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污染控制與資源利用創新團隊

時間: 2020/07/23   作者:   點擊:

 

一.團隊簡介

團隊立足農業環境保護和環境污染控制領域國際前沿,面向國家需求,緊扣我國農業生產與農村生態環境面臨的重大課題,依托湖南省環境保護畜禽養殖與農業種植污染控制工程技術中心湖南省農業典型污染物生態修復與實地保護國際科技合作基地湖南省農村生活污水處理處置工程研究中心等省部級愛游戲體育登錄與教學平臺,開展農業與農村流域水土污染治理與修復、環境材料與廢物資源化、環境污染物及檢測技術、環境污染物生態毒理學等方面的愛游戲體育登錄與教學、技術推廣工作。

團隊近5年來,團隊先后承擔了50余項國家級省部級研究課題,獲資助1800余萬元,在國內外期刊發表研究論文150余篇,獲得專利10余項,省部級獎勵2項,主持或參與編制國家級和團體標準/行業標準4項。

二(er).團(tuan)隊人員

團隊現有固定成員14人,包括教授4人,副教授7人,其中湖南省委組織部青年百人計劃1人,香江學者”1人,國家博士后創新人才1人,湖南省省青年骨干教師2人、愛游戲app“1515”人才學術骨干2人、愛游戲app神農學者青年英才層次人才5人,現有博士后、博士、碩士研究生近30人。 

序號

姓名

學(xue)歷

職稱

從事(shi)方向(xiang)

1

博(bo)士

教授

固體廢(fei)物資(zi)源化、重金(jin)屬污染土壤與水體修復

2

顏智(zhi)勇(yong)

博士

教授

農(nong)村(cun)和工(gong)業(ye)污水處理(li)及裝備化

3

吳(wu)根義

博士

教授

農業面源污(wu)(wu)染(ran)(ran)防(fang)治、畜禽養殖污(wu)(wu)染(ran)(ran)防(fang)治與管理(li)

4

秦普豐(feng)

博士

教授

重金屬污染場地修復和污水處理處置

5

顏丙(bing)花

博士

教授

固體(ti)廢物資(zi)源化(hua)、厭氧膜生物反應

6

張嘉(jia)超

博(bo)士

教授

固體廢物(wu)資(zi)源化、重金(jin)屬物(wu)污染土壤(rang)修復

7

周(zhou)耀渝

博士

教授

典型農業區土壤及(ji)地下(xia)水污染修復

8

羅(luo)惠莉

博(bo)士

副教授

重金屬污(wu)染(ran)農(nong)田修(xiu)復、農(nong)藥殘留檢測

9

黃紅麗(li)

博士

副(fu)教授

固體廢物(wu)資源化、重金屬物(wu)污染水體與土(tu)壤(rang)修(xiu)復

10

戴(dai)春皓

博士

副(fu)教授

區域大(da)氣污染(ran)物防治

11

羅雙

博士

副(fu)教授

有機污(wu)染物治理、環境模型、復雜(za)廢水(shui)處理

12

謝先德

博(bo)士

副教授

重金(jin)屬污染修復與治理

13

曹林英(ying)

博士(shi)

副教授

環境毒(du)理學與評價(jia)

14

張立華

博士(shi)

副教授

固體(ti)廢物資源(yuan)化、環境微生物

15

楊建

博士

副(fu)教授(shou)

環(huan)境(jing)安(an)全學、環(huan)境(jing)污染風險評估(gu)

16

鄧娜

博士

講師

流域與區域污染修復與規劃

17

楊遠

博士(shi)

講師

分析(xi)化學與納米顆粒(li)

18

彭慧

博士

講師

濕地污染(ran)物治理與(yu)修(xiu)復

19

智(zhi)丹

博士

講師

環(huan)境功能材料(liao)與應用

三.主要研究(jiu)方向

1. 礦山(shan)酸性廢水被動式處理技術(shu)與推廣

為解決鐵離子在被動式處理系統中造成的堵塞問題、錳離子在系統中難去除的問題,提出了鐵錳氧化-硫酸鹽還原的技術路線。前端鐵錳氧化采用由愛游戲app篩選馴化的鐵錳氧化菌,利用生物固錳除錳理論,將鐵錳氧化菌與材料進行組配,應用生物擴培技術,進行接種。該菌能在酸性條件下對鐵錳重金屬離子進行氧化,形成生物錳氧化物。末端應用硫酸鹽還原生物濾池,通過異化SO42-為電子受體將其還原,它能把硫酸鹽、亞硫酸鹽、硫代硫酸鹽、單硫還原為硫化物,在處理富含硫酸鹽和金屬離子的廢水具有較強的能力,利用SRB可以同時去除廢水中硫酸根和金屬離子,從而達到以廢治廢的目的。

新(xin)(xin)(xin)型污(wu)染物(wu)控制(zhi)(zhi)技(ji)術的(de)(de)(de)(de)研發和推廣是環境工程重要的(de)(de)(de)(de)研究方向,系統開展了基于鐵錳新(xin)(xin)(xin)材料(liao)和新(xin)(xin)(xin)工藝(yi)的(de)(de)(de)(de)研發與推廣,通過對現有鐵錳材料(liao)的(de)(de)(de)(de)定向修飾和基于鐵錳氧(yang)化(hua)還原工藝(yi)的(de)(de)(de)(de)改良,針對性的(de)(de)(de)(de)用于新(xin)(xin)(xin)型環境污(wu)染物(wu)的(de)(de)(de)(de)處理,為污(wu)染物(wu)的(de)(de)(de)(de)控制(zhi)(zhi)提供切實可(ke)行的(de)(de)(de)(de)技(ji)術方案。

2. 農業源新型(xing)污染物的環境歸趨及風險(xian)評價(jia)

主要開展農業源新型污染物在環境中的遷移、轉化、歸趨、及其對生態系統各要素的影響,包括水解、氧化降解、光降解、生物降解、降解產物毒性、污染物在環境介質中的累積、污染物對生態系統各要素的毒性;利用模擬實驗和污染物結構與性質/活性定量關系(QSAR)模型計算等研究方法,預測污染物在環境中的遷移、歸趨和毒性,為農業源化學品的風險評價和管理提供數據支撐。

3. 環境(jing)健康與污(wu)染物生態毒(du)理

新興有機污染物內分泌干擾效應及分子機制:從分子、細胞、動物活體以及理論模擬計算等多個層面,系統研究新興污染物通過干擾內分泌系統對人體健康的危害作用,包括生殖發育毒性、激素相關癌癥以及糖尿病和肥胖等代謝相關疾病,并探究污染物毒害作用的分子起始事件和毒性通路以及污染物的結構-效應關系。

納(na)米(mi)(mi)毒理及(ji)聯合毒性(xing):主要研究納(na)米(mi)(mi)塑料、金(jin)屬(shu)納(na)米(mi)(mi)材料、納(na)米(mi)(mi)農藥等的細胞毒性(xing)及(ji)分子機制(zhi),與典型污染物(wu)聯合暴露的生物(wu)效應及(ji)作用機制(zhi)。

微(wei)污染物(wu)復(fu)合生(sheng)態毒(du)(du)理:通過不同(tong)營養級生(sheng)物(wu)的(de)生(sheng)態毒(du)(du)理評價方(fang)法和基于細胞(bao)關鍵毒(du)(du)性通路的(de)體外高通量診斷技術,評價實際環境介質中(zhong)微(wei)污染物(wu)的(de)復(fu)合生(sheng)態毒(du)(du)性及毒(du)(du)理機制。

4. 基于種養(yang)平衡調控的農林有機(ji)固廢定(ding)向(xiang)化(hua)學生物轉化(hua)及(ji)應用

開展基于種養平衡調控的(de)農(nong)林廢(fei)棄物(wu)定向化(hua)學(xue)生(sheng)物(wu)轉化(hua)機制(zhi)研究,實現農(nong)林廢(fei)棄物(wu)碳氮磷等關(guan)鍵元素的(de)平衡和資源(yuan)化(hua)利用,對于提高(gao)廢(fei)棄物(wu)資源(yuan)化(hua)利用效率(lv)和價值(zhi)和推動(dong)湖(hu)南(nan)農(nong)業綠色可持續發展具(ju)有重要的(de)現實意義(yi)。

項(xiang)目團隊根據湖南區域種(zhong)養高度分離和集約化(hua)(hua)(hua)水平(ping)較低的(de)(de)(de)特(te)點(dian),通過(guo)(guo)秸(jie)稈制生(sheng)(sheng)物炭(tan)解決(jue)其(qi)利(li)用中儲存、運輸難的(de)(de)(de)問題,突破生(sheng)(sheng)物炭(tan)調控秸(jie)稈與畜禽糞污共(gong)堆肥過(guo)(guo)程碳氮元(yuan)素(su)釋(shi)放(fang)的(de)(de)(de)技(ji)術(shu)瓶(ping)頸,結合厭氧產沼(zhao)和堆肥化(hua)(hua)(hua)等相(xiang)關技(ji)術(shu)的(de)(de)(de)元(yuan)素(su)轉(zhuan)(zhuan)化(hua)(hua)(hua)規律和生(sheng)(sheng)物學機制的(de)(de)(de)深入研究,系統(tong)闡(chan)釋(shi)農林(lin)廢(fei)(fei)棄物定向化(hua)(hua)(hua)學生(sheng)(sheng)物處置的(de)(de)(de)效率與機制,掌握化(hua)(hua)(hua)學生(sheng)(sheng)物處理處置過(guo)(guo)程中抗生(sheng)(sheng)素(su)及殘(can)留農藥等毒害物質的(de)(de)(de)轉(zhuan)(zhuan)化(hua)(hua)(hua)與減控機理,實現碳氮磷元(yuan)素(su)平(ping)衡的(de)(de)(de)農林(lin)廢(fei)(fei)棄物全量、高價資源化(hua)(hua)(hua)利(li)用。

四.承擔的(de)主要愛游戲體育(yu)登錄項目

[1]      國家重點研發計劃項目,2016YFC0403000,重金屬廢水深度處理與安全利用技術集成示范及轉化模式,2016.09-2019.08,主持人:羅琳

[2]      國家自然科學基金青年項目,2190605,基于雌激素膜受體GPER探究新煙堿農藥對乳腺癌增殖轉移的影響及分子機制,2020.01-2022.12,主持人:曹林英

[3]      國家自然科學基金青年項目,UV活化亞硫酸鹽/過硫酸鹽協同礦化難降解有機污染物的機理及模型研究,2019.01-2021.12,主持人:羅雙

[4]      國家自然科學基金青年項目,21806170,厭氧發酵集成離子置換型電滲析強化揮發性脂肪酸代謝和CO2回用的效能與機制研究,2019.01-2021.12,主持人:顏丙花

[5]      國家自然科學基金青年基金,21806003,洛克沙胂在針鐵礦/水界面的光化學轉化行為及機理研究,2019.01-2021.12,主持人:謝先德

[6]      國家自然科學基金青年項目,51709103,雜化多孔碳納米鐵微囊修復地下水中芳香族有機砷污染的效能及機理研,2018.01-2020.12,主持人:周耀渝

[7]      國家自然科學基金青年項目,51408219,農業廢物堆肥氨氧化細菌(AOB)和古菌(AOA)對基質微環境變化的響應特征及驅動氨氧化的關鍵因子分析,2015.01-2017.12,主持人:張嘉超

[8]      國家自然科學基金青年項目,51108178,禽畜糞便堆肥對印度芥菜修復重金屬污染土壤中銅鋅遷移轉化的影響,2012.01-2014.12,主持人:黃紅麗

[9]      國家博士后創新人才支持計劃,BX20200127,以小型豬為模型研究抗菌劑三氯卡班誘導脂代謝異常和肥胖的分子機制,2021.01-2022.12,主持人:曹林英

[10]    第二次全國污染源普查農業行業普查數據宏觀質量校核技術方案編制,2018.12-2019.12,主持人:吳根義

[11]    中國博士后科學基金面上項目,2017M620507典型(xing)苯胂(shen)酸類化合物在鐵錳(meng)氧化物上(shang)的(de)吸(xi)附解吸(xi)機理研究2017.10-2019.3,主持人:謝先德

[12]    中國博士后基金,典型金屬納米顆粒在水-水稻體系中遷移轉化及毒性研究,2019-2021年,No. 2019M652768,主持人:楊遠

[13]    湖南省自然科學基金青年項目,2020JJ5222,新煙堿農藥通過雌激素膜受體GPER介導的雌激素干擾分子機制研究,2021.01-2022.12,主持人:曹林英

[14]    湖南省自然科學基金,水-水稻體系中鉑納米顆粒遷移轉化及納米毒性研究, 2020-2022年,No.2020JJ5227,主持人:楊遠

[15]    湖南省自然科學基金項目,農業廢物堆肥化過程中酒糟及其生物炭添加的N2O減排特征及微生物學機制,2020/04-2023/03,主持人:張嘉超

[16]    湖南省重點研發項目,2019SK2281,入河水體重金屬污染阻控與銻微污染深度凈化關鍵技術,2019.07-2021.06,課題負責人:羅雙

[17]    湖南省自然科學基金,湘自科2018JJ3240,農業面源區域氨基污染源對大氣細顆粒物貢獻率及轉化機理研究,2018.01-2020.12,主持人:戴春皓

[18]    湖南省重點研發計劃項目,2018SK2022,高濃度含鉈廢水高效處理技術及集成裝備研發,2018.01-2020.12,主持人:黃紅麗

[19]    湖南省重點研發項目,濕式氧化調理污泥多元復配制備砷污染土壤專用修復劑技術及示范,2017.09-2020.08,課題負責人:張嘉超

[20]    湖南省重點研發項目,2016WK2010,典型農藥污染物在水環境中的痕量快速檢測及強化去除技術集成與示范,2016.09-2018.08,主持人:張嘉超

[21]    湖南省科技計劃項目,2015WK3016,湘江流域重金屬礦山酸性廢水的耐受微生物種群的篩選及其生物固定化處理技術,2016.01-2018.12,主持人:羅琳

[22]    湖南省自然科學基金,高級還原-高級氧化協同礦化新型含氯有機農藥的機理及預測模型研究,2019.01-2021.12,在研,主持人:羅雙

[23]    山東省自然科學基金項目,ZR2016BB06, 電膜原位分離促進餐廚垃圾與剩余污泥高固厭氧共消化產脂肪酸的應用研究,2016.11-2018.08, 主持人:顏丙花

[24]    湖南省重點研發計劃,稻田重金屬污染修復的新型硅肥技術引進創新與示范,2019.01-2021.122019KW2031,課題負責人:楊遠

五.發表(biao)學術論文

[1] Dongmei Hou, Pan Zhang, Jiachao Zhang, Yaoyu Zhou, Yuan Yang, Qiming Mao, Daniel C.W. Tsang, Avelino Nú?ez-Delgado, Lin Luo?. Spatial variation of sediment bacterial community in an acid mine drainage contaminated area and surrounding river basin. Journal of Environmental Management, 2019, 251:109542.

[2] Qiming Mao, Yaoyu Zhou, Yuan Yang, Jiachao Zhang, Lifen Liang, Hailong Wang, Shuang Luo?, Lin Luo?, Paramsothy Jeyakumar, Yong Sik Ok, Muhammad Rizwan. Experimental and theoretical aspects of biochar-supported nanoscale zero-valent iron activating H2O2 for ciprofloxacin removal from aqueous solution. Journal of Hazardous Materials, 2019, 380:120848.

[3] Dongmei Hou, Pan Zhang, Dongning Wei, Jiachao Zhang, Binghua Yan, Linying Cao, Yaoyu Zhou*, Lin Luo*. Performance and microbial community profiles in pilot-scale biofilter for the simultaneous removal of ammonia, iron and manganese at different manganese concentrations. Bioprocess and Biosystems Engineering, 2019, 42(5):741-752.

[4] Danxing Yang, Xiaocheng Liu, Yaoyu Zhou*, Lin Luo*, Jiachao Zhang, Anqi Huang, Qiming Mao, Xiao Chen, Lin Tang. Aptamer-based biosensors for detection of lead(II) ion: a review, Analytical methods, 2017,9(13): 1976-1990.

[5] Rui Zhou, Xiaochen Liu, Lin Luo*, Yaoyu Zhou*, Jianhong Wei, Anwei Chen, Lin Tang, Haipeng Wu, Yaocheng Deng, Fengfeng Zhang, Yangyang Wang. Remediation of Cu, Pb, Zn and Cd-contaminated agricultural soil using a combined red mud and compost amendment, International Biodeterioration & Biodegradation, 2017, 118:73-81.

[6] Cao Lin-Ying, Ren Xiao-Min*, Yang Yu, et al. Hydroxylated polybrominated biphenyl ethers exert estrogenic effects via nongenomic G protein-coupled estrogen receptor mediated pathways. Environmental Health Perspectives, 2018, 126 (5), 057005.

[7] Cao Lin-Ying, Zheng Zi-Ye., Ren Xiao-Min, et al. Structure-dependent activity of polybrominated diphenyl ethers and their hydroxylated metabolites on estrogen related receptor γ: in vitro and in silico study. Environmental Science & Technology, 2018, 52 (15), 8894–8902.

[8] Cao Lin-Ying, Ren Xiao-Min*, Li Chuan-Hai, et al. Bisphenol AF and bisphenol B exert higher estrogenic effects than bisphenol A via G protein coupled estrogen receptor pathway, Environmental Science & Technology, 2017, 51 (19), 11423-11430.

[9] Cao Lin-Ying, Ren Xiao-Min*, Li Chuan-Hai, et al. Organophosphate esters bind to and inhibit estrogen-related receptor γ in cells. Environmental Science & Technology Letters, 2018, 5(2), 68-73.

[10] Lin-Ying Cao*, Yun-Hao Xu, Sen He, et al. Antimicrobial triclocarban exhibits higher agonistic activity on estrogen-related receptor γ than triclosan at human exposure levels: a novel estrogenic disruption mechanism. Environmental Science & Technology Letters, 2020, 2020, 7 (6): 434-439.

[11] Dai C., Qin P. Wang Z. et al. Mercury enrichment in Brassica napusin response to elevated atmospheric mercury concentrations. Frontiers of Environmental Science & Engineering, 2017, 11(1):1-8.

[12] Dai C., Zhou Y., Peng H., et al. Current progress in remediation of chlorinated volatile organic compounds: a review. Journal of Industrial and Engineering Chemistry, 2018,106-119.

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[16] Dongning Wei, Bingyu Li, Lin Luo, Yongxin Zheng, Liuhui Huang, Jiachao Zhang, Yuan Yang, Hongli Huang*. Simultaneous adsorption and oxidation of antimonite onto nano zero-valent iron sludge-based biochar: Indispensable role of reactive oxygen species and redox-active moieties. Journal of Hazardous Materials, 2020, 391: 122057.

[17] Dongning Wei, Bingyu Li, Hongli Huang*, Lin Luo, Jiachao Zhang, Yuan Yang, Jiajun Guo, Lin Tang, Guangming Zeng, Yaoyu Zhou. Biochar-based functional materials in the purification of agricultural wastewater: Fabrication, application and future research needs. Chemosphere, 2018, 197: 165-180.

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[19] Shuang Luo, Ruiyang Xiao, Liyuan Chai, Dionysios D. Dionysiou, et al. Mechanistic insight into reactivity of sulfate radical with aromatic contaminants through single-electron transfer pathway. Chemical Engineering Journal, 2017, 327:1056–1065. ESI熱點+高被引

[20] Shuang Luo, Ruiyang Xiao, Liyuan Chai, Dionysios D. Dionysiou, et al. UV direct photolysis of sulfamethoxazole and ibuprofen: An experimental and modelling study. Journal of Hazardous Materials, 2018, 343:132–139. ESI高(gao)被引(yin)

[21] Shuang Luo, Ruiyang Xiao, Liyuan Chai, et al. Quantitative structure?activity relationships for reactivities of sulfate and hydroxyl radicals with aromatic contaminants through single?electron transfer pathway. Journal of Hazardous Materials. 2018, 344:1165-1173. ESI高(gao)被引

[22] Shuang Luo, Ruiyang Xiao, Liyuan Chai, et al. A novel model to predict gas-phase hydroxyl radical oxidation kinetics of polychlorinated compounds. Chemosphere, 2017, 172: 333-340. ESI高被引(yin)

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[29] Waktole Berkessa Y., Yan, B. H.*, Li T. F., Jegatheesan J., Zhang Y. *, 2019.Treatment of anthraquinone dye textile wastewater using anaerobic dynamic membrane bioreactor: performance and microbial dynamics. Chemosphere, 238, 124539.

[30] Zhou, M. M., Yan, B. H.*, Lang, Q. L., Zhang, Y. * 2019. Elevated volatile fatty acids production through reuse of acidogenic off-gases during electro-fermentation. Science of the Total Environment, 668, 295-302.

[31] Waktole Berkessa Y., Yan, B. H.*, Li T. F., Tan M., She Z. L., Jegatheesan J., Jiang H.Q., Zhang Y. *, 2018. Novel anaerobic membrane bioreactor (AnMBR) design for wastewater treatment at long HRT and high solid concentration. Bioresource Technology, 250, 281-289.

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[33] Li Lei, Wang Qiang*, Yang Yuan*, Luo Li, Ding Ru, Yang Zhao-Guang, Li Hai-Pu. Extraction Method Development for Quantitative Detection of Silver Nanoparticles in Environmental Soils and Sediments by Single Particle Inductively Coupled Plasma Mass Spectrometry. Analytical Chemistry, 2019, 91(15), 9442-9450.

[34] Dan Zhi, Danxing Yang, Yongxin Zheng, Yuan Yang*, Yangzhuo He, Lin Luo, Yaoyu Zhou*. Current progress in the adsorption, transport and biodegradation of antibiotics in soil. Journal of Environmental Management, 2019, 251,19598.

[35] Qiang Wang, Lei Li, Li Luo, Yuan Yang*, Zhaoguang Yang*, Haipu Li, Yaoyu Zhou. Activation of Persulfate with Dual-doped Reduced Graphene Oxide for Degradation of Alkylphenols. Chemical Engineering Journal, 2019, 367, 120891.

[36] Yaoyu Zhou*, Yujia Xiang, Yangzhuo He, Yuan Yang*, Jiachao Zhang, Lin Luo, Hui Peng, Chunhao Dai, Feng Zhu, Lin Tang. Applications and factors influencing of the persulfate-based advanced oxidation processes for the remediation of groundwater and soil contaminated with organic compounds. Journal of hazardous materials, 2018, 359: 396-407.

[37] Qiang Wang, Lei Li, Chen-Lu Long, Li Luo, Yuan Yang*, Zhao-Guang Yang*, Yaoyu Zhou. Detection of C60 in Environmental Water using Dispersive Liquid-Liquid Micro-Extraction Followed by High-Performance Liquid Chromatography. Environmental Technology, 2020, 41(8): 1015-1022.

[38] Nianhui Liu, Peng Liao, Jiachao Zhang*, Yaoyu Zhou, Lin Luo, Hongli Huang, Lihua Zhang. Characteristics of denitrification genes and relevant enzyme activities in heavy-metal polluted soils remediated by biochar and compost. Science of the Total Environment, 2020, 739, 139987

[39] Jiayi Tang, Lihua Zhang, Jiachao Zhang*, Liheng Ren, Yaoyu Zhou, Yuanyuan Zheng, Lin Luo, Yuan Yang, Hongli Huang, Anwei Chen. Physicochemical features, metal availability and enzyme activity in heavy metal-polluted soil remediated by biochar and compost. Science of the Total Environment, 2020, 701, 134751

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[47] Lihua Zhang, Guangming Zeng*, Haoran Dong, Yaoning Chen, Jiachao Zhang, Ming Yan, Yuan Zhu, Yujie Yuan, Yankai Xie, Zhenzhen Huang. The impact of silver nanoparticles on the co-composting of sewage sludge and agricultural waste: Evolutions of organic matter and nitrogen. Bioresource Technology, 2017, 230: 132-139.

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[49] Yaoyu Zhou, Lin Tang*, Guangming Zeng*, Jun Chen, Jiajia Wang, Changzheng Fan, Guide Yang, Yi Zhang, Xia Xie. Amplified and selective detection of manganese peroxidase genes based on enzyme-scaffolded-gold nanoclusters and mesoporous carbon nitride. Biosensors and Bioelectronics, 2015, 65, 382-389.

[50] Xiaocheng Liu, Yaoyu Zhou*, Jiachao Zhang, Lin Luo, Yuan Yang, Hongli Huang, Hui Peng, Lin Tang, Yang Mu*. Insight into electro-Fenton and photo-Fenton for the degradation of antibiotics: mechanism study and research gaps. Chemical Engineering Journal, 2018, 347, 379-397.

[51] Dan Zhi, Jianbing Wang, Yaoyu Zhou*, Zirui Luo, Yuqing Sun, Zhonghao Wan, Lin Luo, Daniel C.W.Tsang, Dionysios D. Dionysiou. Development of ozonation and reactive electrochemical membrane coupled process: Enhanced tetracycline mineralization and toxicity reduction. Chemical Engineering Journal, 2019, 123149.

[52] Yaoyu Zhou*, Shikang Wu, Hao Zhou, Hongli Huang, Jia Zhao, Yaocheng Deng*, Hua Wang, Yuan Yang, Jian Yang, Lin Luo. Chiral pharmaceuticals: Environment sources, potential human health impacts, remediation technologies and future perspective. Environment International, 2018, 121, 523-537.

 

六(liu).國際合作(zuo)與學(xue)術交流

項目團隊依托的“湖南省農業典型污染物生態修復與實地保護國際科技合作基地”,是我省第一個(2018年)批準成立的以農業農村環境污染治理與濕地保護為工作核心的國際合作基地。基地建設探索開展項目-人才-基地相結合的國際科技合作模式,通過積極吸引匯聚國際創新力量和資源,集聚世界一流專家學者,合作培養國際化人才。能夠有效地推動協同創新和開放創新,引領和支撐國家創新驅動發展戰略實施,進一步擴大科技對外影響力,提升國際科技合作的質量和水平,并對我國農業面源污染防控、農業水資源安全利用、農業與礦山的可持續發展產生引領和示范效果。

項目團隊(dui)通過與(yu)法(fa)國、菲律(lv)賓(bin)、澳大利亞(ya)、西(xi)班牙等國家開展(zhan)深層次、多形式、全方(fang)位的科技合作(zuo),突破關鍵技術(shu),積極吸收對方(fang)工程化(hua)(hua)、產業(ye)化(hua)(hua)的經驗,重(zhong)(zhong)點(dian)攻克礦山酸(suan)性廢(fei)水被動式生態(tai)(tai)處理、重(zhong)(zhong)金屬面(mian)源污染生態(tai)(tai)攔截、農田養分高效利用、農田退水生態(tai)(tai)凈化(hua)(hua)與(yu)回用等一(yi)批關鍵技術(shu)與(yu)裝備,構建農業(ye)典型(xing)污染物(重(zhong)(zhong)金屬、過量氮磷、農藥)防控與(yu)修復技術(shu)體系,形成(cheng)集成(cheng)示范,建立相關技術(shu)規范與(yu)標準。

 
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