Basic Information

 

徐芙清 特聘研究员, 博导

Research Fields

  • 固体废弃物资源化利用
  • 农业生物质资源化利用
  • 土壤改良和土肥管理
  • 经济技术分析和生命周期评价

Contact Information

 Email: xufuqing@xjtu.edu.cn

人居环境与建筑工程学院

西安交通大学创新港校区19号楼

 

站点计数器

News

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2019.5-          西安交通大学人居学院  特聘研究员

2017.4-2019.4   俄亥俄州立大学食品、农业与生物工程学院  研究科学家

2014.9-2017.3   俄亥俄州立大学食品、农业与生物工程学院  博士后

2010.9-2014.8   俄亥俄州立大学  环境科学研究院 生态学专业 博士

2005.9-2009.6   武汉大学  资源与环境科学学院  环境科学专业  学士

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  • Bioreource Technology 杂志最高引用奖,2019。

  • 海外华人农业, 生物及食品工程师协会 (AOCABFE) 领导力与服务奖。AOC Graduate Leadership and Service Award2015。

  • 美国农业和生物工程学会 (ASABE) Boyd-Scott Graduate Research Award, 博士类第一名,2014

  • 海外华人农业, 生物及食品工程师协会 (AOCABFE) 学生科研竞赛第一名,2014

  •  俄亥俄州立大学食品,农业与生物工程学院研究生成就奖。 Taiganides Graduate Student of the Year” Award 2014

  • 美国农业及生物工程学会(ASABE)会员,美国科学促进会(AAAS)会员

  • 海外华人农业、生物及食品工程师协会会员及学生会主席(2014)、副主席(2013),活动组织委员(2012)。

  • 新能源及有机废物处理公司quasar energy group 咨询顾问。

  • 近二十个SCI期刊审稿人:Applied Energy; Environmental Science Technology; Bioresource Technology; Waste Management; ChemSusChem; Energy and Fuels ; Applied Microbiology and Biotechnology; Biotechnology for Biofuels; Environmental Modeling & Assessment; Waste and biomass valorization; Resources, conservation & Recycling; International Biodeterioration & Biodegradation; Journal of Animal Science; Journal of energy institute; Journal of Environmental Science & Health; Energy Reports; Industrial Biotechnology; International Journal of Agricultural and Biological Engineering; AIMS Bioengineering 等。

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  1. Okopi, S-I, Wang J., Kong W.; Yu, Z.; Ndudi, E-A, Che, L., Gu, Z., Xu, F.* (2023) Valorization of food waste impurities by catalytic co-pyrolysis for production of pyrolysis oil with high energy potential. Journal of Analytical and Applied Pyrolysis, 2023, 170: 1-12
  2. Xu, F., Okopi, S-I, Jiang, Y., Chen, Z., Meng, L., Li, Y., Sun, W., Li, C. (2022). Multi-criteria assessment of food waste and waste paper anaerobic co-digestion: Effects of inoculation ratio, total solids content, and feedstock composition. Renewable Energy, 194, 40-50.
  3. Xu, F., Ma, H., Liang, J., Okopi, S-I, Yang, S., Cao L., Sun, W. (2022). Effects of different conditions tested “in vitro” on the phosphorus runoff potential of livestock manure. Waste Management, 147, 30- 35
  4. Wang, J., Inalegwu, S.O., Ma, H., Wang, M., Chen, R., Tian, W., Xu, F.*2021. Life cycle assessment of the integration of anaerobic digestion and pyrolysis for treatment of municipal solid waste. Bioresource technology, 2021, 125486.
  5. Wang, J., You, S., Lu, Z., Chen, R., Xu, F.* (2020). Life cycle assessment of bio-based levoglucosan production from cotton straw through fast pyrolysis. Bioresource Technology, 307:123179.
  6. Cao, L., Keener, H., Huang, Z., Liu, Y., Ruan, R., Xu, F.* (2020). Effects of temperature and inoculation ratio on methane production and nutrient solubility of swine manure anaerobic digestion. Bioresource Technology, 229: 122552.
  7. Shang, G., Zhang, C., Wang, F., Qiu, L., Guo, X., Xu, F. * (2019). Liquid hot water pretreatment to enhance the anaerobic digestion of wheat straw—effects of temperature and retention time. Environmental Science and Pollution Research, 1-11.
  1. Keener, H., Xu, F.* (2019). Novel Mathematical Model for Predicting Performance of the Sequential Batch Anaerobic Digestion Process-Part I. Transactions of the ASABE, 62719-729.
  2. Wang, F., Xu, F.*, Liu, Z., Cui, Z., Li, Y. (2019). Effects of outdoor dry bale storage conditions on corn stover and the subsequent biogas production from anaerobic digestion. Renewable Energy,134: 276-283.
  3. Xu, F., Li, Y., Ge, X., Yang, L., Li, Y.* (2018). Anaerobic digestion of food waste–challenges and opportunities. Bioresource Technology, 247: 1047-1058. (ESI Top 1% 高被引)
  1. Xu, F.#, Wang F.#, Lin L., Li Y.* (2016). Comparison of digestate from solid anaerobic digesters and dewatered effluent from liquid anaerobic digesters as inocula for solid state anaerobic digestion of yard trimmings. Bioresource Technology, 200: 753-760.
  2. Xu, F., Wang, Z.W., Li, Y. * (2015). Mathematical modeling of solid-state anaerobic digestion. Progress in Energy and Combustion Science, 51: 49-66.  
  3. Xu, F., Wang, Z.W., Li, Y.* (2014). Predicting the methane yield of lignocellulosic biomass in mesophilic solid-state anaerobic digestion based on feedstock characteristics and process parameters. Bioresource Technology, 173: 168-176.
  4. Shi, J., # Xu, F. #, Wang, Z., Stiverson, J., Yu, Z., Li, Y.* (2014). Effect of microbial and  non-microbial  features  of  inoculum  on  biogas  production  and  microbial  community dynamics  during  solid-state  anaerobic  digestion  of  corn  stover.  Bioresource Technology, 157: 188-196.
  5. Xu, F., Wang, Z.W., Tang, L., Li, Y.* (2014). A mass diffusion-based interpretation of the effect of total solids content on solid-state anaerobic digestion of cellulosic biomass. Bioresource Technology, 167: 178-185.
  1. Xu, F., Shi, J., Lv, W., Yu, Z., Li, Y.* (2013). Comparison of different anaerobic digestion effluent as inocula and nitrogen sources for solid-state anaerobic digestion of corn stover. Waste Management, 33: 26-32.
  2. Wang, Z. #, Xu, F. #, Li, Y.* (2013). Effects of total ammonia nitrogen concentration on solid-state anaerobic digestion of corn stover. Bioresource Technology, 144: 281-287.
  3. Xu, F., Li, Y.* (2012). Solid-state co-digestion of expired dog food and corn stover for methane production. Bioresource Technology, 118: 219-226.
  4. Xu, F., He, W., Zheng, X., Zhang, W.*, Cai, W., Xiong, S. (2010). Inhibition on Microcystis aeruginosa by Artemisia lavandulaefolia and its three organic solvent extracts. Acta Ecologica Sinica, 30: 745 -750.
  5. Cao,L., J Wang, T Zhou, Z Li, S Xiang, Xu, F.Ruan, R., Liu, Y. (2019). Evaluation of ammonia recovery from swine wastewater via a innovative spraying technology. Bioresource technology 272, 235-240.
  6. Lin, L., Xu, F., Ge, X., Li, Y., (2018). Anaerobic digestion and composting in the food-energy-water nexus: a comparative review of sustainable waste management practices. Renewable and Sustainable Energy Reviews, 89, 151-167.
  7. Li, Y., J Lu, Xu, F., Y Li, D Li, G Wang, S Li, H Zhang, Y Wu, A Shah, G Li, (2018). Reactor performance and economic evaluation of anaerobic co-digestion of dairy manure with corn stover and tomato residues under liquid, hemi-solid, and solid state conditions. Bioresource technology 270, 103-112.
  8. Li, Y., Y Wang, Z Yu, J Lu, D Li, G Wang, Y Li, Y Wu, S Li, Xu, F., G Li, X Gong, (2018). Effect of inoculum and substrate/inoculum ratio on the performance and methanogenic archaeal community structure in solid state anaerobic co-digestion of tomato residues with dairy manure and corn stover. Waste Management 81, 117-127.
  9. Li, Y., Xu, F., Li., Y, Lu, J., Li, S., Shah, A., Zhang, X., Zhang, H., Gong X., Li, G.* (2018). Reactor performance and energy analysis of solid state anaerobic co-digestion of dairy manure with corn stover and tomato residues. Waste Management, 73130-139.
  1. Wang, Z.W., Xu, F., Manchala, K.R., Sun, Y., Li, Y.* (2016). Fractal-like kinetics of the solid-state anaerobic digestion. Waste Management, 53: 55-61.
  2. Liu, S., Xu, F., Ge, X., Li, Y.* (2016). Comparison between ensilage and fungal pretreatment for storage of giant reed and subsequent methane production. Bioresource Technology, 209: 246-253.
  3. Liu, S., Xu, F., Liew, L., Li, Y.* (2016). Food waste addition for enhanced giant reed esilage and methane production. Transactions of the ASABE 59 (3), 727-736.
  4. Liu, S., Ge, X., Xu, F., Li, Y.* (2016). Effect of total solids content on giant reed ensilage and subsequent anaerobic digestion. Process Biochemistry 51 (1): 73-79.
  5. Ge, X., Xu, F., Li, Y.* (2016). Solid-state anaerobic digestion of lignocellulosic biomass: Recent progress and perspectives. Bioresource Technology, 205: 239-249.
  6. Ge, X., Xu, F., Vasco-Correa, J., Li, Y.* (2016). Giant reed: A competitive energy crop in comparison with miscanthus. Renewable and Sustainable Energy Reviews, 54: 350-362.
  7. Yang, L., Xu, F., Ge, X. (2015). Challenges and strategies for solid-state anaerobic digestion of lignocellulosic biomass. Renewable and Sustainable Energy Reviews, 44: 824-834. ESI Top 1% 高被引
  8. Hochman, G.*, Wang, S., Li, Q., Gottlieb, P.D., Xu, F., Li, Y. (2015). Cost of organic waste technologies: A case study for New Jersey. AIMS Energy, 3 (3): 450–462.
  9. Lin, L., Yang, L., Xu, F., Frederick, M., Li, Y.* (2014). Comparison of solid-state anaerobic digestion and composting of yard trimmings with effluent from liquid anaerobic digestion. Bioresource Technology, 169: 439-446.
  10. Zhu, J., Zheng, Y., Xu, F., Li, Y.* (2014). Solid-state anaerobic co-digestion of hay and soybean processing waste for biogas production. Bioresource Technology, 154: 240-247.
  11. Zheng, Y., Zhao, J., Xu, F., Li, Y.* (2014).  Pretreatment of lignocellulosic biomass for enhanced biogas production. Progress in Energy and Combustion Science, 42: 35-53. (IF: 26.467, ESI Top 1% 高被引)
  12. Zhang, W.*, Xu, F., He, W., Zheng, X., Yang, C. (2009). Inhibitive effects of three compositae plants on Microcystis aeruginosa. Frontier of Environmental Science & Engineering in China, 3: 48-55.

 中文文章:

  1. 李超, 周瀛, 刘刚金, 徐芙清,寇巍,钱明宇 (2016) 基于渗滤液回流的干式厌氧发酵研究进展。可再生能源 34 (11), 1727-1738
  2. 徐芙清,何伟, 郑星,张维昊*,蔡伟伟,唐倩(2010)。野艾蒿及其有机提取物对铜绿微囊藻生长的抑制作用。生态学报,201030(3):745~750