»ù±¾ÇéÐÎ
ÕÅЦǧ�£¬£¬Å®�£¬£¬Öй²µ³Ô±�£¬£¬ÏÖÈÎÒ¼ºÅÓéÀÖAPPÇéÐÎÓ뻯ѧ¹¤³ÌѧԺרÈÎÎ÷ϯ¡£�¡£�¡£½ü3Äê�£¬£¬ÒÔµÚÒ»/ͨѶ×÷Õß½ÒÏþSCIÂÛÎÄ14ƪ�£»ÏÖÔÚÖ÷³Ö¹ú¼Ò×ÔÈ»¿Æѧ»ù½ðÇàÄê¿Æѧ»ù½ðµÈ¿ÆÑÐÏîÄ¿/¿ÎÌâ7Ïî¡¢�¡¢ÆóÒµÊÖÒÕ×ÉѯÏîÄ¿1Ïî�£¬£¬ÒÔÏîÄ¿Ö÷¸É¼ÓÈë¹ú¼ÒÖصãÑз¢ÍýÏë¡¢�¡¢¹ã¶«Ê¡×ÔÈ»¿Æѧ»ù½ð׿ԽÇàÄêÍŶӵÈÏîÄ¿¡£�¡£�¡£×÷ΪµÚÒ»Ö¸µ¼ÏÈÉú�£¬£¬»ñµÃµÚÊ®¾Å½ì¡°ÌôÕ½±¡±ÌìÏ´óѧÉú¿ÎÍâѧÊõ¿Æ¼¼×÷Æ·¾ºÈü¡°½Ò°ñ¹Ò˧¡±×¨ÏîÈüÌìÏÂÌصȽ±¡£�¡£�¡£
ÁªÏµ·½Ê½
µØµã�£º�£º£º¹ã¶«Ê¡½ÃÅÊÐÅî½Çø¶«³É´å22ºÅ Ò¼ºÅÓéÀÖAPP ÇéÐÎÓ뻯ѧ¹¤³ÌѧԺ
Óʱà�£º�£º£º529020
ÓÊÏä�£º�£º£ºzhangxq@wyu.edu.cn
ÊÂÇéÂÄÀú
2025Äê6ÔÂÖÁ½ñ�£¬£¬Ò¼ºÅÓéÀÖAPP�£¬£¬ÇéÐÎÓ뻯ѧ¹¤³ÌѧԺ�£¬£¬Ë¶Ê¿Éúµ¼Ê¦
2020Äê5ÔÂÖÁ2025Äê5ÔÂ�£¬£¬»ªÄÏÀí¹¤´óѧ�£¬£¬ÏȽøÔìÖ½ÓëÖ½»ùÖÊÁÏÌìÏÂÖصãʵÑéÊÒ�£¬£¬×¨Ö°¸±Ñо¿Ô±
2017Äê5ÔÂÖÁ2020Äê5ÔÂ�£¬£¬Éú̬ÇéÐβ¿ÇéÐÎÍýÏëÔº�£¬£¬ÖúÀíÑо¿Ô±
2015Äê7ÔÂÖÁ2017Äê7ÔÂ�£¬£¬Ç廪´óѧ�£¬£¬²©Ê¿ºó
½ÌÓý¼°Ñ§Ï°ÂÄÀú
2013Äê7ÔÂ-2014Äê8ÔÂ�£¬£¬ÃÀ¹úÆնɴóѧ�£¬£¬ÁªºÏ×÷Óý
2009Äê9ÔÂ-2015Äê7ÔÂ�£¬£¬ÖйúÅ©Òµ´óѧ�£¬£¬²©Ê¿
2005Äê9ÔÂ-2009Äê6ÔÂ�£¬£¬Ìì½ò´óѧ�£¬£¬Ñ§Ê¿
Ö÷ÒªÑо¿Æ«Ïò
ÉúÎïÖÊÂÌÉ«´¦ÀíÓë¸ßֵʹÓá¢�¡¢ÉúÎïÖÊ»ù¹¦Ð§ÖÊÁÏ
¿ÆÑÐÏîÄ¿
1. ¹ú¼Ò×ÔÈ»¿Æѧ»ù½ðÇàÄê¿Æѧ»ù½ðÏîÄ¿�£¬£¬2025.01-2027.12�£¬£¬30Íò�£¬£¬Ö÷³Ö
2. ¹ã¶«Ê¡×ÔÈ»¿Æѧ»ù½ðÃæÉÏÏîÄ¿�£¬£¬2025.01-2027.12�£¬£¬10Íò�£¬£¬Ö÷³Ö
3. ¹ã¶«Ê¡»ù´¡ÓëÓ¦Óûù´¡Ñо¿ÇøÓòÁªºÏ»ù½ð�£¬£¬2023.11-2026.10�£¬£¬10Íò�£¬£¬Ö÷³Ö
4. ¹ãÖÝÊÐÓ¦Óûù´¡Ñо¿ÍýÏëÏîÄ¿�£¬£¬2025.01-2026.12�£¬£¬5Íò�£¬£¬Ö÷³Ö
5. ÖÐÑë¸ßÐ�£»ù±¾¿ÆÑÐÓªÒµ·ÑÃæÉÏÏîÄ¿�£¬£¬2023.01-2024.12�£¬£¬10Íò�£¬£¬Ö÷³Ö
6. ¹ú¼ÒÖصãʵÑéÊÒ¿ª·Å»ù½ðÏîÄ¿�£¬£¬2023.01-2024.12�£¬£¬5Íò�£¬£¬Ö÷³Ö
7. ÁëÄÏÏÖ´úÅ©Òµ¿ÆѧÓëÊÖÒչ㶫ʡʵÑéÊÒÕØÇì·ÖÖÐÐÄ¡°Ê®ËÄÎ塱×Ó¿ÎÌâ�£¬£¬2022.10-2024.09�£¬£¬70Íò�£¬£¬Ö÷³Ö
8. ¹ã¶«Ê¡×ÔÈ»¿Æѧ»ù½ð׿ԽÇàÄêÍŶÓÏîÄ¿�£¬£¬2023.01-2026.12�£¬£¬300Íò�£¬£¬Ö÷¸É
9. ¹óÖÝę́¾Æ¹É·ÝÓÐÏÞ¹«Ë¾ÊÖÒÕ¿ª·¢ÏîÄ¿�£¬£¬2024.12-2027.12�£¬£¬260Íò�£¬£¬Ö÷¸É
½ÒÏþѧÊõÂÛÎÄ
1. X. Zhang, L. Lin, H. Zhou, J. Zou, W. Zhao, G. Zhou, Z. Lei, X. Wang*. A dual-dynamic crosslinking network enabled strong, flexible, self-healing, and biodegradable chitosan fiber paper/vitrimer composites for plastic substitution. Carbohydrate Polymers, 2025, 358: 123523.
2. X. Zhang, L. Lin, H. Zhou, G. Zhou, X. Wang*. All-natural chitosan-based polyimine vitrimer with multiple advantages: A novel strategy to solve nondegradable plastic waste pollution. Journal of Hazardous Materials, 2024, 465: 133030.
3. X. Zhang, H. Zhang, G. Zhou, Z. Su, X. Wang*. Flexible, thermal processable, self-healing, and fully bio-based starch plastics by constructing dynamic imine network. Green Energy & Environment, 2024, 9(10): 1610-1618.
4. H. Zhou1, X. Zhang1, G. Zhou, M. Demi?r, Z. Lei*, W. Zhang, X. Wang*. Water-mediated synthesis of full-biomass vitrimer with enhanced moldability, recyclability, and biodegradability. ACS Sustainable Chemistry & Engineering, 2024, 12(18): 6952¨C6959.
5. G. Zhou, X. Zhang*, Z. Lei, H. Zhou, X. Wang*. Dynamic imine crosslinking for waterproof starch plastic with tunable mechanical properties. International Journal of Biological Macromolecules, 2024, 282, 136872.
6. X. Zhang, Z. Wu, Y. Wu, A. S. Giwa, S. Huang*, L. Niu. Visible-light-driven simultaneous decontamination of multi-antibiotics by facile synthesized BiOCl loaded food wastes biochar. Environmental Pollution, 2023, 316: 120683.
7. Y. Lu1, L. Liu1, X. Zhang1, T. Zhao, Y. Jin, Y. Zhang, S. Huang*. Effects of chemical oxygen demand/nitrogen on electrochemical performances and denitrification efficiency in single-chamber microbial fuel cells: Insights from electron transfer and bacterial communities. Bioresource Technology, 2023, 387: 129690.
8. L. Kan, X. Zhang*, Q. Huang, Y. Wang, M. Tiao, Q. Huang, W. Wei, F. Zhang, X. Wang*. Fabrication of cellulose-based and fluorine/silane free superhydrophobic paper by a green and sustainable approach. Industrial Crops & Products, 2023, 203: 117226.
9. X. Zhang, Y. Wu, A. S. Giwa, J. Xiong, S. Huang*, L. Niu. Improving photocatalytic activity under visible light over a novel food wastes biochar-based BiOBr nanocomposite. Chemosphere, 2022, 297: 134152.
10. Y. Wang, X. Zhang*, L. Kan, F. Shen, H. Ling, X. Wang*. All-biomass-based eco-friendly waterproof coating for paper-based green packaging. Green Chemistry, 2022, 24, 7039-7048.
11. Y. Wu, X. Zhao, Y. Li, Y. Ling, Y. Zhang, X. Zhang*, S. Huang*. New insights into the efficient charge transfer by construction of adjustable dominant facet of BiOI/CdS heterojunction for antibiotics degradation and chromium Cr (VI) reduction under visible-light irradiation. Chemosphere, 2022, 302: 134862.
12. Y. Lu, A. T. Chow, L. Liu, Y. Wang, X. Zhang*, S. Huang*, Y. Zhang. Effects of Vallisneria natans on H2S and S2? releases in black-odorous waterbody under additional nitrate: Comprehensive performance and microbial community structure. Journal of Environmental Management, 2022, 316: 115226.
13. L. Niu, Y. Hu, H. Hu, X. Zhang*, Y. Wu, A. S. Giwa, S. Huang*. Kitchen-waste-derived biochar modified nanocomposites with improved photocatalytic performances for degrading organic contaminants. Environmental Research, 2022, 214: 114068.£¨±¾¿ÆÉúÒ»×÷£©
14. X. Zhang, I. M. Lopes, J.-Q. Ni*, Y. Yuan, C.-H. Huang, D. R. Smith, I. Chaubey, S. Wu. Long-term performance of three mesophilic anaerobic digesters to convert animal and agro-industrial wastes into organic fertilizer. Journal of Cleaner Production, 2021, 307: 127271.
»ñ½±¼°ÉùÓþ
×÷ΪµÚÒ»Ö¸µ¼ÏÈÉú£¨1/3£©�£¬£¬»ñµÃµÚÊ®¾Å½ì¡°ÌôÕ½±¡±ÌìÏ´óѧÉú¿ÎÍâѧÊõ¿Æ¼¼×÷Æ·¾ºÈü2024Äê¶È¡°½Ò°ñ¹Ò˧¡±×¨ÏîÈüÌìÏÂÌصȽ±¡£�¡£�¡£
