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地址:江苏省南京市栖霞区仙林大道163号

南京大学仙林校区环境学院A530

邮编:210023

电话:025-89680637 (陆老师)

E-mail: biogeochemnju@163.com

      

2014年(23篇

[23]  Chen, K., L.  Huang*, B. Yan, H. Li, H. Sun*, and J. Bi. 2014. Effect of lead  pollution control on environmental and childhood blood lead level in Nantong, China: An interventional study. Environmental Science & Technology. 48: 12930–12936.

[22]  de Oliveira, L. M., L. Q. Ma*, J. A. G. Santos, L. R. G. Guilherme, and J. T. Lessl. 2014. Effects of arsenate, chromate, and sulfate on arsenic and chromium uptake and translocation by arsenic hyperaccumulator Pteris vittata L. Environmental Pollution. 184: 187–192.

[21]  Ding, W., X. Dong, B. Gao, I. M. Ime, and L. Q. Ma*. 2014. Pyrolytic temperatures impact lead sorption mechanisms by bagasse biochars. Chemosphere. 105: 68–74.

[20]  Dong, X., L. Q. Ma*, J. Gress, W. Harris, and Y. Li. 2014. Enhanced Cr(VI) reduction and As(III) oxidation in ice phase: Important role of dissolved organic matter from biochar. Journal of Hazardous Materials. 267: 62–70.

[9]  Dubey, S. P.*, A. D. Dwivedi, C. Lee*, Y. N. Kwon*, M. Sillanpaa M., and L. Q. Ma. 2014. Raspberry derived mesoporous carbon-tubules and fixed-bed adsorption of pharmaceutical drugs. Journal of Industrial and Engineering Chemistry. 20(3): 11261132.

[18]  Dwivedi, A. D. and L. Q. Ma*. 2014. Biocatalytic synthesis pathways, transformation and toxicity of nanoparticles in the environment. Critical Reviews in Environmental Science and Technology. 44: 16791739.

[17]  Fan, Y. Y., J. L. Zheng, J.  H. Ren, J. Luo, X. Y. Cui*, and L. Q. Ma*. 2014. Effects of storage temperature  and duration on release of antimony and  bisphenol A from polyethylene terephthalate drinking water bottles of  China. Environmental Pollution. 192: 113120.

[16]  Gress, Julia, J. T. Lessl, X. Dong and L. Q. Ma*. 2014. Assessment of children’s exposure to arsenic from CCA-wood staircases at apartment complexes in Florida. Science of the Total Environment. 476–477: 440–446.

[15]  Lessl, J. T., J. Luo, and L. Q. Ma*. 2014.  Pteris vittata continuously removed arsenic from non–labile fraction  in three  contaminated–soils during 3.5–year of phytoextraction. Journal of Hazardous Materials. 279: 485492.

[14]  Li, H. B.J. Li,  A. L. Juhasz, and L. Q. Ma*. 2014. Correlation of in vivo relative  bioavailability to in vitro bioaccessibility for arsenic in household dust from  China and its implication for human exposure assessment. Environmental Science & Technology. 48: 13652–13659.

[13]  Li, H. B., X. Y. Cui, K. Li, J. Li, A. L. Juhasz, and L. Q. Ma*. 2014. Assessment of in vitro lead bioaccessibility in house dust and its relationship to in vivo lead  relative bioavailability. Environmental Science & Technology. 48: 85488555.

[12]  Liang, S., D. X. Guan, J. H. Ren, M. Zhang, J. Luo*, and L.  Q. Ma*. 2014.  Effect of aging on arsenic and lead fractionation and availability  in  soils: Coupling sequential extractions with diffusive gradients in  thin–films  technique. Journal of Hazardous Materials. 273: 272279.

[11]  Luo, J., H. Cheng, J. Ren,  W. Davison, and H. Zhang*. 2014. Mechanistic insights from DGT and soil solution  measurements on the uptake of Ni and Cd by radish. Environmental Science & Technology. 48:  7305–7313.

[10]  Ren, J.  H., L. Q. Ma*, H. J. Sun, F. Cai, and J. Luo*. 2014. Antimony uptake,  translocation and speciation in rice plants exposed to antimonite and  antimonate. Science of the Total Environment. 475: 8389.

[9]  Ren, J. H., H. J. Sun, S. F. Wang, J. Luo, and L. Q. Ma*. 2014.  Interactive effects of mercury and arsenic on their uptake, speciation and  toxicity in rice seedling. Chemosphere. 117: 737744.

[8]  Sun,  H. J., B. Rathinasabapathi, B. Wu, J. Luo, L. P. Pu, and L. Q. Ma*. 2014. Arsenic and selenium toxicity and their interactive effects in humans. Environment International. 69: 148158.

[7]  Tisaruma, R., J. M. Lessl, X. Dong, L. M. de Oliveira, B. Rathinasabapathi, and L. Q. Ma*. 2014. Antimony uptake, efflux and speciation in arsenic hyperaccumulator Pteris vittata. Environmental Pollution. 186: 110114.

[6]  Wang, X. and L. Q. Ma*. 2014. Recent advances in phytoremediation of arsenic-contaminated soils. In: In-Situ Remediation of Arsenic-Contaminated Sites.  Bundschuh, J.,  H. M. Holländer, and L. Q. Ma (eds). CRC Press, Boca Raton, FL. pp 6986.

[5]  Xu, J. Y., H. B. Li, S. Liang,  J. Luo, and L. Q. Ma*. 2014. Arsenic enhanced plant growth and altered rhizosphere characteristics of hyperaccumulator Pteris vittata. Environmental Pollution.  194: 105111.

[4]  Yang, W. W., Y. Wang, B. Huang, N. X. Wang, Z. B. Wei,  J. Luo, A. J. Miao*, and L. Y. Yang. 2014. TiO2 nanoparticles act as a carrier  of Cd bioaccumulation in the ciliate Tetrahymena thermophila. Environmental Science & Technology. 48: 75687575.

[3]  Zhu, Y., B. Gu, D. L. Irick, S. Ewe, Y. Li, M. S. Ross, and L. Q. Ma*. 2014. Wading bird guano contributes to Hg accumulation in tree island soils in the Everglades. Environmental Pollution. 184:313–319.

[2]  Zhu, Y., L. Q. Ma*, X. Dong, W. Harris, J. C. Bonzongo, and F. Han. 2014. Ionic strength reduction and flow interruption enhanced colloid-facilitated Hg transport in contaminated soils. Journal of Hazardous Materials. 264:286–292.

[1]  Zhu, L. J., D. X.  Guan, J. Luo, B. Rathinasabapathi, and L. Q. Ma*. 2014. Characterization of  arsenic-resistant endophytic bacteria from hyperaccumulators Pteris vittata and  Pteris multifida. Chemosphere. 113: 916.