Xiaoyan Hu·Xianwu Bi·Ruizhong Hu·Guosheng Cai·Youwei Chen



Tin partition behavior and implications for the Furong tin ore formation associated with peralkaline intrusive granite in Hunan Province，China

Xiaoyan Hu1·Xianwu Bi1·Ruizhong Hu1·Guosheng Cai2·Youwei Chen1

Tin deposits are often closely associated with granitic intrusions.In this study，we analyzed tin partition coefficients between different fluids and meltsas well as various crystals and meltsfrom the Furong tin deposit associated with the Qitianling A-type granite.Our experimental results indicate that tin partition behavior is affected by the chemical compositions of fluids，melts，and minerals.Tin is prone to partitioning into the residual magma in fractional crystallization or other differential magmatic processes if the magma originated from crustal sources with high alkali content，high volatile content，and low oxygen fugacity.Highly evolved residual peralkaline granitic magma enriched in tin can lead to tin mineralization in a later stage.Furthermore，the volatiles F and Cl in the magma play important roles in tin partitioning behavior.Low F contents in the melt phase and high Cl content in the aqueous fluid phase are favorable factors for tin partitioning in the aqueous fluid phase.High Cl content in the aqueous fluid catalyzes water-rock interaction and leads to the extraction of tin from tinbearing minerals.All these findings support a hydrothermal origin for the tin deposits.In light of the geotectonic setting，petrochemicalcharacteristics，andmineralizing physicochemical conditions of the Furong tin deposit，it is inferred that the ore-forming fluid of the Furong tin ore deposit could have derived from the Qitianling peralkaline intrusion.

Tin·Partition·Peralkaline granite·

Hunan Province

1 Introduction

Tin deposits are typically closely related to granite spatially，temporally，and metallogenically（Lehmann 1990；Xia and Liang 1991）.Most granites associated with tin deposits display an extreme degree of differentiation and generally share the petrochemical characteristics of being peraluminous，enriched in K（relative to Na），and high in Si content，but lower in Ca，Fe，Mg，and Ti content（Lehmann 1990；Xia and Liang 1991；Chesley et al.1993；Yeap 1993；Sun and Higgins 1996；Botelho and Moura 1998；Bettencourt et al.2005）.Historically，tin mineralization has been thought to be tied to peraluminous，K-rich，orogenic S-type granites.However，in recent decades，important economic tin deposits associated closely with A-type granites have been found（Taylor 1979；Mitchell and Carson 1981；Sawkins 1990；Bi et al.1993；Botelho and Moura 1998；Liverton and Botelho 2001；Haapala and Lukkari 2005）. For example，the Furong superlarge tin deposit in Hunan Province，southeast China is closely associated with the Qitianling peralkaline A-type granite intrusion（Zhao et al. 1998，2000；Zheng and Jia 2001；Wang et al.2003a，b；Li 2006；Shuang et al.2006）.A-type granite is generally characterized as peralkaline and anorogenic.Nearly all peralkaline intrusive granites contain alkalis more than 8 wt%more than those in calc-alkali anorogenic granites（Tu 1989）.It is important to research the metallogeny of this new type of tin deposit.While there has been someresearch on the new type of tin deposit associated with A-type granite，the question of whether tin-rich aqueous fluid could be derived through peralkaline intrusion remains unsettled.One point of view is that the mineralized fluids of the Furong tin deposit were derived directly from later highly evolved magma（Wang et al.2004；Li and Liu 2005；Shuang et al.2006；Li et al.2007a，b），but another is that the tin-bearing fluids were provided by post-magmatic hydrothermal alteration of the Qitianling granite（Zhao et al.2005；Jiang et al.2006）.

✉ Xiaoyan Hu huxiaoyan@mail.gyig.ac.cn

1State Key Laboratory of Ore Deposit Geochemistry，Institute of Geochemistry，Chinese Academy of Sciences，Guiyang 550081，People’s Republic of China

2Guizhou Bureau of Nonferrous Metal and Nuclear Industry Geological Exploration，Guiyang 550002，People’s Republic of China

Metal mineralization associated with intrusions depends to a great extent on fractional crystallization of the magma and partitioning of metallic elements between the melt and aqueous fluid phases in the evolution of the magma.The fractional crystallization of magma and the partition behavior of its metallic elements depend on the composition of the melt，the composition of fluid derived from the melt，and the physicochemical conditions under which the partitioning occurs（Holland 1972；Feiss 1978；Candela and Holland 1984；Urabe 1985；Candela 1989；Keppler and Wyllie 1991；Lowenstern et al.1991；Peiffert et al.1994；Candela and Piccoli 1995；Chantal et al.1996；Webster 1997；Bai et al.1998；Halter et al.2002）.Existing experimental data of tin partitioning behavior have been collected for this paper.These data include the tin partition coefficients between the crystals and liquids between different granitic melts and aqueous fluid phases in known experimental physicochemical conditions.Based on the existing data，geochemical behavior of tin throughout magma evolution and the factors leading to the tin-bearing granite’s petrochemical characteristics are discussed.Furthermore，whether the mineralized aqueous fluids of the Furong tin deposit were derived from the Qitianling peralkaline intrusion is discussed in the context of the petrochemical characteristics of the Qitianling A-type granite，the mineralizing physicochemical conditions，and the geotectonic setting.Finally，the favorable factors of tin mineralization associated with the peralkaline granites are summarized，a significant step inunderstanding the mechanism of tin ore-forming processes related to peralkaline intrusive granite.

2 Tin partitioning behavior

2.1 Tin partition between minerals and melts

Fractional crystallization is the dominant petrogenetic process controlling magmatic evolution.The main tin carrier in tin deposits related to granitic rocks is cassiterite. Some accessory minerals such as biotite，hornblende，titanite，ilmenite，and magnetite are usually important hosts for tin in granitic rocks because of the preferential substitution of major cations Ti4+and Fe3+in those crystals by Sn4+（Barsukov 1957；Petrova and Legeydo 1965）. These substitutions are possible because the coordination radii of Ti4+，Fe3+，and Sn4+are similar（61，65，and 69 pm，respectively）（Shannon 1976）.In contrast，tin contents in feldspar and quartz are generally very lowmuch less than tin content in bulk granite rocks.

Table 1 Partition coefficients of tin between different minerals and melts

Thecompileddataoftinpartitioncoefficientsbetween different minerals and melts are shown in Table 1（Gan 1993）.Generally，tin tends to partition into biotite，magnetite，ilmenite，and amphibole rather than plagioclase，K-feldspar，and quartz.As the table shows，tin partition coefficients are affected by the melt composition.For example，the value 5.18 ofbetween amphibole and metaluminous andesitic melt is almost ten times that between amphibole and peralkaline rhyolitic melt（0.57）. The bulk tin partition coefficients between the minerals and different melts are estimated roughly as the average of the coefficients ofthe individual minerals against the melts.The bulk tin partition coefficients between the minerals and peralkaline basaltic melt，metaluminous andesitic melt，peralkaline andesitic melt，metaluminous acidic melt，peralkaline rhyolitic melt，and peraluminous acidic melt are 0.92，2.41，1.04，1.21，0.50 and 1.03，respectively.The majority of the bulk tin partition coefficients between the minerals and the melts are near 1.The bulk tin partition coefficient between the minerals and the peralkaline rhyoliticmeltisthelowestat0.50.Thisimpliesthattheresidual magma is likely to be enriched in tin following fractional crystallization of peralkaline granitic magma.In contrast，when the magma is rich in Ti4+，Fe3+，Mg2+，etc.，the residual magma will be deficient in tin after abundant tin-bearing minerals crystallize.For example，tin is depleted in melt from the mantle at 1000°C for melts containing abundant olivine and pyroxene crystals，a result of a higher bulk tin partition coefficient（＞1）（Lehmann（1990），and tin content in the melt generally is less than 1 μg/g（Hamaguchi and Tin 1969）.Tin enrichment in residual melt is almost impossible through andesitic magma evolution because of higher bulk tin partition coefficients between sphene/magnetite and andesitic melt（Petrova and Legeydo 1965；Gill 1978；Osborn1979）.However，peralkalineandesiticmagma candifferentiatetin-richmelt，asisthecaseintheSilsilahtinbearing peralkaline granite in the northeast Arabia shield（Bray1985），whichimpliesthatperalkalinemeltisfavorable for tin enrichment in the melt phase（Linnen et al.1995，1996）.Furthermore，if a crustal source intrusion is initially rich in tin，the residual later stage magma will be more enrichedintinafter highly evolving duetolow initial Ti，Fe，andMgcontentsintheintrusion.Therefore，tintransportand enrichment in residual magma should occur in peralkaline crustalsourceintrusionswithahigherdegreeof fractionation.

High volatile content，particularly F and Cl，can increase tin solubility in the granite melt phase（Bhalla et al.2005；Farges et al.2006）.F in melt can reduce the melt viscosity and liquidus and lower the crystallizing temperature（Baker and Vaillancourt 1995；Xiong et al.1998）.These factors decrease bulk（with crystals including biotite， hornblende，titanite，ilmenite and magnetite，plagioclase，K-feldspar and quartz，etc.）because of the decreasing substitution by tin in the minerals for the higher crystal order under lower temperature conditions（Badejoko 1984；Xu et al.1995）.As a result，tin contents in the minerals are lower and tin becomes enriched in the melt phase when granitic magma contains more volatiles.

Magmaticoxygenfugacityisanotherveryimportantfactor influencing tin partitioning behavior between minerals and melts.TheionicradiusofSn2+is93 pmandislargerthanthat of Sn4+（Huheey et al.1993）.Existing data show thatisgenerallylessthan1and，and that crystals include tin-bearing biotite， hornblende，sphene，ilmenite，and magnetite（Ishihara，1981）. If the oxygen fugacity is higher，the Sn4+/Sn2+ratio value in the melt will increase（Linnen et al.1995，1996；Farges et al. 2006），accompanied by a higher bulkAs a result， tinintheresidualmeltwillberelativelydepleted.Lowoxygen fugacity is also a favorable factor for enriching tin in residual magmabydecreasingbulk，asobservedinthemany tinoredepositsassociatedwithhighlydifferentiallowoxygen fugacity granite（Ishihara 1981；Lehmann 1990）.

It is speculated that tin tends to partition into the residual magma in differential fractional crystallization processes， when the initial magma is characterized as peraluminous（crustal sources）with lower contents of Ti4+，Fe3+，and Mg2+；peralkaline；volatile-rich；and having low oxygen fugacity.Such magmas probably serve as favorable reservoirs or as an important transport media for tin ore formation.

2.2 Tin partition between granitic melt and aqueous fluid phase

Experimental results of tin partition coefficientsbetween granitic melt and coexisting aqueous fluid show thatis influenced by oxygen fugacity，temperature，pressure，and chemical compositions of melt and coexisting aqueous fluid（Wang et al.1986；Li 1989；Webster 1990；Keppler and Wyllie 1991；Chen and Peng 1994；Xiong et al.1998；Villemant and Boudon 1999；Hu et al.2008）.

Previous experimental results imply that tin favors partitioning into aqueous fluids with abundant Cl-and F-ligands（Wang et al.1986；Li 1989；Keppler and Wyllie 1991；Chen and Peng 1994；Hu et al.2008）.The geochemistry of tin in aqueous fluids indicatesthat Sn2+complexeswith Cl-more easilythanwithothercomplexions，anddivalenttinchloride compounds are stable in reducing acid media（Jackson and Helgeson 1985；Chen 1986；Li 1989；Wilson and Eugster 1990；Taylor and Wall 1993；Barnes 1997；Sherman et al. 2000；Mu¨ller and Seward 2001）.An experimental study（Hu etal.2008）conductedat850°C，100 MPaandfo2nearNNO revealed thatincreases with increasing HCl content in aqueous fluid in which Sn2+is the dominant species. Additionally，the aluminum saturation index（ASI）of the melts after equilibrium with high HCl concentration in the aqueous fluid phase will increase due to the transport of alkalisinthemelttotheaqueousfluidphase.Thepresenceof fluorine in the starting fluid does not significantly influence

Daq.fl./meltSnbecause fluorine isinclinedto partitioninginto the melt phase（Webster 1990；Xiong et al.1998；Villemant and Boudon 1999）.Furthermore，compounds of Sn4+and F-could play an important role for tin transport in aqueous fluids when Sn4+is the dominant species at higher oxygen fugacity conditions（Liu and Chen 1986）.

2.3 Tin partition influenced by F and Cl

Volatileelements，particularlyFandCl，playimportantroles in the evolution of magmas and hydrothermal ore-forming fluid（Webster and Holloway 1988；Webster 1990）.The halogens affect intrusion properties such as viscosity，diffusibility，and vapor saturation.Fluorine and chlorine in silicatemelt canimprovediffusibilityofcationsbyreducing cation activation energies for diffusion（Baker and Watson 1988）.Therefore，diffusibility and solubility of tin in melt increasewithincreasingFandClcontentsinthemelt（Bhalla et al.2005），and high-F and high-Cl content melt could extract tin during magma evolution before the magma is water-saturated.By complexing with metals，they exert strong controls over the compositional variations and the style of mineralization in hydrothermal ore deposits.

According to previous studies（Webster 1990；Xiong et al.1998；Villemant and Boudon 1999），F is preferentially partitioning into the melt phase，and the partition coefficients of F between aqueous fluid and silicate melt at high pressure and temperature conditions are generally less than 1.As a result，F should be enriched in those kinds of melts through granitic crystallization and differentiation.In contrast to F，Cl prefers partitioning into aqueous fluids with a wide range of partition coefficients from 2 to 117（Webster 1992b，c，1997；Bureau et al.2000）.Mg，Ca，Fe，Si，and F clearly influence Cl partitioning behavior between aqueous fluids and silicate melts.Chlorine partition coefficientsincreasewithdecreasingmolarratiosof（Al+Na+Ca+Mg）/Si and F content in silicate melts；increasing H2O/（H2O+CO2）molar ratios and Cl content in the system are also favorable for chlorine partitioning into the aqueous fluid phase（Webster and Holloway 1988；Webster 1992a；Signorelli and Carroll 2000；Mathez and Webster 2005）.

Experimentalstudiesontinpartitioningbehavior between the aqueous fluid and granitic melt phases in systems with coexisting F and Cl at 850°C，100 MPa，and fo2near NNO show thatis generally less than 0.1，with a little variation when F content in the melt is more than about 1 wt%.Howeverincreases rapidly when F content in the melt is less than about 1 wt%-i.e.decreasing F content in the melt phase is favorable for tin partitioning into the aqueous fluid phase（Hu et al.2009）.In other words，granitic silicate melt with high F content（more than about 1 wt%）could extract tin，becoming enriched in tin in the melt phase.This is consistent with the fact that a lot of granites associated with tin deposits have a relatively high F content.Increasingvalues can be caused by increasing Cl partition coefficients，especially in a water-saturated magma system with high HCl content but low F content.Stronger partitioning of Cl into the fluid phase also may cause the partitioning of major elements such as Na and K into the aqueous fluid phase，while the concentrations of SiO2and Al2O3in the melt phase are evidently unaffected by increasing HCl concentrations（Frank et al.2003；Hu et al. 2008）.Additionally，Na and K will lead to increased ASI in the melts.It is also implied that increasingis a result of decreasing F content in the melt phase，which could be caused by a great deal of F-bearing minerals crystallizing from tin-rich melt or F degassing into the aqueous fluid phase when pressure is abruptly lowered through fractures or faults，or near the edge of the magma chamber.Furthermore，lower F content in the melt also could decrease tin saturated solubility in the melt（Bhalla et al.2005），contributing to disseminated cassiterite crystallization in the melt accompanied by F-bearing minerals. Noticeably，chlorine and fluorine begin to exsolve at respective pressures of～100 MPa and≤10 MPa and degas at the rates of 22-55%，and 0-15%，respectively，upon eruption（Spilliaert et al.2006）.In shallow magma degassing processes，the aqueous fluids generated by the different degassing paths are deficient in F but enriched in Cl（Villemant and Boudon 1999），which apparently is favorable for Cl-rich aqueous fluid extraction of tin from the melt phase，as well as water-rock interactions.

3 The Furong tin deposit and the Qitianling intrusion

3.1 Geological characteristics

As a new-found superlarge tin deposit，the Furong deposit is located in the largest Nanling Mountains’tungsten-tin polymetallic metallogenic belt in Hunan Province，southeast China（Xu et al.2000；Wei et al.2002）.The deposit is closely associated with the Qitianling granite intrusion spatially，temporally，and metallogenically（Wang et al. 2003a；Cai et al.2004；Wang et al.2004；Jiang et al.2006；Li 2006；Shuang 2007；Peng et al.2008）.The tin ore bodies of the deposit occur in the Qitianling granite complex or along its contacts with the wall rocks（Wei et al.2002）.The host mineral is cassiterite with accessory minerals such as pyrite， chalcopyrite， magnetite， galena， sphalerite，arsenopyrite，etc.Located at the intersection of the NE-trending Yanling-Chenzhou-Lanshan and the NW-trending Chenzhou-Shaoyang tectonomagmatic belts，the Qitianling granite complex crops out over an area of about 520 km2and includes the Qiguling，Wuliqiao，Goutouling，Maziping，Nanxi，and Lijiadong units（Fig.1）.According to40Ar-39Ar isotopic dating，the ages of the granites associated with the deposit are in the range of 151-160 Ma and the Qitianling granite intrusion occurred in Yanshanian（Liu et al.2003）.The results of further studies suggest that the main geological period of mineralization occurred between 150 and 160 Ma（Mao et al.1997）.This implies that the intrusion of the Qitianling granite and the mineralization of the Furong tin deposit occurred in the same geological period.

Fig.1 Geological sketch map of the Qitianling granite（modified from Zhu et al.2007）

3.2 Petrological and geochemical characteristics of the Qitianling granite complex

The Qitianling granite complex is primarily composed of amphibole-biotite granite and biotite granite.Generally，both are peralkaline，K-rich，and have high volatiles contents mainly in the form of biotite and fluorite.Crystallization temperatures of the amphibole-biotite granite are in the range of 680-740°C，which is higher than that of the later biotite granite with crystallization temperatures of 530-650°C（Li et al.2007a）.The oxygen fugacities of the amphibole-biotite granite and biotite granite range from -16.00 to-15.31 and-19.20 to-17.50，respectively（Li et al.2007a）.The oxygen fugacities of both granites are relatively low，especially those of the biotite granites which approach NNO（Zhao et al.2005）.The chemical compositions of the two granites are shown in Tables 2 and 3.

The geologic age of the early stage amphibole-biotite granite is in the range of 158.6 to 162.9±0.4 Ma（Bi et al. 2008）.It has a porphyritic texture with phenocrysts of quartz，K-feldspar，plagioclase，biotite，hornblende，etc.，and its accessory minerals are apatite，sphene，zircon，magnetite，etc.The contents of SiO2，alkalis（K2O+Na2O），FeOtotal，and TiO2in the amphibole-biotite granite have weight percentages in the range of 68.59-69.96，7.45-7.97，4.04-4.12，and 0.49-0.59，respectively.The ASI is in the range of 1.27-13.7 and the differentiation index（DI）is in the range of 82.40-84.71.Tin concentrations in the amphibole-biotite granite range from 14.90 to 95.80 μg/g.

The biotite granite is the later intrusion with a geologic age of 156.7-153.5±0.4 Ma（Bi et al.2008）.The contents of SiO2，alkalis（K2O+Na2O），FeOtotal，and TiO2in the granite have weight percentages in the range of 75.07-76.49，7.95-8.59，1.64-1.87，and0.09-0.12，respectively.Tin concentrations in the biotite granite are less than 12.80 μg/g.The ASI of the biotite granite is higher than that of the early stage amphibole-biotite granite，as is the DI value of the biotite granite with a range of 92.80-93.93.In contrast to the early amphibole-biotite granite，the biotite granite is characterized by its enrichment in silicon and potassium，peraluminous categorization，and high degrees of differentiation.

Table 2 Chemical compositions of the Qitianling granite（wt%）

Table 3 Volatiles F and Cl contents of biotite in the amphibolebiotite granite and biotite granite

Furthermore，a series of studies on the Qitianling granite provide important information on the tectonic background of the formation（Zheng and Jia 2001；Shuang et al.2006；Li et al.2007b；Bi et al.2008）.The Qitianling granite is characterized as peralkaline granite，having characteristic levels of rare earth elements，trace elements，and major elements，as well as Sr，He，Pb，S，H，and O isotope geochemistry characteristics of a peralkaline granite.Peralkaline granite may derive from crustal melting triggered byheat from the upwelling mantle.The two-stage granites of the Qitianling intrusion have a common magmatic origin and are assigned to A-type granite.It is implied that the Qitianling intrusion occurred under the geodynamic setting of lithospheric thinning of South China and post-orogenic crustal extension during the Mesozoic.

4 Discussion

As above mentioned，the Qitianling peralkaline granite derived mainly from crustal resources with some mantle material incorporated.Tin content in the early-stage amphibole-biotite granite varies from 14.90 to 95.80 μg/g（average 39.3 μg/g），and volatile content of the whole rock is rather high，especially Cl content as compared to the later stage biotite granite（Table 3）.The early tin-rich and volatile-rich magma could have derived from tin-rich crustal strata melted by upwelling mantle heat.Additionally，the Qitianling granite is characterized as peralkaline and volatile-rich with lower oxygen fugacity near NNO，all of which are advantages for tin enrichment in residual magma during early-stage crystallization and differentiation processes under high pressure and closed conditions. As a result，the later stage peralkaline silicate magma would be a favorable reservoir with higher tin and volatile contents.The Cl-rich and tin-bearing hydrothermal fluid could be derived from the residual magma because of the higherachieved by higher silicon and water contents in the system.Average SiO2content in the late-stage biotite granite is 75.60 wt%，which is higher than that in the amphibole-biotite granite（69.21 wt%）. Highercould also be caused by a great deal of F-bearing minerals such as fluorite and topaz crystallizing from tin-rich melt during magma cooling or by F degassing into the aqueous fluid phase when pressure is lower around fractures and faults and at the top of the magma chamber.The combination of the above favorable factors enhancesgreatly，which enhances tin partitioning in the aqueous fluids. BasedonthedataofthefluidinclusionstudyontheFurong tin deposits（Shuang 2007），the temperature and pressure of the deposits at formation are mainly in the ranges of 300-450°C and 17.9-180 MPa.The physicochemical conditions are favorable for F-bearing crystals crystallizing and Cl-rich volatiles degassing.So，the later stage magma of the Qitianling intrusion possessed advantageous physicochemical conditions to produce Cl-rich fluid.The Cl-rich fluid reacted withthemelt，leadingtoincreasedthatisafactorin deriving high tin-bearing aqueous fluids.At the same time，the Cl-rich fluid also reacted with tin-bearing minerals，such as biotite and magnetite，thus extracting more tin from these minerals to the aqueous fluid phase.

AsshowninTables 2and3，SnandClcontentsinthelater stage biotite granite are less than those in the amphibolebiotite granite，which may be the result of Sn and Cl partitioning into the aqueous fluid phase.In contrast with Cl distribution behavior，F is inclined to partition into the melt phase，with a degassing pressure and degassing rate of 10 MPa and 15%，respectively，which are lower than those of Cl at 100 MPa and 22-55%，respectively（Spilliaert et al. 2006）.Fcontentinthemeltphaseincreaseswiththeevolution of magma in a closed，high-pressure system；F mainly remains in the late-stage biotite granite because the oreforming pressure of the Furong deposit is more than 10 MPa. Therefore，the F/Cl ratio（1.02-2.92）in biotite of the later stage biotite granite is evidently higher than that of the amphibole-biotite granite（0-0.21）.Furthermore，the ASI of biotitegraniteishigherthanthatofamphibole-biotitegranite，which may be related to the abstraction of alkalis by the Clrichaqueousfluidphasederivedfromtheresidualmeltphase.

The evidence from the fluid inclusion study on the Furong deposit shows that the physical chemistry of the ore-forming fluidischaracterizedbymid-to-hightemperatureandsalinity，and by a Cl-bearing fluid solution with the composition of CO2-CH4-CaCl2-NaCl-KCl-H2O（Shuang 2007；Bi et al. 2008）.Researchontheminerals（Lietal.2007a）hasrevealed that the values of log（fH2O/fHF）fluid，log（fH2O/fHCl）fluid，and log（fHF/fHCl）fluidin the aqueous fluids coexisting with the amphibole-biotite granite are 4.22-4.39，2.78-3.24，and -1.82 to-1.73，respectively.The parallel values of the aqueous fluid coexisting withthe late-stagebiotitegranite are 3.27-3.53，2.85-3.22，and-0.75 to-0.02，respectively. Evidently，themagmatichydrothermalfluidsderivedfromthe magma in the later stage of the Qitianling intrusion bear higher levels of Cl，which is a favorable condition for tin partitioning into the aqueous fluid phase.

According to Sn，F，and Cl partition behavior and the petrological geochemical characteristics of the Qitianling granite mentioned above，the later stage magma of the Qitianling intrusion possesses favorable physicochemical conditions for deriving a Sn-rich aqueous fluid phase as part of tin ore formation.It can be deduced that tin-bearing ore-forming hydrothermal fluid could be derived from peralkaline，peraluminous，volatile-rich intrusions under favorable physicochemical conditions.

5 Conclusion

Based on the behavior of tin mineralization associated with granitic magmatism and on tin partition coefficients between the minerals and the different melts，we concludethat tin is likely to be concentrated in residual granitic melt and in the aqueous fluid phase during crystallization and differentiation processes when the granitic magma is peralkaline，high in volatiles，and low in Ca，Fe，and Mg.The highly evolved residual peralkaline granitic magmas could have silicate melts enriched in tin，and thus serve as favorable tin ore reservoirs for later-magmatic hydrothermal tin deposit formation.Tin-rich aqueous fluid could be derivedfromlaterperalkalinegraniticmagmawith decreasing F content，increasing water saturation and silica content，under favorable lower pressure and temperature physical conditions.Acidic，Cl-rich aqueous fluids are particularly likely to scavenge abundant tin from highly evolved K-rich，peralkaline，granitic silicate melts，as well as from the high tin-bearing minerals such as biotite，hornblende，titanite， etc.Theyarefavorablefor hydrothermal tin metallization.Therefore，the Qitianling peralkaline intrusion could have produced tin-bearing mineralized hydrothermal aqueous fluid for the Furong tin deposit formation.

AcknowledgmentsThe authors wish to thank Professor Fan Wenling for her instruction.Constructive，detailed comments by the reviewers and the chief editor were greatly appreciated.This research project was supported by National Natural Science Foundation of China（Grant Nos.41103030；41130423）.

Badejoko TA（1984）Correlations between microstructures，k-feldspar triclinicity and trace element geochemistry in stanniferous and barren granites，northern Nigeria.Lithos 17：259-271

Bai TB，Koster AF，Gross V（1998）The distribution of Na，K，Rb，Sr，Al，Ge，Cu，W，Mo，La，and Ce between granitic melts and coexistingaqueousfluids.GeochimetCosmochimActa 63：1117-1131

Baker DR，Vaillancourt J（1995）The low viscosities of F+H2O-bearing granitic melts and implications for melt extraction and transport.Earth Planet Sci Lett 132：199-211

Baker DR，Watson EB（1988）Diffusion of major and trace elements in compositionally complex Cl-and F-bearing silicate melts. J Non-Cryst Solids 102（1-3）：62-70

Barnes HL（1997）Geochemistry of hydrothermal ore deposits，3rd edn.Wiley，New York，pp 435-469

Barsukov VL（1957）The geochemistry of tin，（translated from Geokhimiya 1957：36-45）.Geochemistry 1：41-52

Bettencourt JS，Leute WB Jr，Goraieb CL，Sparrenberger I，Bello RMS，Payolla BL（2005）Sn-polymetallic greisen-type deposits associated with late-stage rapakivi granites，Brazil：fluid inclusion and stable isotope characteristics.Lithos 80：365-386

Bhalla P，Holtz F，Linnen RL，Behrens H，Koepke J（2005）Solubility of cassiterite in evolved granitic melts；effect of T，fo2and additional volatiles.Lithos 80：387-400

Bi CS，Shen XY，Xu QS，Ming KH，Sun HL，Zhang CS（1993）Geologicalcharacteristicsofstanniferousgranitesinthe Beilekuduk tin metallogenic belt.Xinjiang Acta Petrol et Mineral 12：213-223（in Chinese with English abstract）

Bi XW，Li HL，Shuang Y，Hu XY，Hu RZ，Peng JT（2008）Geochemical characteristics of fluid inclusions from Qitianling A-type granite，Hunan Province，China.Geol J China Univ 14（4）：539-548（in Chinese with English abstract）

Botelho NF，Moura MA（1998）Granite-ore deposit relationships in Central Brazil.J S Am Earth Sci 11：427-438

Bray EA（1985）Geology of the Silsilah ring complex，and associated tin mineralization，Kingdom of Saudi Arabia-a synopsis.Am Mineral 70：1075-1086

Bureau H，Keppler H，Metrich N （2000）Volcanic degassing of bromine and iodine：experimental fluid/melt partitioning data and applications to stratospheric chemistry.Earth Planet Sci Lett 183：51-60

Cai JH，Wei CS，Mao XD，Chen KX，Cai MH（2004）Characters of mineralizing geology and metallogenic pattern of Furong tin orefield in southern Hunan province.Geol Sci Technol Inf 23：69-76

Candela PA（1989）Magmatic ore-forming fluids：thermodynamic and mass transfer calculation of melt concentrations.Rev Econ Geol 4：203-221

Candela PA，Holland HD（1984）The partitioning of copper and molybdenumbetweensilicatemeltsandaqueousfluids. Geochim Cosmochim Acta 48：373-380

Candela PA，Piccoli PM（1995）Moldel ore-metal partitioning from melts into vapor and vapor/brine mistures.In：Thompson JFH（ed）Magmas，fluids，and ore deposits.Mineralogical Association of Canada，Ottawa，pp 101-127

Chantal P，Chinh N，Michel C（1996）Uranium in granitic magmas：part 2.Experimental determination of uranium solubility and fluid-melt partition coefficients in the uranium oxide-hapligranite-H2O-NaX（X=Cl，F）system at 770°C，2kar.Geochim Cosmochim Acta 60：1515-1929

Chen J（1986）Experiment on solubility of cassiterite in the presence of charcoal.Geol Rev 32：287-294（in Chinese with English abstract）

Chen ZL，Peng SL（1994）The experimental results of W and Sn Partitioning between fluid and melts and their significance for the origin of W and Sn ore deposits.Geol Rev 40：274-282（in Chinese with English abstract）

Chesley JT，Halliday AN，Snee LW，Mezger K，Shepherd TJ，Scrivener RC （1993）Thermochronology of the Cornubian batholith in southwest England：implications for pluton emplacement and protracted hydrothermal mineralization.Geochim Cosmochim Acta 57：1817-1835

Farges F，Linnen RL，Brown GEJ（2006）Redox and speciation of tin in hydrous silicate glasses：a comparison with Ta，Mo and W. Can.Mineral 44：795-810

Feiss PG（1978）Magmatic sources of copper in porphyry copper deposits.Econ Geol 72：197-404

Frank MR，Candela PA，Piccoli PM（2003）Alkali exchange equilibra between a silicate melt and coexisting magmatic volatile phase：an experimental study at 800°C and 100 MPa.Geochim Cosmochim Acta 67：1415-1427

Gan GL（1993）Mineral-melt element partition coefficients：data and major variation regularities.Acta Petrol et Mineral 12：144-181（in chinese with English abstract）

Gill JB（1978）Role of trace element partition coefficients in models of andesite genesis.Geochim Cosmochim Acta 42：709-724

Haapala I，Lukkari S（2005）Petrological and geochemical evolution of the Kymi stock，a topaze granite cupola within the Wiborg rapakivi batholith，Finland.Lithos 80：247-362

Halter WE，Pettke T，Heinrich CA（2002）The origin of Cu/Au ratios in porphyry-type ore deposits.Science 296：1844-1846

Hamaguchi H，Tin KR（1969）In：Wedepohl KH（ed）Handbook of geochemistry.vol II/4.Springer，Berlin Heidelberg，50-B-1 to 50-M-5

Holland HD（1972）Granites，solutions，and base metal deposits.Econ Geol 67：281-301

Hu XY，Bi XW，Hu RZ，Shang LB，Fan WL（2008）Experimental study on tin partition between granitic silicate melt and coexisting aqueous fluid.Geochem J 42：141-150

Hu XY，Bi XW，Shang LB，Hu RZ，Cai GS，Chen YW（2009）An experimental study of tin partition between melt and aqueous fluid in F/Cl-coexisting magma.Chin Sci Bull 54（6）：1087-1097

Huheey JE，Keiter EA，Keiter RL（1993）Inorganic chemistry：principles of structure and reactivity，4th edn.HarperCollins，New York

Ishihara S（1981）The granitoid series and mineralization.Econ Geol 75th Anniv Vol 458-484

Jackson KJ，Helgeson HC（1985）Chemical and thermodynamic constraints on the hydrothermal transport and deposition of tin：I. Calculation of the solubility of cassiterite at high pressures and temperatures.Geochim et Cosmochim Acta 49：1-22

Jiang SY，Zhao KD，Jinag YH，Ling HF，Ni P（2006）New type of tin mineralization related to granite in South China：evidence from mineralchemistry，elementandisotopegeochemistry.ActaPetrol Sin 22（10）：2509-2516（in Chinese with English abstract）

Keppler H，Wyllie PJ（1991）Partitioning of Cu，Sn，Mo，U and Th between melt and aqueous fluid in the systems haplogranite-H2O-HCl and haplogranite-H2O-HF.Contrib Mineral Petrol 109：149-1601

Lehmann B（1990）Metallogeny of tin.Springer，Berlin，pp 19-29

Li TJ（1989）Experimental studies of the solubility of cassiterite and the extraction of tin from granitic melts.Chin J Geochem 8：84-96

Li ZL（2006）Geochemical relationship between tin mineralization and A-type granite：a case of the Furong tin orefield，Hunan province，South China.A dissertation Submitted for the degree of Doctor of Philosophy of the Chinese Academy of Sciences and for Diploma of the Institute of Geochemisty.（in Chinese with English abstract）

Li TY，Liu JQ （2005）Characteristics and composition of fluid inclusions in Furong tin orefield，Qitianling aream，South Huan Province.Geol Mineral Resour South China 3：44-49（in Chinese with English abstract）

Li HL，Bi XW，Hu RZ，Peng JT，Shuang Y，Li ZL，Li XM，Yuan SD（2007a）Mineral chemistry of biotie in the Qitianling granite associated with the Furong tin deposit：trancing tin mineralization signatures.Acta Petrol Sin 23：2605-2614（in Chinese with English abstract）

Li ZL，Hu RZ，Yang JS，Peng JT，Li XM，Bi XW（2007b）He，Pb and S isotopic constraints on the relationship between the A-type Qitianling granite and the Furong tin deposit，Hunan Province，China.Lithos 97：161-173

Linnen RL，Pichavant M，Holtz F，Burgess S（1995）The effect of fo2on the solubility，diffusion and speciation of tin in haplogranitic melt at melt at 850°C and 2kbar.Geochim et Cosmochim Acta 59：1579-1588

Linnen RL，Pichavant M，Holtz F（1996）The combined effect of fo2and melt composition on SnO2solubility and tin diffusion in haplogranitic melts.Geochim Cosmochim Acta 60：4965-4976

Liu YS，Chen SQ （1986）An experimental study on cassiterite solubility and tin transport during mineralization.Acta Geol Sin 59：78-87

Liu YM，Xu JF，Dai TM，Li XH，Deng XG，Wang Q（2003）40Ar-39Ar isotopic ages of Qitianling granite and their geologic implications.Sci China（D）46：50-59

Liverton T，Botelho NF（2001）Fractionated alkaline rare-metal granites：two examples.J Asian Earth Sci 19：399-412

Lowenstern JB，Mahood GA，Rivers ML，Sutton SR（1991）Evidence for extreme partitioning of copper into a magmatic vapor phase. Science 252：1405-1409

Mao JW，Li YH，Li HY，Wang DH，Song HB（1997）Helium isotopic evidence on metalgenesis of mantle fluids in the Wangu gold deposit，Hunan Province.Geol Rev 43：646-649（in Chinese with English abstract）

Mathez EA，Webster JD（2005）Partitioning behavior of chlorine and fluorine in the system apatite-silicate melt-fluid.Geochim Cosmochim Acta 69：1275-1286

Mitchell AHG，Carson MS（1981）Mineral deposits and global tectonic settings.Academic Press，Cambridge

Mu¨ller B，Seward TM （2001）Spectrophotometric determination of the stability of tin（II）chloride complexes in aqueous solution up to 300°C.Geochim Cosmochim Acta 65：4187-4199

Osborn EF（1979）The reaction principle.In：Yoder HS（Ed）The evolution of Igneous Rocks，fiftieth anniversary perspectives. Princeton University Press，Princeton，pp 133-170

Peiffert C，Cuney M，Chinh NT（1994）Uranium in granitic magmas：part I.experimental determination of uranium-solubility and fluid-melt partition coefficients in the uranium oxide-haplogranite-H2O-Na2CO3system at 720-770°C，2kbar.Geochim Cosmochim Acta 58：2495-2507

Peng JT，Hu RZ，Yuan SD，Bi XW，Sheng NP（2008）The time ranges of granitoid emplacement and related nonferrous metallic mineralization in Southern Hunan.Geol Rev 54：617-625（in Chinese with English abstract）

Petrova ZI，Legeydo VA（1965）Geochemistry of tin in the magmatic process.Geochem Intern 2：301-307（translated from Geokhimiya 4，482-489）

Sawkins FJ.Metal deposits in relation to plate tectonics.2nd，Springer-Verlay；1990.p.315

Shannon RD（1976）Revised effective ionic radii and systematic studies of interatomic distances in halides and chalcogenides. Acta Cryst A32：751-767

Sherman DM，Ragnarsdottir KV，Oelkers EH，Collins CR（2000）Speciation of tin（Sn2+and Sn4+）in aqueous Cl solutions from 25°C to 350°C：an in situ EXAFS study.Chem Geol 167：169-176

Shuang Y（2007）The geochemistry of ore-forming fluid of Furong tin polymetallic deposit in Hunan Province，P.R.China.Ph.D. thesis，IGCAS（in Chinese with English abstract）

Shuang Y，Bi XW，Hu RZ，Peng JT，Li ZL，Li XM，Yuan SD，Qi YQ（2006）Tin-polymetallic deposit and its indication of source of hydrothermal ore-forming fluid.Mineral Petrol 26：57-65（in Chinese with English abstract）

Signorelli S（2000）Carroll MR solubility and fluid-melt partitioning of Cl in hydrous phonolitic melts.Geochim Cosmochim Acta 64：2851-2862

Spilliaert N，Metrich N，Allard P（2006）S-Cl-F degassing pattern of water-rich alkali basalt：modelling and relationship with eruption stylesonMountEtanavolcano.EarthPlanetSciLett248：772-786

Sun SS，Higgins NC（1996）Neodymium and strontium isotope study of the Blue Tier Batholith，NE Tasmania，and its bearing on the origin of tin-bearing alkali feldspar granites.Ore Geol Rev 10：339-365

Taylor GR（1979）Geology of tin deposits.Elsevier，NewYork

Taylor JR，Wall VJ（1993）Cassiterite solubility，tin speciation，and transport in a magmatic aqueous phase.Econ Geol 88：437-460

Tu GZ（1989）Alkali-rich intrusive rocks.Mineral Resour Geol 13：1-4（in Chinese）

Urabe T（1985）Aluminous granite as a source magma of hydrothermal ore deposits：an experimental study.Econ Geol 80：148-157 Villemant B，Boudon G （1999）H2O and halogen（F，Cl，Br）behaviour during shallow magma degassing processes.Earth Planet Sci Lett 168：271-286

Wang YR，Haselton T，Aruscavage P（1986）Experimental research on the partitioning coefficients of tin between fluids and granitic melts.Annual Report Institute of Geochemistry Academia Sinica.GuiYang.GuiZhouPeople’sPublishingHouse，pp 180-181（in Chinese）

Wang DH，Chen YC，Li HQ，Chen ZH，Yu JJ，Lu YF（2003a）Geochemistry characteristics of Furong tin deposit and its significance for ore prospecting，Hunan.Geol Bull China 22：50-56（in Chinese with English abstract）

Wang DH，Chen YH，Li HQ，Chen ZH，Yu JJ，Lu YF，Li JY（2003b）Geological and geochemical features of the Furong tin deposits in Hunan and their significance for mineral prospecting.Bull Geol 22：50-56（in Chinese with English abstract）

Wang XW，Wang XD，Liu JQ，Chang HL（2004）Relationship of Qitianling granite to Sn mineralization in Hunan Province.Geol Sci Technol Inf 23：1-12（in Chinese with English abstract）

Webster JD（1990）Partitioning of F between H2O and CO2fluids and topaz rhyolite melt.Contrib Mineral Petrol 104：424-438

Webster JD（1992a）Fluid-melt interactions in Cl-rich granitic systems：effects of melt composition at 2kbar and 800°C. Geochim Cosmochim Acta 56：659-678

Webster JD（1992b）Fluid-melt interactions involving Cl-rich granites：experimental study from 2 to 8 kbar.Geochim Cosmochim Acta 56：679-687

Webster JD（1992c）Water solubility and chlorine partitioning in Clrich granitic systems：effect of melt composition at 2kbar and 800°C.Geochim Cosmochim Acta 56：678-687

Webster JD（1997）Exsolution of magmatic volatile phases from Clenriched mineralizing granitic magmas and implications for ore metal transport.Geochim Cosmochim Acta 61：1017-1029

Webster JD，Holloway JR（1988）Experimental constraints on the partitioning of Cl between topaz rhyolite melt and H2O and H2O+CO2 fluids：new implications for granitic differentiation and ore deposition.Geochim Cosmochim Acta 52：2091-2105

Wei SL，Zeng QW，Xu YM，Lan XM，Kang WQ，Liao XJ（2002）Characteristics and ore prospects of tin deposits in the Qitianling area，Hunan.Geol China 29：67-75（in Chinese with English abstract）

Wilson GA，Eugster HP（1990）Cassiterite solubility and tin speciation in supercritical chloride solutions.In：Spencer RJ，Chou-I-Ming（eds）Fluid-mineral interactions；a tribute to H.P. Eugster，vol 2.Geochemical Society Special Publications，Houston，pp 179-195

Xia HY，Liang SY（1991）The genesis of granitic Tin-Tungsten rare metal ore deposits in the South-east of China.China Science Press，Beijing（in Chinese）

Xiong XL，Zhao ZH，Zhu JC，Rao B，Lai M（1998）Experiments on the fluid/melt partition of fluorine in the system albite granite-H2O-HF.Geochimica 27：67-73

Xu H，Zhao M，Ji SY（1995）A study on the composition and structural state of K-feldspars from Qianlishan granites，Hunan Province. J Nanjing Univ 31：121-127（in Chinese with English abstract）

Xu YM，Hou MS，Liao XJ，Ao ZW（2000）Deposit types and prospect for prospecting of Sn deposits in Furong ore fluid，Chenzhou. Hunan Geol 19：95-100（in Chinese with English abstract）

Yeap EB（1993）Tin and gold mineralizations in Peninsular Malaysia and their relationships to the tectonic development.J South East Asian Earth Sci 8：329-348

Zhao ZH，Bao ZW，Zhang BY（1998）Geochemistry of the Mesozoic basaltic rocks in southern Hunan Province.Sci China（D）41（-suppl.）：102-112（in Chinese with English abstract）

Zhao ZH，Bao ZW，Zhang BY，Xiong XL（2000）Crust-mantle interaction and its contribution to the Shizhuyuan tungstenpolymetallic mineralization.Sci China（D）30（suppl.）：161-168（in Chinese with English abstract）

Zhao KD，Jiang SY，Jiang YH，Wang RC（2005）Mineral chemistry of the Qitianling granitoid and the Furong tin ore deposit in Hunan province，South China：implication for the genesis of granite and related tin mineralization.Eur J Mineral 17：635-648

Zheng JJ，Jia BH（2001）Geological characteristics and related tin polymetallic mineralization of the Qitianling granite complex in southern Hunan province.Geol Mineral Resour South China 9：50-57（in Chinese with English abstract）

Zhu J，Zhang P，Xie C（2007）Qitianling granite body.In：Zhou X et al（eds）Genesis of late mesozoic granites in Nanning region and geodynamic evolution of lithosphere.Science Press，Beijing，pp 520-533（in Chinese）

22 June 2014/Revised：19 November 2015/Accepted：8 January 2016/Published online：21 January 2016ⒸScience Press，Institute of Geochemistry，CAS and Springer-Verlag Berlin Heidelberg 2016