XUYueYANG YaomingYU HongjunGAO WeiGAO XiangxingLIU BaohuaTIAN XuYANG Jichaoand ZHANG Wenquan

Geochemistry and Petrogenesis of Volcanic Rocks from the Continent-Ocean Transition Zone in Northern South China Sea and Their Tectonic Implications

XUYue1),2),3), YANG Yaoming2), YU Hongjun1),2),*, GAO Wei2), GAO Xiangxing2), LIU Baohua1),2), TIAN Xu2), YANG Jichao2), and ZHANG Wenquan2)

1),,266061,2),,266237,3),,266100,

Miocene–Pliocene (22–5Myr) volcanism and associated seamounts are abundant in the continent-ocean transition (COT) zone in the margin of the north South China Sea (SCS). The petrogenesis of volcanic rocks from these seamounts and regional tectonic evolution of COT zone are poorly known. In this paper, we obtained whole-rock major and trace element compositions and Sr-Nd-Pb isotopic data for these volcanic rocks from the Puyuan and Beipo seamounts within COT zone, in northeastern SCS. Based on the geochemical analyses, the volcanic rocks are classified as alkaline ocean island basalts (OIB) and enriched mid-ocean ridge basalts (E-MORB). The OIBs from the Puyuan seamount are alkaline trachybasalts and tephrites that show enrichment of the light rare earth elements (LREE) relative to heavy rare earth elements (HREE) and more radiogenic Sr-Nd isotopic compositions, and have significant ‘Dupal isotopic anomaly’. In contrast, the E-MORBs from the Beipo seamount are tholeiitic basalts that have less enrichment in LREE and less radiogenic Sr-Nd isotopic compositions than the counterparts from the Puyuan seamount. Petrological and geochemical differences between the OIBs and MORBs from these two seamounts can be explained by different mantle sources and tectonic evolution stages of the COT zone. Syn-spreading OIB type basalts from the Puyuan seamount were derived from an isotopically ‘enriched’, and garnet facies-dominated pyroxenitic mantle transferred by the Hainan mantle plume. In contrast, post-spreading E-MORB type basalts from the Beipo seamount are considered to be derived from the melting of isotopically ‘depleted’ pyroxenite mantle triggered by lithosphere bending and subsequent post-rifting at the lower continental slope of the northern margin.

volcanic rocks; geochemistry; tectonic evolution; South China Sea; continent-ocean transition zone

1 Introduction

The continent-ocean transition (COT) zone of the passive margin in the north South China Sea (SCS) is a significant transition region between continental and oceanic crust, and the rocks occurred records the SCS extension and subsequent rifting process (Lester., 2014; Eagles., 2015; Sibuet., 2016; Zhao., 2018). The spreading and rifting in COT has been accompanied with a series of magmatic activities and associated seamounts that were identified in seismic profiles (Briais., 1993; Lüdmann and Wong, 1999; Zhu., 2012). Most previous studies focused on volcanic rocks from subbasin seamounts and Hainan-Leizhou-Indochina area, and these rocks have been used to investigate the composition of the mantle sources and the geodynamic processes in SCS sub-basin and adjacent areas (., Hoang and Flower, 1998; Zou and Fan, 2010; Wang., 2012b, 2013; Hoang., 2013; Yan., 2014, 2015; Zhang., 2017, 2018). However, little has been reported that deals mainly with volcanic seamounts in the COT zone, as it is difficult to collect samples from these seamounts. Questions concerning the nature of the mantle source and the tectonic evolution in the COT zone are unresolved (Zhu., 2012; Wu., 2014; Gao., 2015, 2016). Answers may be found in the geochemistry of volcanic rocks from the seamounts within the COT zone.

In this study, we present new whole-rock elemental and Sr-Nd-Pb isotopic compositions of volcanic rocks from Puyuan and Beipo seamounts that were acquired by two dives of the submersible Jiaolong within COT zone. We compare the geochemical characteristics between syn-sprea- ding OIB type basalts from Puyuan seamount and post- spreading E-MORB type basalts from Beipo seamount, and draw conclusions on the petrogenesis of the two type volcanic rocks and their mantle sources at different evolutional stages, and propose a model in which different tectonic evolution scenario are responsible for the hete- rogeneity.

2 Geological Background and Sample Description

2.1 Geological Background

The SCS is a Cenozoic marginal sea and formed by the interactions among the Eurasia plate, the Indian plate, the Australian plate and the Pacific plate (Sun., 2006; Xia., 2006). Based on bathymetry and magnetic data, the seafloor spreading of SCS basin occurred from 33 to 15Myr in a roughly NS direction (Taylor and Hayes, 1980, 1983; Briais., 1993; Li., 2014). The seafloor spreading in the east sub-basin initiated at about 33Myr and terminated at about 15Myr, whereas the spreading of southwest sub-basin started at about 23.6Myr and terminated at about 16Myr (Li., 2014).

A hypothesized young plume, termed as ‘Hainan mantle plume’, located near Hainan Island-Leizhou Peninsula was observed by seismic tomography (., Lebedev and Nolet, 2003; Huang and Zhao, 2006; Zhao, 2007; Lei., 2009). The plume-like mantle is further confirmed by extensive Miocene–Pliocene OIB-type basalts, including continental flood basalts (17–1Myr) in the Hainan-Lei- zhou-Indochina area and fossil ridge basalts (15.7–3.5Myr) in the eastern and southwestern sub-basin of SCS (Fig.1;., Tu., 1991; Hoang and Flower, 1998; Zou and Fan, 2010; Wang., 2012b, 2013; Yan., 2015; Zhang, 2018).

The COT zone in the margin of the north SCS is a region of transition between oceanic crust and continental crust with normal thickness during SCS spreading (Mjelde., 2007; Minshull, 2009; Franke., 2011).The initial opening of the northern continental slope may have started at around 37Myr, earlier than the sub-basin (Hsu., 2004).

The Puyuan seamount (22–21Myr) marked an episode of sys-spreading intra-plate volcanism in the northeastern COT zone (Fig.1; Wang., 2012a). After spreading cessation (<15Myr), continental thinning of COT zone has been accommodated by a series of rises (., Dongsha Rise) and depressions (McIntosh., 2013; Wu., 2014). Based on seismic data, several late Miocene–Plio- cene volcanic centers in the Dongsha Rise and adjacent depressions, including the Beipo seamount, have been iden- tified within the COT zone (Fig.1; Lüdmann and Wong, 1999; Zhu, 2012). Recent wide-angle tomographic velocity models have shown that continental crust in the COT zone has subducted at the Manila Trench underneath the Philippine plate after the late Miocene (McIntosh., 2013).

2.2 Sample Description

Two dives (Dives 139 and 141) have been performed in the COT zone of the northeastern SCS margin by submersible,Dayang 38th-IIcruise during May 5–8, 2017. Dive 139 was carried out ac- ross the Puyuan seamount, and Dive 141 was performed on the Beipo seamount.

Six fresh rock samples (Dive 139) were collected from Puyuan seamount, including trachybasalts and tephrites (Figs.2a–c). Trachybasalts are porphyritic with pheno- crysts dominated by plagioclase and clinopyroxene in a groundmass of plagioclase-sanidine-Fe-Ti oxide (Figs.2e and f; Table 1). Tephrites contain phenocrysts of clinopyroxene, sanidine and plagioclase. Samples are fresh to moderately altered with carbonate infillings (Fig.2g).

Two basalts (Dive 141) from Beipo seamount contain phenocrysts of clinopyroxene, sanidine, plagioclase, and minor orthopyroxene (Figs.2d and h; Table 1). Minerals in the hyalopilitic groundmass are mainly composed of microlitic clinopyroxene, sanidine, and plagioclase.

Fig.2 Hand specimens and photomicrographs of volcanic rocks from Puyuan (a–c, e–g) and Beipo (d, h) seamounts. Cpx, clinopyroxene; Opx, orthopyroxene; Pl, plagioclase; Sa, sanidine.

Table 1 Phenocryst and groundmass mineralogy of the basalts from the Puyuan and Beipo seamounts

Notes: Opx, orthopyroxene; Cpx, clinopyroxene; Sa, sanidine; Pl, plagioclase. Volume proportions in percent of pheno- crysts shown in parentheses (%).

3 Analytical Methods

3.1 Whole-Rock Major- and Trace-Element Analyses

Rock samples were cut into thin slabs and the freshest portions were used for bulk-rock analyses. Major elemental compositions were determined by an X-ray fluorescence spectrometer (PANalytical Axios-advance) at the ALS Labo-ratory Group, Guangzhou. 1g sample powder was heated up to 1100℃ for 1h to calculate loss on ignition (LOI). Analytical precision was generally better than 5%, as determined based on the Chinese National standard GSR-3.

Trace elements were measured by using a PE DRC-e ICPMS at the state Key Laboratory of Ore Deposit Geochemistry, Institute of Geochemistry, Chinese Academy of Sciences. Rock powder (50mg) was dissolved in PTFE lined stainless steel bombs using a mixture of HF and HNO3for 48h at 190℃. As an internal standard, Rh was used to monitor signal drift during counting. The international standards JG-2, SG-3, GSR-1, G-2, NIM-G, and SG-1a were used for monitoring analytical quality. The analytical uncertainty is lower than 5%. The detailed ana- lytical methods were described by Qi. (2000).

3.2 Whole-Rock Sr-Nd-Pb Isotope Analyses

The Sr-Nd-Pb isotopic compositions were analyzed by using on a Finnigan Neptune plus MC-ICP-MS at Institute of Oceanology, Chinese Academy of Sciences. Whole- rock powders were dissolved in Teflon bombs using HF+HNO3. Sr and Nd were separated in solution by using cationic ion-exchange procedures (Richard., 1976; Zhang, 2002; Fan.,2003). Sr and Nd isotopic ratios were normalized to86Sr/88Sr of 0.1194 and146Nd/144Nd of 0.72419. Standard Reference material NBS987 for Sr yielded average87Sr/86Sr=0.710216±0.000012 (2σ,=10) and Standard Reference material Jndi-1 ESA Delf for Nd yielded143Nd/144Nd=0.512118±0.000006 (2σ,=10).

Lead was separated and purified using conventional anion-exchange techniques with dilute HBr as eluent (Zhang., 2002). The whole procedural blank was less than 0.4ng Pb. During the analyses, the international standard material NBS981 yielded a weighted mean206Pb/204Pb of 16.935±0.0004 (2σ,=8) (the recommended value is 16.9356), a207Pb/204Pb of 15.486±0.0004 (2σ,=8) (the recommended value is 15.4891), and a208Pb/204Pb of 36.691±0.010 (2σ,=8) (the recommended value is 36.7006) (Todt., 1996).

4 Results

4.1 Major and Trace Elements

Major and trace elemental composition results of Puyuan and Beipo basalts are presented in Table 2. The Puyuan volcanic rocks vary from tephrite to trachybasalt (SiO2=(41.94–44.96)wt%; K2O=(1.15–1.34)wt%; Na2O=(2.88–3.00)wt%) with Mg-numbers (Mg#) ranging from 38 to 47 [Mg#=molar Mg×100/(Mg+Fe2+)] and high TFe2O3contents ((11.36–12.40)wt%) (Table 2). They have high K2O, Na2O contents and Nb/Y ratios, and belong to alkaline series (Fig.3). The tephrites have higher CaO con- tents than that of trachybasalts. In terms of trace elements, they show enrichment in the LREE and LILE relative to HREE and HFSE with steep chondrite-nor- malized REE patterns [(La/Yb)N=6.75–16.27, (La/Sm)N=3.31–5.26, (Er/Yb)N=1.16–1.51] and absence of Eu negative anomalies (Eu/Eu*=0.89–1.06), which exhibit OIB affinity (Fig.4; Table 2).

Table 2 Major (wt%) and trace elemental (×10−6) concentrations of basalts from Puyuan and Beipo seamounts

Fig.3 Geochemical classification of volcanic rocks from Puyuan (a–c) and Beipo (d) seamounts. (a) TAS diagram (Le Maitre et al., 1989); the dashed line separating alkaline series from subalkaline series is from Irvine and Baragar (1971); all the major element values are normalized to 100% on a volatile-free basis. (b) Nb/Y vs. Zr/(P2O5´104) (Floyd and Winchester, 1975).

Fig.4 (a) Primitive mantle normalized multi-element and (b) chondrite-normalized rare earth element (REE) pattern diagrams for volcanic rocks from Puyuan and Beipo seamounts. Chondrite and primitive mantle normalizing values, ocean island basalt (OIB), enriched mid-ocean ridge basalt (E-MORB) and normal mid-ocean ridge basalt (N-MORB) are from Sun and McDonough (1989).

The basalts from Beipo seamount have high SiO2((49.32–49.41)wt%) and Na2O ((3.12–3.15)wt%) but low K2O ((0.78–0.81)wt%) contents, and plot in the tholeiitic basalt field on the Zr/(P2O5×104)-Nb/Y diagram (Fig.3b). Compared with the alkaline ones from Puyuan seamount, they have similar MgO ((4.10–4.14)wt%) but lower CaO ((9.75–9.81)wt%) and TFe2O3((10.79–10.84)wt%) contents. They exhibit LREE enrichments with rela- tively flat REE patterns [(La/Yb)N=2.37–3.15, (La/Sm)N=1.46–1.69, (Er/Yb)N=1.03–1.31], and are similar to the averaged E-MORB defined by Sun and McDonough (1989) (Fig.4; Table 1).

4.2 Sr-Nd-Pb Isotopes

Sr, Nd, and Pb isotopic compositions are presented in Table 3, and plotted in Fig.5. The Puyuan alkaline basalts have87Sr/86Sr ratios of 0.704360–0.705146 and εNdof 2.0–5.3 (Fig.5a). They have narrow ranges of206Pb/204Pb (18.6463–18.6822),207Pb/204Pb (15.6408–15.6560), and208Pb/204Pb (38.8670–38.9150), plotting well in the field of ‘Dupal isotopic anomaly’ (Fig.5b). The Beipo tholei- itic basalts show almost the same Pb isotopic compositions (206Pb/204Pb=18.6345,207Pb/204Pb=15.6579, and208Pb/204Pb=38.8917) as those of the Puyuan basalts. However, they have lower87Sr/86Sr ratios of 0.703680 and higher εNdof 6.6 than those of Puyuan basalts (Fig.5).

5 Discussion

5.1 Petrogenesis of Volcanic Rocks from Puyuan Seamount and Beipo Seamount

In view of high loss on ignition (LOI) of some samples(Table 2), secondary seawater alteration has to be considered. CaO and LILEs (., K, Sr, Ba, Cs and Rb) are generally mobile and tend to display decreasing trends with increasing LOI contents in seawater altered rocks (Smith and Smith, 1976; Bédard, 1999; Wang., 2006). However, none of these trends have been observed for the studied basaltic samples (Fig.6). Thus, the effect of secondary seawater alteration appears to be negligible in the study of petrogenesis for the basalts from the Puyuan and Beipo seamounts in this paper.

Table 3 Sr-Nd-Pb isotopic data for the basalts from Puyuan and Beipo seamounts

Notes: TP, tephrite; TB, trachybasalt; B, basalt.

Fig.5 (a) εNdvs.87Sr/86Sr; (b) 207Pb/204Pb vs.206Pb/204Pb; (c) 208Pb/204Pb vs.206Pb/204Pb; (d) 87Sr/86Sr vs.206Pb/204Pb. The NHRL (Northern Hemisphere Reference Line; Hart, 1984), enriched mantle I (EMI; Zindler and Hart, 1986), enriched mantle II (EMII; Hart et al., 1992) and Dupal Pb anomaly (Hamelin and Allègre, 1985) are shown for reference. The aubergine dot-dash lines are mixing curves between depleted mantle (DM; Workman and Hart, 2005; 87Sr/86Sr=0.7026, Sr=7.66×10−6, εNd=9.3, and Nd=0.58×10−6) and enriched mantle II (EMII; Hart et al., 1992; 87Sr/86Sr=0.7078, εNd=−1); numbers beside the mixing curves indicate the weight fraction of EMII end member in the mixture. Isotope data for the East Pacific Rise (EPR) and the Indian Ocean MORBs (Gale et al., 2013), Hainan OIBs (Han et al., 2009; Zou and Fan, 2010; Li et al., 2013), Indochina OIBs (Hoang et al., 1996, 2013), SCS fossil ridge seamount (Tu et al., 1992; Yan et al., 2008; Expedition 349 Scientists, 2014) were plotted for comparison.

We assess the effect of crustal contamination during the generation of these basalts. Generally, their low SiO2and high MgO contents may reflect their mantle origin and limited degree of crustal contamination (Yan., 2015; Tian., 2019). Furthermore, large crustal contamination can be ruled out based on the following observations:

1) all these rocks have relatively uniform Ni and Cr contents (Table 2); 2) their206Pb/204Pb ratios show restricted range (Fig.5d), as crustal contamination tend to result in a large variation in206Pb/204Pb (Jiang., 2006); 3) there are no crust-derived xenocrysts in these rocks (Fig.2). Therefore, their geochemical compositions could be used to reflect the nature of mantle source region.

5.1.1 OIB type basalts from Puyuan seamount

Direct partial melting of the mantle can yield melts less silicic than andesitic compositions with <57wt% SiO2(Lloyd., 1985; Baker., 1995). Alkaline basalts from Puyuan seamount have low SiO2((41.97–44.96)wt%),high contents of MgO ((3.37–5.16)wt%), Cr ((56–204)× 10−6), and Ni ((85–165)×10−6; Table 2), suggesting they might be derived from partial melting of mantle (Frey., 1978; Herzberg and Asimow, 2008). Some basalt samples with low MgO might have experienced fractionation of plagioclase, olivine and pyroxene. However, the fractional crystallization of plagioclase should be negligible because of no Eu negative anomaly (Eu/Eu*=0.89–1.06). The chondrite-normalized REE patterns of all alkaline samples exhibit pronounced enrichment in LREE relative to HREE, which are in good accordance with those of OIBs (Fig.4b; Sun and McDonough, 1989). Their OIB affinity is further suggested by enrichment in radiogenic Sr-Nd- Pb isotopes and their ‘Dupal isotopic anomaly’ feature, roughly consistent with those of plume-related OIB-like basalts in the Indochina peninsula (Fig.5; Hoang., 1996, 2013; Wang., 2012b, 2013). In Fig.5a, the Sr-Nd isotopic compositions of Puyuan basalts define a binary mixing trend between the proposed depleted mantle (DM) and enriched mantle II (EMII) end members. In detail, they originate from the DM mixing with 10%–20% of EMII.

Fig.6 Plots of incompatible elements (K2O, CaO, Rb, Sr, Cs and Ba) vs. LOI contents.

FC3MS value (FeO/CaO−3*MgO/SiO2, all inwt%) can be used to determine whether basalts are pyroxenite-de- rived melts or peridotite-derived melts even if fractionation process of basaltic magmas is taken into account (Yang and Zhou, 2013). Generally, the FC3MS values of experimental peridotite-derived melts are −0.07±0.51 (2δ,=656), and the FC3MS values of experimental pyroxe- nite-derived melts are 0.46±0.96 (2δ,=494), respectively.The FC3MS values of Puyuan basalts are 0.56–0.71,which is consistent with those of pyroxenite-derived melts rather than peridotite-derived melts (Fig.7a).

Fig.7 (a–b) Plots of FC3MS vs. TiO2 and La/Yb ratio. Results of experiments (2δ) and batch melting models (blue and green curves) on pyroxenite and peridotite are based on Yang and Zhou (2013). (c) Plots of a La/Sm vs. Sm/Yb. The pyroxenite with a depleted MORB chemical composition (La of 1.5×10−6, Sm of 2.5×10−6, and Yb of 4×10−6) modeled with varying melting degrees (F) and mineral compositions (Cpx, clinopyroxene; Opx, orthopyroxene; Gt, garnet) are calculated by Zhang et al. (2018).

Furthermore, the batch melting model based on the FC3MS values and La/Yb ratios suggests that the Puyuan basaltic magmas could be generated by partial melting of average pyroxenite (Fig.7b). Additionally, low HREE con- tents (., Er, Tm, Yb, Lu Y), steep chondrite-normalized REE patterns ([La/Yb]N=6.75–16.27; Table 2) and high Er/Yb ratios (>1; Table 2) suggest the origin of the Puyuan magmas is within the garnet stability field. In detail, garnet has higher partition coefficients for the element Yb (3.9) and Er (2.8) (http://www.earthref.org) and its fractionation from the parent magma would be expected to yield Er/Yb ratios of >1 in the residual magma phase, thus either garnet fractionation process or partial melting of mantle with garnet in the residual would produce fractionated HREE (., Er/Yb>1) in the basaltic liquid phase. Based on the La/Sm and Sm/Yb ratios, quantitative modeling results suggest that the Puyuan basalts can be formed by low degree melting (<1%) of the garnet-bearing pyroxenite (Fig.7c).

5.1.2 E-MORB type basalt from Beipo seamount

Tholeiitic basalts from Beipo seamount have E-MORB- like trace elemental characteristics (Fig.4). Absence of Eu negative anomaly (Eu/Eu*=1.05–1.11) rule out the possibility of plagioclase fractional crystallization. We compare the isotopic compositions of the Beipo basalts with the plume-related basalts (Tu., 1992; Hoang, 1996, 2013; Yan., 2008; Han., 2009; Zou and Fan, 2010; Li., 2013; Expedition 349 Scientists, 2014), and find that the Hainan-Indochina-fossil ridge basalts that were derived from the Hainan mantle plume overlap with the counterparts from the Beipo seamount in Sr-Pb isotopic compositions. However, the Beipo basalts have higher εNdvalues than those of plume-related basalts, suggesting a more ‘depleted’ mantle origin than plume-like mantle. This is consistent with the less contribution of EMII (< 10%) in mantle source, which is inferred from the Sr-Nd isotopic compositions of the Beipo tholeiitic basalts (Fig.5). Thus, the Hainan mantle plume might have a minor role in the generation of the Beipo basalts.

The FC3MS values of the Beipo tholeiitic basalts are 0.69, which fall in the range of pyroxenite melts (Fig.7a). In Fig.7b, the FC3MS values and La/Yb ratios of Beipo basalts are close to the batch melting curve of average py- roxenite rather than that of peridotite. In fact, the La/Sm and Sm/Yb ratios of the tholeiitic basalts from Beipo seamount can be yielded by 3%–10% melting of the pyroxenite without or with minor garnet (Fig.7c). These modeling results suggest that these E-MORB type basalts were probably formed by high degree melting of pyroxenite at shallow mantle depths (Zhang, 2018).

5.2 A Tectonic Evolution Scenario for Puyuan and Beipo Seamount Volcanism

Different types of basalts may originate by different tec- tonic processes at different times. The Puyuan seamount in the northeastern SCS is probably related to the Hainan mantle plume, which is evidenced by the following works: 1) according to the whole-rock40Ar/39Ar ages (22–21Myr;Wang., 2012a), Puyuan seamount was formed during the syn-spreading period of the SCS that has been proposed to be triggered by the Hainan mantle plume (Yan and Shi, 2007; Yan., 2014; Zhang., 2018; Yang., 2019); 2) the OIB-like Puyuan basalts have similar geochemical compositions to the plume-related basalts in the Indochina peninsula (Hoang., 1996, 2013; Wang., 2012b, 2013); 3) the Sr-Nd isotopic compositions of Puyuan basalts have indicated the high contribution (10%–20%) of EMII that has been proposed as the main component of the Hainan mantle plume (Yan., 2008; Zou and Fan, 2010; Wang., 2012b). Furthermore, the Puyuan basalts originated from garnet-bearing pyroxenite source, probably reflecting an eclogite-rich plume that im- pacted on the SCS. The conclusion is consistent with the results evidenced by thermometric data from Hole U1431E of IODP Expedition 349 and 3D geodynamic modeling, which suggest that the Hainan mantle plume might contain recycled Indian and Pacific oceanic crust in the form of eclogite (Zhang and Li, 2018; Yang., 2019).

However, other mechanisms, rather than the Hainan mantle plume, might have important effect on the Beipo volcanic events, due to apparent transition of rock types from alkaline OIBs to tholeiitic E-MORBs and low EMII contribution in the Beipo mantle source (Figs.3, 4 and 5). TheBeipo seamount was inferred to be formed in the pe- riod of post-spreading (about 5.5Myr) based on the seismic section data from the Dongsha Rise and the adjacent depressions in the northeastern SCS (Fig.1; Wu., 2014; Gao., 2015, 2016). Previous studies have shown that post-rifting movement with extensive uplift occurred at the northeastern margin of SCS after the cessation of the seafloor spreading (Lüdmann and Wong, 1999; Lüdmann., 2001; Wu., 2014).The post-rifting me- chanism was inferred to be associated with subduction of the SCS slab beneath the Philippine Sea Plate at the Manila trench (McIntosh., 2013). In this model, large resistance stresses of the subducted crust with lower density may have led to lithosphere bending and post-rifting in the Dongsha and adjacent area (Wu., 2014). Mel- ting of the lithospheric mantle beneath the lower slope of the northern margin might generate the Beipo seamount that represents E-MORB type volcanic rocks. Based on geochemical data, they were formed by relatively high degree melting of pyroxenite at shallow mantle depths, without or with minor garnet in the mantle source. Additionally, the relatively ‘depleted’ Sr-Nd isotopic compositions suggest that the enriched Hainan mantle plume have less effect on the post-spreading volcanism in Beipo seamount than the syn-spreading volcanism in Puyuan seamount (Fig.5a).

Collectively, alkaline OIB type basalts from the Puyuan seamount reveal an syn-spreading, eclogite-bearing Hainan mantle plume, whereas tholeiitic E-MORB type basalts in the Beipo seamount were derived by decompression melting of pyroxenite mantle without or with mi- nor garnet, which was trigged by lithosphere bending and subsequent post-rifting at the lower slope of the northern margin.

6 Conclusions

Volcanic rocks from the Puyuan and Beipo seamounts within COT zone show different geochemical compositions, probably reflecting different petrogenesis and tectonic evolution stages from Miocene to Pliocene. Puyuan OIB-type volcanic rocks reveal an isotopically ‘enriched’, and garnet pyroxenite mantle transferred by the Hainan mantle plume, whereas E-MORB type rocks in the Beipo seamount were derived by decompression melting of isotopically ‘depleted’ pyroxenite mantle, which was trigged by lithosphere bending and post-rifting at the lower slope of the northern margin.

Acknowledgements

This study was jointly supported by the National Key R&D Program of China (No. 2018YFC0309802), the 13th Five- Year Plan Program of the China Ocean Mineral Resour- ces Research and Development Association Research (No. DY135-S2-2-08), the Soft Science Project of Shandong Province Key Research and Development Plan (No. 2019 RZA02002), the China Postdoctoral Science Foundation (No. 2017M610403), and the Taishan Scholar Project Funding (No. tspd20161007).

Bédard, J., 1999. Petrogenesis of boninites from the Betts Cove ophiolite, Newfoundland, Canada: Identification of subducted source components., 40 (12): 1853-1889.

Baker, M., Hirschmann, M., Ghiorso, M., and Stolper, E., 1995. Compositions of near-solidus peridotite melts from experimentsand thermodynamic calculations., 375 (6529): 308-311, DOI: 10.1038/375308a0.

Briais, A., Patriat, P., and Tapponnier, P., 1993. Updated interpretation of magnetic anomalies and seafloor spreading stages in the South China Sea: Implications for the Tertiary tectonics of Southeast Asia., 98 (B4): 6299-6328, DOI: 10.1029/92JB02280.

Eagles, G., Pérez-Díaz, L., and Scarselli, N., 2015. Getting over continent ocean boundaries., 151: 244- 265, DOI: 10.1016/j.earscirev.2015.10.009.

Expedition 349 Scientists, 2014. Opening of the South China Sea and its implications for Southeast Asian tectonics, climates, and deep mantle processes since the late Mesozoic. International Ocean Discovery Program Expedition 349 Preliminary Report. http://dx.doi.org/10.14379/iodp.pr.349.2014.

Fan, W. M., Guo, F., Wang, Y. J., and Lin, G., 2003. Late Mesozoic calc-alkaline volcanism of post-orogenic extension in the northern Da Hinggan Mountains, northeastern China., 121 (1): 115-135, DOI: 10.1016/S0377-0273(02)00415-8.

Floyd, P., and Winchester, J., 1975. Magma type and tectonic setting discrimination using immobile elements., 27 (2): 211-218, DOI: 10.1016/00 12-821X(75)90031-X.

Franke, D., Barckhausen, U., Baristeas, N., Engels, M., Ladage, S., Lutz, R., Montano, J., Pellejera, N., Ramos, E., and Schna- bel, M., 2011. The continent-ocean transition at the southeastern margin of the South China Sea., 28 (6): 1187-1204.

Frey, F., Green, D., and Roy, S., 1978. Integrated models of basalt petrogenesis: A study of quartz tholeiites to olivine melilitites from south eastern Australia utilizing geochemical and experimental petrological data., 19 (3): 463- 513, DOI: 10.1093/petrology/19.3.463.

Gale, A., Dalton, C. A., Langmuir, C. H., Sun, Y. J., and Schilling, J. G., 2013. The mean composition of ocean ridge basalts., 14 (3): 489-518, DOI: 10.1029/2012GC004334.

Gao, J., Wu, S., McIntosh, K., Mi, L., Liu, Z., and Spence, G., 2016. Crustal structure and extension mode in the northwestern margin of the South China Sea., 17 (6): 2143-2167.

Gao, J., Wu, S., McIntosh, K., Mi, L., Yao, B., Chen, Z., and Jia, L., 2015. The continent-ocean transition at the mid-northern margin of the South China Sea., 654: 1-19.

Hamelin, B., and Allègre, C. J., 1985. Large-scale regional units in the depleted upper mantle revealed by an isotope study of the South-West Indian Ridge., 315 (6016): 196-199, DOI: 10.1038/315196a0.

Han, J., Xiong, X., and Zhu, Z., 2009. Geochemistry of late- Cenozoic basalts from Leigiong area: The origin of EM2 and the contribution from sub-continental lithosphere mantle., 25 (12): 3208-3220, DOI: 10.1007/BF02 943552 (in Chinese with English abstract).

Hart, S. R., 1984. A large-scale isotope anomaly in the Southern Hemisphere mantle., 309: 753-757, DOI: 10.1038/30 9753a0.

Hart, S. R., Hauri, E., Oschmann, L., and Whitehead, J. A., 1992. Mantle plumes and entrainment: Isotopic evidence., 256 (5056): 517-520, DOI: 10.1126/science.256.5056.517.

Herzberg, C., and Asimow, P. D., 2008. Petrology of some oceanic island basalts: PRIMELT2.XLS software for primary mag- ma calculation., 9 (9): 269-283, DOI: 10.1029/2008GC002057.

Hoang, N., and Flower, M. F. J., 1998. Petrogenesis of Cenozoic basalts from Vietnam: Implication for origins of a ‘diffuse ig- neous province’., 39 (3): 369-395.

Hoang, N., Flower, M. F. J., and Carlson, R. W., 1996. Major, trace element, and isotopic compositions of Vietnamese basalts: Interaction of hydrous EM1-rich asthenosphere with thinned Eurasian lithosphere., 60 (22): 4329-4351, DOI: 10.1016/S0016-7037(96)00247-5.

Hoang, N., Flower, M. F. J., Chí, C. T., Xuân, P. T., Quý, H. V., and Sơn, T. T., 2013. Collision-induced basalt eruptions at Plei- ku and Buôn Mê Thuột, south-central Viet Nam., 69: 65-83, DOI: 10.1016/j.jog.2012.03.012.

Huang, J., and Zhao, D., 2006. High-resolution mantle tomogra- phy of China and surrounding regions., 111 (B9): B09305, DOI: 10.1029/200 5JB004066.

Hsu, S. K., Yeh, Y., Doo, W. B., and Tsai, C. H., 2004. New bathymetry and magnetic lineations identifications in the northernmost South China Sea and their tectonic implications., 25 (1-2): 29-44, DOI: 10.100 7/s11001-005-0731-7.

Irvine, T., and Baragar, W., 1971. A guide to the chemical classification of the common volcanic rocks., 8 (5): 523-548, DOI: 10.1139/e71-055.

Jiang, Y. H., Jiang, S. Y., Ling, H. F., and Dai, B. Z., 2006. Low- degree melting of a metasomatized lithospheric mantle for the origin of Cenozoic Yulong monzogranite-porphyry, East Tibet: Geochemical and Sr-Nd-Pb-Hf isotopic constraints., 241 (3): 617-633.

Lebedev, S., and Nolet, G., 2003. Upper mantle beneath Southeast Asia from S velocity tomography., 108 (B1): 2048, DOI: 10.1029/ 2000JB000073.

Lei, J., Zhao, D., Steinberger, B., Wu, B., Shen, F., and Li, Z., 2009. New seismic constraints on the upper mantle structure of the Hainan plume., 173 (1-2): 33-50, DOI: 10.1016/j.pepi.2008.10.013.

Le Maitre, R. W., Bateman, P., Dudek, A., Keller, J., Lameyre, J., Le Bas, M. J., Sabine, P. A., Schmid, R., Sorensen, H., Stre- ckeisen, A., Woolley, A. R., and Zanettin, B., 1989.. Blackwell Scientific, Oxford, 1-193.

Lester, R., van Avendonk, H. J., McIntosh, K., Lavier, L., Liu, C. S., Wang, T., and Wu, F., 2014. Rifting and magmatism in the northeastern South China Sea from wide-angle tomography and seismic reflection imaging., 119 (3): 2305-2323.

Li, C. F., Xu, X., Lin, J., Sun, Z., Zhu, J., Yao, Y., Zhao, X., Liu, Q., Kulhanek, D. K., and Wang, J., 2014. Ages and magnetic structures of the South China Sea constrained by deep tow magnetic surveys and IODP Expedition 349., 15 (12): 4958-4983, DOI: 10.1002/ 2014GC005567.

Li, N., Yan, Q., Chen, Z., and Shi, X., 2013. Geochemistry and petrogenesis of Quaternary volcanism from the islets in the eastern Beibu Gulf: Evidence for Hainan plume., 32 (12): 40-49.

Lloyd, F., Arima, M., and Edgar, A., 1985. Partial melting of a phlogopite-clinopyroxenite nodule from South-west Uganda: An experimental study bearing on the origin of highly potassic continental rift volcanics., 91 (4): 321-329.

Lüdmann, T., and Wong, H. K., 1999. Neotectonic regime on the passive continental margin of the northern South China Sea., 311 (1-4): 113-138.

Lüdmann, T., Wong, H. K., and Wang, P., 2001. Plio–Quater- nary sedimentation processes and neotectonics of the northern continental margin of the South China Sea., 172 (3-4): 331-358, DOI: 10.1016/S0025-3227(00)00129-8.

McIntosh, K., van Avendonk, H., Lavier, L., Lester, W. R., Eakin, D., Wu, F., Liu, C. S., and Lee, C. S., 2013. Inversion of a hyper-extended rifted margin in the southern central range of Taiwan., 41 (8): 871-874, DOI: 10.1130/G34402.1.

Minshull, T. A., 2009. Geophysical characterisation of the ocean- continent transition at magma-poor rifted margins., 341 (5): 382-393.

Mjelde, R., Raum, T., Murai, Y., and Takanami, T., 2007. Continent-ocean-transitions: Review, and a new tectono-magmatic model of the Vøring Plateau, NE Atlantic., 43 (3): 374-392, DOI: 10.1016/j.jog.2006.09.013.

Qi, L., Jing, H., and Gregoire, D. C., 2000. Determination of trace elements in granites by inductively coupled plasma massspectrometry., 51 (3): 507-513, DOI: 10.1016/S0039- 9140(99)00318-5.

Richard, P., Shimizu, N., and Allegre, C., 1976.143Nd/146Nd, a natural tracer: An application to oceanic basalts., 31 (2): 269-278.

Sibuet, J. C., Yeh, Y. C., and Lee, C. S., 2016. Geodynamics of the South China Sea., 692: 98-119.

Smith, R. E., and Smith, S. E., 1976. Comments on the use of Ti, Zr, Y, Sr, K, P and Nb in classification of basaltic magmas., 32 (2): 114-120.

Sun, S. S., and McDonough, W. F., 1989. Chemical and isotopic systematics of oceanic basalts: Implications for mantle composition and processes., 42 (1): 313-345.

Sun, Z., Zhou, D., Zhong, Z., Xia, B., Qiu, X., Zeng, Z., and Jiang, J., 2006. Research on the dynamics of the South China Sea opening: Evidence from analogue modeling., 49 (10): 1053-1069.

Taylor, B., and Hayes, D. E., 1980. The tectonic evolution of the South China Basin., 23: 89-104.

Taylor, B., and Hayes, D. E., 1983. Origin and history of the South China Sea Basin., Part 2: 23-56.

Tian, Z. X., Yan, Y., Huang, C. Y., Zhang, X. C., Liu, H. Q., Yu, M. M., Yao, D., and Dilek, Y., 2019. Geochemistry and geochronology of the accreted mafic rocks from the Hengchun Peninsula, southern Taiwan: Origin and tectonic implications., 124 (3): 2469- 2491, DOI: 10.1029/2018JB016562.

Todt, W., Cliff, R., Hanser, A., and Hofmann, A., 1996. Evaluation of a202Pb-205Pb double spike for high-precision lead isotope analysis., 95: 429-437.

Tu, K., Flower, M. F. J., Carlson, R. W., Xie, G., Chen, C. Y., andZhang, M., 1992. Magmatism in the South China Basin: 1. Iso- topic and trace-element evidence for an endogenous Dupal mantle component., 97 (1-2): 47-63.

Tu, K., Flower, M. F. J., Carlson, R. W., Zhang, M., and Xie, G., 1991. Sr, Nd, and Pb isotopic compositions of Hainan basalts (South China): Implications for a subcontinental lithosphere Dupal source., 19 (6): 567-569.

Wang, K. L., Lo, Y. M., Chung, S. L., Lo, C. H., Hsu, S. K., Yang, H. J., and Shinjo, R., 2012a. Age and geochemical features of dredged basalts from offshore SW Taiwan: The coincidence of intra-plate magmatism with the spreading South China Sea., 23 (6): 657-669, DOI: 10.3319/TAO.2012.07.06.01(TT).

Wang, Q., Wyman, D. A., Xu, J. F., Zhao, Z. H., Jian, P., Xiong, X. L., Bao, Z. W., Li, C. F., and Bai, Z. H., 2006. Petrogenesis of Cretaceous adakitic and shoshonitic igneous rocks in the Luzong Area, Anhui Province (eastern China): Implications for geodynamics and Cu-Au mineralization., 89 (3): 424-446, DOI: 10.1016/j.lithos.2005.12.010.

Wang, X. C., Li, Z. X., Li, X. H., Li, J., Liu, Y., Long, W. G., Zhou, J. B., and Wang, F., 2012b. Temperature, pressure, and composition of the mantle source region of late Cenozoic basalts in Hainan Island, SE Asia: A consequence of a young thermal mantle plume close to subduction zones?, 53 (1): 177-233, DOI: 10.1093/petrology/egr061.

Wang, X. C., Li, Z. X., Li, X. H., Li, J., Xu, Y. G., and Li, X. H., 2013. Identification of an ancient mantle reservoir and young recycled materials in the source region of a young mantle plume: Implications for potential linkages between plume and plate tectonics., 377: 248- 259, DOI: 10.1016/j.epsl.2013.07.003.

Workman, R. K., and Hart, S. R., 2005. Major and trace element composition of the depleted MORB mantle (DMM)., 231 (1-2): 53-72, DOI: 10. 1016/j.epsl.2004.12.005.

Wu, S., Gao, J., Zhao, S., Lüdmann, T., Chen, D., and Spence, G., 2014. Post-rift uplift and focused fluid flow in the passive margin of northern South China Sea., 615: 27-39, DOI: 10.1016/j.tecto.2013.12.013.

Xia, B., Zhang, Y., Cui, X., Liu, B., Xie, J., Zhang, S., and Lin, G., 2006. Understanding of the geological and geodynamic controls on the formation of the South China Sea: A numerical modelling approach., 42 (1-3): 63-84, DOI: 10.1016/j.jog.2006.06.001.

Yan, Q., and Shi, X., 2007. Hainan mantle plume and the formation and evolution of the South China Sea., 13 (2): 311-322 (in Chinese with English abstract).

Yan, Q., Shi, X., and Castillo, P. R., 2014. The late Mesozoic–Cenozoic tectonic evolution of the South China Sea: A petrologic perspective., 85 (2): 178-201, DOI: 10.1016/j.jseaes.2014.02.005.

Yan, Q., Castillo, P., Shi, X., Wang, L., Liao, L., and Ren, J., 2015. Geochemistry and petrogenesis of volcanic rocks from Daimao seamount (South China Sea) and their tectonic implications., 218: 117-126.

Yan, Q., Shi, X., Wang, K., Bu, W., and Xiao, L., 2008. Major element, trace element, and Sr, Nd and Pb isotope studies of Cenozoic basalts from the South China Sea., 51 (4): 550-566.

Yang, F., Huang, X. L., Xu, Y. G., and He, P. L., 2019. Plume- ridge interaction in the South China Sea: Thermometric evidence from Hole U1431E of IODP Expedition 349., 324-325: 466-478, DOI: 10.1016/j.lithos.2018.11.031.

Yang, Z. F., and Zhou, J. H., 2013. Can we identify source litho- logy of basalt?, 3: 1856, DOI: 10.1038/srep 01856.

Zindler, A., and Hart, S., 1986. Chemical geodynamics., 14: 493-571, DOI: 10.1016/0040-1951(82)90125-1.

Zhang, G. L., Chen, L. H., Jackson, M. G., and Hofmann, A. W., 2017. Evolution of carbonated melt to alkali basalt in the South China Sea., 10 (3): 229-235.

Zhang, G. L., Sun, W. D., and Seward, G., 2018. Mantle source and magmatic evolution of the dying spreading ridge in the South China Sea., 19 (11): 4385-4399, DOI: 10.1029/2018GC007570.

Zhang, H. F., Sun, M., Zhou, X. H., Fan, W. M., Zhai, M. G., and Yin, J. F., 2002. Mesozoic lithosphere destruction beneath the North China Craton: Evidence from major-, trace-element and Sr-Nd-Pb isotope studies of Fangcheng basalts., 144 (2): 241-254.

Zhang, N., and Li, Z. X., 2018. Formation of mantle ‘lone plu- mes’ in the global downwelling zone–A multiscale modelling of subduction-controlled plume generation beneath the South China Sea., 723: 1-13.

Zhao, D., 2007. Seismic images under 60 hotspots: Search for mantle plumes., 12 (4): 335-355.

Zhao, M., He, E., Sibuet, J. C., Sun, L., Qiu, X., Tan, P., and Wang, J., 2018. Postseafloor spreading volcanism in the central east South China Sea and its formation through an extremely thin oceanic crust., 19 (3): 621-641, DOI: 10.1002/2017GC007034.

Zhu, J., Qiu, X., Kopp, H., Xu, H., Sun, Z., Ruan, A., Sun, J., and Wei, X., 2012. Shallow anatomy of a continent-ocean transition zone in the northern South China Sea from multichannel seismic data., 554: 18-29.

Zou, H., and Fan, Q., 2010. U-Th isotopes in Hainan basalts: Im- plications for sub-asthenospheric origin of EM2 mantle endmember and the dynamics of melting beneath Hainan Island., 116 (1-2): 145-152, DOI: 10.1016/j.lithos.2010.01.010.

. Tel: 0086-532-67726668

E-mail: hjyu@ndsc.org.cn

May 9, 2019;

November 21, 2019;

January 13, 2020

(Edited by Chen Wenwen)