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Journal of Geoscience,  
Engineering, Environment, and Technology 
Vol 6 No 4 2021 

 

248 Oo, T.N. et al./ JGEET Vol 6 No4/2021 

RESEARCH ARTICLE 
 

Fluid Inclusion Study of Epithermal Quartz Veins from the 
Kyaukmyet Prospect, Monywa Copper-Gold Ore Field, Central 

Myanmar 

Toe Naing Oo*1,2, Agung Harijoko1, Lucas Donny Setijadji1 
1Department of Geological Engineering, Faculty of Engineering, Gadjah Mada University, Yogyakarta, Indonesia  

2Department of Geology, West Yangon University, Yangon, Myanmar 
 

* Corresponding author : toenaingoo.geol84@gmail.com 
Tel.: +62-812-289-256-46 
Received: Sept 16, 2021; Accepted: Dec 31, 2021. 
DOI 10.25299/jgeet.2021.6.4.7726 

 
Abstract 

The Kyaukmyet prospect is located near the main ore bodies of the Kyisintaung and Sabetaung high-sulfidation Cu-Au deposits, 
Monywa copper-gold ore field, central Myanmar. Lithologic units in the research area are of mainly rhyolite lava, lapilli tuff and silicified 
sandstone, mudstone and siltstone units of Magyigon Formation which hosted to be polymetallic mineralization. Our field study recorded 
that epithermal quartz veins are hosted largely in rhyolite lava and lapilli tuff units. Those quartz veins show crustiform, banded 
(colloform), lattice bladed texture and comb quartz. The main objectives of the present research in which fluid inclusion studies were 
considered to conduct the nature, characteristics and hydrothermal fluids evolution from the epithermal quartz veins. In this research, 
there are three main types of fluid inclusions are classified according to their phase relationship (1) two-phase liquid-rich inclusions, (2) 
the coexisting liquid-rich and vapor-rich inclusions, and (3) only vapor-rich inclusions. Microthermometric measurements of fluid 
inclusions yielded homogenization temperatures (Th) of 148–282 °C and final ice-melting temperature (Tm)  of -0.2°C to -1.4°C . The value 
of (Tm) are equal to the salinities reaching up 0.35 to 2.07 wt % NaCl equiv. respectively. Estimation formation temperature of the quartz 
veins provide 190°C and 210°C and paleo-depth of formation are estimated to be between 130m and 210m. Petrography of fluid inclusion 
and microthermometric data suggest that fluid boiling as well as mixing processes were likely to be happened during the hydrothermal 
fluid evolution at the Kyaukmyet prospect. According to the characteristics of many parameters including petrography of fluid inclusion, 
microthermometric data, paleo-depth, evidence of quartz vein textures and types of hydrothermal alteration from the Kyaukmyet prospect 
allows to interpret these data to be the low-sulfidation epithermal system. 

 
Keywords: Kyaukmyet, epithermal quartz veins, fluid inclusions, formation temperature, paleo-depth, Monywa copper-gold ore field 
 

 
 
1. Introduction  

The Kyaukmyet prospect is a well-known for a low 
sulfidation (LS) epithermal deposit which situated in the 
western part of Chindwin River (Monywa City), Monywa 
copper-gold ore field, which is belonged to the Wuntho-
Popa magmatic arc (also known as Wuntho Popa arc), 
central Myanmar (Figure 1,2). In general, Monywa copper-
gold ore field is a very foremost epithermal copper-gold 
deposit as recognized by its the second largest deposit in 
the South East mainland Asia and ore containing more than 
7 × 107 tons of Cu and 3 to 10g/t Au (Htet, 2008; A. H. G. 
Mitchell et al., 2011; Zaw, Swe, Myint, & Knight, 2017). The 
prospect area was discovered by Ivanhole Copper Company 
Limited in 1995 during the extensive exploration in the 
search for Cu-Au deposit, Au-Ag deposit and base metals 
mineralization in the Monywa copper-gold ore field. An 
exploration program discovering of copper-gold and 
polymetallic mineralization had been searched by based on 
the detailed on geological and geophysical investigation. 
Geologically, the prospect area is mainly composed of 
rhyolite lava, lapilli tuff and silicified sandstone, mudstone 
and siltstone units (Figure 3). On the basis of field 
investigation, the characteristics and different types of 
epithermal quartz veins observed such as banded 
(colloform) quartz vein, crustiform quartz vein, comb 
quartz and lattice bladed texture in the Kyaukmyet prospect 

is shown in (Figure 4). Those quartz veins are trending 
nearly ENE-WSW direction because of controlling regional 
structure. Htet, (2008) and Naing Oo, Harijoko, & Setijadji, 
(2021)reported that a typical characteristics of quartz vein 
textures as well as minor adularia at Kyaukmyet prospect 
remark on a LS epithermal deposit.  

Previous research has also demonstrated that, in the 
Kyaukmyet prospect area of ore mineralization had 
occurred in veins, filling structurally in weak fractures 
(Htet, 2008). The mineralized veins commonly show 
complex nature of brecciation, banding, vuggy, comb and 
lattice bladed texture. Moreover, mineralization veins are 
found in silicified zone where gold is intimately associated 
with base metals sulfide mineral assemblages along with 
gangue mineral assemblages consisting mainly of quartz, 
adularia, sericite and calcite (Htet, 2008; Naing Oo et al., 
2021). The rhyolite lava as well as lapilli tuff rock units in 
the Kyaukmyet prospect are mainly recognized by distinct 
alteration mineral assemblages and zoning which are 
associated with areas of epithermal gold mineralization. 
Most common hydrothermal alterations in the research 
area are silicic alteration (quartz, adularia, calcite, pyrite), 
argillic alteration (illite, illite/smectite, quartz, sericite, 
chlorite) and propylitic alteration (chlorite, epidote, quartz 
pyrite) (Htet, 2008; Naing Oo et al., 2021). This paper aims 
to emphasize study on fluid inclusion of epithermal quartz 

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Oo, T.N. et al./ JGEET Vol 6 No4/2021 249 

 

veins from the Kyaukmyet prospect especially to determine 
the formation temperature, trapping pressure, paleo-depth, 
density and to identify the characteristics of hydrothermal 
fluid condition.  

2. Geologic Setting 

Myanmar is situated in mainland of Southeast Asia and 
prosperous in mineral resources and a very complex 
tectonic region which lie in the eastern boundary of India-
Asia collision zone and characterized by a well-known right 
lateral movement of Sagaing Fault. A. H.G. Mitchell et al., 
(2007), Searle et al., (2007) and Lee, Chung, & Yang, (2016) 
reported that they are tectonically connected to the eastern 
tip of Alpine Himalayan to the north as well as the Andaman 
Sea to the south (Figure 1). Based on the tectonic events, 
Myanmar can be classified into two distinct tectonic 
provinces including the eastern province as well as the 
western province (Liu et al., 2016). The eastern part is made 
up of the Mogok Mandalay Mergui Belt and the Shan Plateau 
whereas the western part is composed of the Wuntho-Popa 
magmatic arc and the Indo-Myanmar Ranges (Figure 1). In 
general, a N-S trending of the Wuntho-Popa magmatic arc 
has played a prominent geological factor and a very 
important mineral resources in Myanmar. In deep, the 
Wuntho Popa magmatic arc has belonged to different type 
of mineral deposits, such as HS type epithermal copper-gold 
deposit, LS epithermal deposit and Mesothermal gold 
deposit (Htet, 2008; A. H. G. Mitchell et al., 2011; Naing Oo 
et al., 2021; Zaw, 1990; Zaw et al., 2017). Geologically, it is 

characterized by the occurrence of both Mesozoic volcanic 
and intrusive rocks which are widely distributed by 
Cretaceous-Pliocene sedimentary formations. Accordingly, 
the Wuntho Popa magmatic arc is composed dominantly of 
Upper Cretaceous to Tertiary granodioritic intrusive rocks, 
and with minor part of volcanic rocks of Upper Cretaceous 
to Quaternary ages (A. Mitchell, Chung, Oo, Lin, & Hung, 
2012; A. H. G. Mitchell et al., 2011; Zaw et al., 2017).  

The Monywa copper-gold ore field is located within the 
Wuntho Popa magmatic arc, central part of Myanmar (A. H. 
G. Mitchell et al., 2011; Zaw, 1990; Zaw et al., 2017) (Figure 
1). In the Monywa copper-gold ore field, Mesozoic volcanic 
rocks are mainly intruded by Upper Cretaceous age of 
granodiorites (A. H. G. Mitchell et al., 2011). Based on the 
previous research (Htet, 2008; A. H. G. Mitchell et al., 2011), 
the Monywa copper-gold ore field of high-sulfidation (HS) 
copper-gold deposit and low-sulfidation (LS) gold-silver 
deposit in the Monywa copper-gold ore field are spatially 
and temporally related to basement rocks as well as granitic 
intrusions. Meanwhile, the basement rocks are widely 
spread out by volcanic rocks such as andesite, quartz 
andesite porphyry, dacite, and rhyolite (Figure 2). Most 
copper-gold (high-sulfidation type) and gold-silver (low-
sulfidation type) deposits between the Chindwin River and 
Powintaung are mainly formed by the Late Oligocene to 
Middle Miocene Magyigon Formation as well as porphyry 
intrusions (Figure 2).  

 

Fig 1. Simplified geological map of Myanmar illustrating outline of Wuntho Popa magmatic arc, principal tectonic units and major 
Quaternary calc-alkaline volcanoes (modified after Lee et al., 2016; Searle et al., 2007). 



 
250  Oo, T.N. et al./ JGEET Vol 6 No4/2021 
 

 

Fig 2. Regional geological map of the Monywa copper-gold ore field and the black rectangle is the Kyaukmyet prospect  (Modified after A. 
H. G. Mitchell et al., 2011). 

 

Fig 3. Geological map with distribution of  quartz vein at Kyaukmyet prospect (modified from Htet, 2008). 

3. Sample Preparation and Analytical Methods  

 Fluid inclusion studies have played a crucial method to 
reveal the conditions of hydrothermal ore-forming fluids in 
mineralization system and their origin. In the field study, 
the different types of epithermal quartz vein samples were 
collected systematically from the surface outcrops at 
Kyaukmyet prospect, Monywa copper-gold ore field in 
order to perform for fluid inclusion studies. Representative 
sample selections were carefully determined and 
considered to be intimately associated with ore 
mineralization and clear quartz samples which are 
accessible to recognize as well as elucidate for fluid 
inclusions studies under transmitted light microscope. In 
support of microthermometric analysis, the doubly 
polished thin sections were made from representative 
quartz vein samples in order to conduct for studying of fluid 
inclusion. The thickness of quartz wafers are approximately 
between 100-200µm, depending upon the transparent 
quality of quartz samples. Firstly, these quartz wafers were 
performed by transmitted light microscope in order to 
examine petrography of fluid inclusion where shapes, sizes 
and nature of appearances and phases in the fluid inclusions 

were recorded on the basis of the standard citations of 
(Bodnar, Reynolds, & Kuehn, 1985; Roedder, 1984). 
Subsequently, about 57 primary fluid inclusions from the 
crustiform, and banded (colloform) quartz vein samples 
were measured to get microthermometry data. Applying 
the equations of Bodnar, (1993), the values of salinity were 
considered from the final ice-melting temperature (Tm). 
Fluid inclusions microthermometry was performed 
applying a Linkam TH600 combine heating and cooling 
stages with a range of temperature of -196-600°C and 
reproducibility of ±0.1°C, in Kyushu University, Japan, 
mounted on a Nikon polarizing microscope with Axiovison 
software where reproducibility of temperature is ±0.1°C. 

4. Result 

4.1 Vein Textures 

Vein textures in the Kyaukmyet prospect area can be 
classified into three principal categories i.e. primary, 
recrystallization and replacement textures according to the 
paragenetic as well as textural evidence which support for 
the elucidation of their source as well as environment of 
formation (Morrison, Dong, & Jaireth, 1995).  



 
Oo, T.N. et al./ JGEET Vol 6 No4/2021 251 

 

In this study, the most common occurrence of primary 
textures include comb, banded (colloform) and crustiform 
quartz textures (Figure 4a-e). Replacement texture consists 
of lattice bladed quartz texture (Figure 4f). Crustiform 
texture is noted as a primary texture and characterized by 
distinguishing feature of epithermal veins (Buchanan, 
1981). This texture is commonly observed as symmetric 
relative to the footwall and hanging wall of the vein. The 
crustiform texture in quartz is composed of dominantly 
sequential development of banded quartz with a variety of 
textures including comb, lattice blade, microcrystalline and 
colloform (Figure 4a,b). In general, it is caused as a product 
of fluid conditions whereas two fluids of cooling 
depressurization and isothermal mixing, interaction fluid-
host rocks, and the fluid boiling is the significant processes 
during the evolution of hydrothermal system (Buchanan, 
1981). Otherwise, fluid boiling has produced in the 
hydrothermal fluid system as a result of dropping confining 
pressure. Fournier, Berger, & Bethke, (1985), Roedder, 
(1984), and Bodnar et al., (1985) revealed that banded 
(colloform) texture is represented as a primary texture and 
generally characterized by a distinguishing feature an 
aggregates of chalcedonic in fine rhythmic bands in support 
of silica minerals (Figure 4c,d). It is also recognized by the 
occurrence of asymmetrical with their spherical, botryoidal, 
reniform, or mammillary surfaces indicating towards the 
center of the veins (Figure 4c,d). Comb texture is a primary 
texture and attributes to groups of parallel or subparallel 
euhedral quartz crystals elongated perpendicular to vein 
walls (Figure 4e). It is typically formed from fluid slightly 
supersaturated with quartz, indicating slowly changing or 
very mildly fluctuating of the physical conditions as well as 
chemical nature of the temperature, pressure and pH 
solution throughout crystals growth (Fournier et al., 1985). 
Simmons & Christenson, (1994) stated that lattice bladed 
texture is mainly designated by a product of aggregate of 
platy calcite with considerable interstices each other’s 
(Figure 4f) which results from boiling solution. 

 

Fig. 4. Photographs showing representative epithermal quartz 
veins texture of (a) crustiform quartz vein in mineralization, (b) 

crustiform quartz vein with bladed texture , (c,d) banded 
(colloform) quartz veins in mineralization (e) comb quartz and (f) 
lattice bladed texture from the Kyaukmyet prospect. (Note: figure 

(a) and (c) used for fluid inclusions studies) 

4.2. Petrography of Fluid Inclusion 

On the basis of their time of entrapment relative to the 
formation in the quartz crystals, fluid inclusions were 
identified as not only primary but also secondary in origin 
based on the standard citations of Roedder, (1984) and 
Bodnar et al., (1985). In support of this research, a total of 6 
quartz vein samples from two different quartz veins 
crustiform and banded (colloform) were conducted for fluid 
inclusion studies. Initially, quartz wafers of crustiform and 
banded (colloform) quartz vein samples were analyzed 
under transmitted light microscope in order to identify 
petrography of fluid inclusion. This analyzing comprises 
studying on sizes, shapes, mode of appearances and fluid 
inclusions types respectively. Most of primary fluid 
inclusions occur as a variety of shapes including sub-
rounded, negative crystal shapes and irregular shapes that 
are typically ranging from 5µm to a maximum 20µm and 
most inclusions were approximately 20µm across. A total of 
57 representative primary fluid inclusions were identified 
and measured from the crustiform and banded (colloform) 
quartz vein samples. Secondary fluid inclusions were also 
present from the samples along with primary inclusions. 
They were also less common and their sizes were generally 
less than 5 µm. Microthermometric data from the secondary 
fluid inclusions were not deplorable. 

According to their phase relations as well as their 
behavior during freezing and heating experiments, there 
are three main types of fluid inclusions are distinguished at 
Kyaukmyet prospect: (1) two-phase liquid-rich inclusions, 
(2) the coexisting of two-phase liquid-rich and vapor-rich 
inclusions and (3) only vapor-rich inclusions (Figure 5). In 
general, the liquid to vapor ratios at room temperature 
occur as liquid rich (10-30% vapor phase) and vapor rich 
(60-90% vapor phase) by volume (optical estimation). On 
the other hand, the coexistence of two-phase liquid-rich and 
vapor-rich fluid inclusions are point out that epithermal 
quartz vein samples are considered to be fluid boiling or or 
immiscible fluid system (Bodnar et al., 1985) (Figure 5b). 

 

Fig. 5. Photomicrographs of (a) two-phase liquid-rich inclusions, 
(b) coexisting liquid-rich and vapor-rich inclusions, and (c) only 

vapor-rich inclusions in crustiform and banded (colloform) quartz  
vein samples at Kyaukmyet prospect. 

5. Discussion 

The fluid inclusion study has played a crucial role to 
know the estimating the temperature of homogenization 



 
252  Oo, T.N. et al./ JGEET Vol 6 No4/2021 
 

and final ice-melting temperature. In support of this 
research, typical primary two-phase liquid-rich and vapor- 
rich fluid inclusions from the crustiform and banded 
(colloform) quartz vein samples were systematically 
prepared and selected to carry out for microthemometric 
measurements. Fluid inclusions microthermometric 
analysis was undertaken on all 57 primary fluid inclusions 
from 6 samples of quartz veins and 2 quartz vein samples of 
crustiform and banded (colloform) quartz veins. Those two 
different quartz veins were measured to conduct for 
homogenization temperature (Th) and final ice-melting 
temperature (Tm). According to the fluid inclusions data, 
the homogenization temperature of primary fluid 
inclusions is 165-279°C (mean of 222°C) for crustiform 
quartz vein and 148-282°C (mean of 215°C) for banded 
(colloform) quartz vein respectively. Frequency 
distributions of homogenization temperature (Th) of two 
different quartz veins (Figure 6a and 6b) display that the 
mode of homogenization temperature of primary fluid 
inclusions give  between 180-200°C for crustiform quartz 
vein and 200-220°C for banded (colloform) quartz vein 
respectively. The results of final ice melting temperatures in 
those vein samples from the Kyaukmyet area are varied 
from -0.2°C to -1.2°C (mean of -0.7°C). The apparent fluid 
inclusion salinities were interpreted based on the final ice-
melting temperature and by using Bodnar’s equation 
(1993) where salinities value is ranged from 0.35 to 2.07 
wt.% NaCl equiv. (mean of 1.2 wt.% NaCl equiv.). In fact, 
salinity and homogenization temperature has played a 
crucial role to estimate the formation temperature, 
pressure of trapping, paleo-depth, fluid evolution processes 
(boiling, mixing and dilution) and mineral deposit types. 

Wilkinson, (2001) stated that a plot diagram of 
homogenization temperature (Th) and salinity of fluid 
inclusions was considered to classify the type of deposits. 
The results of this study, low homogenization temperature 
(Th) and low salinity values suggest that a plot of these fluid 
inclusions microthermometric data from the Kyaukmyet 
prospect is considered to be consistent with epithermal 
deposit field (Figure 7). Meanwhile, from Th versus salinity 
diagram, fluid inclusion densities of the Kyaukmyet area are 
typically ranged from 0.7 to 0.9 gcm-3 (Figure 7). Besides, 
the correlation between fluid inclusions salinity (wt% NaCl 
equiv.) and homogenization temperature (Th) are likely to 
be revealed as a fluid evolution processes, including boiling, 
cooling, and mixing (Wilkinson, 2001). In a correlation 
diagram of Th versus salinity for fluid inclusions in quartz 
veins from the Kyaukmyet prospect is also displayed in 
(Figure 8). From the diagram despite the small data set, it 
can be observed that the occurrence of a broad range 
variation of fluid inclusion salinities and homogenization 
temperature whereas the trend of increasing salinities with 
decreasing temperature.  

Fluid inclusion microthermometric data shows trends 
of increasing salinity with decrease temperature (negative 
direction) indicating that an evidence of boiling condition. 
Salinity variation pointed out boiling or effervescence in the 
system, however important salinity increases might have 
been took place by continuous boiling in the restrained 
fractures (Wilkinson, 2001). On the other hand, fluid mixing 
also could be formed by combination or mixing with more 
or less saline solutions as a result of some fluid inclusions in 
specific temperatures showed their fluid mixing trends in 
figure 8. 

Alternatively, the formation temperatures of quartz 
veins refer to first peak of histograms illustrating the 
primary fluid inclusion of homogenization temperatures  

under the boiling condition (Bodnar et al., 1985). In this 
place, formation temperature of the research area can be 
envisaged that 190°C for crustiform quartz vein and 210°C 
for banded (colloform) quartz vein respectively (Figure 6a 
and 6b). As a consequence, an estimation of formation 
temperature of quartz veins from the microthermometry 
was then interpreted for the paleo-depth of formation, and 
pressure of trapping applying a boiling point curve (Figure 
9) (Haas, 1971). Based on the present results of formation 
temperature, applying the boiling point curve supported by 
(Haas, 1971) likewise considering of 2 wt% NaCl equiv. and 
an estimate for paleo-depth of formation is 130m to 210m 
under the water table in the hydrothermal system which is 
equivalent to the hydrostatic fluid pressure between 12 and 
19 bars respectively (Figure 9). 

 
 

Fig 6. Th histograms of the primary fluid inclusions showing (a) 
banded (colloform) quartz vein and (b) crustiform quartz vein 

from the Kyaukmyet area (n= number of fluid inclusion). 

 

Fig 7. Th vs salinity diagram showing various types of mineral 
deposits (Wilkinson, 2001) and a plot of Kyaukmyet fluid 

inclusions points lie in the epithermal deposit field. 



 
Oo, T.N. et al./ JGEET Vol 6 No4/2021 253 

 

 

Fig 8. Salinity and Th plot diagram of the Kyaukmyet prospect 
epithermal quartz veins illustrating the trend of fluid evolution 

processes (Wilkinson, 2001). 

 

Fig 9. An estimated for paleo-depth of formation of epithermal 
quartz veins from the Kyaukmyet prospect applying the boiling 

point curve with formation temperature and salinity (after Haas, 

1971). 

6. Conclusion 

On the basis of current understanding from the all 
available data including petrography of fluid inclusion as 
well as microthermometric measurements, epithermal 
quartz veins of the Kyaukmyet prospect are belonged to 
typical characters of low salinity as well as low 
homogenization temperature (Th) values. In support of 
fluid inclusion petrography, the coexisting of liquid-rich and 
vapor-rich fluid inclusions as well as only vapor-rich 
inclusions strongly suggested that they were occurred as a 
fluid boiling event in the hydrothermal system of the 
research area. In addition, the occurrence of lattice bladed 
texture, crustiform and banded (colloform) primary quartz 
veins texture that supported again for fluid boiling feature 
observed. The occurrence of wide range variation in fluid 
inclusion salinities and homogenization temperature 
indicated that evidence of fluid boiling condition as well as 
fluid mixing with more or less saline solutions.  Accordingly, 
the primary fluid inclusions in the crustiform and (banded) 

colloform quartz veins possess salinities ranging from 0.35 
wt% to 2.07 wt% NaCl equiv. and homogenization 
temperatures from 148 to 282°C. Plotting these data on the 
salinity versus homogenization temperature diagram 
indicated that the Kyuakmyet epithermal quartz veins 
formed at low salinity as well as low temperature by fluid 
boiling and fluid mixing during the evolution of 
hydrothermal fluid system. In general, low-salinity fluids 
can be generated by the mixing of meteoric water with 
magmatic fluids (Wilkinson, 2001). This suggests that the 
low-salinity (0.35-2.07 wt% NaCl equiv.) of the Kyaukmyet 
epithermal quartz veins are likely to be produced by the 
mixing of a dominant meteoric water with minor amounts 
of magmatic fluid.  

In a subsequent study, a compilation of salinity and 
homogenization temperature, the Kyaukmyet fluid 
inclusions of microthermoetric data is occupied in the 
epithermal deposit field. Furthermore, based on Th and 
salinity data, fluid inclusion densities for the Kyaukmyet 
area are between 0.7-0.9 g/cm3. In contrast, the 
microthermometric data of primary fluid inclusions in the 
crustiform and banded (colloform) quartz veins from the 
Kyaukmyet prospect indicated that an estimation of 
formation temperature provides 190 to 210°C and their 
formation of paleo-depth are estimated at 130m to 210m.  
Pressure of trapping at those depths are between 12 and 19 
bars, respectively. All of these current conducting available 
data from fluid inclusions petrography and 
microthermometric data, formation temperature, an 
estimation of paleo-depth and evidence of quartz vein 
textures, and alteration mineral assemblages, the 
Kyaukmyet prospect is considered to be consistent with a 
low-sulfidation (LS) epithermal system. 

Acknowledgments 

Funding for this paper was supported by the 
AUN/SEED-Net (JICA program). The authors are  
immensely grateful to Prof. Dr. Akira Imai, Assoc. Prof. Dr. 
Kotaro Yonezu and laboratory members from the Kyushu 
University, Japan for their huge support and insightful 
suggestions on the data analysis as well as interpretation. 
The authors also would like to thank the editor and 
anonymous reviewers for their critical reading of the 
manuscript and providing valuable comments and 
suggestions, which greatly improve this paper. 

References 

Bodnar, R. ., Reynolds, T. ., & Kuehn, C. . (1985). Fluid 
inclusion systematics in epithermal systems. Reviews 
in Economic Geology, 2, 73–73. 

Bodnar, R. J. (1993). Revised equation and table for 
determining the freezing point depression of H2O-
NaCl solutions. Geochimica et Cosmochimica Acta, 
57(3), 683–684. 

Buchanan, I. J. (1981). Precious metal deposits associated 
with volcanic environments in the Southwest. In W. 
R. Dickson & W. D. Payne (Eds.), Relations of Tectonics 
to Ore Deposits in the Southern Cordillera: Arizona 
Geological Society Digest (Vol. 14, pp. 237–262). 

Fournier, R. O., Berger, B. R., & Bethke, P. M. (1985). Geology 
and geochemistry of epithermal systems. SOC ECON 
GEOL REV ECON GEOL, 2, 45–62. 

Haas, J. L. (1971). The effect of salinity on the maximum 
thermal gradient of a hydrothermal system at 
hydrostatic pressure. Economic Geology, 66(6), 940–
946. 

Htet, W. T. (2008). Volcanic-hosted gold-silver 



 
254  Oo, T.N. et al./ JGEET Vol 6 No4/2021 
 

mineralization in the Monywa mining district, central 
Myanmar. Mandalay University. 

Lee, H. Y., Chung, S. L., & Yang, H. M. (2016). Late Cenozoic 
volcanism in central Myanmar: Geochemical 
characteristics and geodynamic significance. Lithos, 
245, 174–190. Elsevier. 

Liu, C. Z., Chung, S. L., Wu, F. Y., Zhang, C., Xu, Y., Wang, J. G., 
Chen, Y., et al. (2016). Tethyan suturing in Southeast 
Asia: Zircon U-Pb and Hf-O isotopic constraints from 
Myanmar ophiolites. Geology, 44(4), 311–314. 
Geological Society of America. 

Mitchell, A., Chung, S.-L., Oo, T., Lin, T.-H., & Hung, C.-H. 
(2012). Zircon U–Pb ages in Myanmar: Magmatic–
metamorphic events and the closure of a neo-Tethys 
ocean? Journal of Asian Earth Sciences, 56, 1–23. 
Retrieved from 
https://linkinghub.elsevier.com/retrieve/pii/S1367
91201200185X 

Mitchell, A. H. G., Htay, M. T., Htun, K. M., Win, M. N., Oo, T., & 
Hlaing, T. (2007). Rock relationships in the Mogok 
metamorphic belt, Tatkon to Mandalay, central 
Myanmar. Journal of Asian Earth Sciences, 29(5–6), 
891–910. 

Mitchell, A. H. G., Myint, W., Lynn, K., Htay, M. T., Oo, M., & 
Zaw, T. (2011). Geology of the High Sulfidation 
Copper Deposits, Monywa Mine, Myanmar. Resource 
Geology, 61(1), 1–29. 

Morrison, G. W., Dong, G., & Jaireth, S. (1995). Textural 
Zoning in Epithermal Quartz Veins. Klondike. 
Klondike Exploration Services, Townsville, Australia. 

Naing Oo, T., Harijoko, A., & Setijadji, L. D. (2021). Origin of 

the kyaukmyet low-sulfidation epithermal gold 
prospect, monywa district, central myanmar. Iraqi 
Geological Journal, 54(1), 1–18. Union of Iraqi 
Geoogists. 

Roedder, E. (1984). Volume 12: fluid inclusions. Reviews in 
mineralogy (p. 646). 

Searle, M. P., Noble, S. R., Cottle, J. M., Waters, D. J., Mitchell, 
A. H. G., Hlaing, T., & Horstwood, M. S. A. (2007). 
Tectonic evolution of the Mogok metamorphic belt, 
Burma (Myanmar) constrained by U-Th-Pb dating of 
metamorphic and magmatic rocks. Tectonics, 26(3), 
n/a-n/a. 

Simmons, S. F., & Christenson, B. W. (1994). Origins of 
calcite in a boiling geothermal system. American 
Journal of Science, 294(3), 361–400. 

Wilkinson, J. J. (2001). Fluid inclusions in hydrothermal ore 
deposits. Lithos (Vol. 55). Retrieved from 
www.elsevier.nlrlocaterlithos 

Zaw, K. (1990). Geological, petrogical and geochemical 
characteristics of granitoid rocks in Burma: with 
special reference to the associated WSn 
mineralization and their tectonic setting. Journal of 
Southeast Asian Earth Sciences, 4(4), 293–335. 

Zaw, K., Swe, Y. M., Myint, T. A., & Knight, J. (2017). Copper 
deposits of Myanmar. Geological Society Memoir (Vol. 
48, pp. 573–588). Geological Society of London. 

 
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