Geology And The Correlation Between Geological Control And Nickel Quality In Gag Island, Raja Ampat Islands, West Papua

Bambang Kuncoro Prasongko, Agus Harjanto, Muhammad Ghifary Askaria

Abstract


The geology of Gag Island, Raja Ampat Islands, West Papua Province is composed of volcanic rocks and ultramafic rocks as carriers of laterite nickel deposits (Supriatna, et al. 1995). The research was conducted by surface mapping supported by drill data, and drill geochemical data. Data collection by surface mapping aims to determine the relationship of geological control to the quality of laterite nickel. The characteristics of laterite nickel deposits are influenced by geological factors in the form of lithology, topography, Drainage drainage, tectonics, and geological structures (Elias, 2002), so that geological control of the quality of laterite nickel deposits needs to be studied further.

The research area found 3 rock units in the form of peridotite unit (harzburgite), serpentinite unit, and alluvial deposit unit. The data shows that the highest nickel content is in peridotite (harzburgite) units. In addition, the shape of the land based on the geomorphological aspect shows that in the form of weak wavy hills, laterite deposits are quite well developed and thick. The landform is supported by a relatively sloping slope (0-8 o ) with an undulating morphology and a dendritic Drainage pattern with a content of > 1.5% Ni and a thickness of 9-16 meters, while levels of < 1.5% Ni reach a thickness of 5-22 meters. The geological structure in the morphology is only found in the form of paired joints and filled joints. These joints become an important component in the process of garnierite mineralization as a carrier of Ni.

Keywords


geomorphology, grade, lithology, nickel laterite, Drainage pattern

Full Text:

PDF

References


Ali Jason R, Hall Robert. 1995. Evolution of The Boundary Between The Philippine Sea Plate And Australia: Paleomagnetic Evidence From Eastern Indonesia. Techtonophysics 251 (1995) 251-275.

Anbiyak Nur, Cahyaningrum Tyas. 2020. Identification of Cobalt Rich Zones in Laterite Nickel Deposits in Indonesia . Indonesian Mining Professionals Journal, Volume 2, Number 2, November 2020 : 103 – 110.

Butt, C. Cluzel, D. 2013. Nickel Laterite Ore Deposits: Weathered Serpentinits. Article in Elements , April 2013.

Charlton TR, Hall Robert, Partoyo E. 1991. The Geology and Tectonic Evolution of Waigeo Island, NE Indonesia. Journal of Southeast Asian Earth Science , Vol.6, No.3/4, pp.289-297, 1991.

Cox, DP and Singer, DA 1986: The Mineral Deposit Model . USGS. United States.

Edwards, R. and Atkinson, K. 1986: Ore Deposit Geology and Its Influence on Mineral Exploration, London-New York. Chapman and Hall.

Ministry of Energy and Resources Mineral Power . 2020. Opportunity Investation Indonesian Nickel . Ministry of Energy and Resources Mineral Resources of the Republic of Indonesia.

Golightly, JP 2010. Progress in Understanding the Evolution of Nickel Laterites . Society of Economic Geologists Special Publication, v. 15.

Howard AD 1967. Drainage Analysis In Geologic Interpretation: A Summation. The American Association of Petroleum Geologists Bulletin . V.51, No.11 (November 1967), P. 2246-2259. 4 Figs., 1 Table.

Huggett, R. 2007. Fundamentals of Geomorphology Second Edition, Routledge. London.

Ilyas Asran, Koki Kashiwaya, Koike Katsuaki. 2016. Ni grade distribution in laterite characterized from geostatistics , topography and the paleo-groundwater system in Sorowako , Indonesia. Journal of Geochemical Exploration . doi : 10.1016/j.gexplo.2016.03.002.

Ilyas Asran, Koike Katsuaki. 2012. Geostatistical Modeling of Ore Grade Distribution from Geomorphic Characterization in a Laterite Nickel Deposit. Natural Resources Research, Vol. 21, No. 2, June 2012.

Marsh Erin, Anderson Eric, Gray Floyd. 2010. Nickel-Cobalt Laterites A Deposit Model . Virginia. USGS.

Milsom J, Parson L, Masson D, Nichols G, Sikumbang N, Dwiyanto B. 1996. Tectonic of The Palau – Halmahera – Waigeo Triangle. AAPG Bulletin; Circum-Pacific Council for Energy and Mineral Resources 2009.

Parvis Merle. 1950. Drainage Pattern Significance in Airphoto Identification of Soils and Bedrock. Highway Research Board .

Indonesian Mineral Reserve Committee. 2011. Indonesian Exploration Results Reporting Code, Mineral Resources and Ore Reserves; Code-KCMI 2011. PERHAPI and IAGI.

Revuelta MB 2018. Mineral Resources From Exploration to Sustainability Assessment. Spanish. Springer .

Sam Permanadewi , Joko Wahyudiono , Armin Tampubolon . 2017. Laterite Nickel Deposits on Gag Island, Raja Ampat Regency, West Papua Province. Geological Resources Bulletin Volume 12 Number 1 - 2017 : 55 – 70.

Supriatna , S., Hakim AS and Apandi , T. (1995), Geological Map of Waigeo Sheet , Irian Jaya, Research and Development Center Geology , Bandung.

USGS. 2011. Ni-Co Laterites – A Deposit Model. US Geological Survey, Reston, Virginia.

Van Zuidam , RA (1983). Guide to Geomorphology Aerial Photographic Interpretation and Mapping . ITC, Enschede, The Netherlands, 324 pp.

Verstappen, HT (1983). Applied Geomorphology, Geomorphological Surveys for Environmental Development. Amsterdam: Elsevier, 437 pp.

Waheed, A. 2018. Nickel Laterite : Fundamentals Of Chemistry, Mineralogy Weathering Processes, Formation And Exploration . Sorowako.

Zhengwei Zhang, Shu Qiao, Yang Xiaoyong, Wu Chengquan, Zheng Chaofei, Xu Jinhong. 2019. Review on The Tectonic Terraces Associated With Metallogenic Zone in Southeast Asia. Journal of Earth Science, Vol. 30, No.1, P 1-9, February 2019. https://doi.org/ 10.1007/s1258 3-019-0858-0.


Refbacks

  • There are currently no refbacks.



Creative Commons License
Techno LPPM by http://jurnal.upnyk.ac.id/index.php/teknoslppm is licensed under a Creative Commons Attribution-ShareAlike 4.0 International License.
View My Stats
slot gacor slot