�ΕԱ��A�S��W���ڣ���ʿ��������1984��������؞��������������Ҫ�о�����ˮ�c�Uˮ̎�����ڸ߼��������������b�﷽�����о����L��2014���廪��ѧ��ʿ��ҵ�󵽻��ȴ�ѧ�������䲩ʿ�����ٻ�“ȫ����������רҵ���㲩ʿ���Ľ�”; 2018����ѡȪ���и߲���˲ţ�2022����ѡ�����и߲���˲š�ǰ��3�θ���������ɣ��������ѧ�����ݴ�ѧ��ά˹��У���Ͽ������ɴ�ѧ����Ϊ�����º�1��ķ�ѧ���Ⱥ��ձ��������μ�“�����n��ʿ���n��”��Ŀ�����ѷ�������90��ƪ�������Ե�һ���߻�ͨѶ���߷�������70��ƪ��40��ƪSCI������2���ר���������д1���鼮��������±���1300��Ρ����ֹ��ҡ�ʡ�м���Ŀ9����й�����Ȼ��ѧ����2��; �й���ʿ���ѧ�����ر�����1��й���ʿ���ѧ��������������һ�ȣ�1��Ͷ���ʡ�м���Ŀ�����ι�����Ȼ��ѧ������ί�����ҿƼ���ר�ң����ſƼ�ר�ҿ��һ��ר�ң����ź���Ƽ�ר�ң������������������ί��Frontiers in Environmental Science ��־�����ࣻWater and Wastewater Management ��־����༭�����ڵ���һ��TOP�ڿ�Environmental Science and technology, Water Research, Science of the total environment, Journal of hazardous material����־����ˡ�

• ˮ̎��

• �����������b��ǰ�w����R�e�����əC���������о�

• �Bֳˮѭ�hʹ�ü��g�аl

• ���͜Qˮ���ϵ��аl

[1] 2010.9 -- 2014.7
���A��W       ��������       ��ʿ�о������I       ��ʿ�Wλ

[2] 2007.9 -- 2010.7
�A��������W       �h������       �Tʿ�о������I       �Tʿ�Wλ

[3] 2003.9 -- 2007.7
��h������W       �h������       ����(�Wʿ)       �Wʿ�Wλ

[4] 2019.7 -- 2020.7
�Ͽ��_�R�{��W       �L���W��

[5] 2016.1 -- 2016.4
���ݴ�W���S˹��У       �L���W��

[6] 2013.10 -- 2014.2
����ɣ��������W       “�����B��ʿ

[7] 2013.7 -- 2013.8
�����n��ʿ���n��

[1] 2020.1 -- ����
�A�S��W      ��ľ���̌WԺ      ����

[2] 2017.1 -- 2019.12
�A�S��W      ��ľ���̌WԺ      ������

[3] 2014.8 -- 2016.12
�A�S��W      ��ľ���̌WԺ      �v��

• [1]�����A������������ǰ�w�����ÙC���о�,�Y�},�A�S��WУ���І��ӻ���,2015/02/01

• [2]΢��ȾˮԴ����Ԥ�������������ɻ���������о�,����,����ʡ�������������ʦ���������Ŀ,2015/07/01

• [3]���׻�������ǰ�w���ڳ����A�����^���е��Р��wڅ�������m������ˇ��Ӱ�,�Y�},����ʡ��Ȼ���������Ŀ,2015/04/01

• [4]����NDMAǰ�w���R�e�{�س����������pNDMA����,�Y�},�Ї���ʿ��ƌW���������Y����һ�ȣ�,2016/01/01

• [5]�~�G΢��������������b��������əC���c�����о�,�Y�},�Ї���ʿ��ƌW�����؄e�Y��,2016/07/01

• [6]�{�׽���������߻���������������ǰ�w��C���о�,�Y�},�A�S��W����������Ƽ������˲�,2016/10/01

• [7]�����A�����^����NDMA���əC����ǰ�w���R�e,������Ȼ�ƌW���������Ŀ,2018/12/31

• [8]�߻���������������ǰ�w����ϵ��аl�c����,�Y�},Ȫ���пƼ�Ӌ�����c�Ŀ,2018/01/01

• [9]�������M��/�Ȱ�����NDMA���ɵĸ�ؕ�I��ǰ�w���R�e���{�ؙC���о�,������Ȼ�ƌW���������Ŀ,2022/12/31

• �A�S��W�̌W���Ȫ�,2017

• �A�S��W��ľ���̌WԺ���ߌ�����̎�“����һ���n”���Ȫ�

• �����̸����� ������ѧ����“�������̸���”�γ̽�ѧ�е�Ӧ��[J].,2016

• �����̸����� ��������������⼰�Բ�-�����������������γ��°���[J].,2020

• �����̸����� ��������������⼰�Բ�-�����������������γ��°���.,2020

• �����̸����� ����ǿ������ѧϰ�Ľ�ѧ�����ĸ��о���ʵ��[J].,2022

• �����̸����� ����OBE��SPOC�ġ�ˮ������ѧ���γ��������»�Ͻ�ѧ�ĸ��о���ʵ��.,2023

• �A�S��W��W�����„��IӖ��Ӌ���Ŀ�����Ҽ���헣�,2018

• "�Ї��oˮ��ˮ��"ȫ����У�o��ˮ�ƌW�c���̌��I�������Ƽ������Ŀ���Ȫ�,2019

• [1]Influencing pathways and toxicity changes of pre-ozonation on carcinogenic NDEA formation from greenhouse gas adsorbent DEAPA in subsequent disinfection processes.Top�ڿ� SCIһ��IF=10.752:Total Environ.,2023,873(162355):

• [2]THMs, HAAs and NAs production from culturable microorganisms in pipeline network by ozonation, chlorination, chloramination and joint disinfection strategies.Top�ڿ� SCIһ��IF=10.752:Total Environ.,2023,744(140833):

• [3]Validation of the promotion mechanism between bromide and UDMH to form NDMA during ozonation.Total Environ.,2023,792(148316):

• [4]Analysis of rainwater storage and use recommendations: From the perspective of DBPs generation and their risks.Top�ڿ� SCI һ�� IF=14.224:Hazard Mater.,2023,448(130833):

• [5]Exploring Br-’s roles on non-brominated NDMA formation during ozonation: Reactive oxygen species contribution and brominated intermediate path validation.Top�ڿ� SCI һ�� IF=14.224:Hazard Mater.,2023,444(130205):

• [6]���_ϴ��ʽ������ʽ������ԞV���\��Ӱ��о�.�������g,2022,40(12):137-142.

• [7]How well does XAD resin extraction recover halogenated disinfection byproducts for comprehensive identification and toxicity testing.SCI ���� IF=5.565:Environ Sci.,2022,117264-275.

• [8]NDMA formation during ozonation of DMAPA: Influencing factors, mechanisms, and new pathway exploration.Top�ڿ� SCIһ��IF=10.752:Total Environ.,2022,825(153881):

• [9]NDMA Reduction mechanism from UDMH by O3/ PMS technology.Top�ڿ� SCIһ��IF=10.752:Total Environ.,2022,805(150418):

• [10]hich pre-oxidation methods to choose? from perspective of DBPs formation and toxicities reduction.SCI ���� IF=6.158:Process Saf Environ.,2022,161118-125.

• [11]NDMA formation during ozonation of metformin: roles of ozone and hydroxyl radicals.Top�ڿ� SCIһ��IF=10.752:Total Environ.,2021,796(149010):

• [12]�{��pH�����͝��pH����ˮ����Ч���о�.�h���@Ⱦ�c����,2021,4376-78.

• [13]Ȫ��ijˮ��ˮ�|����׃��ԭ�򼰌���̽��.�Ї��oˮ��ˮ,2020,36(1):44933.

• [14]Comparative study on sulfides removal by HClO and KMnO4 in drinking water.SCI ���� IF=4.251:Environ Sci-WAT Water Res.,2020,62871-2880.

• [15]Humic acid’s (HA) role on NDMA formation from daminozide (DMNZD) during ozonation.SCI ���� IF=4.251:Environ Sci-WAT Water Res.,2020,62766-2775.

• [16]Effect of pre-ozonation on N-nitrosodimethylamine (NDMA) formation from four drinking water sources during subsequent chloranimation.SCI ���� IF=1.033:Water Sci Tech-W Sup.,2019,19(6):1816-1822.

• [17]ijˮ���ļ�ˮ�|��ֱ�ֲ�ԭ���������ʾ���x.�h���ƌW�c���g,2019,1(42):212-216.

• [18]NDMA formation from 4,4′-hexamethylenebis (HDMS) during ozonation: influencing factors and mechanisms.SCI ���� IF=4.223:Environ Sci Pollut R.,2019,26(2):1584-1594.

• [19]New perspective of Br’s role on NDMA formation from daminozide (DMNZD) during ozonation.Top�ڿ� SCIһ��IF=10.752:Total Environ.,2019,696(133892):

• [20]Performance of BAC for DBPs precursors’ removal for one year with micro-polluted lake water in East-China.SCI ���� IF=3.247:Environ Technol.,2019,19(6):1816-1822.

• [21]Reduction of N-nitrosodimethylamine formation from ranitidine by ozonation preceding chloramination: influencing factors and mechanisms.SCI ���� IF=4.223:Environ Sci Pollut R.,2018,25(14):13489-13498.

• [22]evaluating the biosafety of conventional and O-3-BAC process and its relationship with NOM characteristics.TAYLOR & FRANCIS LTD:ENVIRONMENTAL TECHNOLOGY,2017,

• [23]Evaluation the bio-safety of conventional and O3-BAC process and its relationship with NOM characteristics.SCI ���� IF=3.247:Environ Technol.,2017,39221-230.

• [24]Control of Nitrosamines, THMs, and HAAs in Heavily Impacted Water With O-3-BAC.2016JCR����-���̼���4��:JOURNAL AMERICAN WATER WORKS ASSOCIATION,2016,109(6):215-225.

• [25]Biodegradation of chlortetracycline by acclimated microbiota.2016JCR����-������ѧ����̬ѧ3��:PROCESS SAFETY AND ENVIRONMENTAL PROTECTION,2016,

• [26]���������^���и��b��������װ�������.����ʡ�h���ƌW�о�Ժ:�h���ƌW�c���g,2016,

• [27]��/����ʽ�������̿�˳ش���΢��Ⱦ����ˮ�Ƚ�.�й��������̻�������о�Ժ ;�й����и�ˮ��ˮ���̼����о�����:�й���ˮ��ˮ,2016,

• [28]Identification of nitrosamine precursors from urban drainage during storm events: A case study in southern China.Top�ڿ� SCI ���� IF=7.086:Chemosphere.,2016,160323-331.

• [29]Sorption and Desorption of Organic Matter on Solid-phase Extraction Media to Isolate and Identify N-nitrosodimethylamine Precursors.SCI ���� IF=3.645:Sep Sci.,2016,39(14):2796-2805.

• [30]Biomass development in GAC columns receiving influents with different levels of nutrients.2015JCR-����-������ѧ����̬ѧ4��:Water Science and Technology-Water Supply,2015,16(4):

• [31]Biodegradation of antibiotic ciprofloxacin: pathways, influential factors, and bacterial community structure.2015JCR-����-������ѧ����̬ѧ3��:ENVIRONMENTAL SCIENCE AND POLLUTION RESEARCH,2015,23(8):

• [32]Antibiotic sulfanilamide biodegradation by acclimated microbial populations.2015JCR-����-���̼���2��:APPLIED MICROBIOLOGY AND BIOTECHNOLOGY,2015,

• [33]Determination of Seven N-Nitrosamines in Eutrophic Drinking Water after Chlorination by High Performance Liquid Chromatography-Tandem Mass Spectrometry.SCI ���� IF=1.134:Chinese J Anal Chem.,2015,4502-506.

• [34]Dimethylamine biodegradation by mixed culture enriched from drinking water biofilter.Top�ڿ� SCI ���� IF=7.086:Chemosphere.,2015,119935–940.

• [35]Toluene decomposition performance and NOx by-product formation during a DBD-catalyst process.SCI ���� IF=5.565:Environ Sci.,2015,28187–194.

• [36]Operational performance, biomass and microbial community structure: impacts of backwashing on drinking water biofilter.SCI ���� IF=4.223:Environ Sci Pollut R.,2015,22(1):546-554.

• [37]Applying the polarity rapid assessment method to characterize nitrosamine precursors and to understand their removal by drinking water treatment process.Top�ڿ� SCI һ�� IF=11.236:Water Res.,2015,(87):292-298.

• [38]Bacterial community change through drinking water treatment processes.SCI ���� IF=2.860:Int J Environ Sci Technol.,2015,12(6):1867-1874.

• [39]Nitrosamine Precursor and DOM Control in a Wastewater Impacted Drinking Water.SCI ���� IF=0.805:Am Water Works Ass.,2015,106(7):307-318.

• [40]Nitrosamine Precursor Removal by BAC: A Case Study of Adsorption Versus Biotreatment.2014JCR-����--����:JOURNAL AMERICAN WATER WORKS ASSOCIATION,2014,

• [41]Evaluation of disinfection by-product formation potential (DBPFP) during chlorination of two algae species—Blue-green Microcystis aeruginosa and diatom Cyclotella meneghiniana.2014JCR-����-������ѧ����̬ѧ-����:SCIENCE OF THE TOTAL ENVIRONMENT,2014,

• [42]������O3-BAC��ˇ̎��΢�@Ⱦ����ˮ�о�.�oˮ��ˮ,2014,401-7.

• [43]Pyrosequencing analysis of bacterial communities in drinking water biofilters receiving influents of different types.SCI ���� IF=3.757:Process Biochem.,2013,48(4):703-707.

• [44]Application of conventional and O3-BAC process to treat the organic matters and antibiotics pollutants in one lake in East China.SCI ���� IF=1.033:Water Sci Tech-W Sup.,2013,13(6):1470-1477.

• [45]��Ҏ�����������̿ȥ���ЙC�Ｐ������ǰ�w������.���A��W�W��,2013,53(4):520-525.

• [46]����ʽ�������̿ϵ�y��������\�����c�QˮЧ���о�.������W�W��,2013,49(3):504-508.

• [47]Changes of biomass and bacterial communities in biological activated carbon filters for drinking water treatment.SCI ���� IF=3.757:Process Biochem.,2013,48(2):312-316.

• [48]Heterogeneity of microbial community structures inside up-flow biological activated carbon (BAC) filtration system for drinking water treatment.SCI ���� IF=2.836:Biotechnol Bioproc E.,2012,17881-886.

• [49]���@���y�����|�����늽���ױ��Юb�����ǻ����ɻ�.�V�ݴ�W�W��,2011,10(1):85-89.

• [50]Hydroxyl Radicals Formation in Dielectric Barrier Discharge During Decomposition of Toluene.SCI ���� IF=3.148:Plasma Chem Plasma P.,2010,30841-853.

• [51]��ͬ������������x���w����ױ��������о�.�h���ƌW�W��,2010,30(9):44935.

• [52]Effect of manganese oxide catalyst on the dielectric barrier discharge decomposition of toluene.Top�ڿ� SCI ���� IF=6.766:Catal Today.,2010,153176–183.

• [53]Detection of hydroxyl radical in plasma reaction on toluene removal.SCI ���� IF=5.565:Environ Sci.,2008,201429-1432.

• [1]ˮ�ČW��ˮ�ĵ��|�W

• [2]ˮ�������W

• [3]�h�����̸�Փ

• [4]�h�����o��Փ

• [5]��������̎���c̎��

�ʱ� : 361021

ͨѶ/�칫��ַ : �����м������������668#���ȴ�ѧ��ľ����ѧԺ

���� : liaoxb@hqu.edu.cn