Late Anisian/Early Ladinian (Middle Triassic) chert represented by the Triassocampe deweveri radiolarian assemblage [28,31]. The chronostratigraphic range of pelagic sediments in the Changning–Menglian Suture Zone is therefore from Middle Devonian to late Middle Triassic.
The eastern fringe of the Changning–Menglian Suture Zone is intimately associated with paired metamorphic belts (Lancang Metamorphic Belts), which are constituted mainly of Permian–Triassic greenschists and blueschists [20,85,86]. That is, a low-P/T metamorphic belt in the east is associated with the Lincang Batholith (island arc), and an outer high-P/T metamorphic belt in the west is on the oceanward side to the Changning–Menglian Suture Zone (i.e., the Palaeo-Tethys subduction zone). Within the high-P/T belt, the metamorphic grade increases eastwards [20,85], suggesting an east-dipping subduction zone. The Lancang Metamorphic Belts of Zhang et al. [85] are regarded as representing typical paired metamorphic belts which can be developed in a subduction zone associated with an island arc (e.g., [1,54]), and this is taken as evidence of the Permo-Triassic east-dipping subduction beneath the Lincang arc.
2.2 Inthanon Suture Zone
The Inthanon Suture Zone of Thailand is largely equivalent to the Inthanon Zone described by Barr and Macdonald [3]. It is interpreted as an extensive accretionary complex of the closed Palaeo-Tethys Ocean, following the view of Ueno and Hisada [71]. Note that the term Chiang Mai Suture used by Metcalfe [52] is essentially equivalent to part of the Inthanon Suture Zone (see [71,72]).
Various types of rocks are distributed within the Inthanon Suture Zone, including Permian basaltic volcanics, Carboniferous–Permian limestones, Devonian–Triassic radiolarian cherts, Triassic S-type granitoids, and mylonitic/migmatitic gneisses. The Permian Chiang Mai Volcanics were analysed by Barr et al. [6] and Phajuy et al. [57]. The former considered it to have been generated in a back-arc rift setting within the Shan-Thai Terrane, whereas the latter suggested an oceanic island or a seamount in an oceanic within-plate setting. The latter interpretation is here supported.
Like the Changning–Menglian Suture Zone, the Inthanon Suture Zone also contains pure carbonate successions spanning from Early Carboniferous through to Late Permian, which yield abundant micro-fossils of warm-water Tethyan type [32,73,76]. These limestones are regarded as seamount caps originally formed within the Palaeo-Tethys Ocean [52].
The deep-sea sediments of the Inthanon Suture Zone can be classified into two main units, the Fang Chert and the Mae Sariang Group. The Fang Chert consists of ribbon-bedded radiolarian cherts, and represents a typical pelagic deposit of the Palaeo-Tethys. It ranges from late Middle Devonian through to late Middle Triassic in age [11,23,61,80]. The oldest strata documented in the Fang Chert are Givetian (late Middle Devonian) [80]. The youngest horizon is the Late Anisian/Early Ladinian (Middle Triassic) represented by the Triassocampe deweveri radiolarian assemblage [23].
The Mae Sariang Group is distributed around westernmost Thailand, and consists of Middle–Late Triassic radiolarian cherts and turbiditic clastics, with the Carnian beds (early Late Triassic) being the youngest [12,40,69]. Facies of the Mae Sariang Group is non-pelagic, and represents deposits more proximal to the Sibumasu passive margin than the Fang Chert [40]. Tofke et al. [69] interpreted these as typical pre- to syn-orogenic successions. The Middle Triassic sequence of the Fang Chert, not the Late Triassic of the Mae Sariang Group, is here regarded as the latest pelagic deposit in the Inthanon Suture Zone.
The southern part of the Inthanon Suture Zone is not well observed due to the extensive Cenozoic fluvial cover of the Menam Delta. In East Thailand, a transcurrent fault zone is recognised to the east of Chonburi through to near Klaeng [42]. This fault zone, called the “Klaeng Fault” by local geologists (P. Chaodumrong, pers. commun., 2005), corresponds to the boundary between the S- and I-type granitoid belts shown by Cobbing et al. [18,19], and is here defined also as the eastern boundary of the Inthanon Suture Zone (Figs. 1, 3).
Some deep-sea sediments of Devonian to Triassic ages are sporadically recognised in the southern part of the Inthanon Suture Zone (Fig. 1). In East Thailand, pelagic radiolarian cherts of Late Devonian or Early Carboniferous age near Rayong [62] and of Latest Permian age near the Klaeng Fault [63] have been reported. To the west of Bangkok (Kanchanaburi Province), Middle Triassic radiolarian chert of the Bo Phloi Formation was reported [64].
3 Back-arc basin suture
The Nan and Sra Kaeo sutures in Thailand and the Jinghong Suture (new name) in Yunnan are here regarded as the trace of a former back-arc basin. These local sutures have traditionally been thought to represent the Palaeo-Tethys Suture (e.g., [10,34,82]). However, the limited Permian deep-sea record precludes these as representing the Devonian–Triassic Palaeo-Tethys Ocean. Permian mélanges of possible ophiolites are recognised consistently in these local sutures, as noted below. Some authors (e.g., [55]) now suggest that ophiolites can form in back-arc basin environment, supporting the current case.
3.1 Nan Suture
The Nan Suture, also called the Nan–Uttaradit Suture, forms the tectonic boundary between the Sukhothai Terrane and the Indochina Terrane (Fig. 1). It is a narrow zone of Permian ophiolites and mélange. The Pha Som Metamorphic Complex consists mainly of greenschist and minor blueschist (crossite schist) associated with Permian bedded cherts and basic/ultrabasic igneous rocks, and represents the Nan ophiolitic mélange [2,5,66,67]. Actinolite from mafic schist of the Pha Som Complex yields a K/Ar age of 269 ± 12 Ma (i.e., Middle/Late Permian), indicating its minimum metamorphic age [2].
A late Middle Permian radiolarian chert in the Nan Mine area reported by Hada et al. [34] is the only evidence of deep-sea environment in this suture. The Pha Som Complex only reveals a Permian deformational episode. Thus, available chronological evidence suggests that the Nan basin was not a major Palaeo-Tethyan ocean, but was a short-lived Permian basin. Some authors [58,71] suggested it to be of back-arc basin origin.
The Nam Pat Group is distributed in the east of the Pha Som Complex, and it contains turbiditic sandstones and volcaniclastic conglomerates of Late Triassic age [49,65]. It overlies the Pak Pat Volcanics of possible Permian–Triassic age, which then is in contact with metasediments of the Pha Som Complex [65]. Thus, an Early/Middle Triassic unconformity below the Nam Pat Group is plausible (see [49,65]), and this may suggest that the Nam Pat sediments were deposited after back-arc uplift of the Nan Suture.
A curious find is that Hada et al. [34] reported a single specimen of the Middle Triassic radiolarian Triassocampe sp. found in a red-chert clast reworked in the continental Khorat Group in the Nan area. Hada et al. [34] presented it as evidence of a Triassic Palaeo-Tethys ocean in the Nan Suture. However, no host Triassic cherty sequence is so far known in the Nan Suture or the Nam Pat Group. Therefore, there is doubt that the Triassocampe clast was derived in situ. The chert clast might have been transported from the Palaeo-Tethys Suture Zone in the west, where Middle Triassic cherts (e.g., the Fang Chert) are common, during post-Triassic continental sedimentation. The Triassic chert in question seems unlikely to be a genuine element of the Nan Suture.
The deformational structure of the Pha Som Metamorphic Complex shows the northwest dipping vergence, and this has been interpreted to be an accretionary prism of a west-dipping subduction zone beneath the Sukhothai Terrane [10,66,67]. This subduction was considered by those authors to have produced the Permo-Triassic arc magmatism of the Sukhothai Terrane. However, the cause of the Sukhothai Arc magmatism is now better explained by the eastwards Palaeo-Tethys subduction at the Inthanon Suture Zone [71]. Considering that the Pha Som Complex is a small accretionary prism of limited Permian age, the occurrence of the prolonged west-dipping subduction in the former Nan basin is implausible.
In addition, some authors (e.g., [4,52]) correlated the Nan Suture with the Ailaoshan Suture in China. However, the Ailaoshan Suture likely represents a longer-lived Carboniferous–Triassic ocean [78], unlike the suggested Permian basin of the Nan Suture. The Nan Suture is, therefore, more reasonably correlated with the Jinghong Suture (southern Lancangjiang Suture) outlined later.
3.2 Sra Kaeo Suture
The Sra Kaeo Suture in East Thailand is regarded as the southern extension of the Nan Suture and the boundary between the Indochina Terrane and the Chanthaburi Terrane (new name). It represents a closed back-arc basin marginal to Indochina, as suggested by Ueno and Hisada [71,72]. An ophiolitic rock assembly called the Thung Kabin Mélange is distributed in the Sra Kaeo Suture [34], and it consists of bedded cherts, limestones, serpentinites, gabbros, and pillow lavas (also pers. observation, 2002). The cherts and limestones are dated with micro-fossils to be Permian in age [34]. The radiolarians of Sakmarian to Kungurian (Early Permian) [34] and Capitanian to Wuchiapingian (late Middle to early Late Permian) [60] are gained from the cherts, suggesting a limited Permian age for the former Sra Kaeo basin, similar to that of the Nan Suture. Thus, a Permian back-arc basin is more plausible for the origin of the Sra Kaeo Suture rather than a major Palaeo-Tethys Ocean.
Middle Triassic radiolarian-bearing cherts and black shales are distributed to the South of the Sra Kaeo Suture, and they are called the Chanthaburi Chert-clastic Sequence [34,60]. Hada et al. [34] interpreted this Triassic unit to be sediment of the former Sra Kaeo basin, and proposed the extended Sra Kaeo–Chanthaburi Suture Zone to represent the Palaeo-Tethys Suture. However, there is a certain stratigraphic gap between the Permian and Middle Triassic strata (Fig. 2). This may suggest an Early Triassic unconformity due to the Late Permian uplift in the Sra Kaeo back-arc basin. Moreover, the geographic extent of the Triassic unit is clearly separable from the Permian mélange of the Sra Kaeo Suture (see [34]). The Triassic cherts/clastics may have been deposited in a separate depression from the Sra Kaeo basin. The Triassic strata are not regarded as a genuine element of the Sra Kaeo Suture.
The Sra Kaeo Suture probably extends to Cambodia. Just beyond the Thai-Cambodia border, another mélange including basalts, peridotites, and possible Late Palaeozoic pelagic cherts is exposed near Pailin [9]. It is probably equivalent to the Permian Thung Kabin Mélange of the Sra Kaeo Suture.
3.3 Jinghong Suture (new name)
The Jinghong Suture is named for a minor suture between the Simao Subterrane of the Indochina Terrane and the Lincang Terrane (Fig. 1). It is after the ‘Jinghong Mélange’ used by Chen et al. [15], and is equivalent to that arbitrarily called the Lancangjiang Belt or the southern Lancangjiang Suture by some authors (e.g., [21,24,27,47,48]).
The so-called Lancangjiang Suture in eastern Tibet is generally accepted as the main Palaeo-Tethys Suture, and is often mistakenly correlated with the southern Lancangjiang Suture (i.e., Jinghong Suture) in Yunnan along the lengthy Lancang River (Mekong River) (e.g., [82]). However, as outlined earlier, the Palaeo-Tethys Suture in Yunnan is represented by the Changning–Menglian Suture, to which the Langcangjiang Suture in Tibet should be correlated. Hence, it is misleading to treat both Tibetan and Yunnan sections of the Lancang River together as the single Lancangjiang Suture. In order to avoid any confusion, the term Lancangjiang Suture should be restricted to Tibet. The (southern) Lancangjiang Suture in Yunnan, which is not attributable to the Palaeo-Tethys Suture, is renamed the Jinghong Suture, accordingly.
Volcanic and volcaniclastic rocks of possible Permo-Triassic ages are distributed extensively in the Jinghong Suture (e.g., [85]). Mélange-type deposits in this suture include serpentinites, basalts, and cherts (e.g., [8,27]), and these assemblages possibly represent ophiolites. The deep-sea cherts are dated by radiolarians, that is, late Early Permian cherts from the upper Longdonghe Formation [29], late Middle or earliest Late Permian red cherts of the Daxinshan Formation [27], and Early Changhsingian (Latest Permian) cherts from the Bangsha area near Jinghong [26]. The Daxinshan cherts are associated with tholeiitic basalts in the Jinghong Mélange [27]. These deep-sea sediments found are limited to the Permian, suggesting the existence of a minor short-lived basin separate to the Devono-Triassic Palaeo-Tethys closed in the Changning–Menglian Suture Zone in the west.
4 Sukhothai Arc terranes
It is proposed here that the Lincang Terrane of Yunnan, the Sukhothai Terrane and the Chanthaburi Terrane (new name) of Thailand were originally formed as parts of the same island-arc system developed along the margin of the Indochina Terrane, which was subsequently amalgamated to Indochina due to back-arc collapse and succeeded as a continental arc in the Triassic. This Permo-Triassic magmatic arc is here named “the Sukhothai Arc”, with the Permian Sukhothai island-arc system. The name is after the Sukhothai tectonostratigraphic zone of Barr and Macdonald [3], to which this magmatic arc principally corresponds in Thailand. Ueno and Hisada [71,72] indicated that the Sukhothai Terrane was developed as a Permian island arc marginal to the Indochina Terrane with the opening of the Nan back-arc basin, induced by the eastward subduction of the Palaeo-Tethys in the Inthanon Suture Zone.
4.1 Sukhothai Terrane
The Sukhothai Terrane of Barr and Macdonald [3] not Barr et al. [4] is used herein. It is delineated by the Inthanon Suture Zone to the west and by the Nan Suture to the east (Fig. 1). It is dominated by folded and faulted sequences of shallow-marine sedimentary rocks and igneous rocks with I-type granitoids, mostly of Permian and Triassic ages. There is general agreement that it is a Permo-Triassic magmatic arc [4,7,10,56]. Two Middle Triassic volcanics, the Lampang and Chiang Khong suites, show chemical characteristics indicative of a continental arc [4,7,56]. This may imply that the island arc has a continental basement.
Some authors (e.g., [10,34]) have treated the Sukhothai Terrane as part of the Shan-Thai (Sibumasu) Terrane. However, Permian marine faunas of the Sukhothai Terrane (e.g., [17,74,79]) are of warm-water Tethyan type and show no linkage with Sibumasu of Gondwanan origin.
4.2 Chanthaburi Terrane (new name)
The Chanthaburi Terrane introduced here is defined as the southern extension of the Sukhothai Terrane (Fig. 1). The name is after the Chanthaburi Pluton, which constitutes the core of this magmatic arc terrane. In East Thailand, the whole area west of the Sra Kaeo Suture was previously considered to belong to the Sibumasu Terrane (e.g., [10,34,52]). However, this area is defined as largely being the Chanthaburi Terrane, a magmatic arc of Indochina. The eastern boundary of the Chanthaburi Terrane is marked by the Sra Kaeo Suture, and the western boundary with the southern Inthanon Suture Zone is drawn by the Klaeng Fault. The Cambodian portion of the Chanthaburi Terrane is not clearly definable, but, together with the Sra Kaeo Suture, it likely extends to Cambodia, as mentioned earlier.
The tectonic correlation with the Sukhothai Terrane to the north is supported chiefly by the distribution of Permian to Triassic I-type granitoids, that is, the Eastern Granitoid Province (see later discussion in §7, Granitoid Emplacement). For example, the Chanthaburi Pluton yields I-type granitoids of 40Ar/39Ar (ca. 210 Ma) age [14], suggesting the fact that magmatism of the Chanthaburi arc was active until the very Late Triassic.
4.3 Lincang Terrane
The Lincang Terrane in Yunnan is defined as the northern extension of the Sukhothai Terrane (Fig. 1). Such correlation has been suggested by some authors (e.g., [7,48,82]), although the tectonic interpretations differ from author to author. The term Lincang Terrane is used after Liu et al. [47], and a core part of the terrane is referred to the so-called Lincang Batholith. This terrane has been variously called, for example, the Lincang Arc Terrane [46] or the Lincang Massif [70].
The Lincang Batholith has been commonly interpreted to be of magmatic arc origin [e.g. 7,46,82]. Rb/Sr isotopic ages on Lincang granitoids range between 280 and 210 Ma [16], that is, from Early Permian to Late Triassic. This range closely fits with that (280–200 Ma) of the Eastern Granitoid Province of Cobbing et al. [18], supporting the current inclusion of the Lincang Terrane to the Sukhothai Arc.
5 Indochina Terrane
The Indochina Terrane is the most substantial tectonic block in Southeast Asia. Nevertheless, recent studies reveal that Indochina may be a composite terrane including micro-terranes, metamorphic complexes, possible sutures, and mylonitic fault zones [44]. The Truong Son Belt and the Kontum Massif occupy much of central Vietnam to eastern Laos. They are sites of Early Triassic ductile deformation and high-temperature metamorphism, which may have been caused by the collision between South China and Indochina [44,45,50].
The Simao block occupies a narrow triangle region in western Yunnan to northern Laos. It was interpreted by some authors [52,81] as being separated from the South China and Indochina terranes by the Ailaoshan Suture and the Nan Suture possibly connected along the Dien Bien Phu Fault. However, the Dien Bien Phu Fault does not seem to be the substantive boundary between the Simao block and the Indochina Terrane. This fault is one of the most seismically active zones in Indochina today [88]. It does not show evidence of pre-Cenozoic activity, and there is no evidence of tectonic collision along this fault zone. Correlation between the Ailaoshan suture and the Nan sutures via the Dien Bien Phu Fault is unlikely. We here suggest that the Simao block is more likely a semi-detached portion of the Indochina Terrane, here renamed “the Simao Subterrane” (Fig. 1).
6 Chronostratigraphic comparison between the two parallel sutures
As outlined earlier, two tectonic sutures of contrasting stratigraphic records are apparent, that is, the Palaeo-Tethys Suture Zone in the west and the back-arc suture in the east. Chronostratigraphic ranges of deep-sea sediments recovered from these two sutures are summarised below and in Fig. 2.
Both the Changning–Menglian and Inthanon suture zones reveal similar age ranges of deep-sea environments from the early Middle Devonian through to the Late Triassic. Of them, the early Middle Devonian beds (the Lalei Formation in Yunnan) and the Late Triassic beds (the Mae Sariang Group in NW Thailand) are not assignable to proper pelagic sediments, because they show rather proximal facies to continental sources. Thus, unequivocal pelagic deposits are confined to an age range of late Middle Devonian (Givetian) to late Middle Triassic (Ladinian) (Fig. 2). This is a plausible age span of the Palaeo-Tethys Ocean that existed between the Indochina Terrane and the Sibumasu Terrane.
Facies change from early to late Middle Devonian sediments of the Changning–Menglian Suture Zone suggests that the rifting and initial spreading of the Palaeo-Tethys already started in the early Middle Devonian and its fuller oceanic stage commenced from the late Middle Devonian. The Mae Sariang Group shows typical pre- to syn-orogenic successions [69], suggesting that closure of the Palaeo-Tethys was already in progress in the Middle Triassic.
In contrast to the Palaeo-Tethys Suture Zone, a relatively minor mélange zone along the Jinghong, Nan, and Sra Kaeo local sutures yields much shorter records of deep-sea sedimentation. The Jinghong Suture reveals deep-sea environment of the late Early Permian up to Latest Permian (Early Changhsingian). The Nan Suture provides only late Middle Permian chert as deep-sea evidence. The Sra Kaeo Suture preserves deep-sea records spanning from the Sakmarian to the Wuchiapingian (Early to early Late Permian). In summary, overall deep-sea records of the Jinghong–Nan–Sra Kaeo suture are limited to the Permian, with a maximum age span from the Sakmarian to the Early Changhsingian (Fig. 2). This means that some part of the back-arc basin (e.g., Sra Kaeo) already gained a substantial depth in the Sakmarian. This further implies the probability that the initial back-arc rifting and opening already occurred in the Asselian (Earliest Permian) or even earlier. This Early Permian opening correlates well with the earliest magmatic age (280 Ma, middle Early Permian) recorded for the Sukhothai island-arc system (as in the Lincang Batholith). The Early Changhsingian marks the latest stage of deep-sea environment for the back-arc basin. Thus, it is plausible that the basin was tectonically closed before the Triassic.
From the overall chronostratigraphic ranges of deep-sea sediments in the Palaeo-Tethys Suture Zone and the Jinghong–Nan–Sra Kaeo back-arc suture, it is clear that these two former seas had contrasting age spans (Fig. 2), and should therefore be treated separately as an ocean and a marginal sea.
7 Granitoid emplacement
The tectonic feature of the parallel sutures with the island arc between fits well with the observed two granitoid provinces of contrasting geochemical characters, that is, the Main-Range Province and the Eastern Province (Fig. 3), originally recognised by Cobbing et al. [18]. These two granitoid provinces are also characterised by having distinct age ranges of their pre-Cretaceous plutonic activities.
The Main-Range Province consists mainly of S-type granitoids, whose ages range from early Late Triassic to late Early Jurassic (ca. 230–180 Ma) [14,18,41]. The petrogenesis of those S-type granitoids is explained by partial melting of the Sibumasu crust subducted beneath the Palaeo-Tethys accretionary complex [37,53]. This explains that the distribution of Main-Range granitoids overlaps the Palaeo-Tethys Suture Zone (Fig. 3). Thus, the granitoids are interpreted as orogenic and due to the collision of Sibumasu to the Sukhothai Arc. The earliest magmatic age (230 Ma) implies that the collisional orogeny (crustal thickening) started in or prior to the early Late Triassic. This appears consistent with the suggested late Middle Triassic closure of the Palaeo-Tethys.
By contrast, the granitoids of the Eastern Province are chiefly I type, and thus are regarded of magmatic arc origin [18,37,41,53]. The magmatism is considered to have been induced by the eastward subduction of the Palaeo-Tethys beneath the margin of Indochina [53,71]. These granitoids range from Early Permian to Latest Triassic in age (ca. 280–200 Ma), with occasional Cretaceous intrusions [14,18,41], the main period indicating the likely life span of the Sukhothai Arc magmatism. In summary, the collision of Sibumasu involved two plutonic episodes, that is, the initiation of Main-Range orogenic magmatism in the early Late Triassic and the cessation of the Sukhothai Arc magmatism at the end of the Triassic.
Meantime, the Eastern Province of Cobbing et al. [18] originally included the Loei-Phetchabun Volcanic Belt of the western Indochina Terrane. This volcanic belt was previously considered by Bunopas [10] to be a Permo-Triassic magmatic arc induced by the eastward subduction of the Nan–Sra Kaeo Sea. However, it is here noted that there is no clear evidence of such east-dipping subduction and resultant arc magmatism. No isotopic data of Permo-Triassic I-type granitoids is available from the same volcanic belt. Moreover, some igneous rocks in this volcanic belt are now confirmed much older (Devonian) or younger (Cenozoic) [38,39].
Some granodiorites from the Paklay Volcanics in Laos, which is the northern extension of the Loei-Phetchabun Volcanic Belt, are Triassic in age [77]. Even Late Triassic and Cretaceous granites were reported from the Paklay Volcanics by Stokes [68]. In addition, granites of the Tasal Pluton in central Cambodia (Fig. 3), which may be relevant to the Loei-Phetchabun Volcanic Belt, are Late Triassic in age, and show S-type affinity [43]. Thus, so-called Permo-Triassic granitoids of the Loei-Phetchabun Volcanic Belt are supposed to be mostly Mesozoic in age. Their genesis is here interpreted to be related to the crustal thickening of western Indochina induced by back-arc compression and enhanced later by the Sibumasu collision. Therefore, subduction-induced arc magmatism for the Loei-Phetchabun Volcanic Belt is unlikely. The Eastern Province is here revised to consist only of the Sukhothai Arc granitoids delimited to the west of the Jinghong–Nan–Sra Kaeo back-arc suture and to exclude those in the Indochina Terrane (Fig. 3).
8 Tectonic evolution: brief summary
A new tectonic scenario is here proposed incorporating the two parallel sutures (Fig. 4). In the margin of Gondwana, rifting and initial spreading of the Palaeo-Tethys started by the Middle Devonian, and its fuller oceanic stage started from the late Middle Devonian (Givetian). It probably gained its greatest oceanic width during the Carboniferous.
Subduction of the Palaeo-Tethys oceanic floor beneath Indochina likely started in the Latest Carboniferous or very Early Permian. As a result, arc magmatism started along the margin of the Indochina Terrane. The Jinghong–Nan–Sra Kaeo back-arc Basin probably started to open as early as the Asselian (Earliest Permian), and the Sukhothai island-arc system emerged. The back-arc basin already gained a substantial depth by the Sakmarian (in Sra Kaeo). Back-arc opening further proceeded during the Early Permian. An extensive carbonate platform (e.g., Saraburi and Sisophon limestones in Thailand and Cambodia) developed over the western Indochina Terrane inboard of the back-arc basin from Early to late Middle Permian.
The back-arc basin started to collapse in the Middle to Late Permian, and, in the Nan back-arc basin, the short-term west-dipping subduction took place and formed the narrow Pha Som Metamorphic Complex. The entire back-arc basin was probably closed and uplifted by the end of the Permian, leaving ophiolitic mélanges in the Jinghong, Nan, and Sra Kaeo local sutures. The carbonate platform of western Indochina was uplifted in the Late Permian. Thus, the Late Permian was the main phase of back-arc compression. Consequently, the Sukhothai island-arc system was amalgamated to marginal Indochina.
In the Early–Middle Triassic, the Palaeo-Tethys subduction beneath the continental Sukhothai Arc continued. Seamounts carrying Carboniferous–Permian limestone caps were accreted over the subduction zone. In the Triassic, orogenic plutonism after the back-arc collapse occurred in the western Indochina Terrane (e.g., Pak Lay to Loei areas).
By the early Late Triassic, the Sibumasu Terrane (including the Baoshan and Tenchong blocks) collided with the continental Sukhothai Arc of western Indochina. Thus, the Palaeo-Tethys Ocean was closed, forming the extensive accretionary prism of the Palaeo-Tethys Suture Zone upon the subducted part of Sibumasu. Some syn-orogenic sedimentation remained in a remnant fore-deep basin (Mae Sariang Group) during the Late Triassic. From the early Late Triassic, plutonism in the Main-Range Province started, stitching the Palaeo-Tethys Suture Zone as a consequence of collisional crustal thickening. In concert, the Sukhothai Arc ceased magmatism by the end of the Triassic, as a consequence of the termination of the Palaeo-Tethys subduction.
9 Conclusions and implications for the timing of the Indosinian orogeny
- • The Sukhothai Terrane is not part of the Sibumasu (or Shan-Thai) Terrane, but forms part of a former island arc marginal to the Indochina Terrane.
- • The Changning–Menglian Suture and the Inthanon Suture represent the Palaeo-Tethys Suture Zone in Yunnan and Thailand.
- • The Jinghong, Nan, and Sra Kaeo sutures do not represent the Palaeo-Tethys Suture, but rather a closed Permian back-arc basin behind the Sukhothai island-arc system.
- • Permo-Triassic double subduction zones in the Nan Suture suggested by Bunopas [10] are highly unlikely, and the so-called Loei-Petchabun magmatic arc is unsubstantiated.
- • The Nan Suture is unlikely to correlate with the Ailaoshan Suture.
- • The Jinghong–Nan–Sra Kaeo back-arc Basin closed at about the end of the Permian.
- • The Palaeo-Tethys Ocean closed as Sibumasu collided with the continental Sukhothai Arc of Indochina in the late Middle Triassic–early Late Triassic (post-Anisian).
Are the end-Permian and mid-Triassic suturing events described in this paper (Fig. 5) related to the so-called Indosinian orogeny? Two peaks of folding episodes recognised in Indochina by Fontaine and Workman [33] have often been linked with the Indosinian orogeny, that is, Indosinian I (latest Permian–Early Triassic) and Indosinian II (Late Triassic). Helmcke and Lindenberg [36] then recognised two correlatable tectonic phases in central and northern Thailand, that is, Middle–Late Permian deformation in the Phetchabun Foldbelt and Late Triassic deformation in the Sukhothai Foldbelt. These two phases can be more or less correlated with the two suturing events recognised in this study. It is here proposed that the Late Permian deformation in the Phetchabun Foldbelt is related to the closure of the Jinghong–Nan–Sra Kaeo back-arc Basin and that the Late Triassic deformation in the Sukhothai Arc/Foldbelt is due to the collision of Sibumasu.
Further to the east, Early–early Middle Triassic thermotectonism (ca. 250–240 Ma) of the Truong Son Belt and the Kontum Massif in Vietnam was recently advocated by several authors [13,44,50,59] to correspond with the Indosinian orogeny. Some [44,50] interpreted this to be related with the South China–Indochina collision, and it seems plausible. Carter et al. [13], on the other hand, proposed that it was affected by collision of Sibumasu–Indochina. However, the present study indicates that the Sibumasu collision with Indochina must have been younger than the Vietnamese event (Fig. 5). Instead, the end-Permian collapse of the Jinghong–Nan–Sra Kaeo back-arc Basin appears temporally closer. It is still an open question as to whether the Indosinian orogeny was a result of a single or multiple collisional episodes, but we favour the latter.
Acknowledgements
H. Fontaine, P. Chaodumrong, S. Salyapongse, C. Chonglakmani, K. Malila, Q. Feng, K. Ueno, and T. Kurihara are thanked for providing valuable information and having rewarding discussion. Constructive reviews from C. Lepvrier and an anonymous referee have improved the manuscript. The bulk of the work presented here was undertaken whilst Sone was a PhD candidate at the University of New England.