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[1] Tang, H.; Wu, X.; Yang, Y.; Xian, H.*; Zhu, J.; Fan, M. et al. Site-specific interactions enhanced dissolution of natural aragonite (110) surfaces in succinic acid (SUC) solutions: Implications for the oceanic aragonite dissolution fluxes. Geochimica et Cosmochimica Acta. (2021) DOI: 10.1016/j.gca.2021.11.016.

[2] H. Xian, X. Wu, J. Zhu, R. Du, J. Wei, R. Zhu, H. He, Environmental-sulfur-controlled surface properties of pyrite: a first principles PBE + U study. Phys. Chem. Miner. 48 (2021).

[3] X. Wang, H. Xian, H. H. Teng, M. Ren, Ultra-long magma residence time leading to a new model for the tungsten mineralization in the Nanling Range (South China). Ore Geol. Rev. 135, 104217 (2021).

[4] Du, R., Xian, H.*, Wu, X., Zhu, J., Wei, J., Xing, J., Tan, W., He, H. (2021) Morphology dominated rapid oxidation of framboidal pyrite. Geochemical Perspectives Letters 16, 53–58.

[5] Tang, H.; Wu, X.; Xian, H.*; Zhu, J.; Wei, J.; Liu, H.; He, H. (2020) Heterogeneous Nucleation and Growth of CaCO₃ on Calcite (104) and Aragonite (110) Surfaces: Implications for the Formation of Abiogenic Carbonate Cements in the Ocean. Minerals, 10 (4), 294.

[6] Xian H., He H.*, Zhu J., Du R., Wu X., Tang H., Tan W., Liang X., Zhu R. and Teng H. H. (2019) Crystal habit-directed gold deposition on pyrite: Surface chemical interpretation of the pyrite morphology indicative of gold enrichment. Geochimica et Cosmochimica Acta 264, 191–204.

[7] Xian H., Zhu J.*, Tan W., Tang H., Liu P., Zhu R., Liang X., Wei J., He H. and Teng H. H.* (2019) The mechanism of defect induced hydroxylation on pyrite surfaces and implications for hydroxyl radical generation in prebiotic chemistry. Geochimica et Cosmochimica Acta 244, 163–172.

[8] Tang H., Xian H.*, He H., Wei J., Liu H., Zhu J. and Zhu R. (2019) Kinetics and mechanisms of the interaction between the calcite (10.4) surface and Cu²⁺-bearing solutions. Science of The Total Environment 668, 602–616.

[9] 何宏平*, 鮮海洋, 朱建喜, 譚偉, 梁曉亮, 陳錳 (2019) 從礦物粉晶表面反應性到礦物晶面反應性——以黃鐵礦氧化行為的晶面差異性為例. 巖石學(xué)報 35, 129–136.

[10] Xian H., Du R., Zhu J.*, Chen M., Tan W., Zhu R., Wei J. and He H.* (2018) Hydration induced bandgap shift at pyrite-water interface. Applied Physics Letters 113, 123901.

[11] Zhu J.*, Xian H., Lin X., Tang H., Du R., Yang Y., Zhu R., Liang X., Wei J., Teng H. H. and He H. (2018) Surface structure-dependent pyrite oxidation in relatively dry and moist air: Implications for the reaction mechanism and sulfur evolution. Geochim. Cosmochim. Acta 228, 259–274.

[12] Xian H., Zhu J.*, Tang H., Liang X., He H. and Xi Y. (2016) Aggregative growth of quasi-octahedral iron pyrite mesocrystals in a polyol solution through oriented attachment. CrystEngComm 18, 8823–8828.

[13] Xian H., Zhu J.*, Liang X. and He H. (2016) Morphology controllable syntheses of micro-and nano-iron pyrite mono-and poly-crystals: a review. RSC Advances 6, 31988–31999.