Citations tracked by Google Scholar & ResearchGate
Full-text PDFs of my publications are available upon request via email.
* Corresponding author † Equal contribution
第一或通讯作者论文:
[18] Gong, Z.*, Evans, D. A. D., Elming, S.-Å. & Li, Y. X. (2026). Evaluating the dipolarity of the mid-Proterozoic geomagnetic field. Earth and Planetary Science Letters, 690, 120172.
[17] Gong, Z.*, Evans, D. A. D., Youbi, N., Ait Lahna, A., Brenner, A., Chamberlain, K., Wen, B., Jing, X. Q., Ding, J. K., Oukhro, R., Ounar, J., Mediany, M. A. & Boumehdi, M. A. (2026). Occurrence and origin of Hercynian remagnetization in Proterozoic mafic rocks in the Anti-Atlas Belt, Morocco. Journal of Geophysical Research: Solid Earth, 131, e2026JB034056.
[16] Shen, F. Y., Wen, B.*, McCausland, P. J. A., Gong, Z.*, Zhu, Z. M., Liu, F. Z. & Wang, J. Y. (2025). A >70-Myr-long geomagnetic field reversal hyperactivity across the Ediacaran-Cambrian transition. Geophysical Research Letters, 52, e2025GL118030.
[15] Gong, Z.*, Fu, R. R., Ortega-Arroyo, D., O’Ghaffari, H., Peč, M. & Lambert, V. R. (2025). Imaging localized slip-induced frictional heating during laboratory earthquakes using magnetic microscopy. Journal of Geophysical Research: Solid Earth, 130, e2025JB031286.
[14] Gong, Z.*, Evans, D. A. D., Fu, R. R. & Xu, S. (2025). Reassessing the geocentric-axial-dipole (GAD) model for Proterozoic time with paleomagnetic directions from dike swarms. Earth and Planetary Science Letters, 667, 119508.
[13] Gong, Z.*, Baillie, I., Nelson, L. L., Gerasimov, S. H., Rose, C. & Smith, E. F. (2025). Magnetic susceptibility cyclostratigraphy of the lower Schwarzrand Subgroup in southern Namibia refines temporal calibration of late Ediacaran bilaterian radiation. Global and Planetary Change, 245, 104668.
[12] Wang, Q. Z.†, Gong, Z.*†, Victor, S. K., Corolla, M., Underhill, A. P., McIntosh, R. J., Fang, H., Ding, J. K., Zhao, Y. C., Chen, X. X. & Song, Y. B.* (2023). New archaeomagnetic directions from late Neolithic sites in Shandong province, China. Geophysical Journal International, 232(2), 1159-1172.
[11] Gong, Z.*, Wei, G. Y., Fakhraee, M., Alcott, L. J., Jiang, L., Zhao, M. Y. & Planavsky, N. J. (2023). Revisiting marine redox conditions during the Ediacaran Shuram carbon isotope excursion. Geobiology, 21(4), 407-420.
[10] Gong, Z.*, Evans, D. A. D., Zhang, Z. & Yan, C. (2023). Mid-Proterozoic geomagnetic field was more consistent with a dipole than a quadrupole. Geology, 51(6), 571-575.
[9] Gong, Z.* & Evans, D. A. D. (2022). Paleomagnetic survey of the Goulburn Supergroup, Kilohigok Basin, Nunavut, Canada: Toward an understanding of the Orosirian apparent polar wander path of the Slave craton. Precambrian Research, 369, 106516.
[8] Gong, Z.* & Evans, D. A. D. (2021). Constraints on the Precambrian paleogeography of West African Craton. In: Pesonen, L. J., Salminen, J. M., Elming, S. Å., Evans, D. A. D. & Veikkolainen, T. (eds.), Ancient Supercontinents and the Paleogeography of the Earth (pp. 423-443). Elsevier.
[7] Gong, Z.*, Evans, D. A. D., Youbi, N., Ait Lahna, A., Söderlund, U., Ait Malek, M., Wen, B., Jing, X. Q., Ding, J. K., Boumehdi, M. & Ernst, R. E. (2021). Reorienting the West African craton in Paleoproterozoic-Mesoproterozoic supercontinent Nuna. Geology, 49(10), 1171-1176.
[6] Gong, Z.* (2021). Cyclostratigraphy of the Cryogenian Fiq Formation, Oman and its implications for the age of the Marinoan glaciation. Global and Planetary Change, 204, 103584.
[5] Gong, Z.* & Li, M. (2020). Astrochronology of the Ediacaran Shuram carbon isotope excursion, Oman. Earth and Planetary Science Letters, 547, 116462.
[4] Gong, Z.*, Kodama, K. P. & Li, Y. X. (2019). Paleomagnetism and rock magnetic cyclostratigraphy of the Ediacaran Doushantuo Formation, South China: Constraints on the remagnetization mechanism and the encoding process of Milankovitch cycles. Palaeogeography, Palaeoclimatology, Palaeoecology, 528, 232-246.
[3] Gong, Z.*, Evans, D. A. D., Elming, S. Å., Söderlund, U. & Salminen, J. M. (2018). Paleomagnetism, magnetic anisotropy and U-Pb baddeleyite geochronology of the early Neoproterozoic Blekinge-Dalarna dolerite dykes, Sweden. Precambrian Research, 317, 14-32.
[2] Gong, Z.*, Xu, X., Evans, D. A. D., Mitchell, R. N., Hoffman, P. F. & Bleeker, W. (2018). Paleomagnetism and rock magnetism of the ca. 1.87 Ga Pearson Formation, Northwest Territories, Canada: A test of vertical-axis rotation within the Great Slave basin. Precambrian Research, 305, 295-309.
[1] Gong, Z.*, Kodama, K. P. & Li, Y. X. (2017). Rock magnetic cyclostratigraphy of the Doushantuo Formation, South China and its implications for the duration of the Shuram carbon isotope excursion. Precambrian Research, 289, 62-74.
合作作者论文:
[16] Brenner, A. R., Fu, R. R., Foley, B. J., Lourenço, D. L., Palma-Gomez, J., Gong, Z., Steele, S. C., Li, J., Flannery, D. T., Brown, A. J. & Hodgin, E. B. (2026). Paleomagnetic detection of relative plate motions and an infrequently reversing core dynamo at 3.5 Ga. Science, 391(6791), 1278-1282.
[15] Farrell, Ú. C., Olson, H. C., Thompson, M. O., Abshire, M. L., Adeboye, O. O., Ahm, A.-S. C., Alcott, L. J., Algeo, T. J., Anderson, R. P., ..., Gong, Z., ..., Lau, K. V., Planavsky, N., Johnston, D. T. & Sperling, E. A. (in press). The sedimentary geochemistry and paleoenvironments project phase 2 data release: An open data resource for the study of Earth's environmental history. Chemical Geology, 712, 123148.
[14] Ben-Daoud, M., Ibouh, H., Youbi, N., El Mostafa, M., Boumehdi, M. A., Fadili, M., Diallo, M., Azmi, M., Evans, D. & Gong, Z. (2026). ASTER and SPOT 5 satellite data for mapping dyke swarms and hydrothermal alteration minerals in the Tagragra d’Akka inlier (western Anti-Atlas, Morocco): Implications for gold exploration. Journal of African Earth Sciences, 238, 106082.
[13] Ding, J. K., Evans, D. A. D., Kilian, T., Mitchell, R. N., Gong, Z., Chamberlain, K., Bleeker, W. & Zhang, S. H. (2025). Local rotations biasing supercontinental configurations: Revisiting a key ca. 780 Ma paleomagnetic pole for Laurentia and Rodinia. Journal of Geophysical Research: Solid Earth, 130, e2025JB031762.
[12] Li, J. H., Zhang, C. Q., Li, C., Chen, Y., Zhang, Q. H., Lan, Q. Q., Wang, Y. Q., Wu, W. W., Wang, J., Gong, Z., Tang, X., Sha, X. C., Gu, L. X., Cheng, S. Q., Liu, P. Y., Liu, J. W., Li, Q. L., Gu. L., Li, G., Li, Y., Dunin-Borkowski, R. E., Roberts, A. P. & Pan, Y. X. (2025). Impact-generated magnetite in Chang’e-5 soil as a potential recorder of the lunar dynamo. Communications Earth & Environment, 6, 878.
[11] Jing, X. Q., Yang, Z. Y., Gong, Z., Tong, Y. B., Hu, L. M. & Yang, S. (2025). Tonian true polar wander events recorded by paleolatitudinal variations of South China and its Southern Hemispheric position in Rodinia. Geology, 53(12), 1017-1022.
[10] Ortega-Arroyo, D., O’Ghaffari, H., Peč, M., Gong, Z., Fu, R. R., Ohl, M., Cattania, C. & Plümper O. (2025). “Lab-quakes”: Quantifying the complete energy budget of high-pressure laboratory failure. AGU Advances, 6, e2025AV001683.
[9] Li, J. H., Xing, L., Gong, Z., Liu, J. W., Liu, Y., Wu, W. W., Zhu, K. L., Wang, Y. Q., Tang, X., Gu, L. X., Chen, Y., Li, Q. L., Cao, Z. Y., Liu, S. C., Cai, S. H. & Pan, X. Y. (2025). Magnetic signatures and origins of ferromagnetic minerals in Chang’e-6 lunar farside soils. Nature Communications, 16, 6218.
[8] Gan, S., Huang, S., Guo, P., Wu, Y., Wang, F., Jiang, B., Song, Y., Pan, J. & Gong, Z. (2025). Refining resolution settings for analysis of dissolved organic matter in varied natural environments by Fourier‐transform ion cyclotron resonance mass spectrometry. Limnology and Oceanography: Methods, 23(7), 509-521.
[7] Ding, J. K., Rogers, C., Söderlund, U., Evans, D. A. D., Gong, Z., Ernst, R. E., Chamberlain, K. & Kilian, T. (2024). Paleomagnetic evidence for Neoarchean plate mobilism. Nature Communications, 15, 10814.
[6] Evans, D. A. D., Pesonen, L. J., Eglington, B. M., Elming, S. Å., Gong, Z., Li, Z. X., McCausland, P., Meert, J. G., Mertanen, S., Pisarevsky, S. A., Pivarunas, A. F., Salminen, J. M., Swanson-Hysell, N., Torsvik, T., Trindade, R., Veikkolainen, T. & Zhang, S. (2021). An expanding list of reliable paleomagnetic poles for Precambrian tectonic reconstructions. In: Pesonen, L. J., Salminen, J. M., Elming, S. Å., Evans, D. A. D. & Veikkolainen, T. (eds.), Ancient Supercontinents and the Paleogeography of the Earth (pp. 605-639). Elsevier.
[5] Zhang, Z. Y., Peng, P., Feng, L. J., Gong, Z., Mitchell, R. N. & Li, Y. L. (2021). Oldest-known Neoproterozoic carbon isotope excursion: Earlier onset of Neoproterozoic carbon cycle volatility. Gondwana Research, 94, 1-11.
[4] Zhao, M. Y., Planavsky, N. J., Oehlert, A. M., Wei, G. Y. & Gong, Z. (2020). Simulating meteoric and mixing zone carbonate diagenesis with a two-dimensional reactive transport model. American Journal of Science, 320(7), 599-636.
[3] Wei, G. Y., Hood, A. vS., Chen, X., Li D., Wei, W., Wen, B., Gong, Z., Yang, T., Zhang, Z. F. & Ling, H. F. (2019). Ca and Sr isotope constraints on the formation of Marinoan cap dolostones. Earth and Planetary Science Letters, 511, 202-212.
[2] Salminen, J. M., Hanson, R., Evans, D. A. D., Gong, Z., Larson, T., Walker, O., Gumsley, A., Söderlund, U. & Ernst, R. E. (2018). Direct Mesoproterozoic connection of Congo and Kalahari cratons in proto-Africa: Strange attractors across supercontinental cycles. Geology, 46(11), 1011-1014.
[1] Li, Y. X., Zhao, X., Jovane, L., Petronotis, K. E., Gong, Z. & Xie, S. (2015). Paleomagnetic constraints on the tectonic evolution of the Costa Rican subduction zone: New results from sedimentary successions of IODP drill sites from the Cocos Ridge. Geochemistry, Geophysics, Geosystems, 16(12), 4479-4493.
