The Shwebontha Prospect area is one of prominent epithermal Au-Ag prospects in Monywa mining district, central Myanmar, characterized by the appearance of gold-bearing and base metal quartz veins with gold grade is around 3g/t -10.4g/t. The geology of the area consists of the volcanic and volcaniclastic rocks of Upper Oligocene-Middle Miocene Magyigon Formation that served as the host rock of the ore mineralization. This research focused on fluid inclusion study is aimed to know the characteristics of hydrothermal fluids during ore mineralization as well as the possible paleo- depth and temperature of formation of gold-bearing and base metal quartz veins. The mineralization styles are gold-bearing brecciated quartz veins and chalcedonic quartz veins where sulfides are clustered as well as disseminated both in quartz gangue and volcanic host rocks. Those quartz veins include pyrite, sphalerite, galena, chalcopyrite and gold (electrum). Fluid inclusion microthermometry indicates that the ore mineralization is characterized by the values of homogenization temperature range from 158°C to 310°C and salinities range from 0.35 to 2.41wt.% NaCl equiv. This temperature is consistent with the formation temperature of 250°C to 270 °C and also their estimate paleo-depth of formation is between 440m and 640m respectively. Microthermometric data indicates that fluid mixing and dilution were significant processes during ore mineralization and evolution of hydrothermal fluids. Based on the petrography of fluid inclusion, microthermometric measurements and ore minerals assemblage as well as estimation of paleo-depth from the Shwebontha Prospect imply that forming in under shallow level epithermal environment

Barber, C.T. (1936) The Tertiary igneous rocks of the Pakokku District and the Salingyi Township of the Lower Chindwin District, Burma, with special reference to the determination of the feldspar by the Federov Method. Memoirs Geological Survey of India, 68: 121–292.

Bodnar, R. J., Burnham, C. W., and Sterner, S.M. (1985) Synthetic fluid inclusions in natural quartz. III. Determination of phase equilibrium properties in the system H2O-NaCl to 1000?C and 1500 bars, Geochim. Cosmochim. Acta. 49(9): 18611873.

Gardiner, N.J., Searle, M.P., and Robb, L.J. (2015) Neo-Tethyan magmatism and metallogeny in Myanmar – an Andean Analogue? Asian Journal of Earth Sciences. 106, 197–215.

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

Htet, W.T. (2008) Volcanic-hosted gold-silver mineralization in the Monywa mining district, central Myanmar phd.dissteration, Mandalay University.

Kirwin, D. (1994) Technical assessment of the Monywa porphyry copper district, Mandalay province, Union of Myanmar. Vol. 1, 2, 3.

Knight, J., Zaw. K. (2015) The geochemical and geochronological framework of the Monywa high sulphidation Cu and low sulphidation Au-epithermal deposits, Myanmar. Poster No. 104 presented at the SEG 2015 Conference, September, Hobart, Tasmania, Australia. 27–30

Leach. T., Hawkw. M., Corlett. G., Simpson. M and Merchant. R. (1996) Petrographic studies of samples from the Kaukmyet, Nache taung and Shwebontha prospects, Myanmar.

Lee, H.Y., Chung, S.L., and Yang, H.M. (2016) Late Cenozoic Volcanism in Central Myanmar: Geochemical Characteristics and Geodynamic Significance. Lithos. 245: 174–2190.

Mitchell, A. H. G., Htay, M. T., Htun, K. M., Win, M.N., Oo, T., and Hlaing, T. (2007) Rock Relationships in the Mogok Metamorphic Belt, Tatkon to Mandalay, Central Myanmar. Journal of Asian Earth Sciences. 29: 891910.

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

Mitchell, A., Chung, S.L., Oo, T., Lin, T.H., and 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.

Oo.T.N., Harijoko, A., and Setijadji, L. D. (2019) Hydrothermal alteration and epithermal gold mineralization system in the Shwebontha Prospect, Monywa district, Central Myanmar. The tenth international conference on science and engineering. 252–2256.

Roedder, E. (1984) Fluid inclusions. Mineralogical Society of America. Reviews in Mineralogy. 2: 644.

Searle, M.P., Noble, S.R., Cottle, J.M., Waters, D.J., Mitchell, A.H.G., Hlaing, T., and 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, TC2083.

Shepherd, T.J., Ranbin, A.H., and Alderton, D.H.M. (1985) In: A Practical Guide to Fluid Inclusion Studies. Blackie, Glasgow. 223.

Sillitoe, R.H., Hedenquist, J.W. (2003) Linkages between volcanotectonic settings, ore fluid compositions, and epithermal precious metal deposits: Society of Economic Geologists Special Publication. 10: 315–343.

United Nations, (1979a) Geology and Exploration Geochemistry of the Salingyi-Shinmataung area, central Burma, Technical Report No. 5. Geological Survey and Exploration Project, United Nations Development Programme, DP/UN/BUR-72- 002/14, United Nations, New York. 29.

Wilkinson, J. J. (2001) Fluid inclusions in hydrothermal ore deposits. Elsevier Science, Lithos. 55: 229–272.

Win, K., Kirwin, D. (1998) Exploration, geology and mineralization of the Monywa copper deposits, Central Myanmar, In: Porphyry and Hydrothermal Copper and Gold Deposits: A Global Perspective. Proceedings of the Australian Mineral Foundation Conference, Perth, 61–74.

Zaw, K. (1990) Geological, petrological and geochemical characteristics of granitoid rocks in Burma: with special reference to the associated W-Sn mineralization and their tectonic setting. Jour. South East Asian Earth Sciences. 4(4): 293–2335.

Zaw, K., Swe. M., Myint, T.A., and Knight. J. (2017) Copper deposits of Myanmar, In: A.J, Barber, K. Zaw, M.J, Crow, Eds., Myanmar: Geology, Resources and Tectonics, the Geological Society (London) Memoir, 48: 573–588.