The Mallina Basin in Western Australia, situated in the central part of the Pilbara Craton which is one of the world's oldest cratons, is a structurally deposited basin subjected to multiple episodes of deformation and magmatic intrusion. The Calvert gold deposit in Mallina Basin is heavily covered by Quaternary, thus, it is hardly to identify any distinct mineralization indicators, and there is no any significant progress in exploration so far. The SQ-3C dual frequency induced polarization facility that is developed by China is introduced to carry out the dual frequency IP survey, the author’s team have tested all the types of different rock samples to collect the geophysical parameters in the Calvert area, and the selection of suitable facility and working frequency is based on the geological characters of the Calvert deposit and the geophysical parameters of rocks, and some processes are undertaken to weaken the interference triggered by the electromagnetic coupling, and an IP anomaly zone was delineated. Through the drilling program in the IP anomaly zone, a gold ore body that has the same orientation with the IP anomaly zone was controlled; this result demonstrated the dual frequency IP survey is effective in the local area and provide an efficient technical method for the mineralization prospecting, and this geophysical survey project sets an example for the familiar type of gold deposit in the local area.
Published in | Earth Sciences (Volume 13, Issue 2) |
DOI | 10.11648/j.earth.20241302.11 |
Page(s) | 49-57 |
Creative Commons |
This is an Open Access article, distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution and reproduction in any medium or format, provided the original work is properly cited. |
Copyright |
Copyright © The Author(s), 2024. Published by Science Publishing Group |
Dual Frequency Induced Polarization, Australia, Calvert Gold Deposit
Lithology | Samples (Pieces) | Amplitude-Frequency (%) | Amplitude-Frequency Arithmetic mean | Resistivity (Ω·m) | Resistivity Arithmetic mean |
---|---|---|---|---|---|
Pyrites-quartz sandstone | 18 | 2.4~4.5 | 3.38 | 65~390 | 210 |
Pyrites shale | 20 | 2.6~8.4 | 4.42 | 26~350 | 192 |
Siltstone | 4 | 1~1.6 | 1.33 | 15~140 | 83 |
sale | 50 | 1.3~3.2 | 2.07 | 32~210 | 125 |
wacke | 66 | 0.7~2.4 | 1.57 | 19~120 | 75 |
Granite complex | 10 | 1.2~4.1 | 2.75 | 165~870 | 470 |
Ore Type | Lithology Description | Au Grade (ppm) | Amplitude-Frequency (Fs) |
---|---|---|---|
Quartz Veins | Pyrites 2%~3%, minor shale | 0.69 | 1.23 |
Quartz Veins | minor shale | ||
Quartz Veins | Quartz veins 50%, shale 50% | ||
Wacke | Quartz veins 5% | 1 | 3.30 |
Wacke | Minor shale, Quartz veins 5% | ||
Shale | Few carbonate veins, strongly deformed, pyrites 5% | ||
Quartz Veins | Quartz veins 95% | 1.28 | 1.60 |
Quartz Veins | Quartz veins 60%, shale 40% | ||
Quartz Veins | Minor shale breccia, fine pyrites 5% | ||
Shale | Quartz veins 60%, fractured | 1.86 | 2.60 |
Shale | Few carbonate veins, strongly deformed, pyrites 5% | 2.59 | 3.65 |
Shale | Quartz veins 5%~8%, massive pyrites 5% | 3 | 4.40 |
Shale + Quartz Veins | Porphyry breccia in the quartz veins | ||
Shale | Fractured, quartz-carbonate veins 30%, pyrites 1%~2% | ||
Shale + Quartz Veins | Shale breccia in the quartz veins | 3.6 | 3.14 |
Shale + Quartz Veins | Shale breccia in the quartz veins, pyrites 8% | ||
Quartz Veins | Quartz veins in the shale, fractured | ||
Quartz Veins | Minor pyrophyllitization, | ||
Shale | Quartz veins 5% | ||
Siltstone | Shale 30%, quartz veins 15%, siltstone 55% | 4 | 3.53 |
Shale+Siltstone | Massive pyrites 7-8% |
4.1. Field Work Arrangement
4.2. Selection of Work Devices
4.3. Selection of Work Frequency Bands
4.4. Measures to Reduce Electromagnetic Coupling Effects
5.1. Electrokinetic Anomaly Characteristics
5.2. Drilling Verification Results
[1] | Huston D L, Smithies R H, Sun S-S. Correlation of the Archaean Mallina-Whim Creek Basin: Implications for base-metal potential of the central part of the Pilbara granite-greenstone terrane. Australian Journal of Earth Sciences, 2001, 47(2): 217-230. |
[2] | Jaques A L, Subhash Jaireth, John Walshe. Mineral systems of Australia: An overview of resources settings and processes. Australian Journal of Earth Sciences, 2002, 49(4): 623-660. |
[3] | Liu J X, Liu C M, Tong T G, Liu H F. The application of the dual frequency induced polarization method in a copper and polymetallic ore deposit in Tibet. Geology and Exploration, 2004, 40(2): 59-61. |
[4] | Zhou Y M. Application effects of geophysical prospecting method for hidden deposits in the northeastern yunnan. Geology and Exploration, 2006, 42(3): 81-85. |
[5] | Wu W, Zhang B L, Liang G H, Li Z Y, Shen X L, Qi M. Application of dual—frequency IP method in metal ore prediction in two types of typical overburden areas in Western China. Geology and Exploration, 2009, 45(6): 669-675. |
[6] | Dai Q W, Zhang B, Feng D S, Chen D P, Yu K. Integrated detection of leakage paths in reservoirs by the pseudorandom flow—field method and dual frequency induced polarization method. Progress in Geophysics, 2010, 25(4): 1453-1458. |
[7] |
Yang L G, Liu J S, Yin L J, Liu W M, Liu W H, Guo J. Application of the dual— frequency IP method to rapid prospecting of mineral resources in the Lizi area of Gansu Province. Geology and Exploration, 2013, 49(2): 330-336.
http://www.dzykt.com/dzyktcn/ch/reader/view_abstract.aspx?file_no=20130215&flag=1 |
[8] | Yang Z W, Yan J Y, Chen X B. The application of spectral induced polarization in Shaxi porphyry copper in Anhui Province. Progress in Geophysics, 2013, 28(4): 2014-2023. |
[9] | Li H W, Bai J, Huang X. Application of electrical survey on a porphyry copper deposit exploration area of Gongbogyamda County, Tibet. Geoscience, 2014, 28(4): 850-858. |
[10] | Li J L. Application of the down—hole IP method to a general survey in the Jinya gold deposit. Geology and Exploration, 2016, 52(5): 924-930. |
[11] | Huston D L, Blewett R S. Lode Gold and Epithermal Deposits of the Mallina Basin, North Pilbara Terrain, Western Australia. Economic Geology, 2002. 97, 801-818. |
[12] | Barley M E. The tectonic and metallogenic evolution of the Pilbara Craton: preface. Precambrian Research, 1998. 88: 1-2. |
[13] | Collins W J, Van Kranendonk M J, Teyssier C. Partial convective overturn of Archaean crust in the east Pilbara Craton, Western Australia: Driving mechanisms and tectonic implications. Journal of Structural Geology, 1998. 20(9): 1405-1424. |
[14] | Nelson D R, Trendall A F, Altermann W. Chronological correlations between the Pilbara and Kaapvaal cratons. Precambrian Research, 1999. 97(s3-4): 165-189. |
[15] | Hickman H. Two contrasting granite-greenstone terranes in the Pilbara Craton, Australia: Evidence for vertical and horizontal tectonic regimes prior to 2900 Ma. Precambrian Research, 2004.131(3): 153-172. |
[16] | Blewett R S. Archaean tectonic processes: a case for horizontal shortening in the North Pilbara Granite-Greenstone Terrane, Western Australia. Precambrian Research, 2002. 113: 87-120. |
[17] | Smithies R H, Nelson D R, Pike G. Development of the Archaean Mallina Basina, Plibara Craton, northwestern Australia; a study of detrital and inherited zircon ages. Sedimentary Geology, 2001. 141-142: 79-94. |
[18] | Smithies R H, Champion D C, Sun S S. Evidence for Early LREE-enriched Mantle Source Regions: Diverse Magmas from the c. 3.0Ga Mallina Basin, Pilbara Craton, NW Australia. Journal of Petrology, 2004. 45: 1515-1537. |
[19] | Cui Y A, Ji T X, Li X Y, Zhu X X. Inversion of multi—anomalies in resistivity profiling based on particle swarm optimization. Progress in Geophysics, 2013, 28(4): 2164-2170. |
[20] | Bai Y C, Zuo H, Luo W B. Several technique problems in dual-frequency IP method used in reconnaissance survey. Mineral Resources and Geology, 2003, 17(S1): 451-454. |
[21] | Wang H Y, Li T. The application of dual frequency IP method to the exploration of mineral resources in Western Australia. Geophysical and Geochemical Exploration. 2016, 40(5): 923-928. |
[22] |
Zhan K, Zhu B Q. Electromagnetic coupling of ladder device in the frequency domain of uniform earth. Geophysical and Geochemical Exploration, 1981, 5(1): 11-16.
https://www.wutanyuhuatan.com/CN/article/downloadArticleFile.do?attachType=PDF&id=3233 |
[23] | Xiong B, Yu Y C. Numerical calculation and analysis of induction coupling of double frequency IP method. Computing Techniques for Geophysical and Geochemical Exploration, 2009, 31(1): 30-35. |
[24] | Qiang J K, He J S. Algorithm of forward and inversion of dual—frequency induced polarization method on elliptical sphere. J. Cent. South Univ. (Science and Technology), 2007, 38(6): 1199-1205. |
[25] | Wynn J C, Zong K L. Electromagnetic coupling. Geophysical Prospecting, 1977, 25(1): 29-51. |
[26] | Wang L, Yang W, Zou L Z. On Dual— Frequency IP Abnormal Observation in the Intermediate Gradient. Chinese Journal of Engineering Geophysics, 2009, 6(5): 607-611. |
[27] | Wang L, Zou L Z, Yang W. An Exploration Case of IP Gradient Method in a Lead-Zinc Ore in the Middle of Dongchuan. Chinese Journal of Engineering Geophysics. 2009, v. 6(06): 708-711. |
[28] | Yu L, Ma H L, Li D. A Study of Water Tank Modeling Based on Dual-frequency IP Method. Chinese Journal of Engineering Geophysics. 2010, v. 7(03): 307-312. |
[29] | Liu J X, Gong L, Liu H F. Application of Dual-frequency Induced Polarization Method for Water Exploration in Gobi, Xinjiang. Chinese Journal of Engineering Geophysics. 2013, v. 10(06): 745-751. |
[30] | Zhou W, Yuan J L, Ran Z Y. The Application of Dual-frequency IP Method to Surveying Polymetallic Ore Deposits in Yueqiacuo Area of Tibet. Chinese Journal of Engineering Geophysics. 2014, v. 11(01): 12-17. |
[31] | Huang X C, Lin R S, Yu J J. The Application of Dual-frequency IP Sounding to One Geothermal Exploration. Chinese Journal of Engineering Geophysics. 2015, v. 12(04): 455-458. |
[32] | Zhang D S, Yang B N, He S. Application Research of Geophysical Method on Lead-zinc Mine Area in Panshi, Songtao County. Chinese Journal of Engineering Geophysics. 2020, v. 17(04): 447-456. |
APA Style
Liu, Z., Zheng, Y. (2024). The Application of Dual Frequency IP Survey to Identify the Concealed Ore Body in Pilbara Craton, Australia: A Case Study from Calvert Gold Deposit. Earth Sciences, 13(2), 49-57. https://doi.org/10.11648/j.earth.20241302.11
ACS Style
Liu, Z.; Zheng, Y. The Application of Dual Frequency IP Survey to Identify the Concealed Ore Body in Pilbara Craton, Australia: A Case Study from Calvert Gold Deposit. Earth Sci. 2024, 13(2), 49-57. doi: 10.11648/j.earth.20241302.11
AMA Style
Liu Z, Zheng Y. The Application of Dual Frequency IP Survey to Identify the Concealed Ore Body in Pilbara Craton, Australia: A Case Study from Calvert Gold Deposit. Earth Sci. 2024;13(2):49-57. doi: 10.11648/j.earth.20241302.11
@article{10.11648/j.earth.20241302.11, author = {Zhangle Liu and Yawen Zheng}, title = {The Application of Dual Frequency IP Survey to Identify the Concealed Ore Body in Pilbara Craton, Australia: A Case Study from Calvert Gold Deposit }, journal = {Earth Sciences}, volume = {13}, number = {2}, pages = {49-57}, doi = {10.11648/j.earth.20241302.11}, url = {https://doi.org/10.11648/j.earth.20241302.11}, eprint = {https://article.sciencepublishinggroup.com/pdf/10.11648.j.earth.20241302.11}, abstract = {The Mallina Basin in Western Australia, situated in the central part of the Pilbara Craton which is one of the world's oldest cratons, is a structurally deposited basin subjected to multiple episodes of deformation and magmatic intrusion. The Calvert gold deposit in Mallina Basin is heavily covered by Quaternary, thus, it is hardly to identify any distinct mineralization indicators, and there is no any significant progress in exploration so far. The SQ-3C dual frequency induced polarization facility that is developed by China is introduced to carry out the dual frequency IP survey, the author’s team have tested all the types of different rock samples to collect the geophysical parameters in the Calvert area, and the selection of suitable facility and working frequency is based on the geological characters of the Calvert deposit and the geophysical parameters of rocks, and some processes are undertaken to weaken the interference triggered by the electromagnetic coupling, and an IP anomaly zone was delineated. Through the drilling program in the IP anomaly zone, a gold ore body that has the same orientation with the IP anomaly zone was controlled; this result demonstrated the dual frequency IP survey is effective in the local area and provide an efficient technical method for the mineralization prospecting, and this geophysical survey project sets an example for the familiar type of gold deposit in the local area. }, year = {2024} }
TY - JOUR T1 - The Application of Dual Frequency IP Survey to Identify the Concealed Ore Body in Pilbara Craton, Australia: A Case Study from Calvert Gold Deposit AU - Zhangle Liu AU - Yawen Zheng Y1 - 2024/04/02 PY - 2024 N1 - https://doi.org/10.11648/j.earth.20241302.11 DO - 10.11648/j.earth.20241302.11 T2 - Earth Sciences JF - Earth Sciences JO - Earth Sciences SP - 49 EP - 57 PB - Science Publishing Group SN - 2328-5982 UR - https://doi.org/10.11648/j.earth.20241302.11 AB - The Mallina Basin in Western Australia, situated in the central part of the Pilbara Craton which is one of the world's oldest cratons, is a structurally deposited basin subjected to multiple episodes of deformation and magmatic intrusion. The Calvert gold deposit in Mallina Basin is heavily covered by Quaternary, thus, it is hardly to identify any distinct mineralization indicators, and there is no any significant progress in exploration so far. The SQ-3C dual frequency induced polarization facility that is developed by China is introduced to carry out the dual frequency IP survey, the author’s team have tested all the types of different rock samples to collect the geophysical parameters in the Calvert area, and the selection of suitable facility and working frequency is based on the geological characters of the Calvert deposit and the geophysical parameters of rocks, and some processes are undertaken to weaken the interference triggered by the electromagnetic coupling, and an IP anomaly zone was delineated. Through the drilling program in the IP anomaly zone, a gold ore body that has the same orientation with the IP anomaly zone was controlled; this result demonstrated the dual frequency IP survey is effective in the local area and provide an efficient technical method for the mineralization prospecting, and this geophysical survey project sets an example for the familiar type of gold deposit in the local area. VL - 13 IS - 2 ER -