RESUME

  OFFICE ADDRESS AND TELEPHONE

727# South Jingming Road, Chenggong, Kunming, China, 650500

Faculty of Environmental Sciences and Engineering

Kunming University of Science and Technology (Chengong campus)

E-mail : panbocai@aliyun.com

Name: Bo Pan            Date of birth: August 1976              Gender:  Male

Associate editor, European Journal of Soil Science

Dean, Faculty of Environmental Sciences and Engineering, KUST

Director, Yunnan Provincial Key Laboratory of Carbon Sequestration and Pollution Control in Soils

Funding Committee of Environmental Geoscience, NSFC

Outstanding Young Scholar, NSFC

Science and Technology Leading Talent, MOE China

Experience

2014.3-2015.3   Senior visiting professor   University of Massachusetts, Amherst, USA         Environmental Soil Chemistry

2008.12-present  Professor      Faculty of Environmental Sciences and Engineering, KUST

2006.4-2008.12  Post Doc.   University of Massachusetts, Amherst, USA         Environmental Soil Chemistry

1999.9-2006.1    Ph.D.   Peking University, Beijing, China   Environmental Science

2001.7-2001.12  Exchange Student   University of Freiburg, Germany   Environmental Chemistry

1995.9-1999.7    B.S.   Kunming University of Science and Technology, China   Environmental Engineering

Research Interest

· Environmental implications of natural organic matter

· Environmental applications and implications of nanotechnology

· Carbonaceous materials and organic pollutants

Selected Papers:

1. Chang, Z., Tian, L., Li, F., Wu, M., Steinberg, C.E.W., Pan, B., Xing, B., 2020. Organo-mineral complexes protect condensed organic matter as revealed by benzene-polycarboxylic acids. Environmental Pollution 260.

2. Chang, Z., Tian, L., Li, F., Zhou, Y., Wu, M., Steinberg, C.E.W., Dong, X., Pan, B., Xing, B., 2018a. Benzene polycarboxylic acid - A useful marker for condensed organic matter, but not for only pyrogenic black carbon. Science of the Total Environment 626, 660-667.

3. Chang, Z., Tian, L., Wu, M., Dong, X., Peng, J., Pan, B., 2018b. Molecular markers of benzene polycarboxylic acids in describing biochar physiochemical properties and sorption characteristics. Environmental Pollution 237, 541-548.

4. Chang, Z., Tian, L., Zhang, J., Zhao, Q., Li, F., Wu, M., Pan, B., 2019. Combining bulk characterization and benzene polycarboxylic acid molecular markers to describe biochar properties. Chemosphere 227, 381-388.

5. Chen, Q., Tang, Z., Li, H., Wu, M., Zhao, Q., Pan, B., 2020. An electron-scale comparative study on the adsorption of six divalent heavy metal cations on MnFe2O4@CAC hybrid: Experimental and DFT investigations. Chemical Engineering Journal 381.

6. Chu, G., Zhao, J., Huang, Y., Zhou, D., Liu, Y., Wu, M., Peng, H., Zhao, Q., Pan, B., Steinberg, C.E.W., 2018. Phosphoric acid pretreatment enhances the specific surface areas of biochars by generation of micropores. Environmental Pollution 240, 1-9.

7. Chu, G., Zhao, J., Liu, Y., Lang, D., Wu, M., Pan, B., Steinberg, C.E.W., 2019. The relative importance of different carbon structures in biochars to carbamazepine and bisphenol A sorption. Journal of Hazardous Materials 373, 106-114.

8. Cu, L., Huang, B., Han, F., Pan, B., Xu, Z., Cu, X., Xu, H., Pan, X., Dionysiou, D.D., 2019. Spontaneous changes in dissolved organic matter affect the bio-removal of steroid estrogens. Science of the Total Environment 689, 616-624.

9. Dong, X., Wang, Q., Peng, J., Wu, M., Pan, B., Xing, B., 2018. Transfer of polycyclic aromatic hydrocarbons from mother to fetus in relation to pregnancy complications. Science of the Total Environment 636, 61-68.

10. Fan, J., Li, Y., Yu, H., Li, Y., Yuan, Q., Xiao, H., Li, F., Pan, B., 2020. Using sewage sludge with high ash content for biochar production and Cu (II) sorption. Science of the Total Environment 713.

11. Ghosh, S., Guo, Q., Wang, Z., Zhang, D., Pradhan, N.R., Pan, B., Xing, B., 2019. Tannic acid- and cation-mediated interfacial self-assembly and epitaxial growth of fullerene (nC(60)) and kaolinite binary graphitic aggregates. Journal Of Colloid And Interface Science 556, 717-725.

12. Ghosh, S., Guo, Q., Wang, Z., Zhang, D., Pradhan, N.R., Pan, B., Xing, B., 2020. Tannic acid- and cation-mediated interfacial self-assembly and epitaxial growth of fullerene (nC(60)) and kaolinite binary graphitic aggregates (vol 556, pg 717, 2019). Journal Of Colloid And Interface Science 564, 513-513.

13. Guo, Q., Wang, Z., Xu, Q., Mao, H., Zhang, D., Ghosh, S., Pradhan, N.R., Pan, B., Xing, B., 2020. Suspended state heteroaggregation kinetics of kaolinite and fullerene (nC(60)) in the presence of tannic acid: Effect of pi-pi interactions. Science of the Total Environment 713.

14. Jin, H., Huang, S., Wang, L., Chen, X., Pan, B., Li, J., 2019. Selective ensemble learning based on evolutionary multi-objective optimization for soft sensor development. Journal of Chemical Engineering of Chinese Universities 33, 680-691.

15. Konczak, M., Pan, B., Ok, Y.S., Oleszczuk, P., 2020. Carbon dioxide as a carrier gas and mixed feedstock pyrolysis decreased toxicity of sewage sludge biochar. Science of the Total Environment 723.

16. Li, F., Chang, Z., Khaing, K., Zhou, Y., Zhao, H., Liang, N., Zhou, D., Pan, B., Steinberg, C.E.W., 2019a. Organic matter protection by kaolinite over bio-decomposition as suggested by lignin and solvent-extractable lipid molecular markers. Science of the Total Environment 647, 570-576.

17. Li, F., Liang, N., Zhang, P., Xu, Y., Chang, Z., Wu, M., Duan, W., Steinberg, C.E.W., Pan, B., 2018a. Protection of extractable lipid and lignin: Differences in undisturbed and cultivated soils detected by molecular markers. Chemosphere 213, 314-322.

18. Li, F.F., Zhang, P.C., Wu, D.P., Xu, Y., Chen, F.Y., Chang, Z.F., Chu, G., Wang, L., Pan, B., Xing, B.S., 2018b. Acid pretreatment increased lipid biomarker extractability: a case study to reveal soil organic matter input from rubber trees after long-term cultivation. European Journal of Soil Science 69, 315-324.

19. Li, H., Cao, Y., Zhang, D., Pan, B., 2018c. pH-dependent K-OW provides new insights in understanding the adsorption mechanism of ionizable organic chemicals on carbonaceous materials. Science of the Total Environment 618, 269-275.

20. Li, H., Wei, C., Zhang, D., Pan, B., 2019b. Adsorption of bisphenol A on dispersed carbon nanotubes: Role of different dispersing agents. Science of the Total Environment 655, 807-813.

21. Li, J., Chen, Y., He, L., Liang, N., Wang, L., Zhao, J., Pan, B., 2020. Sorption of sulfamethoxazole on biochars of varying mineral content. Environmental Science-Processes & Impacts 22, 1287-1294.

22. Lieke, T., Zhang, X., Steinberg, C.E.W., Pan, B., 2018. Overlooked Risks of Biochars: Persistent Free Radicals trigger Neurotoxicity in Caenorhabditis elegans. Environmental Science & Technology 52, 7981-7987.

23. Liu, G., Zheng, H., Jiang, Z., Zhao, J., Wang, Z., Pan, B., Xing, B., 2018a. Formation and Physicochemical Characteristics of Nano Biochar: Insight into Chemical and Colloidal Stability. Environmental Science & Technology 52, 10369-10379.

24. Liu, S., Liu, Y., Pan, B., He, Y., Li, B., Zhou, D., Xiao, Y., Qiu, H., Vijver, M.G., Peijnenburg, W.J.G.M., 2020. The promoted dissolution of copper oxide nanoparticles by dissolved humic acid: Copper complexation over particle dispersion. Chemosphere 245.

25. Liu, S., Yu, W.-H., Li, F., Zhao, J., Yin, R.-Y., Zhou, Z.-M., Pan, B., 2018b. Fertilizer application in rural cropland drives cadmium enrichment in bats dwelling in an urban area. Environmental Pollution 242, 970-975.

26. Liu, Y., Dai, Q., Jin, X., Dong, X., Peng, J., Wu, M., Liang, N., Pan, B., Xing, B., 2018c. Negative Impacts of Biochars on Urease Activity: High pH, Heavy Metals, Polycyclic Aromatic Hydrocarbons, or Free Radicals? Environmental Science & Technology 52, 12740-12747.

27. Pan, B., Jin, H., Yang, B., Feng, L., Chen, X., 2019a. Soft Sensor Development Based on Ensemble Locally Weighted Partial Least Squares Using Diverse Weighted Similarity Measures. Information and Control 48, 217-223,231.

28. Pan, B., Li, H., Lang, D., Xing, B., 2019b. Environmentally persistent free radicals: Occurrence, formation mechanisms and implications. Environmental Pollution 248, 320-331.

29. Pignatello, J., Yang, J., Pan, B., Xing, B., 2018. Inherent reactivity of chars from model feedstocks, lignin and cellulose: Persistent free radicals, reactive oxygen species, and non-radical direct reacting sites. Abstracts of Papers of the American Chemical Society 255.

30. Ren, M., Yan, L., Pang, Y., Jia, X., Huang, J., Shen, G., Cheng, H., Wang, X., Pan, B., Li, Z., Wang, B., 2020. External interference from ambient air pollution on using hair metal(loid)s for biomarker-based exposure assessment. Environment International 137.

31. Tao, W., Duan, W., Liu, C., Zhu, D., Si, X., Zhu, R., Oleszczuk, P., Pan, B., 2020. Formation of persistent free radicals in biochar derived from rice straw based on a detailed analysis of pyrolysis kinetics. Science of the Total Environment 715.

32. Wang, P., Pan, B., Li, H., Huang, Y., Dong, X., Ai, F., Liu, L., Wu, M., Xing, B., 2018. The Overlooked Occurrence of Environmentally Persistent Free Radicals in an Area with Low-Rank Coal Burning, Xuanwei, China. Environmental Science & Technology 52, 1054-1061.

33. Wang, P., Zhang, D., Tang, H., Li, H., Pan, B., 2019. New insights on the understanding of the high adsorption of bisphenol compounds on reduced graphene oxide at high pH values via charge assisted hydrogen bond. Journal of Hazardous Materials 371, 513-520.

34. Wu, D., Li, F., Chen, Q., Wu, M., Duan, W., Zhao, Q., Pan, B., Xing, B., 2020. Mediation of rhodamine B photodegradation by biochar. Chemosphere 256, 127082-127082.

35. Wu, M., Wu, D., Chang, Z., Xu, Y., Pan, B., 2019. Characterization of Biochars Properties in Soil System by BPCA Molecular Biomarkers. Materials Review 33, 536-540.

36. Yi, P., Chen, Q., Li, H., Lang, D., Zhao, Q., Pan, B., Xing, B., 2019. A Comparative Study on the Formation of Environmentally Persistent Free Radicals (EPFRs) on Hematite and Goethite: Contribution of Various Catechol Degradation Byproducts. Environmental Science & Technology 53, 13713-13719.

37. Zhang, D., Qiu, J., Shi, L., Liu, Y., Pan, B., Xing, B., 2020. The mechanisms and environmental implications of engineered nanoparticles dispersion. Science of the Total Environment 722.

38. Zhang, T., Lowry, G.V., Capiro, N.L., Chen, J., Chen, W., Chen, Y., Dionysiou, D.D., Elliott, D.W., Ghoshal, S., Hofmann, T., Hsu-Kim, H., Hughes, J., Jiang, C., Jiang, G., Jing, C., Kavanaugh, M., Li, Q., Liu, S., Ma, J., Pan, B., Phenrat, T., Qu, X., Quan, X., Saleh, N., Vikesland, P.J., Wang, Q., Westerhoff, P., Wong, M.S., Xia, T., Xing, B., Yan, B., Zhang, L., Zhou, D., Alvarez, P.J.J., 2019. In situ remediation of subsurface contamination: opportunities and challenges for nanotechnology and advanced materials. Environmental Science-Nano 6, 1283-1302.

39. Zhao, J., Chu, G., Pan, B., Zhou, Y., Wu, M., Liu, Y., Duan, W., Lang, D., Zhao, Q., Xing, B., 2018a. Homo-Conjugation of Low Molecular Weight Organic Acids Competes with Their Complexation with Cu(II). Environmental Science & Technology 52, 5173-5181.

40. Zhao, L., Liang, N., Lang, D., Zhou, D., Dong, X., Peng, J., Liu, L., Pan, B., Xing, B., 2019. Heating methods generate different amounts of persistent free radicals from unsaturated fatty acids. Science of the Total Environment 672, 16-22.

41. Zhao, Q., Ma, W., Pan, B., Zhang, Q., Zhang, X., Zhang, S., Xing, B., 2018b. Wrinkle-induced high sorption makes few-layered black phosphorus a superior adsorbent for ionic organic compounds. Environmental Science-Nano 5, 1454-1465.