Application of TEM Based on HTS SQUID Magnetometer in Deep Geological Structure Exploration in the Baiyun Gold Deposit, NE China

Junjie Wu, Xiaodong Chen, Yi Yang, Qingquan Zhi, Xingchun Wang, Jie Zhang, Xiaohong Deng, Yi Zhao, Yue Huang

Journal of Earth Science ›› 2021, Vol. 32 ›› Issue (1) : 1-7.

Journal of Earth Science ›› 2021, Vol. 32 ›› Issue (1) : 1-7. DOI: 10.1007/s12583-020-1086-3
Article

Application of TEM Based on HTS SQUID Magnetometer in Deep Geological Structure Exploration in the Baiyun Gold Deposit, NE China

Author information +
History +

Abstract

Exploration of deep mineralization, particularly where the mineralization of interest is covered by a conductive overburden, is still a challenge for the conventional transient electromagnetic (TEM) method, which measures TEM response using induction coils as the sensor. However, sensors such as fluxgate and superconductive quantum interfere device (SQUID) magnetometers can measure the B-field directly, which can provide more reliable deep information for mineralization exploration. In this paper, we report on the research and development of our newly developed high-temperature superconductor (HTS) SQUID magnetometer, which is cooled by liquid nitrogen at 77 K, and its application in TEM measurement for deep exploration in a gold deposit in China. This improved SQUID magnetometer version has a good performance with noise (60 fT/$\sqrt {{\rm{Hz}}} $), slew rate (0.8 mT/S), dynamic range (100 dB), sensitivity (6.25 mV/nT), and bandwidth (DC-20 kHz). To find deep and peripheral ore in the Baiyun gold deposit located in Liaoning Province, NE China, both the SQUID magnetometer and induction coil were used for TEM data acquisition. Results show that TEM can detect the distribution of local strata and the faults contained within them. Results also indicate that the SQUID magnetometer has superior response performance for response over geological targets with slower decay time when compared to the induction coil signals. The SQUID magnetometer is more sensitive at observing the induced-polarization effect which is closely related to the ore-controlling faults.

Keywords

TEM / HTS SQUID magnetometer / B-field / deep exploration / the Baiyun gold deposit

Cite this article

EndNote

Ris (Procite)

Bibtex

Download citation ▾
Junjie Wu, Xiaodong Chen, Yi Yang, Qingquan Zhi, Xingchun Wang, Jie Zhang, Xiaohong Deng, Yi Zhao, Yue Huang. Application of TEM Based on HTS SQUID Magnetometer in Deep Geological Structure Exploration in the Baiyun Gold Deposit, NE China. Journal of Earth Science, 2021, 32(1): 1‒7 https://doi.org/10.1007/s12583-020-1086-3

References

Publishing order | Descend order by publishing year | Descend order by cited within
Arai E, Katamama H, Hart J. Application of a New TEM Data Acquisition System Based on a HTS SQUID Magnetometer (SQUI-TEM) to Metal Exploration in Broken Hill Area. ASEG Extended Abstracts, 2007, 2007(1): 1-5.
CrossRef Google scholar
Asten M W, Duncan A C. The Quantitative Advantages of Using B-Field Sensors in Time-Domain EM Measurement for Mineral Exploration and Unexploded Ordnance Search. Geophysics, 2012, 77(4): WB137-WB148.
CrossRef Google scholar
Bick M, Panaitov G, Wolters N, . A HTS rf SQUID Vector Magnetometer for Geophysical Exploration. IEEE Transactions on Appiled Superconductivity, 1999, 9(2): 3780-3785.
CrossRef Google scholar
Chen X D, Zhao Y, Deng X H, . The Development of the HTc SQUID Magnetometer and Its Application to TEM. Geophysical and Geochemical Exploration, 2006, 30(3): 229-232. (in Chinese with English Abstract)
Chen X D, Zhao Y, Lin T L, . The Applications of HTc SQUID Magnetometer to LOTEM. Geophysical and Geochemical Exploration, 2012, 36(1): 65-68. (in Chinese with English Abstract)
Chen X D, Zhao Y, Wang C J, . The Development of HTc RF SQUID Magnetometer and Its Field Test in TEM. Acta Geoscientia Sinica, 2002, 23(2): 179-182. (in Chinese with English Abstract)
Chen X D, Zhao Y, Zhang J, . Influence of Frequency Characteristics of Nonmagnetic Dewar on High Temperature Superconducting Magnetometer. Computing Techniques for Geophysical and Geochemical Exploration, 2007, 29: 292-303. (Suppl)
Chen X D, Zhao Y, Zhang J, . The Applications of HTc SQUID Magnetometer to TEM. Chinese Journal of Geophysics, 2012, 55(2): 702-708. (in Chinese with English Abstract)
Chwala, A., Stolz, R., IJsselsteijn, R., et al., 2010. “JESSY DEEP”: Jena SQUID Systems for Deep Earth Exploration. 80th Annual International Meeting, SEG, Expanded Abstracts. 779–783. https://doi.org/10.1190/1.3513897
Chwala A, Stolz R, Schmelz M, . SQUID Systems for Geophysical Time Domain Electromagnetics (TEM) at IPHT Jena. IEICE Transactions on Electronics, 2015, E98.C(3): 167-173.
CrossRef Google scholar
Di Q Y, Xue G Q, Zeng Q D, . Magnetotelluric Exploration of Deep-Seated Gold Deposits in the Qingchengzi Orefield, Eastern Liaoning (China), Using a SEP System. Ore Geology Reviews, 2020, 122 103501
CrossRef Google scholar
Di Q Y, Zhu R X, Xue G Q, . New Development of the Electromagnetic (EM) Methods for Deep Exploration. Chinese Journal of Geophysics, 2019, 62(6): 2128-2138. (in Chinese with English Abstract)
Foley C P, Leslie K E, Binks R A. A History of the CSIRO’s Development of High Temperature Superconducting Rf SQUIDs for TEM Prospecting.. ASEG Extended Abstracts, 2006, 2006(1): 1-5.
CrossRef Google scholar
Foley C P, Leslie K E, Binks R, . Field Trials Using HTS SQUID Magnetometers for Ground-Based and Airborne Geophysical Applications. IEEE Transactions on Appiled Superconductivity, 1999, 9(2): 3786-3792.
CrossRef Google scholar
Ji Y J, Du S Y, Xie L J, . TEM Measurement in a Low Resistivity Overburden Performed by Using Low Temperature SQUID. Journal of Applied Geophysics, 2016, 135: 243-248.
CrossRef Google scholar
Lang F Q, Chen H, Liu H G. Geologic Characteristics and Ore Prospecting Orientation of Baiyun Gold Deposit in Liaoning Province. Gold, 2007, 28(11): 16-20. (in Chinese with English Abstract)
Le Roux, C., Macnae, J., 2007. SQUID Sensors for EM Systems. Proceedings of Exploration 7: Fifth Decennial International Conference on Mineral Exploration. 417–423
Lee J B, Turner R J, Downey M A, . Experience with SQUID Magnetometers in Airborne TEM Surveying. Exploration Geophysics, 2001, 32(1): 9-13.
CrossRef Google scholar
Li D D, W Y W, Zhang Z C, . Characteristics of Metallotectonics and Ore-Forming Structural Plane in Baiyun Gold Deposit, Liaoning. Journal of Geomechanics, 2019, 25(S1): 10-20.
Liu Y J, Han X T, Liu Z H, . Zircon U-Pb Ages, Geochemical Characteristics and Geological Significance of Early Cretaceous Granites in Fengcheng Area, Eastern Liaoning Province. Earth Science, 2020, 45(1): 145-155. (in Chinese with English Abstract)
Nagendran R, Thanikai Arasu A V, Mohanty I, . Development of SQUID Based TDEM System for Geophysical Applications. DAE Solid State Physics Symposium 2016. American Institute of Physics Conference Proceedings, 2017, 1832: 060018-1-060018-3.
Panaitov G, Bick M, Zhang Y, . Peculiarities of SQUID Magnetometer Application in TEM. Geophysics, 2002, 67(3): 739-745.
CrossRef Google scholar
Smith R, Annan P. The Use of B-Field Measurements in an Airborne Time-Domain System: Part I. Benefits of B-Field Versus dB/dt data. Exploration Geophysics, 1998, 29(1): 24-29. 2
CrossRef Google scholar
Spies B R. Depth of Investigation in Electromagnetic Sounding Methods. Geophysics, 1989, 54(7): 872-888.
CrossRef Google scholar
Spies B R. Discussion on “Peculiarities of SQUID Magnetometer Application in TEM” (Geophysics, 67: 739–745). Geophysics, 2004, 69(2): 624-625.
CrossRef Google scholar
Wang C J, Chen X D, Zhao Y, . Application of 77K SQUID magnetometer in TEM, Chinese. Journal of Geophysics, 1999, 42: 161-166. (Suppl)
Wang C J, Chen X D, Zhao Y, . Problems and Solutions of HTS RF-SQUID Magnetometer in LOTEM. Chinese Journal of Low Temperature Physics, 1995, 17: 426-428. (Suppl)
Wang C J, Wang B Z. Prospect of Application of HTS Superconducting Technology. Geology and Prospecting, 2002, 38: 15-17. (Suppl)
Wolfgram P, Thomson S. The Use of B-Field Measurements in an Airborne Time-Domain System—Part II: Examples in Conductive Regimes. Exploration Geophysics, 1998, 29(1): 225-229. 2
CrossRef Google scholar
Xue G Q, Gelius L J, Sakyi P A, . Discovery of a Hidden BIF Deposit in Anhui Province, China by Integrated Geological and Geophysical Investigations. Ore Geology Reviews, 2014, 63: 470-477.
CrossRef Google scholar
Xue G Q, Zhang L B, Hou D Y, . Integrated Geological and Geophysical Investigations for the Discovery of Deeply Buried Gold-polymetallic Deposits in China. Geological Journal, 2020, 55(3): 1771-1780.
CrossRef Google scholar
Xue G Q, Zhang L B, Zhou N N, . Developments Measurements of TEM Sounding in China. Geological Journal, 2020, 55(3): 1636-1643.
CrossRef Google scholar
Yin C C, Ren X Y, Liu Y H, . The Effect of Induced Polarization on Time-Domain Airborne EM Diffusion. Chinese Journal of Geophysics, 2016, 58(9): 3370-3379. (in Chinese with English Abstract)
Zeng Q D, Chen R Y, Yang J H, . The Metallogenic Characteristics and Exploring Ore Potential of the Gold Deposits in Eastern Liaoning Province. Acta Petrologica Sinica, 2019, 35(7): 1939-1963.
CrossRef Google scholar
Zhang J, G Y, Guo B L, . Pseudo-2D Inversion of TEM Transient Magnetic Field and Its Application Effect. Geophysical and Geochemical Exploration, 2010, 34(2): 205-208. (in Chinese with English Abstract)
Zhang P, Zhao Y, Kou L, . Zircon U-Pb Ages, Hf Isotopes and Geological Significance of Mesozoic Granites in Dandong Area, Liaodong Peninsula. Earth Science, 2019, 44(10): 3297-3313. (in Chinese with English Abstract)
Zhao P D, Chen Q M, Xia Q L. Quantitative Prediction for Deep Mineral Exploration. Journal of Earth Science, 2008, 19(4): 309-318.
Zhao Y, Chen X D, Wang C J. The Intelligence Control System of rf SQUID Magnetometer. Geology and Prospecting, 2002, 38: 22-24. (Suppl)
Zhi Q Q, Wu J J, Deng X H, . The One-Dimension Inversion of Underground Transient Electromagnetic Data. Computing Techniques for Geophysical and Geochemical Exploration, 2015, 37(5): 566-570. (in Chinese with English Abstract)
Zhi Q Q, Wu J J, Yang Y, . Superiority of Bz-Based Transient Electromagnetic Method and Verification Test in Coastal Tidal Regious. Progress in Geophysics, 2020, 35(1): 379-385. (in Chinese with English Abstract)

Accesses

Citations

Detail
Sections
Recommended

/