E-ISSN : 2541-5794  
   P-ISSN : 2503-216X  

Journal of Geoscience,  
Engineering, Environment, and Technology 
Vol 03 No 01 2018 

 

 
Myaing et al./ JGEET Vol 03 No 01/2018  8 

 

Fluid Inclusion Study of  The Tumpangpitu High Sulfidation 
Epithermal Gold Deposit In Banyuwangi District, East Java, 

Indonesia 

Yu Yu Myaing
 1,2

, Arifudin Idrus 
1,
*, Anastasia Dewi Titisari

1
 

1
Geological Engineering Department, Faculty of Engineering, Universitas Gadjah Mada, Yogyakarta, Indonesia. 

2
Department of Geology, Mandalay University, Mandalay, Myanmar. 

 
*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.2018.3.01.1039 

 
Abstract 

The Tumpangpitu high sulfidation (HS) epithermal gold deposit is located in the south coast of East Java, Banyuwangi 
District, East Java Province, Indonesia. This area lies within the central portion of the Cenozoic Sunda‐Banda magmatic arc 
which trends southeast from northern Sumatra to west Java then eastward through east Java, Bali, Lombok, Sumbawa and 
terminating at Banda sea. The geology of the Tumpangpitu is predominantly occupied by Late Oligocene to Middle Miocene 
low-K calc-alkaline to alkaline andesitic volcanic rocks and interbedded with volcaniclastic rock sequences, which are 
associated with low-K intermediate intrusions. The mineralization style at the Tumpangpitu area is composed of a high‐
sulfidation (HS) epithermal gold-copper system which is typically associated with concealed gold-rich porphyry copper 
system. The HS epithermal mineralization is hosted by volcanic and volcaniclastic rocks in this research area. The 
mineralization domains are divided into Zone A, Zone B and Zone C which are situated along NW-SE-trending silica ledges 
zones. The HS epithermal mineralization is texturally occurs as vuggy replacements mineralization as well as stockworks, 
disseminated forms, fractures and veins. Fluid inclusion study was conducted for 6 quartz vein samples which 
petrographically entrapped fluid inclusions. Homogenization temperature (Th) and melting temperature (Tm) can 
microthermometrically be determined by fluid inclusion analysis. The average homogenization temperature (Th) of the fluid 
inclusions gives 180  to 342 are from -0. -1. . Tm corresponds to the salinities ranging 
from 0.1 to 4.5 wt% NaCl equivalent. The paleodepth of ore formation can be estimated from the salinity of fluid. Since the 
deposit was not formed at boiling condition, the minimum paleodepth of ore (quartz) samples taken from both shallow level 
(53.35 m) and deep level (135.15 m) is determined at 650m and 1,220 m, respectively. The microthermometric data point 
out that the Tumpangpitu deposit formed at moderate temperature and low salinity by magmatic fluid mixing and dilution 
by meteoric water during the hydrothermal fluid evolution. On the basis of the fluid inclusion microthermometric data and 
its other key characteristics, the Tumpangpitu gold mineralization shares some similarities compared to other typical HS-
epithermal gold deposits worlwide although it also shares few differences. 
 
Keywords: Fluid inclusion study, high sulfidation epithermal gold deposit, Tumpangpitu, East Java, Indonesia 

 

 

1. Introduction  

The Tumpangpitu deposit is located in 
Sumberagung village, Banyuwangi Regency, on the 
south-eastern coast of the Java Island, East Java 
Province, Indonesia. It lies about 205 kilometers 
southeast of Surabaya (the capital of East Java), 60 
kilometers southwest of the regional center of 
Banyuwangi and 120 km due west of Denpasar in 
Bali. This research area is within-existing 
infrastructure, with the presence of an active 
world-class operating mine at Batu Hijau on 
Sumbawa and copper-gold smelter at Gresik East 
Java. It is defined as high-sulfidation (HS) 
epithermal Cu-Au-Ag mineralization with a 
concealed porphyry Cu-Au mineralization 
underneath (Maryono et al., 2014).  

Microthermometric results from the fluid 
inclusion study can be used to estimate the 
formation temperature of the deposit and the 
salinity of the hydrothermal fluid. The aim of this 
fluid inclusion study is to understand the physico-
chemical characteristics of the hydrothermal fluids 
which responsible for the formation of the 
Tumpangpitu HS epithermal gold deposit.  

2. Research Methods 

Fluid inclusion study is very important method 
to know the conditions of the hydrothermal fluids 
and their origin. We conducted the fluid inclusion 
study at the Mineral Resource lab, Department of 
Earth Resource Engineering, Kyushu University, 
Japan. For the fluid inclusion study, the four 
selected quartz vein samples were taken from the 
drill core samples crossing the Tumpangpitu 

mailto:arifidrus@ugm.ac.id


 
Myaing et al./ JGEET Vol 03 No 01/2018 9 

 

deposit at the depth of 57.55 meter and the two 
samples are taken from the depth of 135.15 meter 
respectively of the drill hole no 12-003. Firstly, we 
made the double polished thin-section of the 
thickness between 50 
inclusion petrography. Over 130 fluid inclusions 
were measured to get the microthermometric data 
by using Linkam THMSG600 stage. We noted the 
shapes, the sizes, the phases of fluid inclusion, 
homogenization temperature, melting 
temperature of the fluids based on the standard 
citation of Roedder, 1984 and Bodnar et al.,1985. 
We can determine the salinity of fluid inclusion 
from the last ice melting temperature (Tm) by using 
the equation of Bodnar el al.,1983 and Bodnar and 
Vityk, 1994: 

 
Sal. = 0.00 + 1.78 (Tm) - 0.0442 (Tm)

2
 + 0.000557 (Tm)

3
 

 
where: Sal. = Salinity (wt%NaCl equivalent), Tm = 
ice melting temperature ( ). 

 

3. Geological Setting 

3.1 Regional Geology  

This area lies within the central portion of the 
Ceonozoic Sunda‐Banda magmatic arc which 
trends southeast from northern Sumatra to west 
Java then eastward through east Java, Bali, Lombok, 
Sumbawa and terminated at Banda sea. The 
Eastern Sunda Arc is located along the tectonically 
active zone that marks the convergence of three 
major plates: Eurasian, Indo-Australian, and Pacific 
plates (Fig. 1). The western segment of the arc 
(West to East Java) developed on thick continental 
crust on the southern margin of Sundaland, 
whereas the eastern segment (East Java to 
Sumbawa) was constructed on a thinner island arc 
crust bounded by Australian continent crust 

further east (Sumba and Timor) (Maryono et al., 
2014). The Eastern Sunda Arc is located along the 
tectonically active zone that marks the 
convergence of three major plates: Eurasian, Indo-
Australian, and Pacific plates (Fig. 1). The western 
segment of the arc (West to East Java) developed 
on thick continental crust on the southern margin 
of Sundaland, whereas the eastern segment (East 
Java to Sumbawa) was constructed on a thinner 
island arc crust bounded by Australian continent 
crust further east (Sumba and Timor) (Maryono et 
al., 2014). 

The geology of Eastern Sunda arc is mainly 
composed of island arc-type volcano sedimentary 
successions of Oligocene to Quaternary age and 
Igneous rocks of Paleocene-Eocene age (Hellman, 
2011). In east Java the Upper Miocene volcanic 
units are represented by Wuni Formation which is 
widespread at Blitar and Lumajang area (Fig.2). 
Late Oligocene to Middle Miocene magmatic rocks 
are widespread and continuously distribution 
along the whole belt. The volcaniclastic rocks of 
Late Miocene to Pliocene age are more abundant 
than the older volcanic rocks in the southern 
margin of the belt and Low-K calc- alkaline to 
weakly alkaline andesitic volcanic and interbedded 
volcaniclastic rocks, associated low-K intermediate 
intrusions and minor shallow water marine 
sedimentary rocks extend from Java to Bali, 
Lombok and Sumbawa (Macpherson and Hall, 
1999). 

In the Sunda plate, the metallic occurrences are 
abundant and these are associated with 
subduction-related volcanic centers. There are six 
categories of Cu-Au deposits within the arcs: 
porphyry copper-gold, high sulphidation 
epithermal, low sulphidation epithermal, gold-
silver-barite-base metal, skarn, and sediment-
hosted mineralization (Carlile and Mitchell, 1994).

  

 
Fig. 1.  Map of SE Asia highlighting major tectonic plates and plate boundaries (Mapcherson and Hall, 1999) 



 
10  Myaing et al./ JGEET Vol 03 No 01/2018   
 

 

 
Fig. 2.  Regional geological map of the southeast corner of Java and the red rectangle is prospect area (Achdan and Bachri, 

1993) 

 
3.2 Deposit Geology 

The Tumpangpitu area is predominantly 
occupied by Late Oligocene to Middle Miocene 
low-K calc-alkaline to alkaline andesitic volcanic 
and interbedded volcaniclastic rock sequence, 
associated with low-K intermediate intrusions and 
minor shallow water marine sedimentary rocks 
(Harrison, 2012). In the shallow of the 
Tumpangpitu is dominated by epithermal 
environment and in the deeper portion is 
characterized by porphyry system. Fig 3 is 
geological map of Tumpangpitu area. In this 
research, we emphasized only in epithermal 
environment. The typical rock types of this area are 
diorite, volcanic breccia, diatreme breccia, 
hydrothermal breccia and andesitic lava and 
breccia.  

4. Ore Mineralization  

The mineralization at Tumpangpitu is 
composed of an Au‐rich porphyry Cu‐Au‐Mo 
system associated with high‐sulfidation 
epithermal Cu‐Au‐Ag system (Hellman, 2011). The 
HS epithermal mineralization is hosted by volcanic 
and volcaniclastic rocks in the research which 
especially covering 3 domains of mineralization 
consisting of Zone A, Zone B and Zone C. The three 
domains are extended along NW-SE trending silica 
ledges zones (Fig. 4). The mineralization generally 
occurs hosted by lapilli tuffs and vuggy 
replacements mineralization as well as 
stockworks, disseminated forms, arrays of sulfide 
fractures and veins, containing pyrite +/‐ enargite 
+/‐ tetrahedrite‐tennantite +/‐ chalcocite +/‐ 
bornite that occur widely within the more silica‐
rich portions of the silica ledges (Fig 5, 6, 7,8). 
Mineralization generally occurs as vug filling or 
massive replacement within silica ledge zone. The 
dissemination mineralization found in the 
advanced argillic altered rock. In open space or 

fractures, veinlets and some micrro-veinlets 
mineralization can be found in the research area. In 
open space or fractures, veinlets and some micrro-
veinlets mineralization can be found in the 
research area (Fig. 5). Gold mineralization is mainly 
associated with pyrite and enargite mineral and it 
can be found in massive/ vuggy silica zone, 
advanced argillic alteration zone and some are in 
silicic core.  

 

 
Fig. 3.  Geological Map with drill point of the 
Tumpangpitu deposit, Banyuwangi Regency, East Java 
and cross section of the area along A-B (Source from BSI 
Company). 



 
Myaing et al./ JGEET Vol 03 No 01/2018 11 

 

 
Fig. 4. 3D view for Tumpangpitu domains: Zone A- 
mineralized zones dip moderately to the southwest. Zone 
B- mineralized zones strike north‐south and dip steeply 
to the east. Zone C- mineralized zones dip moderately to 
the northeast. Zone E- mineralized zones dip moderately 
to north-south (Source from BSI Company). 

 

 

Fig. 5.  Ore textures: (a) vuggy quartz (b) massive sulfide 

(pyrite) vein texture and (c) small sulfide veinlet 

intercalated with clay. 

 
Fig. 6. Photomicrograph showing Intergrowth of pyrite, 
enargite, luzonite, sphalerite, chalcopyrite, covellite in 
vugs. (Py=pyrite, Eng=enargite, Luz=luzonite, 
Tnt=tennantite, Ccp=chalcopyrite, Sp=sphalerite and 
Cv=covellite 
 

 
Fig. 7.  Photomircograph show (a) euhedral pyrite with 
cracks along the fracture and (b) euhedral-anhedral 
pyrite grains within networks of alunite laths (Py=pyrite, 
Alu=alunite, Eng=enargite and Sp=sphalerite) 
 
 

 
Fig. 8.  Photomircographs of (a) pyrite vein with 
groundmass and (b) quartz and alunite vein with pyrite 
vein (Py=pyrite, Alu=alunite, Qz= quartz). 

5. Fluid Inclusion Study 

5.1 Petrography 

Abundant primary and secondary fluid 
inclusions are found in quartz vein samples taken 
from the deposit. The homogenization 
temperature and melting temperature were 
measured only on the primary inclusions. The sizes 
of fluid inclusion in the quartz phenocrysts 

. The 
morphologies of the fluid inclusions are generally 
spheroidal, elongate, and prismatic forms. Some of 
representative forms of fluid inclusions described 
details in Fig. 11.The two-phase (liquid+vapor) 
fluid inclusion are common. There are two type of 
fluid inclusions consisting of vapor- rich and 
liquid-rich inclusions. The vapor dominated 
inclusions are not common and it contain 5 to 15 
percent of total fluid inclusions.  

 
Fig. 10.  Photographs of some quartz samples associated 

with enargite and pyrite mineralization which has 

inclusions entrapped in quartz.



 
12  Myaing et al./ JGEET Vol 03 No 01/2018   
 

 

 

Fig. 11.Photomicrographs of fluid inclusions petrography: 

(a) the slightly flatted negative crystal form, (b and c) the 

slightly rounded negative crystal form with secondary 

filling in microfracture, (d) the fluid inclusion in cubic 

form ,(e) the oblated tubular form and (f) necking in a 

long tubular inclusion form. 

5.2 Microthermometry 

Fluid inclusion microthermometric data were 

collected from the conducting of the temperature 

of homogenization and melting temperature. We 

conducted the fluid inclusion analysis from the two 

different depths (at 57.55 meter and at 135.15 

meter). Based on the fluid inclusion data, the 

homogenization temperature at 57.55 meter is 

(180 ◦C -340 ◦C) and at the depth of 135.15 meter is 

(230 ◦C -360 ◦C) (Fig. 12).  The distribution of 

homogenization temperatures of fluid inclusions 

(histograms) are shown in Fig 11. According the 

homogenization temperature of histogram, the 

formation temperature of shallow depth is 270 ◦C 

and the deeper is 310 ◦C. The measurement of 

melting temperature of fluid inclusion data is 

range from -0.1 ◦C to -1.4 ◦C. 

5.3 Salinity of hydrothermal fluid 

of fluid inclusion is calculated from the melting 

temperature. The salinity value is range from 0.1 to 

4.5 wt % NaCl equiv and the average salinity is (0.5 

 2 wt.% NaCl eq.) (Fig. 13). Based on the average 

homogenization temperature ranges (270 ºC and 

310 ºC) and the averaging salinity is of 1 wt.% NaCl 

eq. belong to the epithermal system (Wilkinson, 

2001). The salinity variations are controlled by 

fluid mixing. It shows a trend of isothermal mixing 

(Fig 14). Based on the plotting of these data, the 

Tumpangpitu area falls in the epithermal deposit. 
The results for the depths of formation of quartz 

veins from recent depth of 57.55 m (the red line) 

and 135.15 m (the blue line) respectively are 

shown in Fig 15. 

 

Fig.12. Frequency distribution of homogenization 

temperatures (Th) of fluid inclusions study at the depth 

of (a) 57.55 m and (b) 135.15 m. 

 
Fig.13. Frequency distribution of salinity (NaCl wt.% eq..) 

of hydrothermal fluid (a) shallow sample taken at 57.55 

m and (b) the deeper sample at 135.15 m. 

6. Discussion 

Based on the study of the fluid inclusions, the 

Tumpangpitu was not observed for boiling 

evidence. It is possibly related with the isothermal 

fluids mixing and possibly related to surface fluid 

dilution processes (Fig 14). The formation 

temperature can be estimated from the fluid 



 
Myaing et al./ JGEET Vol 03 No 01/2018 13 

 

inclusion microthermometric data and the 

formation depth can be estimated from the boiling 

point curve of Hass, 1971 (Shepherd et al., 1985). 

The formation temperature is plot on the 

temperature axis and the salinity value is plot on 

the curves of salinity (Fig. 15). According to the 

plotting data (Fig. 16), the Tumpangpitu area 

belongs the epithermal environment (cf. Wilkinson, 

2001). 

 

Fig. 14.  Salinity (wt.% NaCl eq..) versus homogenization 

temperatures (Th, ºC) for fluid inclusions of the 

Tumpangpitu deposit. 

 

Fig.15.The formation depth of quartz vein samples from 

the shallow samples (57.55 m blue line) and deep 

samples (135.15 m; red line). 

 

Fig 16. Salinity vs Th illustrating typical ranges for 

inclusions from different types of deposits (Wilkinson, 

2001). The fluid inclusions from the Tumpangpitu area 

fall in the epithermal field.  

7. Conclusion 

In the Tumpangpitu research area, the 
mineralization is hosted by volcanic and 
volcaniclastic rocks and it occurred as vuggy 
replacements mineralization as well as 
stockworks, disseminated forms, fractures and 
veins. By assuming the temperature of 
homogenization is identical to the formation 
temperature, the Tumpangpitu HS epithermal gold 
deposit was formed at temperature between 270◦C 
and 310◦C. The average melting temperature is -0.3 
◦C and -0.7◦C corresponding to the salinity of 
hydrothermal fluid of 0.5 to 2 wt% NaCl equivalent. 
The paleo-depth of both shallow and deep samples 
taken are about 650m and 1220m, respectively (Fig 
15). 

The microthermometric data suggest that the 
Tumpangpitu deposit formed at moderate 
temperature and low salinity by magmatic fluid 
mixing and dilution by meteoric water during the 
hydrothermal fluid evolution. Although the 
Tumpangpitu HS epithermal gold deposit exhibits 
few differences in characteristics, but in general it 
hares some similarities compared to other typical 
HS-epithermal gold deposits worlwide. 

8. Acknowledgements 

We would like to be grateful to the AUN/SEED-
Net (ASEAN University Network Southeast Asia 
Engineering Education Development Network) 
program and JICA (Japanese International 
Cooperation Agency) for financial support. We are 
thankful to PT Bumi Suksesindo (PT. BSI) company 
for their permission and support during fieldwork. 

 

References 

Achdan, A., & Bachri, A., 1993. Peta geologi lembar 
Blambangan, Jawa Timur: Geological map of 
the Blambangan quadrangle, East Java. 
Bandung: Pusat Penelitian dan Pengembangan 
Geologi. 

Bodnar, R.J., 1993. Revised equation and table for 
determining the freezing point depression of 



 
14  Myaing et al./ JGEET Vol 03 No 01/2018   
 

H2O NaCl solutions, Geochimica et 
Cosmochimica Acta 57, 683 684. 

Bodnar, R.J., Reynolds, T.J., and Kuehn, C.A., 1985.  
Fluid inclusion systematics in epithermal 
systems, Reviews in Economic Geology 2, 73
79. 

Bodnar, R. J. and Vityk M.O., 1994. Interpretation of 
microthermometric data for H2O-NaCl fluid 
inclusions. 

Carlile, J.C. and Mitchell, A.H.G., 1994. Magmatic 
arcs and associated gold copper mineralization 
in Indonesia, Journal Geochemical Exploration, 
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Hass, J.L., 1971. The Effect of Salinity on the 
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System at Hydrostatic Pressure, Economic 
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Harrison. R., 2012. Indonesia Basin Summaries, 
North East Java Sea Basin and North East Java 
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SE Asia. Proceedings PACRIM, 99, 359-367. 

Maryono, Setidjaji, L.D., Arif .J., Harrison, R., 
Soeriaatmadja, E., 2014, Gold, Silver, and 
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Roedder, E., 1984. Fluid inclusions, Mineralogical 
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	1. Introduction
	2. Research Methods
	3. Geological Setting
	3.1 Regional Geology
	3.2 Deposit Geology

	4. Ore Mineralization
	5. Fluid Inclusion Study
	5.1 Petrography
	5.2 Microthermometry
	5.3 Salinity of hydrothermal fluid

	6. Discussion
	7. Conclusion
	8. Acknowledgements
	References