PDF《江苏南京市卫岗 1 号 南京农业大学资环学院》

2017 Mar, 1st ENPE, Nanjing, China ?

2016 Sep, 13rd Soil Society Conference, Xi'

an, China ?

2014 Oct, Mineralogical Science and Engineering, Nanjing, China ?

2014 June, Goldschmidt, Sacramento, CA U.S. ?

2014 June, XI GeoRaman, Saint Louis, MO U.S. ?

2014 July, 12th ICSLR, Beijing, China Research Interests: ? Environmental Mineralogy &

Environmental Remediation ? Biomineralization ? Mineralogy in Soils ? Phosphorous Biogeochemistry Grants: ? 2016, Analytical fund of State Key Laboratory for Mineral Deposits Research, Nanjing University, $100,000 ? 2015-2019, National Program on Key Basic Research Project, No. 2015CB150504, $900,000 ? 2015, Scientific Research Foundation for the Returned Overseas Chinese Scholars, State Education Ministry, $35,000 ? 2015, Analytical fund of CAGS, $90,000 ? 2015, Distinguished Project for Returned Scholars, Nanjing, $20,000 ? 2015-2018, Natural Science Foundation of Jiangsu Province, No. BK20150683, $200,000 ? 2015-2017, The Double Innovation Talent Program of Jiangsu Province, $150,000 Authorized Patents: [1] 2016, Li Z. A method of enhancing P release from apatite, ZL201410458823.9. [2] 2017, Li Z. A type of material for soil remediation based on clay and apatite, ZL2014104139475 Representative Publications (*: Corresponding): [18] Shen Z.T., Li Z.*, Alessi D.S. (2018) Stabilization-based soil remediation should consider longterm challenges, Front. Environ. Sci. Eng. 12(2): 16. [17] Li Z., Deng Z.L., Chen S.S., Yang H., Zheng Y.F., Dai L.T., Zhang F., Wang S.M., Hu S.J. (2018) Contrasting physical and biochemical properties of orchard soils suppressive and conducive to Fusarium wilt of banana, Soil Use and Management, DOI: 10.1111/sum.12390 [16] Shen Z.T., Tian D., Zhang X.Y., Tang L.Y., Su M., Zhang L., Li Z*, Hu S.J.*, Hou D.Y. (2018) Mechanisms of biochar assisted immobilization of Pb2+ by bioapatite in aqueous solution, Chemosphere, 190, 260-266. [15] Li Z., Su M., Tian D., Tang L.Y., Zhang L., Zheng Y.F., Hu S.J. Effects of elevated atmospheric CO2 on dissolution of geological fluorapatite in water and soil. Science of the Total Environment, 599-600: 1382-1397. [14] Li Q., Lu L., Xie S.D., Zhang P.H., Wang S.J., Zhang X.Y., Zhou Z.L.*, Li Z*. (2017) Mineralogical changes of bioapatite in femoral bones of mice during pregnancy, Spectroscopy Letters, 50(6), 336-341. [13] Li Z, Tang L.Y., Zheng Y.F., Tian D., Su M., Zhang F., Ma S.J., Hu S.J. (2017) Characterizing the mechanisms of lead immobilization via bioapatite and various clay minerals, ACS Earth and Space Chemistry, 1, 152-157. [12] Wang S.J., Zhang P.H., Kong X.F., Xie S.D., Li Q., Li Z*, Zhou Z.L.* (2017) Delicate changes of bioapatite mineral in pig femur with addition of dietary xylooligosaccharide: Evidences from Raman spectroscopy and ICP, Animal Science Journal, 88(11), 1820-1826. [11] Chen W.K., Wang Q.Z., Meng S.T., Yang P., Jiang L., Zou X., Li Z*, Hu S.J.* (2017) Temperature-related changes of Ca and P release in synthesized hydroxylapatite, geological fluorapatite, and bone bioapatite, Chemical Geology, 451:183-188. [10] Zheng W.J., Yang H., Xuan G.H., Dai L.T., Hu Y.X., Hu S.J., Zhong S.K., Li Z*., Gao M.Y., Wang S.M., Feng Y*. (2017) Longitudinal s........