文嘉

2008.9-2010.12 University of Adelaide (Australia), 博士

2007.8-2008.8 University of Adelaide (Australia), 研究生

2003.9-2007.7 中國海洋大學，化學化工學院， 學士 ^[1] 

本課題組研究土壤重金屬污染的治理和修復方法；應用於修復重金屬和有機污染物的新材料的製備；廢水治理技術；地理信息系統支撐下的農業和環境規劃。 ^[1] 

1. 國家自然科學基金青年基金 主持人

2. 湖南省自然科學基金青年基金、面上基金 主持人 ^[1] 

3. 長沙市自然科學基金 主持人

4. 長沙市科技計劃基礎研究項目 主持人

5. 重慶市自然科學基金面上項目 主持人

[1] Cheng, W.X., Wen, J.^*（文嘉）, 2022. Now and future: Development and perspectives of using polyphenol nanomaterials in environmental pollution control. Coordination Chemistry Reviews, 473:214825

[2] Wen, J.^*（文嘉）, Yang, L.S., 2022. Transport of ZIF-8 in porous media under the influence of surfactant type and nanoparticle concentration. Water Research, 218C: 118490

[3] Yang, L.S., Wen, J.^*（文嘉）, 2022. Can DLVO theory be applied to MOF in different dielectric solvents? Microporous and Mesoporous Materials, 343: 112166.

[4] Yang, L.S., Wen, J.^*（文嘉）, Wang, Q., Cui, H.S., 2022. Effect of solution chemistry on the stability and transport of ZIF-8 in saturated porous media. Journal of Environmental Chemical Engineering, 10(3):107562

[5] Li, Y.F., Wen, J.^*（文嘉）, Xue, Z.Z., Yin, X.Y., Yuan, L., Yang, C.L., 2022. Removal of Cr(VI) by polyaniline embedded polyvinyl alcohol/sodium alginate beads − Extension from water treatment to soil remediation. Journal of Hazardous Materials, 426:127809.

[6] Wen, J.^*（文嘉）, Xue, Z.Z., Yin, X.Y., Wang, X., 2022. Insights into aqueous reduction of Cr(VI) by biochar and its iron-modified counterpart in the presence of organic acids. Chemosphere, 286:131918

[7] 尹茜豔, 文嘉*, 薛壯壯, 楊翠蓮, 李揚芳, 袁利. 2022. 不同pH值和O₂條件下硝酸改性生物炭去除六價鉻機理. 環境科學學報, 42(10):274-283.

[8] Cui, H.S., Wen, J.^*（文嘉）, Yang, L.S., Wang, Q., 2022. Spatial distribution of heavy metals in rice grains and human health risk assessment in Hunan Province, China. Environmental Science and Pollution Research, 29:83126-83137

[9] Xue, Z.Z., Wen, J.^*（文嘉）, Yang, C.L., Yuan, L., Yin, X.Y., Li, Y.F., 2022. Efficient removal of chloramphenicol by K₂CO₃ activated porous carbon derived from cigarette butts. Biomass Conversion and Biorefinery, https://doi.org/10.1007/s13399-022-02515-z

[9] Yuan, L., Wen, J.^*（文嘉）, Xue, Z.Z., Li, Y.F., Yang, C.L., Yin, X.Y., 2021. Microscopic Investigation into Remediation of Cadmium and Arsenite Cocontamination in Aqueous Solution by Fe-Mn-incorporated Titanosilicate. Separation and Purification Technology, 279:119809.

[9] Wen, J.^*，1（文嘉）, Hu, X.H¹. 2021. Metal selectivity and effects of co-existing ions on the removal of Cd, Cu, Ni, and Cr by ZIF-8-EGCG nanoparticles. Journal of Colloid and Interface Science, 589:578-586.

[10] Xing, L., Wen, J.^*（文嘉）, Yan, C.Y., Wang, Q., Hu, X.H., Xue, Z.Z., 2021. Improving the microenvironment of Cd-contaminated river sediments through humic substances washing and zeolite immobilization. Process Safety and Environmental Protection, 146: 779-788.

[11]Yan, C.Y., Wen, J.^*（文嘉）, Wang, Q., Xing, L., Hu, X.H., 2021. Mobilization or immobilization? The effect of HDTMA-modified biochar on As mobility and bioavailability in soil. Ecotoxicology and Environmental Safety, 207: 111565.

[12]Wen, J.^*（文嘉）, Yan, C.Y., Xing, L., Wang, Q., Yuan, L., Hu, X.H., 2021.Simultaneous immobilization of As and Cd in a mining site soil using HDTMA-modified zeolite. Environmental Science and Pollution Research, 28: 9935-9945

[13]Wang, Q., Wen, J.^*（文嘉）， Hu, X.H., Xing, L., Yan, C.Y., 2021. Immobilization of Cr(VI) Contaminated Soil using Green-tea Impregnated Attapulgite. Journal of Cleaner Production, 278: 123967.

[14]Hu, X.H., Wen, J.^*（文嘉）, Zhang, H.B., Wang, Q., Yan, C.Y., Xing, L., 2020. Can epicatechin gallate increase Cr(VI) adsorption and reduction on ZIF-8? Chemical Engineering Journal, 391: 123501.

[15]Fang, Y., Wen, J.^*（文嘉）, Zhang, H.B., Wang, Q., Hu, X.H., 2020. Enhancing Cr(VI) reduction and immobilization by magnetic core-shell structured NZVI@MOF derivative hybrids. Environmental Pollution, 260: 114021.

[16]Zhang, H.B.¹, Wen, J.^1*（文嘉）, Fang, Y., Zhang, S.Y., Zeng, G.M., 2019. Influence of fulvic acid on Pb(II) removal from water using a post-synthetically modified MIL-100(Fe). Journal of Colloid and Interface Science, 551: 155-163.

[17] Zhang, S.Y., Wen, J.*（文嘉）, Hu, Y., Fang, Y., Zhang, H.B., Xing, L., Wang, Y.X., Zeng, G.M., 2019. Humic substances from green waste compost: an effective washing agent for heavy metal (Cd, Ni) removal from contaminated sediments. Journal of Hazardous Materials, 366:210-218

[18] Peng, Z.L., Wen, J.* （文嘉）, Liu, Y.G., Zeng, G.M., Yi,Y.J., Fang, Y., Zhang, S.Y., Deng, J.Q., Cai, X.X., 2018. Heavy metal leachability in soil amended with zeolite- or biochar-modified contaminated sediment. Environmental Monitoring and Assessment, 190:751 ^[1] 

[19] Wen, J.*（文嘉）, Dong, H.R., Zeng, G.M., 2018. Application of zeolite in removing salinity/sodicity from wastewater: A review of mechanisms, challenges and opportunities. Journal of Cleaner Production, 197P1: 1435-1446.

[20] Wen, J.*（文嘉）, Fang, Y., Zeng, G.M., 2018. Progress and prospect of adsorptive removal of heavy metal ions from aqueous solution using metal–organic frameworks: a review of studies from the last decade. Chemosphere, 201:627-643.

[21] Wen, J.*（文嘉）, Zeng, G.M., 2018. Chemical and Biological Assessment of Cd-Polluted Sediment for Land Use: the Effect of Stabilization Using Chitosan-coated Zeolite. Journal of Environmental Management, 212:46-53.

[22] Fang, Y., Wen, J.*（文嘉）, Zeng, G.M., Shen, M.C., Cao, W.C., Gong, J.L., Zhang, Y.X., From nZVI to SNCs: Development of a Better Material for Pollutant Removal in Water. Environmental Science and Pollution Research, 2018, 25(7):6175-6195.

[23] Wen, J.*（文嘉）, Peng, Z.L., Liu, Y.G., Fang, Y., Zeng, G.M., Zhang, S.Y., 2018. A case study of evaluating zeolite, CaCO3, and MnO2 for Cd-contaminated sediment reuse in soil. Journal of Soils and Sediments, 18:323-332.

[24] Fang, Y., Wen, J.*（文嘉）, Zeng, G.M., Jia, F.Y., Zhang, S.Y., Peng, Z.L., Zhang, H.B., Effect of mineralizing agents on the adsorption performance of metal-organic framework MIL-100(Fe) towards chromium(VI). Chemical Engineering Journal,2018, 337:532-540.

[25] 文嘉*，曾光明，安赫，賈民娟，易元傑，彭志龍，沸石改良底泥對土壤中微生物生物量及酶活性的影響。農業環境科學學報，2017，36（2）:302-307.

[26] Yi, Y.J., Wen, J.*（文嘉）, Zeng, G.M., Zhang, T.T., Huang, F.H., Qin, H.Y., Tian, S.Y., A comparative study for the stabilization of heavy metal contaminated sediment by limestone, MnO2 and natural zeolite. Environmental Science and Pollution Research, 2017, 24:795-804.

[27]Wen, J.*（文嘉）, McLaughlin, M.J., Stacey, S.P., Aseptic Hydroponics to Assess Rhamnolipid-Cd and –Zn Availability to Sunflowers (Helianthus Annuus). Environmental Science and Pollution Research, 2016, 23(21):21327-21335,

[28] Wen, J.*（文嘉）, Yi, Y.J., Zeng, G.M., Effects of modified zeolite on the removal and stabilization of heavy metals in contaminated lake sediment using BCR sequential extraction. Journal of Environmental Management, 2016, 178: 63-69.

[29]Zhang, Q.X.*, Xiao, Q., Xu, J.Y., Tong, Y.H., Wen, J.（文嘉）, Chen, X.J., Wei, L.H., Effect of the RetS gene on antibiotics production in Pseudomonas fluorescens FD6. Microbiological Research, 2015, 180: 23-29.

[30] Wen, J.*（文嘉）, McLaughlin, M.J., Stacey, S.P., Kirby, J.K., Is rhamnolipid biosurfactant useful for cadmium phytoextraction? Journal of Soils & Sediments, 2010, 10:1289-1299.

[31] Wen, J.*（文嘉）, Stacey, S.P., McLaughlin, M.J., Kirby, J.K., Biodegradation of rhamnolipid, EDTA and citric acid in cadmium and zinc contaminated soils. Soil Biology and Biochemistry, 2009, 41: 2214-2221.

[1] Wen, J.* #, Zeng, G.M.. Bring contaminated sediment back to life: application of zeolite-amended sediment in soil (Conference Paper). Paper in in the conference abstract book of 7th SETAC World Congress. Nov 6-10, 2016, Orlando, USA.

[2] Wen, J.*#, McLaughlin, M.J., Stacey, S.P., Kirby, J.K.. Rhamnolipid: a useful amendment for Cd phytoextraction? The 20th Society of Environmental Toxicology and Chemistry Europe Annual Meeting. May 23-27, 2010, Seville, Spain. ^[1] 

[3] Wen, J.*#, McLaughlin, M.J., Stacey, S.P., Kirby, J.K.. Investigating the use of rhamnolipid for cadmium phytoextraction in soils. The 13th Aaustralasian Society for Ecotoxicology Conference. Aug 20-23, 2009, Adelaide, Australia.

[4] Wen, J.*#, McLaughlin, M.J., Stacey, S.P., Kirby, J.K.. Improving cadmium phytoextraction using rhamnolipid. The 5th Society of Environmental Toxicology and Chemistry World Congress. Aug 3-6, 2008, Sydney, Australia.

[5] Kelly, J.*, Wen, J., Lanyon, D.. Beneficial water recycling as part of the treatment train for the sustainable management of STEDS wastewater while protecting sensitive environmental assets. Small Water & Wastewater Systems National Conference. Sep 26-28, 2012, Newcastle, Australia.

[1] 【發明人】：文嘉，曾光明，易元傑，彭志龍。【專利名稱】：利用改性沸石分子篩修復重金屬污染底泥的方法和農田土壤的改良方法。【申請人】：湖南大學【申請日期】：2016.09.23【申請專利號】：201610845724.5.

[2] 【發明人】：文嘉，方穎，曾光明。 【專利名稱】：一種利用無氟助劑碳酸鈉製備MIL-100(Fe)的方法和應用。 【申請人】：湖南大學【申請日期】：2017.08.09【申請專利號】：201710675265.5

[3] 【發明人】：文嘉，張思宇，曾光明，方穎，章海波。【專利名稱】：一種腐殖質製備及其修復重金屬污染底泥的方法。 【申請人】：湖南大學【申請日期】：2018.02.09 【申請專利號】：201810135544.7

[4]【發明人】：文嘉，方穎，章海波，曾光明，張思宇。【專利名稱】：納米零價鐵-金屬有機框架核殼材料的製備方法及其應用。【申請人】：湖南大學【申請日期】：2019.01.02【申請專利號】：201910001204.X ^[1]