Profile

研究方向

① 环境微纳米材料（微塑料、纳米材料等）的生态毒理效应，与其他污染物的联合毒性模型建立，以及环境复合污染物的生态风险评价；② 赤潮的生态风险评价与预警机制研究。

学术任职

SCI期刊Environmental Science and Pollution Research副主编（2019年9月至今）

科研项目：

1. 大连理工大学基本科研业务费，DUT15RC(3)069，中国近岸海域典型污染物的海水水质基准研究，5.00万，主持，2015.11-2016.12

2. 工业生态与环境工程重点实验室开放课题，KLIEEE-15-09，微小亚历山大藻对日本虎斑猛水蚤的毒性效应及其机制研究，4.00万，2016.01-2018.12

3. 国家自然科学基金青年基金项目，41606131，大田软海绵酸对日本虎斑猛水蚤（Tigriopus japonicus）的毒性效应及其机制研究，20.00万，主持，2017.01-2019.12

4. 大连理工大学基本科研业务费， DUT17LK45，纳米氧化锌与不同类型污染物的联合毒性作用，10.00万，主持，2017.01-2018.12

5. 国家海洋局近岸海域生态环境重点实验室基金，201812。我国近海两种典型环境激素海水水质基准研究，3.0万，主持，2018.01-2019.12

6. 大连理工大学基本科研业务费，DUT17RC(4)37，多壁碳纳米管与污染物的联合毒性作用，5.00万，主持，2019.01-2020.12

教改项目：

1. 大连理工大学盘锦校区教学改革项目，主持，5000元。

参加学术会议

1. 2016. April, 第三届生态毒理学学术会议, Wuxi, China, oral presentation

2. 2017. January, The third Xiamen symposium on Marine Environmental Science (XMAS-III), Xiamen, China

3. 2018.4.24-25年4月24-25日，第二届海洋微塑料污染与控制国际学术研讨会（The 2^nd International Symposium on Marine Microplastic Pollution and Control）, Shanghai, China

4. 2018.10.14-17, International Conference on Environmental Health Sciences (ICoEHS), Yeosu, Korea. Invited speaker， 特邀报告

5. 2018.10.10-12, International Symposium on Basic Sciences, Incheon, Korea, Invited speaker，特邀报告

6. 2019.4.26-29，第六届全国生态毒理学大会，广州，口头报告

发表论文

2020

[1] Yi, X., Zhang, K., Liu, R.^*, Giesy, J.P., Li, Z., Li, W., Zhan, J., Liu, L., Gong, Y.^*, 2020. Transcriptomic responses of Artemia salina to an environmentally relevant dose of Alexandrium minutum or Gonyautoxin2/3 exposure. Chemosphere, 238, 124661. SCI: 000497885800057

[2] Li, Z., Yi, X.^*, Zhou, H., Chi, T., Li, W., Yang, K., 2020. Combined effect of polystyrene microplastics and dibutylphthalate on the microalgae Chlorella pyrenoidosa. Environmental Pollution, 257, 113604.

[3] Li, Z., Zhou, H., Liu, Y., Zhan, J., Li, W., Yang, K., Yi, X.^*, 2020. Acute and chronic combined effect of polystyrene microplastics and dibutyl phthalate on the marine copepod Tigriopus japonicus. Chemosphere 261, 127711.

[4] Xiao, P., Liu, Y., Zong, W., Wang, J., Wu, M., Zhan, J., Yi, X., Liu, L., Zhou, H.^*, 2020. Highly selective colorimetric determination of catechol based on the aggregation-induced oxidase–mimic activity decrease of d-MnO₂. RSC Advances 10, 6801.

[5] Fu, C., Yi, X., Liu, Y., Zhou, H.^*, 2020. Cu²⁺ activated persulfate for sulfamethazine degradation. Chemosphere 257, 127294.

[6] Liu, Y.^*, Gao, W., Zhou, H.^*, Yi, X., Bao, Y., 2020. Highly reactive bulk lattice oxygen exposed by simple water treatment of LiCoO2 for catalytic oxidation of airborne benzene. Molecular Catalysis 492, 111003.

[7] Zhu, S.-R., Yang, J.-N., Liu, Y.^*, Gao, W., Yi, X., Zhou, H., Wu, M., 2020. Synergetic interaction of lithium cobalt oxide with sulfite to accelerate the degradation of organic aqueous pollutants. Materials Chemistry and Physics, 249, 123123.

[8] Wang, G., Liu, Y., Wu, M., Zong, W., Yi, X., Zhan, J., Liu, L., Zhou, H.^*, 2020. Coupling the phenolic oxidation capacities of a bacterial consortium and in situ-generated manganese oxides in a moving bed biofilm reactor (MBBR). Water Research 166.

2019

[1] Yi, X., Chi, T., Liu, B., Liu, C., Feng, G., Dai, X., Zhang, K., Zhou, H.^*, 2019. Effect of nano zinc oxide on the acute and reproductive toxicity of cadmium and lead to the marine copepod Tigriopus japonicus. Comparative Biochemistry and Physiology Part C: Toxicology & Pharmocology 222, 118-124. SCI:000472812200013

[2] Yi, X., Chi, T., Li, Z., Wang, J., Yu, M., Wu, M., Zhou, H.^*, 2019. Combined effect of polystyrene plastics and triphenyltin chloride on the green algae Chlorella pyrenoidosa. Environmental Science and Pollution Research 26, 15011-15018. SCI:000468842100028

[3] Yi, X., Yu, M., Li, Z., Chi, T., Jing, S., Zhang, K., Li, W., Wu, M.^*, 2019. Effect of multi-walled carbon nanotubes on the toxicity of triphenyltin to the marine copepod Tigriopus japonicus. Bulletin of Environmental Contamination and Toxicology 102, 789-794. SCI:000469475500009

[4] Yi, X., Wang, J., Li, Z., Zhang, Z., Chi, T., Guo, M., Li, W., Zhou, H.^*, 2019. Effect of polystyrene plastics on the toxicity of triphenyltin to the marine diatom Skeletonema costatum – influence of plastic particle size. Environmental Science and Pollution Research 26, 25445-25451. SCI: 000483698500005

2018年

[1] Yi, X., Li, C., Zhong, X., Gong, Y.^*, 2018. Development of a lipovitellin-based sandwich ELISA for determination of vitellogenin in the marine medaka Oryzias melastigma. Chemosphere 197, 477-484. SCI:000426231900054

[2] Yi, X., Zhang, K., Han, G., Yu, M., Chi, T., Jing, S., Li, Z., Zhan, J., Wu, M.^*, 2018. Toxic effect of triphenyltin in the presence of nano zinc oxide to marine copepod Tigriopus japonicus. Environmental Pollution 243, 687-692. SCI:000449891800075

[3] Li, P., Jia, H., Wang, Y., Li, T., Wang, L., Li, Q., Yang, M., Yue, J., Yi, X., Guo, L., 2018. Characterization of PM2.5-bound phthalic acid esters (PAEs) at regional background site in northern China: Long-range transport and risk assessment. Science of The Total Environment 659, 140-149.

2017年

[1] Zheng, L., Liu, Z., Yan, Z., Zhang, Y., Yi, X., Zhang, J., Zheng, X., Zhou, J., Zhu, Y., 2017. pH-dependent ecological risk assessment of pentachlorophenol in Taihu Lake and Liaohe River. Ecotoxicology and Environmental Safety 135, 216-224.

[2] Yi, X., Bao, V.W.W., Leung, K.M.Y., 2017. Binary mixture toxicities of triphenyltin with tributyltin or copper to five marine organisms: Implications on environmental risk assessment. Marine Pollution Bulletin, 124, 839-846.

[3] Yi, X., Leung, K.M.Y., 2017. Assessing the toxicity of triphenyltin to different life stages of the marine medaka Oryzias melastigma through a series of life-cycle based experiments. Marine Pollution Bulletin, 124, 847-855.

[4] Zheng, L., Liu, Z., Yan, Z., Yi, X., Zhang, J., Zhang, Y., Zheng, X., Zhu, Y., 2017. Deriving water quality criteria for trivalent and pentavalent arsenic. Science of the Total Environment, 587-588, 68-74.

[5] Liu, J., Wang, Y., Li, P.-H., Shou, Y.-P., Li, T., Yang, M.-M., Wang, L., Yue, J.-J., Yi, X., Guo, L.-Q., 2017. Polycyclic aromatic hydrocarbons (PAHs) at high mountain site in north China: concentration, source and health risk assessment. Aerosol and Air Quality Research, 17: 2867-2877.

[6] Zhang, Y., Zang, W., Qin, L., Zheng, L., Cao, Y., Yan, Z., Yi, X., Zeng, H., Liu, Z., 2017. Water Quality Criteria for Copper Based on the BLM Approach in the Freshwater in China. PlosOne. DOI:10.1371/journal.pone.0170105

[7] Zhou, H., Che, L., Guo, X., Wang, X., Zhan, J., Wu, M., Hu, Y., Yi, X., Zhang, X., Liu, L., 2017. Interface modulation of bacteriogenic Ag/AgCl nanoparticles by boosting the catalytic activity for reduction reactions using Co²⁺ ions. Chemical Communications 53, 4946-4949.

[8] Leung, P.T.Y., Yi, X., Jack, C.H.I., Mak, S.S., Leung, K.M.Y.*, 2017. Photosynthetic and transcriptional responses of the marine diatom Thalassiosira pseudonana to the combined effect of temperature stress and copper exposure. Marine Pollution Bulletin 22, 938-945.

[9] 易先亮, 孙桦奇, 张可可, 张明乾. 三苯基锡对假微型海链藻(Thalassiosira pesudonana)的生长抑制及温度的影响[J]. 生态毒理学报, 2017, 12(6), 150-155.

Yi, X., Sun, H., Zhang, K., Zhang, M., 2017. Temperature-dependnet toxicities of triphenyltin to the marine diatom Thalassiosira pseudonana. Asian Journal of Ecotoxicology 12(6), 150-155.

2016年

[1] Wu, J., Yan, Z, Yi, X., Lin, Y., Ni, J., Gao, X., Liu, Z., Shi, X., 2016. ·Comparison of species sensitivity distributions constructed with predicted acute toxicity data from interspecies correlation estimation models and measured acute data for Benzo[a]pyrene. Chemosphere 144, 2183-2188.

[2] Li, P.-H., Wang, Y., Li, Y.-H., Yang, M.-M., Sun, M.-H., Guo, J., Shou, Y.-P., Yi, X., Wang, L., Xi, Z.-L., Li, Z.-Y., 2016. Characterization of polycyclic aromatic hydrocarbons in cloud deposition at Mount Heng in Southern China. Aerosol and Air Quality Research 16, 3164-3174.

[3] Jia, H., Wang, L., Li, P.*, Wang, Y.*, Guo, L., Li, T., Sun, L., Shou, Y., Mao, T., Yi, X., Characterization, long-range transport and source identification of carbonaceous aerosols during spring and autumn periods at a high mountain site in South China. Atmosphere 2016, 7(10), 122.

[4] Zhao, Y., Shou, Y., Mao, T., Guo, L., Li, P., Yi, X., Li, Q., Shen, L., Zuo, H., Wang, J., Wang, L., 2016. PAHs exposure assessment for highway toll station workers through personal particulate sampling and urinary biomonitoring in Tianjin, China. Polycyclic Aromatic Compounds. DOI: 10.1080/10406638.2016.1220959

2015年及以前

[1] Li, P.*, Wang, Y., Li, Y., Li, H., Yi, X., 2015. Origin and distribution of PAHs in ambient particulate samples at high mountain region in southern China. Advances in Meteorology 2015(6).

[2] Yan, Z., Wang, W., Zhou, J., Yi, X., Zhang, J., Wang, X., Liu, Z.*, 2015. Screening of high phytotoxicity priority pollutants and their ecological risk assessment in China’s surface waters. Chemosphere 128, 28-35. (本人单位非大工)

[3] Wu, J., Liu, Z., Yan, Z., Yi, X., 2015. Derivation of water quality criteria of phenanthrene using interspecies correlation estimation models for aquatic life in China. Environmental Science and Pollution Research 22(12), 1-7.

[4] Li, P., Wang, Y., Li, T., Sun, L., Yi, X., Guo, L., Su, R., 2015. Characterization of carbonaceous aerosols at Mount Lu in South China: implication for secondary organic carbon formation and long-range transport. Environmental Science and Pollution Research 22, 14189-14199.

[5] Zheng, X., Zang, W., Yan, Z.*, Hong, Y.*, Liu, Z., Yi, X., Wang, X., Liu, T., Zhou, L., 2015. Species sensitivity analysis of heavy metals to freshwater organisms. Ecotoxicology 24, 1621-1631.

[6] Yi, X., Kim, E., Jo, H.-J., Schlenk, D., Jung, J.*, 2009. A toxicity monitoring study on  identification and reduction of toxicants from a wastewater treatment plant. Ecotoxicology and Environmental Safety 72, 1919-1924.

[7] Yi, X., Kang, S.-W., Jung, J.*, 2010. Long-term evaluation of lethal and sublethal toxicity of industrial effluents using Daphnia magna and Moina macrocopa. Journal of Hazardous Materials 178, 982-987.

[8] Yi, X., Kim, E., Jo, H.-J., Han, T., Jung, J*, 2011. A Comparative Study on Toxicity Identification of Industrial Effluents Using Daphnia magna. Bulletin of Environmental Contamination and Toxicology 87, 319-323.

[9] Yi, X., Leung, K.M.Y.*, Lam, M.H.W., Lee, J.-S., Giesy, G.P., 2012. Review of measured concentrations of triphenyltin compounds in marine ecosystems and meta-analysis of their risks to humans and the environment. Chemosphere 89, 1015-1025.

[10] Yi, X., Leung, P.T.Y., Leung, K.M.Y.*, 2014. Photosynthetic and molecular responses of the marine diatom Thalassiosira pseudonana to triphenyltin exposure. Aquatic Toxicology 154, 48-57.

[11] Yi, X., Han, J., Lee, J.-S., Leung, K.M.Y.*, 2014. Ecotoxicity of triphenyltin on the marine copepod Tigriopus japonicus at various biological organisations: from molecular to population-level effects. Ecotoxicology 23, 1314-1325.

[12] Yi, X., Han, J., Lee, J.-S., Leung, K.M.Y.*, 2014. Toxicity of triphenyltin chloride to the rotifer Brachionus koreanus across different levels of biological organisation. Environmental Toxicology 31(1), 13-23.

[13] Li, A.J., Leung, P.T.Y., Bao,V.W.W., Yi, X., Leung, K.M.Y.*, 2014. Temperature-dependent toxicities of four common chemical pollutants to the marine medaka fish, copepod and rotifer. Ecotoxicology 23, 1564-1573.