E-ISSN : 2541-5794 P-ISSN : 2503-216X Journal of Geoscience, Engineering, Environment, and Technology Vol 03 No 01 2018 Idrus A./ JGEET Vol 03 No 01/2018 30 Halogen Chemistry of Hydrothermal Micas: a Possible Geochemical Tool in Vectoring to Ore for Porphyry Copper- Gold Deposit Arifudin Idrus 1, * 1 Geological Engineering Department, Faculty of Engineering, Universitas Gadjah Mada, Yogyakarta, Indonesia. *Corresponding author: arifidrus@ugm.ac.id Tel.: +62-274-513668+81-22-813-8438; Received: Dec 31, 2017. Revised : Feb 23, 2018, Accepted: Feb 25, 2018, Published: 1 March 2018 DOI: 10.24273/jgeet.2018.3.01.1022 Abstract Porphyry copper-gold deposit commonly exhibits an extensive alteration zone of hydrothermal micas particularly biotite and sericite. This study is aimed to analyze and utilize the chemistry of halogen fluorine and chlorine of biotite and sericite to be a possible tool in vectoring to ore for copper porphyry deposits. To achieve the objectives, several selected altered rock samples were taken crossing the Batu Hijau copper-gold mine from inner to outer of the deposit, and hydrothermal micas contained by the rocks were analyzed petrographically and chemically. Mineral chemistry was detected by electron microprobe analyzer, whilst biotite is petrographically classified as either magmatic or hydrothermal types. Sericite replacing plagioclase occurred as fine-grained mineral and predominantly associated with argillic-related alteration types. Biotites in the Batu Hijau deposit are classified as phlogopite with a relatively low mole fraction magnesium (XMg) (~0.75) een the XMg and halogen contents are -F and Mg- inner part of the deposit which is represented by early biotite (potassic) zone where the main copper-gold hosted, to the outer part of the deposit. However, chlorine in both biotite and sericite from each of the alteration zones shows a relative similar concentration, which suggests that it is not suitable to be used in identification of the alteration zones associated with strong copper-gold mineralization. H2O content of the biotite and sericite also exhibits a systematic increase outward which may also provide a possible geochemical vector to ore for the copper porphyry deposits. This is well correlated with fluorine content of biotite in rocks and bulk concentration of copper from the corresponding rocks. Keywords: Biotite, Sericite, Halogen Chemistry, Vector to Ore, Porphyry Copper-Gold Deposit 1. Introduction A number of researchers have suggested that fluorine and chlorine are intimately involved in the hydrothermal transport of metals (Zhu and Sverjersky, 1991; Shinohara, 1994; Gammons and Williams-Jones, 1997; Selby and Nesbitt, 2000). The halogen contents, therefore, may have potential as pathfinder elements in geochemical prospecting for many different types of ore mineral deposits. In the rock forming minerals, F and Cl generally occupy the hydroxyl sites of hydroxysilicate minerals, including micas such as biotite and sericite (Parry et al., 1984; Selby and Nesbitt, 2000; Sarjoughian et al., 2015; Zhang et al., 2016). This paper is aimed to investigate the halogen (F and Cl) chemistry of biotite and sericite as well as the use of halogens for geochemical vector ore, where the Batu Hijau copper-gold porphyry deposit as a case study. The Batu Hijau deposit is located in southwest corner of Sumbawa Island, Indonesia (Fig 1). It contains 914 million metric tons of ore at an average grade of 0.53 % Cu and 0.40 g/t Au (Clode et al., 1999). The Batu Hijau deposit occurs in steeply incised terrain, with the highest point on the deposit at 555 m above sea level. In general, the pre-mineralisation rock units consist of interbedded andesitic lithic breccia, and fine-grained volcaniclastic sandstones and mudstones, porphyritic andesite intrusive and at least two texturally distinct quartz diorite intrusive bodies. These rocks are intruded by multiple phases of tonalite porphyries, which acted as ore mineralization-bearing intrusions (Clode et al., 1999; Garwin, 2002) (Fig 2). The emplacement of tonalite porphyries and mineralisation are spatially and temporally associated with north- south (N-S) and northeast-southwest (NE-SW) trending structures (Priowarsono and Maryono, 2002). Hydrothermal alteration and mineralization developed in four temporally and spatially overlapping stages consists of the early alteration stage is divided into biotite (potassic), actinolite (inner propylitic) and chlorite-epidote (outer propylitic) zones (Idrus, 2005). The transitional alteration stage is typified by a chlorite-sericite (intermediate argillic) zone (Idrus, 2005). The late mailto:arifidrus@ugm.ac.id Idrus A./ JGEET Vol 03 No 01/2018 31 alteration stage is characterized by destruction of feldspar and the formation of pyrophyllite- andalusite (advanced argillic) and sericite- paragonite (argillic) zones (Idrus, 2005). The very late alteration stage is characterized by illite and sericite replacement of feldspar. Alteration zones of the Batu Hijau porphyry copper-gold deposit can be seen in Fig 3. Biotite is observed in the biotite, chlorite- sericite and actinolite alteration zones, while sericite occurs intensively in the biotite and chlorite-sericite zones as well as in the pyrophyllite-andalusite and sericite-paragonite alteration zones. Fluorine and chlorine contents were analyzed in both hydrothermal micas (biotite and sericite) from these alteration zones. BATU HIJAU PROJECT PRAYA LOMBOK STRAIT SELONG MATARAM ALAS STRAIT SUMBAWA BESAR FLORES SEA Indian ocean Fig 1. The Batu Hijau porphyry copper-gold mine site in Sumbawa Island, Indonesia, and study area location (black box). T D U 30 30 35 80 35 C R - 4 N W F A U L T T O N G O L O K A F A U L T Z O N E D 35 5 8°8 0° 8 5° 8 0° 8 5° 8 0° 7 0° 8 5° 7 0° 8 5° 8 0° 35 ZIGZAG FAULT NAGIN FAULT C R -3 N W F A U L T CR-2 N W FAU LT 5 8° 8 5° 42 RINJANI FAULT 8 0° 8 0° 7 2° SEM ER U FA U LT L A W U F A U L T K E L U D F A U L T 8 9° M ERB A BU FA U LT 8 5° 8 0° 7 9° 8 5° 8 5° 8 0° B A T O K B R O M O FA U L T 30 A N A K KA TA L A FA U LT 30 75 7 5° 5 0° 7 0° 7 0° 7 0° 6 5° 5 0° 4 5° 4 3° 8 0° 7 8° 3 5° 7 0° 7 0° 7 0° 8 0° 5 0° 4 5° 4 0° 4 5° 4 5° 2 9° 6 5° 7 5° 8 5° 7 5° 7 6° 7 8° 4 5° 6 0° 8 0° 6 5° 8 0° 3 9° 8 0° 8 2° 7 5° 8 0° 8 5° 7 5° 8 0° 4 5° 4 0° 2 5° 7 5° 8 0° 3 5° 7 8° 4 0° 8 0° 7 0° 7 0° 5 0° 7 0° 6 7° 7 5° 8 5° 8 0° 6 5° 6 6° 7 0° 4 4° 8 2° 5 0° 7 5° 8 2° 7 9° 8 0° 7 5° 7 5° 7 9° 7 5° 6 0° 7 0° 7 5° 8 5° 8 5° 8 5° 8 0° 7 5° 7 7° 8 0° 7 2° 8 5° 6 0° 8 0° 8 5° 7 5° 7 4° 8 0° 3 0° 7 5° 8 5° 8 5° 8 0° 5 5° 6 1° 4 5° 7 5° 7 5° 4 3° 7 5° 3 5° 4 0° 6 5° 8 0° 5 0° 7 0° 8 0° 7 5° 3 5° 8 0° 7 5° 7 8° 7 5° 6 5° 8 0°8 0° 8 0° 8 0° 8 0° 7 0° 7 5° 8 0° 7 0° 7 0° 6 0° 6 0° 7 5° 6 5° 5 0° 4 0° 4 0° 3 0° 4 0° 3 5° 6 5° 6 5° 8 0° 8 0° 3 0°6 0° 5 0° 8 7° 8 0° 8 0° 7 0° 3 5° 70 80 80 80 80 80 4 0° 4 0° 7 0° 7 5° 80 7 5° 8 5° 5 0° 8 0° 5 2° 5 0° 5 5° 6 7° 8 0° 7 0° 8 0° 7 0° 8 5° 4 5° 4 0° ? ? ? ? ? D U 6 0° 6 8 ? ? ? ? 5 0° 7 5° 80 70 70 70 50 45 80 75 70 75 70 80 70 80 3581 80 40 85 75 70 7 0° 6 0° 7 8° 7 0° M E R A PI FA U LT 6 5° 8 0° 7 8° 3 0° 4 5° 3 9° 7 5° 6 8° 80 75 THE BATU HIJAU DEPOSIT 1st Qtr-2002 Geology c om pilation Based on End of Marc h Topography Young tonalite (Yt) Newm ont Nusa Tenggara Corp., 2002 Interm edia te tonalite (It) LEGEND Equigranular quartz diorite (Qde) Porphyritic quartz diorite (Qdp) Undifferentiated quartz diorite (Qdu) Porphyritic andesitic intrusive (Adp) Volc anic lithic brec c ia (Vxl) Fine grained volc anic lastic s (Vfg) N O 100 200 SCALE 1: 2500 Bedding (with dip & dip d irec tion) Jointing (with dip & dip direc tion) Fault with dip direc tion Contac t lithology Ultim ate p it lim it ULT IMA TE PIT LIM IT QDe QDe Qdp Vfg Vfg Vxl Vxl Vfg Adp Vxl Qdu It It Yt Yt TO NG O LO KA-PUN A FAULT 4 8 5 0 0 0 E 4 8 6 2 0 0 E 9008400N 9009000N 9009600N 9010200N 9010200N 9009600N 9009000N 9008400N 4 8 5 0 0 0 E 4 8 5 6 0 0 E 4 8 5 6 0 0 E 4 8 6 2 0 0 E Section 9080N Sec tion 9080N “T o n g o lo ka -B a tu H ija u ” fa u lt c o rr id o r Fig 2. Geological map of the Batu Hijau deposit (Newmont Nusa Tenggara Corp., 2002). 32 Idrus A./ JGEET Vol 03 No 01/2018 Early c entral biotite zone (Bt) THE BATU HIJAU DEPOSIT 1st Qtr-2002 Alteration c om pilation Based on End of Marc h Topography 9008400N Bt Newm ont Nusa Tenggara Corp., 2002 LEGEND N ULT IMA TE PIT LIM IT 4 8 5 0 0 0 E Transitional c hlorite-seric ite zone (Chl-Ser) Early proxim al ac tinolite zone (Ac t) Early distal c hlorite-epidote zone (Chl-Ep) Max. Bt extent and Ac t present (appx.) Epidote present Mafic pa rtly altered to sec ondary biotite (Bt) Late seric ite-paragonite zone (Ser-Pg) Late pyrophyllite-a ndalusite zone (Prl-And) Late argillic zone (Undiff.) Very late illite-seric ite zone (Ill-Ser) Ultim ate pit SCALA 1:2500 0 100 200 9009000N 9009600N 9010200N 4 8 5 6 0 0 E 4 8 6 2 0 0 E 9010200N 9009600N 9009000N 9008400N 4 8 5 0 0 0 E 4 8 5 6 0 0 E 4 8 6 2 0 0 E Bt Ac t Chl-Ser Chl-Ep Prl-And Ser-Pg Argillic (Undiff.) Ill-Ser Chl-Ser Prl-And Ac t Chl-Ep Argillic (Undiff.) Fig 3. Hydrothermal alteration map of the Batu Hijau deposit (Newmont Nusa Tenggara Corp., 2002; Idrus, 2005). 2. Analytical Methods A suite of representative altered samples was systematically taken crossing from inner to outer part of the Batu Hijau porphyry copper-gold mine in SW Sumbawa Island, Indonesia. Several selected rock samples were analyzed petrographically and mineral-chemically. Petrographic methods include the analyses of thin and polished thin sections under a polarized-light microscope, to identify primary and hydrothermal minerals, their textures and occurrences. Mineral chemistry analysis utilizes electron probe micro analyzer (EPMA) JEOL Idrus A./ JGEET Vol 03 No 01/2018 33 JXA-8900R to determine the chemical composition of the biotite and sericite in each of their related alteration zones from the inner to outer part of the deposit. Element determinations (Si, Al, FeTota1, Mg, Ti, Mn, Na, K, F and Cl) were carried out using a beam size 3 µm, an accelerating potential voltage of 15 kV, a probe current of 2.35 nA, and a counting time of 20 second for each element analyzed. Natural apatite, jadeite, rutile, tugtupite, fayalite, spinel, orthoclase, and plagioclase standards were used in the analytical procedure for F, Na, Ti, Cl, Mn, Fe, Mg, Al, K, Ca and Si. Matrix effects were corrected using the ZAF software provided by JEOL. The accuracy of the reported values for the analyses is 1-5 % (1σ) depending on the abundance of the elements. A microprobe analysis is defined as the arithmetic mean of 1- 10 spot analyses of the biotite and sericite depending on mineral grain size. The OH values are calculated on the basis of 24 oxygens. A computer software program MINPET 2.02 was primarily used to calculate the structural formula of the analysed minerals. All analyses were carried out at the Institute for Mineralogy and Economic Geology, RWTH Aachen University, Germany. 3. Results and Discussion 3.1 Biotite petrography Biotites are petrographically classified as either magmatic or hydrothermal types (Fig 4). The term crystallized directly from silicate melt. Magmatic biotite grain is further subdivided into least-altered and altered varieties (Selby and Nesbitt, 2000). The - - present in hydrothermal assemblages (e.g. potassic, phyllic and propylitic). The magmatic biotites of Batu Hijau is only observed as altered magmatic biotite in few intermediate and young tonalite samples. Magmatic biotite occurs characteristically as euhedral to subhedral phenocrysts and microphenocrysts and euhedral to subhedral flakes. Some magmatic biotite is ragged, splintery or inferred to have precipitated from the hydrothermal fluid. Hydrothermal biotite is petrographically distinct from magmatic biotite, occurring as aggregates of fine grained flakes. Biotite that has partially or completely replaced igneous hornblende and occurring as biotite veinlet 3.2 Sericite petrography Hydrothermal sericite is a common alteration product in many hydrothermal deposits. The Batu Hijau porphyry copper-gold deposit exhibits extensive argillic alteration styles, in which sericite becomes a major constituent surrounding or superimposed on the central biotite alteration. The argillic alteration styles include the transitional chlorite-sericite (intermediate argillic), late pyrophyllite-andalusite (advanced argillic) and late sericite-paragonite (argillic) alteration zones. However, very minor sericite occurs in the central biotite (potassic) alteration zone. The sericite associated with the central biotite alteration zone partially replaces plagioclase phenocrysts in the tonalite porphyries. A complete replacement is locally observed in the young tonalite. The replacements mostly occur in the cores, rather than in the rims of the zoned plagioclase grains. In comparison to the intermediate tonalite, the plagioclase in the young tonalite is more intensely dusted by the sericite. The sericites are present in a small portion ( 1 %), and commonly occur as an aggregate of fine to medium-grained flakes (up to 0.8 mm in length). The transitional chlorite-sericite alteration zone occupies a temporal position between the central biotite and late argillic alteration styles (pyrophyllite-andalusite and sericite-paragonite zone). This alteration zone is characterized by weak-moderate chloritization and sericitization (Fig 5A). The plagioclase grains are partially to completely replaced by sericite. The replacement is more conspicuously in the equigranular quartz diorite than in the andesitic volcaniclastic rocks. The hydrothermal sericite is present in variable portion (5-25 %) of the rock volume. The mineral occurs mostly as fine-grained flakes, with length of up to 0.4 mm (commonly < 0.04 mm). Fig 4. Petrographic images of biotite types in rocks from Batu Hijau deposit: (A) euhedral-subhedral altered magmatic biotite contained by tonalite porphyries, and (B) fine-grained hydrothermal biotites replacing hornblende in equigranular quartz diorite. 34 Idrus A./ JGEET Vol 03 No 01/2018 Fig 5. Grey-petrographic images of sericite: (A) intergrowth of chlorite replacing ferromagnesian minerals and sericite replacing plagioclase) of transitional chlorite-sericite-altered volcaniclastic rocks, (B) Euhedral-subhedral andalusite (high relief) after sericite-paragonite replacing plagioclase of late andalusite-pyropyllite (advanced argillic)-altered quartz diorite. Mineral abbreviations: Ser = sericite, Chl = chlorite, Pg = paragonite, And = andalusite, Kln/Ill = kaolinite/illite, Ccp = chalcopyrite, and Py = pyrite. The sericite in the late pyrophyllite-andalusite alteration zone occurs in a relatively minor to moderate amounts (2-20 %) (Fig 5B), and is associated with pyrophyllite, andalusite, kaolinite, diaspore and dickite. The sericite replaces the plagioclase grains completely. They occur as very fine-grained flakes, with a length mostly < 0.04 mm. In comparison to those in the pyrophyllite- andalusite alteration zone, the sericites related to the late sericite-paragonite alteration zone are characterized by relatively fine to medium-grained flakes (up to 0.8 mm). The XRD data indicates that the white-mica solid solutions are predominantly composed of sericite and paragonite end-members. The Rietveld program quantifies the phases as the major components (30-60 % of the rock) (Idrus, 2005). 3.3 Biotite and sericite chemistry Biotite, a trioctahedral mica with the generalized formula (K, Na, Ca, Ba) (Fe +2 , Fe +3 , Mg, Ti, Mn, Al)3 (Al, Si)4O10(OH, F, Cl)2 is a common constituent in many copper porphyry deposits. The previous studies of biotite chemical composition in copper porphyry deposits have mostly concentrated on the determination of F and Cl contents, with the objective of distinguishing between mineralized and barren plutons. Biotites in the Batu Hijau deposit are classified as phlogopite K2Mg6[Si6Al2O20](OH) with a relatively low mole fraction magnesium (XMg) (~0.75) compared to the et al., 1998). Representative composition of the Batu Hijau biotites is given in Table 1. Some elements show a systematic compositional variation in the central biotite (Bt) and partly chloritized (Partly -sericite (Chl- Ser) to the outer actinolite (Act) alteration zones. The relationship between the XMg and halogen -F and Mg- Munoz, 1984; Idrus, 2005). Table 1. Representative microprobe data of major oxides and halogen chemistry of biotite in various altered rocks taken from the inner (central) to the outer part (peripheral) of the deposit Elements Alteration zone (inner  outer deposit) Bt Partly Chl'd Chl-Ser Act SiO2 41.08 39.85 39.52 38.85 TiO2 2.38 1.69 2.15 4.92 Al2O3 13.12 14.18 15.20 13.37 FeO 10.49 10.66 11.17 13.68 MnO 0.05 0.11 0.12 0.35 MgO 19.92 19.59 17.78 15.31 CaO bd 0.03 0.03 0.02 Na2O 0.16 0.15 0.15 0.17 K2O 8.74 8.92 9.38 9.18 F 0.99 0.98 0.64 0.38 Cl 0.19 0.22 0.25 0.31 H2O 3.66 3.48 3.75 3.81 Total 100.78 99.86 100.13 100.32 Si 5.90 5.79 5.75 5.72 Al IV 2.10 2.21 2.25 2.28 Al VI 0.12 0.22 0.35 0.04 Ti 0.26 0.19 0,24 0.55 Fe +2 1.26 1.30 1.36 1.69 B A Idrus A./ JGEET Vol 03 No 01/2018 35 Elements Alteration zone (inner  outer deposit) Bt Partly Chl'd Chl-Ser Act Mn 0.01 0.01 0.01 0.04 Mg 4.27 4.24 3.86 3.36 Ca 0.00 0.01 0.00 0.00 Na 0.04 0.04 0.04 0.05 K 1.60 1.65 1.74 1.73 F 0.90 1.14 0.59 0.35 Cl 0.09 0.11 0.13 0.15 OH 3.51 3.37 3.64 3.75 XFe 0.77 0.77 0.74 0.67 XMg 0.24 0.26 0.31 0.34 XPhl 0.72 0.71 0.66 0.59 -Ser = chlorite-sericite (phyllic); and Act = actinolitic (inner propylitic) alterations. Table 2. Representative microprobe data of major oxides and halogen chemistry of sericite in various altered rocks taken from the inner (central) to the outer part (peripheral) of the deposit Elements Alteration zone (inner  outer deposit) Bt Chl-Ser Prl-And Ser-Pg SiO2 47.07 47.65 47.00 45.90 46.9 TiO2 0.18 0.21 0.14 0.19 0.09 Al2O3 33.01 30.13 32.70 37.26 36.25 FeO 1.83 2.97 2.03 0.74 1.29 MnO bd 0.07 0.02 bd bd MgO 1.97 3.30 1.96 0.19 0.55 CaO 0.03 0.05 0.01 bd bd Na2O 0.52 0.08 0.37 2.01 1.36 K2O 10.32 9.93 10.43 8.37 9.09 F 0.39 0.37 0.24 0.11 0.l5 Cl 0.04 0.04 0.01 0.01 0.02 H2O 4.29 4.26 4.34 4.47 4.48 Total 99.64 99.05 99.26 99.25 100.21 Si 6.30 6.44 6.32 6.08 6.18 Al IV 1.70 1.56 1.68 1.92 1.82 Al VI 3.50 3.23 3.49 3.89 3.80 Ti 0.02 0.02 0.01 0.02 0.01 Fe 0.20 0.34 0.23 0.08 0.14 Mn 0.00 0.01 0.00 0.00 0.00 Mg 0.39 0.66 0.39 0.04 0.11 Ca 0.00 0.01 0.00 0.00 0.00 Na 0.14 0.02 0.10 0.52 0.35 K 1.76 1.71 1.79 1.41 1.53 F 0.33 0.31 0.21 0.09 0.12 Cl 0.02 0.02 0.01 0.00 0.01 OH 3.83 3.84 3.89 3.95 3.93 XSer 0.93 0.99 0.95 0.73 0.81 XPg 0.07 0.01 0.05 0.27 0.19 Note: -Ser = chlorite-sericite (phyllic) alteration; Prl-And = pyrophyllite-andalusite (advanced argillic); and Ser-Pg = Sericite-Paragonite (intermediate argillic) alterations. Sericite, is a term given to fine grained, white mica including muscovite, phengite, illite, and other solid solution end members. Sericite often occurred in mineral aggregates in which chlorite, sericite or albite may be intermixed and therefore not distinguishable with the microprobe optics. Batu Hijau sericites show an inhomogeneity degree in the chemical composition, it may contain unit- thick layers of smectite and chlorite, and/or submicrometerized patches of kaolinite, quartz, and other minerals. Representative composition of the Batu Hijau sericites is shown in Table 2. Mole fractions of sericite (Xser) decrease relative to those in the late alteration zones including pyrophyllite-andalusite (Prl-And) and sericite- paragonite (Ser-Pg) as a decrease of their forming temperatures. In general, sericite chemistry exhibits insignificant variation in the composition (Table 2). However, Si and F decrease as well as Al and Mg increase to the late alteration zones. 3.4 F-OH exchange of biotite-sericite pairs The F and OH contents of biotite, sericite, and hydrothermal fluids in natural systems allow an evaluation of exchange equilibrium between the biotite, sericite and hydrothermal fluids in natural systems allow an evaluation of exchange equilibrium between the biotite, sericite and the fluids (Parry et al., 1984; Selby and Nesbitt, 2000; Siahcheshm et al., 2011; Sarjoughian et al., 2015; Zhang et al., 2016). The F content of sericites from early biotite alteration zone has a positive correlation with the XMg as shown in Fig 6, whereas those from transitional Chl-Ser as well as late Prl- 36 Idrus A./ JGEET Vol 03 No 01/2018 And and Ser-Pg alteration zones show a scatter relationship. The positive correlation of the XMg and F suggest that Mg controls the F-OH exchange (Munoz, 1984; Selby and Nesbitt, 2000; Zhang et al., 2016). Fig 6. A positive correlation of XMg and F in sericite from the early biotite (potassic) and transitional-late alteration zones. The experimentally calibrated F-OH exchange relations of Munoz et al. (1974) and computational techniques of Gunow et al. (1980) have been used to evaluate exchange equilibrium between biotite and sericite at the Batu Hijau deposit. A generalized reaction for F-OH exchange of biotite or sericite with hydrothermal fluid can be written as: OH(mica) + HF(fluid) = F(mica) + H2O(fluid) (1) If the F and OH mix ideally on the hydroxyl sites, the equilibrium expression is: log K = log (XF/XOH)mica + log (fH2O/fHF)fluid (2) where X denotes mole fraction and f is fugacity. Experimental equilibrium constants for exchange reactions have been applied to natural micas of variable composition by Parry et al. (1984) and Gunow et al. (1980) using the following constants: Log Kbiotite = 2100/T + 1.523(Xphlogopite) + 0.416(Xannite) + 0.079(Xsiderite) (3) and log Ksericite=2100/T+1.523(XMg) + 0.4l6(XFe) - 0.l l(XAl) (4) Combination of exchange reactions and equilibrium constants for these two micas produces a relationship between the mica independent of temperature and fluid composition. which can be used to evaluate exchange equilibria between the hydrothermal mica pairs. OHbiotite + Fsericite = Fbiotite + OHsericite (5) log K(biotite+sericite)= 1.523 (Xphlogopite-XMg+0.416(Xannite-XFe) +0.079 (Xsericite - 0.11 XAl) (6) log K = log (XF/XOH) biotite + log (XOH/XF) sericite (7) Equilibrium constants calculated from F-OH content of the sericite-biotite pairs (equation 7) produce values ranging between 0.61-1.12 and an average of 0.82 (Idrus, 2005). 3.5 Variation in halogen fugacity ratios The fugacity ratios of [H2O] and [HF] as well as [H2O] and [HCl] of hydrothermal fluids were calculated using the equations from (Munoz, 1992) which are based on the revised coefficients for F- Cl-OH exchanges between the biotite and the fluid (Zhu and Sverjersky, 1991, 1992). Our results suggest that the ratios increase systematically to the outer alteration zones. By using the same equations (Zhu and Sverjersky, 1991, 1992), the halogen fugacity ratios of fluids based on the sericite chemistry have also been computed and show an increase towards the outer (late) alteration zones (Fig 7). Fig 7. Fugacity ratios of sericite increasing from inner to outer part of alteration zones. Calculation based on forming temperatures at 510, 475, 360 and 250°C for the early, transitional and late alteration zones, respectively (Temperature data from Idrus, 2005). 3.6 Halogen chemistry used for vector to ore The concentration of halogen fluorine and chlorine in rocks might provide an indication of mineralization and thus find utility as an exploration tool. The F and Cl used in exploration has limited to lithogeochemical studies. Due to availability of EPMA analysis, nowadays, the F and Cl studies are more concentrated on hydrous minerals, including biotite and sericite in the rocks, both barren and mineralized rocks. A strong correlation between the F and Cu contents of biotites in mineralized plutons from Basin and Range Province, USA has been described by (Parry and Jacobs, 1975). The high content of F in biotites at Casino Cu-Au-Mo porphyry deposit (Canada) and Lar Cu-Mo porphyry deposit (Iran), respectively is strongly associated with potassic and phyllic alterations, in which high copper-gold mineralization occurred (Selby and Nesbitt, 2000; Moradi et al., 2016). Idrus A./ JGEET Vol 03 No 01/2018 37 Fig 8. The fluorine content of biotite and sericite regularly increase toward central deposit (potassic). Fig 9. Water content of both biotite and sericite decreased toward central deposit Fig 10. A positive correlation between fluorine (F) content in biotite and bulk concentration of copper (Cu) in corresponding altered rocks (Idrus, 2005). Fig 8 shows a compositional variation of fluorine in biotite and sericite at the Batu Hijau deposit. The F content decrease systematically from inner part of the deposit which is represented by early biotite (potassic) zone where the main copper-gold is hosted, to the outer part of the deposit. However, chlorine in both sericite and biotite from each of the alteration zones shows a relative similar concentration, which suggests that it is not suitable to be used in identification of the alteration zones associated with strong copper- gold mineralization. The latest result has also been observed at other deposits worldwide, for instance, the Casino porphyry deposit, Canada (Selby and Nesbitt, 2000), Dalli porphyry deposit (Ayati et al., 2008), Kahang porphyry deposit, Iran (Afshooni et al., 2013) and Dexing porphyry deposit, SE-China (Bao et al., 2016). In addition, H2O content of the biotite and sericite also exhibits a systematic increase outward which may suggest an increase the role of meteoric water in alteration toward outer part of the deposit (Fig 9). The variation of water content may also provide a possible geochemical exploration tool in vectoring to ore for the copper porphyry deposits. The fluorine content of biotite in rocks and bulk concentration of copper from the corresponding rocks indicates a positive correlation (Fig 10). Copper concentration of the altered-rocks increases with an increase of fluorine content of the biotite in the rocks. The highest fluorine and copper contents occur in the central early biotite (potassic) alteration zone and decrease to the outer alteration zones of the porphyry deposit. The central biotite zone contains relative higher copper (Fig 10) compared to average grade of copper in SW Pacific porphyry deposits (~0.52%) (Titley and Beane, 1981; Cooke et al., 1998; Cooke et al., 2005). 4. Conclusions The high concentration of halogen, particularly fluorine in hydrothermal micas (biotite and sericite) is strongly associated with central ore- bearing biotite (potassic) alteration zones in copper porphyry systems. This may imply the important role of halogen particularly fluorine and chlorine in hydrothermal transportation of copper and gold in form of halogen copper and gold complexes. The fluorine content decreases systematically toward the outer part of the deposit. However, the chlorine content of biotite and sericite shows unsystematic variations crossing those alteration zones, suggesting it is not suitable to be used for vector to ore in exploration. The systematic compositional variation of fluorine and H2O contents in the hydrothermal micas might provide a possible geochemical tool in vector to ore for porphyry copper-gold deposits. 5. Acknowledgements This study was fully facilitated by Institute of Mineralogy and Economic Geology, RWTH Aachen University, Germany. Sincere gratitude goes to Prof. Dr. Franz Michael Meyer and staff members for their discussion and collaboration. The author is also thankful to Newmont Nusa Tenggara which gave permission and facilitated the field works. Thomas Derich as well as Dr. Annemarie Wiechowski and Roman Klinghardt are thankful for sample preparation and assistances for electron microprobe analysis, respectively. Valuable long- distance discussion on sericite chemistry with Professor William T. Parry (University of Utah, USA) was very appreciated. This research project was made possible through financial support from DAAD Germany. REFERENCES Afshooni, S.Z., Mirnejad, H., Esmaeily, D., AsadiHaroni, H., 2013. Mineral chemistry of hydrothermal biotite 38 Idrus A./ JGEET Vol 03 No 01/2018 from the Kahang porphyry copper deposit (NE Isfahan), Central Province of Iran. Ore Geol. Rev. 54, 214 232. Ayati, F., Yavus, F., Noghreyan, M., Haroni, H.A., Yavuz, R., 2008. Chemical characteristics and composition of hydrothermal biotite from the Dalli porphyry copper prospect, Arak, central province of Iran. Mineral. Petrol. 94, 107 122. Bao, B., Webster, J.D., Zhang, D-H., Goldoff, B.A., Zhang, R- Z., 2016. Compositions of biotite, amphibole, apatite and silicate melt inclusions from the Tongchang mine, Dexing porphyry deposit, SE China: Implications for the behavior of halogens in mineralized porphyry systems, Ore Geol. Rev. 79, 443-462. Clode, C., Proffett, J., Mitchell, P., Munajat, I., 1999. Relationships of Intrusion, Wall-Rock Alteration and Mineralisation in the Batu Hijau Copper-Gold Porphyry Deposit. Proceedings Pacrim Congress 1999, Bali-Indonesia, 485-498. Cooke, D.R., Hollings, P., Walshe, J.L., 2005, Giant Porphyry Deposits: Characteristics, Distribution, and Tectonic Controls, Econ. Geol. 100, 801-818. Garwin, S.L., 2002. The Geologic Setting of Intrusion- Related Hydrothermal Systems near the Batu Hijau Porphyry Copper-Gold Deposit, Sumbawa, Indonesia: Global Exploration 2002, Integrated Methods for Discovery, Colorado, USA, Society of Economic Geologists Special Publication 9, p. 333- 366. Gammons, C.H., and Williams-Jones, A.E., 1997. Chemical mobility of gold in the porphyry-epithermal environment: Econ. Geol. 92, 45-59. Gunow, A.J., Ludington, S., Munoz, J.L., 1980. Flourine in micas from the Henderson molybdenite deposit, Colorado. Econ. Geol. 75, 1127-1137. Idrus, A., 2005. Petrology, Geochemistry and Composional Changes of Diagnostic Hydrothermal Mineral Within the Batu Hijau Porphyry Copper- Gold Deposit, Sumbawa Island, Indonesia. Doctor Dissertation, RWTH Aachen University, 352 p. Mitchell, P.A., Proffett, J.M., Dilles, J.H., 1998. Geological review of the Batu Hijau porphyry copper-gold deposit, Sumbawa Island, Indonesia. Unpublished Newmont Nusa Tenggara Company final report, 164 p. Moradi, R., Boomeri, M., Bagheri, S., Nakashima, K., 2016. Mineral chemistry of igneous rocks in the Lar Cu- Mo prospect, southeastern part of Iran: . 25, 418-433. Munoz, J.L., 1984. F-OH and Cl-OH exchange in micas with applications to hydrothermal ore deposits. in Reviews in Mineralogy, Bailey, S.W., eds., 13, 469-494. Munoz, J.L., 1992. Calculation of HF and HCl fugacities from biotite compositions: revised equations. Geological Society of America, Abstract Programs 24, A221. Munoz, J.L., Ludington, S.D., 1974. Flouride-hydroxil exchange in biotite. Am. Jour. Sci. 274, 396-413. Newmont Nusa Tenggara Corp., 2002. First quarter 2002 hydrothermal alteration compilation map of the Batu Hijau deposit. Unpublished internal report. Parry, W.T., Ballantyne, J.M., Jacobs, D.C., 1984. Geochemistry of hydrothermal sericite from Roosevelt Hot Springs and the Tictic and Santa Rita porphyry copper systems. Econ. Geol. 79, 72-86. Parry, W.T., Jacobs, D.C., 1975. Flourine and chlorine in biotite from Basin and Range plutons. Econ. Geol. 70, 554-558. Priowarsono, E., Maryono, A., 2002. Structural relationships and their impact on mining at the Batu Hijau mine, Sumbawa, Indonesia: Prosiding Ikatan Ahli Geologi Indonesia (IAGI), Pertemuan Ilmiah Tahunan ke XXXI, Surabaya, 1-11. Sarjoughian, F., Kananian, A., Ahmadian, J., Murata, M., 2015. Chemical composition of biotite from the Kuh-e Dom pluton, Central Iran: implication for granitoid magmatism and related Cu Au mineralization, Arab J Geosci. 8, 1521 1533. Selby, D., Nesbitt, B.E., 2000. Chemical composition of biotite from the Casino porphyry Cu-Au-Mo mineralisation, Yukon, Canada: evaluation of magmatic and hydrothermal fluid chemistry. Chem. Geol., 171, 77-93. Shinohara, H., 1994. Exsolution of immiscible vaper and liquid phases from a crystallizing silicate melt: Implications for chlorine and metal transport: Geochim. et Cosmochim. Acta, 58, 5215-5221. Siahcheshm, K., Calagari, A.A., Abedini, A., Lentz, D.R., 2012. Halogen signatures of biotites from the Maher-Abad porphyry copper deposit, Iran: characterization of volatiles in syn- to post- magmatic hydrothermal uids. Int. Geol. Rev. 54, 1353 1368. Titley, S.R., Beane, R.E., 1981. Porphyry copper deposits; Part I, Geologic settings, petrology and tectogenesis, in Skinner, B.J., eds., Econ. Geol. 75 th anniversary volume, 214-235. Zhang, W., Lentz, D.R., Thorne, K.G., McFarlane, C., 2016. Geochemical characteristics of biotite from felsic intrusive rocks around the Sisson Brook W Mo Cu deposit, west-central New Brunswick: An indicator of halogen and oxygen fugacity of magmatic systems, Ore Geol. Rev. 77, 82 96. Zhu, C., Sverjersky, D.A., 1991. Partitioning of F-Cl-OH between minerals and hydrothermal fluids. Geochim. et Cosmochim. Acta, 55, 1837-1858. Zhu, C., Sverjersky, D.A., 1992. Partitioning of F-Cl-OH between biotite and apatite. Geochim.et Cosmochim. Acta, 56, 3435-3467. http://www.sciencedirect.com/science/journal/01691368 1. Introduction 2. Analytical Methods 3. Results and Discussion 3.1 Biotite petrography 3.2 Sericite petrography 3.3 Biotite and sericite chemistry 3.4 F-OH exchange of biotite-sericite pairs 3.5 Variation in halogen fugacity ratios 3.6 Halogen chemistry used for vector to ore 4. Conclusions 5. Acknowledgements REFERENCES