徐期勇，男，博士，北京大學(xué)副教授，博士生導(dǎo)師，主要研究領(lǐng)域?yàn)楣腆w廢棄物污染控制與資源化利用和管理。2005年美國(guó)佛羅里達(dá)大學(xué)環(huán)境工程系獲工學(xué)博士學(xué)位，博士后，主要從事固體廢棄物資源化方向研究。2006年12月到2010年6月，美國(guó)IWCS公司的高級(jí)工程師，從事環(huán)境工程設(shè)計(jì)與咨詢工作，具有美國(guó)注冊(cè)環(huán)境工程師執(zhí)業(yè)資格。

2010年7月回國(guó)，北京大學(xué)深圳研究生院從事教學(xué)科研工作，深圳市再生復(fù)合環(huán)境材料工程實(shí)驗(yàn)室主任，擔(dān)任Waste Management（Elsevier）和核心期刊《環(huán)境衛(wèi)生工程》副主編，獲得北京大學(xué)優(yōu)秀德育獎(jiǎng)、教學(xué)優(yōu)秀獎(jiǎng)、北京大學(xué)深圳研究生院優(yōu)秀教師。主持各類科研項(xiàng)目20余項(xiàng)。在國(guó)內(nèi)外專業(yè)核心期刊上發(fā)表論文140余篇，其中第一/通訊作者SCI論文70余篇，已授權(quán)中國(guó)發(fā)明專利8件，美國(guó)發(fā)明專利１件，出版中、英文專著各一部。

聯(lián)系方式

地址：北京大學(xué)深圳研究生院E棟315室

電話：0755-26033226

郵箱：qiyongxu@pkusz.edu.cn 

教育工作背景

• 2010.7—至今 北京大學(xué)深圳研究生院,副教授;
• 2006—2010.7 美國(guó)IWCS 環(huán)境咨詢公司的高級(jí)工程師;
• 2005—2006年 美國(guó)佛羅里達(dá)大學(xué)環(huán)境工程系博士后;
• 2005 美國(guó)佛羅里達(dá)大學(xué)環(huán)境工程博士；
• 2000 四川大學(xué)環(huán)境科學(xué)與工程系環(huán)境科學(xué)碩士;
• 1996 南昌航空大學(xué)環(huán)境工程學(xué)士

研究領(lǐng)域

• 城市固廢污染控制與資源化技術(shù);
• 有機(jī)垃圾處理與資源化：餐廚垃圾、木質(zhì)廢棄物
• 生物反應(yīng)器填埋場(chǎng)、填埋場(chǎng)污染場(chǎng)地修復(fù);
• 惡臭污染控制及溫室氣體減排技術(shù);

教授課程

秋季:廢物資源化原理與技術(shù)(北京大學(xué)深圳研究生院精品課程)

春季:固廢工程設(shè)計(jì)與進(jìn)展

英文論文（第一/通訊作者）

1.Yuan, T., Sun, R., Shao, M., and Xu, Q.*. Enhanced food waste anaerobic digestion by controlling simultaneously sludge load selection and iron oxide addition. Renewable Energy. 2023, 217: 119213.

2.Shao, M., Zhang, C., Cui, G., Bai, X., Wang, N., Chen, Q., and Xu, Q.^*. Inhibition insights of hydrothermal liquid digestate in anaerobic digestion: impact on organics conversion and inhibitor degradation. Journal of Hazardous Materials. 2023, 459: 132221.

3.Wang, Q., Duan, H., Miao, Q., Li, H., Liu, J., Wang, N., and Xu, Q.^*Life cycle assessment-driven optimization of venous industry parks strategies: A case study in Shenzhen city. Environmental Impact Assessment Review. 2023, 103: 107250.

4.Noureen, L., Zaman, S., Shah, W., Wang, Q., Humayun, M., Xu, Q.^*, and Wang, X.^*. Bifunctional photothermal membrane for high-temperature interfacial solar steam generation and off-grid sterilization. Chemical Engineering Journal. 2023, 473: 145122.

5.Yuan, T., Shi, X., and Xu, Q.*. Enhancing methane production from food waste with iron-carbon micro-electrolysis in a two-stage process. Bioresource Technology. 2023, 385: 129474.

6.Wang, N., Bai, X., Huang, D., Chen, Q., Shao, M., and Xu, Q.*. Impacts of digestate-based compost on soil property and nutrient availability. Environmental Research. 2023, 234: 116551.

7.Wang, Q., Bai, X., Miao, Q., Wang, T., Wang, X., and Xu, Q.^*Isolation and characterization of quorum quenching bacteria from municipal solid waste and bottom ash co-disposal landfills. Waste Management & Research. 2023 Mar 13;734242X231155807

8.Pan, X., Yu, Q., Chen, S., Li, Y., Jiao, T., Li, W., Zhang, C., Kureshi, A., Cheng, L.^*, and Xu, Q.^*. Dissecting contributions of representative heavy metal components in PM2.5 to its cytotoxicity. Ecotoxicology and Environmental Safety. 2023, 251: 114562.

9.Wang N., Bai, X., Huang, D., Shao, M., Chen, Q., and Xu, Q.*. Insight into the impacting mechanism of digestate-derived biochar on microbial community succession during composting of digestate from food waste. Chemosphere. 2023, 316: 137786.

10.Yuan, T., Sun, R., Shao, M., Chen, Q., Lin, Y., and Xu, Q.*Biochar regulates enzymes activity and interspecies electron transfer to promote bioenergy recovery from a continuous two-stage food waste anaerobic digestion process. Journal of Cleaner Production. 2023, 385: 135690.

11.Shao, M., Zhang, C., Wang, X., Wang, N., Chen, Q., Cui, G., and Xu, Q.*Co-Anaerobic digestion of food waste and hydrothermal treated liquid digestate: promotion of methane production by self-generated hydrochars. Environmental Science and Ecotechnology. 2023, 15: 100239.

12.Noureen, L., Wang, Q., Humayun, M., Shah, W. A., Xu, Q.*, and Wang, X.*. Recent advances in structural engineering of photocatalysts for environmental remediation. Environmental Research. 2023. 219:115084.

13.Bai, X., Huang, D., Chen, Y., Wang, Q., Chen, Q., Wang, N., and Xu, Q.*. Examination of Fe speciation preference for aerobic methane oxidation by using isotopic Fe-modified zeolites. Chemical Engineering Journal. 2023, 455: 140844.

14.Huang, D., Wang, N., Bai, X., Chen, Y, and Xu, Q.^*. The influencing mechanism of O₂, H₂O, and CO₂on the H₂S removal of food waste digestate-derived biochar with abundant minerals. Biochar. 2022, 4:71.

15.Wang, Q., Miao, Q., Liu, F., Wang, X., and Xu, Q.*. Coupled effect of microbiologically induced calcium carbonate and biofilms in leachate. Journal of Environmental Management. 2022, 324: 116350.

16.Wang, Q., Miao, Q., Wang, X., Wang, T., and Xu, Q.*Role of surface physicochemical properties of pipe materials on bio-clogging in leachate collection systems from a thermodynamic perspective. Science of the Total Environment, 2022, 851: 158263.

17.Zhang, C., Bao, Q., Chen, Q., Wu, H., Shao, M., Wang, N., andXu, Q.* Membrane fouling behaviors and evolution during food waste digestate treatment. Journal of Membrane Science. 2022, 660: 120883.

18.Chen, Q., Dong, Z., Zhang, C., Yue, Y., and Xu, Q.*. Variation behavior of organic compounds in melamine-urea-formaldehyde impregnated bond paper in different pyrolysis stages. Journal of Hazardous Materials. 2022, 436:129237.

19.Zhang, C., Wang, X., Shao, M., Li, H., Chen, Q., Wang, N., and Xu, Q.*Synthesis of nitrogen-enriched hydrochar via co-hydrothermal reaction of liquid digestate and corn stalk. Science of the Total Environment. 2022. 836: 155572.

20.Wang, N., Huang, D., Bai, X., Lin, Y., Miao, Q., Shao, M., and Xu, Q.^*. Mechanism of digestate-derived biochar on odorous gas emissions and humification in composting of digestate from food waste. Journal of Hazardous Materials. 2022, 434: 128878.

21.Huang, D.D., Liang, M., Wang, N., and Xu, Q.^*. The efficiency and mechanism of humidity in alleviating CO₂inhibition on H₂S adsorption to straw biochars. Environmental Research. 2022, 210: 113008.

22.Zhang, C., Bao, Q., Wu, H., Shao, M., Wang, X., and Xu, Q.^*. Impact of polysaccharide and protein interactions on membrane fouling: particle deposition and layer formation. Chemosphere. 2022, 296: 134056.

23.Chen, Q., Zhang, J., Zhang, C., Dong, Z., Yue, Y., and Xu, Q.^*. Effects of water-soluble acrylic resin coatings on the pyrolysis behavior of wooden bulky waste. Fuel Processing Technology. 2022, 228: 107170.

24.Wang, N., Chen, Q., Zhang, C., Dong, Z., and Xu, Q.^*. Improvement in the physicochemical characteristics of biochar derived from digestate of food waste with different moisture contents. Science of the Total Environment. 2022, 819: 153100.

25.Wang, N., Huang, D., Shao, M., Sun, R., and Xu, Q.^*. Use of activated carbon to reduce ammonia emissions and accelerate humification in composting digestate from food waste. Bioresource Technology. 2022, 347: 126701.

26.Wang, Q., Liu, F., and Xu, Q.*. Insight into the Effect of Calcium on Bio-clogging Behavior via Quartz Crystal Microbalance with Dissipation Monitoring. Chemosphere.2022, 292: 133547.

27.Zhang, C., Shao, M., Wu, H., Wang, X., Wang, N., and Xu, Q.*. Mechanism insights into dewaterability enhancement of digestate from food waste via hydrothermal treatment. Science of the Total Environment. 2022, 804: 150145.

28.Huang, D., Xu, W., Wang, Q., and Xu, Q.*. Impact of hydrogen sulfide on biochar stimulating the methane oxidation capacity and microbial communities of landfill cover soil. Chemosphere. 2022, 286: 131650.

29.Chen, Q., Wang, N., Huang, D., Yuan, T., Wu, H., and Xu, Q.*. Enhancement of methane production from anaerobic digestion using Different manganese species. Biomass Conversion and Biorefinery. 2021

30.Chen, Q., Wang, Q., Zhang, C., Zhang, J., Dong, Z., and Xu, Q.*. Aging simulation of thin-film plastics in different environments to examine the formation of microplastic. Water Research. 2021, 202: 117462.

31.Wang, N., Huang, D., Zhang, C., Shao, M., Chen, Q., Liu, J., Deng, Z., and Xu, Q.*. Long-term characterization and resource potential evaluation of the digestate from food waste anaerobic digestion plants. Science of the Total Environment. 2021, 794: 148785.

32.Huang D., Bai, X., Wang, Q., and Xu, Q.*. Validation and optimization of key biochar properties through iron modification for improving the methane oxidation capacity of landfill cover soil. Science of the Total Environment. 2021, 793: 148551.

33.Wang, Q., Ko, J., Liu, F., and Xu, Q.*. Leaching characteristics of heavy metals in MSW and bottom ash co-disposal landfills. Journal of Hazardous Materials. 2021, 416: 126042

34.Zhang, C., Shao, M., Wu, H., Wang, N., Chen, Q., and Xu, Q.*. Management and valorization of digestate from food waste via hydrothermal treatment. Resources, Conservation & Recycling. 2021, 171: 105639.

35.Wang, Q., Ko, J., Wu, H., Liu, F., and Xu, Q.*. Impact of bottom ash co-disposed with municipal solid waste on geotextile clogging in landfills. Science of the Total Environment. 2021, 774: 145744.

36.Wang, Q., Zhang, T., Wu, G., and Xu, Q.*. Deciphering acyl-homoserine lactones-mediated quorum sensing on geotextile bio-clogging in municipal solid waste and bottom ash co-disposal landfills. Waste Management. 2021, 124: 136-143.

37.Wang, Q., Ko, J., and Xu, Q.*. Comparison of bio-clogging characteristics of geotextiles in MSW and bottom ash co-disposal landfills. Waste Management. 2021, 120: 459-466.

38.Yuan, T., Shi, X., Sun, R., Ko, J., and Xu, Q.*. Simultaneous addition of biochar and zero valent iron to improve food waste anaerobic digestion. Journal of Cleaner Production. 2021, 278: 123627.

39.Wang, Q., Ko, J., Liu, F., Xiong, F., Wang, X., and Xu, Q.*. Bio-clogging mitigation in the leachate collection system of municipal solid waste landfill using graphene oxide-coated geotextiles. Chemosphere. 2020, 268: 128779.

40.Wu, H., Wang, S., Bao, Q., Li, F., and Xu, Q.*. An Label-free lead(II) ion sensor based on surface plasmon resonance and DNAzyme-Gold nanoparticle conjugates. Analytical and Bioanalytical Chemistry. 2020, 412(27):7525-7533.

41.Wang, N., Yuan, T., Ko, J., Shi, X., and Xu, Q.* Enhanced syntrophic metabolism of volatile fatty acids via nickel-containing granular activated carbon. Journal of Material Cycles and Waste Management. 2020, 22(5): 1529-1538.

42.Yuan, T., Bian, S., Ko, J., Liu, J., Shi, X., and Xu, Q.* Exploring the roles of zero-valent iron in two-stage food waste anaerobic digestion. Waste Management. 2020, 107:91-100.

43.Huang, D., Yang, L., Xu, W., Ko, J., Chen, Q., Xu, Q.* Enhancement of the methane removal efficiency via aeration for biochar-amended landfill soil cover. Environmental Pollution. 2020, 263: 114413.

44.Xu, Q., Liao, Y., and Ko, J. * Effects of biochar addition on the anaerobic digestion of carbohydrate-rich, protein-rich, and lipid-rich substrates. Journal of the Air & Waste Management Association. 2020, 70(4): 455-467.

45.Xu, Q., Qin, J., Yuan, T., and Ko, J. * Extracellular enzyme and microbial activity in MSW landfills with different gas collection and leachate treatment. Chemosphere. 2020, 250: 126264.

46.Xu, Q., Xiang, J., and Ko, J.*. Municipal plastic recycling at two areas in China and heavy metal leachability of plastic in municipal solid waste. Environmental Pollution. 2020, 260: 114074.

47.Yuan, T., Ko, J., Zhou, L., Gao, X., Liu, Y., Shi, X., Xu, Q.*. Iron oxide alleviates acids stress by facilitating syntrophic metabolism between syntrophomonas and methanogens. Chemosphere. 2020, 247: 125866.

48.Xu, F., Zhao, C., Lee, C., Wang, W.*, and Xu, Q.* Anti-biofouling performance of an immobilized indigenous quorum quenching bacterium bacillus cereus HG10 and its influence on the microbial community in a bioreactor. International Journal of Environmental research and public health. 2019, 16 (19): 3777.

49.Huang, D., Yang, L., and Xu, Q.* Comparisons of methane-oxidizing capacities of landfill cover soils amended by biochar produced from different pyrolysis temperatures. Science of the Total Environment. 2019, 693:1-9.

50.KO, J., Wang, Q., and Xu, Q.*. Geotextile clogging at different stages of MSW landfills co-disposed with bottom ash. Science of the Total Environment. 2019, 687: 161-167.

51.Xu, Q., Qin, J., and Ko, J. *. Municipal solid waste landfill performance with different biogas collection practices: biogas and leachate generations. Journal of Cleaner Production. 2019, 222: 446-454.

52.Aung, T., Luan, S. and Xu, Q.*. Application of multi-criteria-decision approach for the analysis of medical waste management systems in myanmar. Journal of Cleaner Production. 2019, 222: 733-745.

53.Yuan, T., Bian, S., Ko, J., Wu, H. and Xu, Q.* Enhancement of hydrogen production using untreated inoculum in two-stage food waste digestion. Bioresourece Technology. 2019, 282: 189-196.

54.Chen, Q.D., Liu, H., Ko, J., Wu, H., Xu, Q.*, Structure characteristics of bio-char generated from co-pyrolysis of wooden waste and wet municipal sewage sludge. Fuel Processing Technology, 2019, 183: 48-54.

55.Ko, J., Wang, N., Yuan, T., Lv, F., He, P., and Xu, Q.* Effect of nickel-containing activated carbon on food waste anaerobic digestion. Bioresourece Technology. 2018, 266: 516-523.

56.Ko, J., Wang, J., and Xu, Q.* Impact of pyrolysis conditions on polycyclic aromatic hydrocarbons (PAHs) formation in particulate matter (PM) during sewage sludge pyrolysis. Chemosphere. 2018, 208: 108-116.

57.Wu, H., Wang, Q., Ko, J.H., and Xu, Q.* Characteristics of geotextile clogging in MSW landfills co-disposed with MSWI bottom ash. Waste Management, 2018, 78: 164-172.

58.Ko, J., Wang, J., and Xu, Q.* Characterization of Particulate Matter Formed during Sewage Sludge Pyrolysis. Fuel. 2018, 224: 210-218.

59.Wu, H., Zhu, Y., Bian, S.W., Ko, J., Li, S.Y., and Xu, Q.*. H₂S adsorption by municipal solid waste incineration (MSWI) fly ash with heavy metals immobilization. Chemosphere, 2018, 195:40-47.

60.Xu, Q., Tang, S., Wang, J., and Ko, J. Pyrolysis kinetics of sewage sludge and its biochar characteristics. Process Safety and Environmental Protection.2018, 115: 49-56.

61.Xu, Q., Tian, Y., Kim, H., Ko, J. Comparison of biogas recovery from MSW using different aerobic-anaerobic operation modes. Waste Management. 2016, 56: 190-195

62.Ko, J., Ma, Z., Jin, X., and Xu, Q.*. Effects of aeration frequency on leachate quality and waste in simulated hybrid bioreactor landfills. Journal of the Air & Waste Management Association. 2016, 66: 1245-1256.

63.Ko, J., Yang, F., Xu, Q.*. The impact of compaction and leachate recirculation on waste degradation in simulated landfills. Bioresource Technology. 2016, 211: 72-79.

64.Ko, J., Li, M., Yang, F., Xu, Q.*. Impact of MSW compression on methane generation in decelerated methanogenic phase. Bioresource Technology. 2015, 192: 540-546.

65.Xu, Q., Tian, Y., Wang, S., Ko, J. A comparative study of leachate quality and biogas generation in simulated anaerobic and hybrid bioreactors. Waste Management. 2015, 41: 94-100.

66.Ko, J., Xu, Q.*., and Jang, Y.C. Emissions and control of hydrogen sulfide at landfills: a review. Critical Reviews in Environmental Science and Technology. 2015, 45: 2043-2083.

67.Xu, Q., Jin, X., Ma, Z., Tao, H., Ko, J.. Methane production in simulated hybrid bioreactor landfill. Bioresource Technology. 2014, 168: 92-96.

68.Xu, Q., Powell, J., Pradeep J., Townsend, T. Modeling of H₂S migration through landfill cover materials. Journal of Hazardous Materials. 2014, 264: 254-260.

69.Xu Q.* and Townsend, T. Factors affecting temporal H₂S emission at construction and demolition (C&D) debris landfills. Chemosphere. 2014, 96: 105-111.

70.Xu, Q., Powell, J., Tolaymat, T., and Townsend, T. Seepage control strategies at bioreactor landfills. Journal of Hazardous, Toxic and Radioactive Waste. 2013, 17(4):342-350.

71.Xu, Q., Kim, H., Jain, P., and Townsend, T. Hydrologic evaluation of landfill performance (HELP) modeling in bioreactor landfill design and permitting. Journal of Material Cycles and Waste Management. 2012, 14: 38-46.

72.Xu, Q., Thabet, T., Townsend, T. Impact of pressurized liquids addition on landfill slope stability. Journal of Geotechnical and Geoenvironmental Engineering. 2012, 138 (4): 472-480.

73.Xu, Q. and Ge, J. Reduction of CO₂emission using bioreactor technology for waste management in China. Energy Procedia. 2011, 5: 1026-1031.

74.Xu, Q., Townsend, T., and Bitton, G. Inhibition of hydrogen sulfide generation from disposed gypsum drywall using chemical inhibitors. Journal of Hazardous Materials. 2011, 191: 204-213.

75.Xu, Q., Liu, F, Townsend, T., Abichou, T., Chanton, J. Tire-derived steel for hydrogen sulfide removal in landfill cover. Practice Periodical of Hazardous, Toxic, and Radioactive Waste Management. 2010, 14(3): 211-214.

76.Xu, Q., Townsend, T., and Reinhart, D. Attenuation of hydrogen sulfide at construction and demolition (C&D) debris landfills using alternative cover materials. Waste Management. 2010, 30: 660-666.

中文論文

1.王前，苗前名，何品晶，徐期勇*. 生活垃圾填埋場(chǎng) 滲濾液導(dǎo)排系統(tǒng)結(jié)垢研究現(xiàn)狀及新挑戰(zhàn). 環(huán)境衛(wèi)生工程. 2022. 30: 81-88.

2.邵明帥,張超,吳華南,王寧,陳欽冬,徐期勇*. 餐廚垃圾沼液水熱處理的固液特征及能耗分析. 化工進(jìn)展.

3.白新月, 陳予珂,黃丹丹,徐期勇*.富鐵炭對(duì)填埋覆土層甲烷氧化主導(dǎo)的微生物活動(dòng)影響. 中國(guó)環(huán)境科學(xué). 2022, 42 (2): 778-793.

4.章佳文,陳欽冬,徐期勇*. 金屬催化劑對(duì)油漆板材催化熱解產(chǎn)物影響研究. 中國(guó)環(huán)境科學(xué). 2022, 42 (2): 770-776.

5.劉豐,王前,吳華南,徐期勇*. 滲濾液中Na⁺在生物膜形成初期的吸附特性研究.中國(guó)環(huán)境科學(xué). 2022, 42 (1): 213-219.

6.許文君,黃丹丹, 梁銘珅, 徐期勇^*. 硫化氫對(duì)填埋場(chǎng)生物炭改性覆土的甲烷氧化影響研究. 環(huán)境工程. 2022, 40(2):7.

7.王倩,陳欽冬,章佳文,吳華南,徐期勇^*. 海岸線塑料垃圾低溫?zé)峤饧捌湮廴疚锱欧盘卣? 中國(guó)環(huán)境科學(xué). 2021, 41(8): 3684-3692.

8.徐期勇, 梁銘珅, 許文君, 黃丹丹^*. 生物炭吸附硫化氫機(jī)制與影響因素研究進(jìn)展. 環(huán)境科學(xué). 2021, 42(11): 29-41.

9.徐期勇,章佳文,劉虎,吳華南,陳欽冬^*. 市政污泥與木屑共熱解特性及動(dòng)力學(xué)分析. 可再生能源. 2021, 39(9): 7.

10.徐期勇,王爍康,鮑琪,張善發(fā),吳華南^*. 納米金增強(qiáng)SPR鉛離子檢測(cè)器構(gòu)建.中國(guó)環(huán)境科學(xué). 40(11): 5038-5044.

11.杜越,Ko, J., 黃丹丹,王前,向靜雅,徐期勇^*.模擬生活垃圾填埋反應(yīng)器堆體底部抽氣對(duì)污染氣體排放的控制.環(huán)境工程學(xué)報(bào).2020,14(11): 3182-3191.

12.王倩,向靜雅,陳欽冬,徐期勇^*.深圳市全海岸線垃圾成分及其特性研究.環(huán)境衛(wèi)生工程. 2020,28(3): 21-27.

13.向靜雅,王倩,邵明帥,王前,吳華南,徐期勇^*.深圳海灘塑料垃圾及其重金屬污染分析. 中國(guó)環(huán)境科學(xué). 2020,40(7): 3097-3105.

14.劉豐,王前,吳華南,徐期勇^*.氧化石墨烯對(duì)填埋場(chǎng)土工布初期生物結(jié)垢的抑制研究. 中國(guó)環(huán)境科學(xué). 2020. 40(2): 688-694.

15.廖雨晴,KO,J.,袁土貴,徐期勇^*.污泥基生物炭對(duì)餐廚垃圾厭氧消化產(chǎn)甲烷及微生物群落結(jié)構(gòu)的影響.環(huán)境工程學(xué)報(bào).2020, 14(2):523-534

16.王經(jīng)臣,楊璐寧,KO,J.,徐期勇^*.市政污泥熱解過程顆粒物中重金屬分布研究.中國(guó)環(huán)境科學(xué).2018,38(10):3781-3787.

17.石笑羽,王寧,陳欽冬,吳華南,徐期勇*.生物炭加速餐廚垃圾厭氧消化的機(jī)理研究.環(huán)境工程學(xué)報(bào). 2018, 12(11): 3204-3212.

18.王前,楊帆,徐期勇^*.爐渣與生活垃圾混填對(duì)填埋場(chǎng)土工膜結(jié)垢的影響.環(huán)境工程學(xué)報(bào).2017,11(9): 5262-5266.

19.高雪濛,周麗麗,秦杰,徐期勇^*.不同的氧化鐵投加方式對(duì)餐廚垃圾厭氧消化產(chǎn)氣的影響. 環(huán)境工程,2017,35:101-105.

20.周麗麗,楊帆,羅瑞芬,徐期勇^*.氧化鐵對(duì)不同有機(jī)負(fù)荷下餐廚垃圾厭氧消化產(chǎn)氣影響的研究. 環(huán)境工程學(xué)報(bào). 2017,11(6):162-168

21.楊帆,Ko, J.,徐期勇^*.雙向?qū)�排系統(tǒng)對(duì)填埋場(chǎng)垃圾中滲濾液和填埋氣產(chǎn)生遷移的影響研究.環(huán)境科學(xué)學(xué)報(bào). 2017,37(6):1-7.

22.吳昊,趙暢,徐期勇^*.改善反應(yīng)器內(nèi)部光照條件對(duì)TiO₂光催化去除H₂S的影響. 環(huán)境工程學(xué)報(bào). 2016 ,10(9): 5089-5094.

23.夏旦凌, 金瀟, 徐期勇^*.餐廚垃圾高溫產(chǎn)甲烷的高鹽度抑制及恢復(fù)性研究. 環(huán)境工程學(xué)報(bào). 2016,10(3): 1426-1431.

24.尚寧,王海洋,吳華南,Ko, J., 徐期勇*. 垃圾焚燒飛灰水泥固化體的抗壓強(qiáng)度和浸出性研究. 環(huán)境工程學(xué)報(bào). 2016, 10(6): 3207-3214.

25.王海洋,査曉雄,徐期勇^*. 幾種水泥基材料的滲透率及其超臨界碳化的應(yīng)用. 土木建筑與環(huán)境工程, 2015,37(2): 121-126.

26.李明英,楊帆,Ko, J.,徐期勇^*.壓力對(duì)填埋垃圾產(chǎn)甲烷階段的影響研究. 環(huán)境科學(xué)學(xué)報(bào). 2015, 35(11): 3755-3761

27.王珅,田穎,劉陽生,徐期勇^*.厭氧消化過程氨抑制解除技術(shù)研究進(jìn)展.工業(yè)水處理2015, 35(5): 10-14.

28.朱彧,吳昊,徐期勇^*.垃圾焚燒飛灰去除硫化氫氣體的研究. 環(huán)境工程學(xué)報(bào). 2015,9(6): 2947-2954.

29.金瀟,夏旦凌,馬澤宇,Jae Hac Ko,徐期勇^*.不同好氧預(yù)處理方式對(duì)餐廚垃圾產(chǎn)甲烷的影響研究.環(huán)境工程學(xué)報(bào). 2015,9(1): 9-15.

30.田穎,王珅,徐期勇^*.曝氣頻率對(duì)生物反應(yīng)器滲濾液與填埋氣的影響研究.環(huán)境工程學(xué)報(bào).2015,9(1): 207-212.

31.田穎,王珅,徐期勇^*.上層曝氣式生物反應(yīng)器填埋工藝特性的研究.環(huán)境科學(xué).2014. 35(11):4365-4370.

32.尚寧,Ko,J.,徐期勇^*.土聚水泥技術(shù)在飛灰資源化中的應(yīng)用.硅酸鹽通報(bào).2014. 33(3): 574-582.

33.李明英, Ko,J.,徐期勇^*. 填埋垃圾滲透系數(shù)的研究進(jìn)展. 環(huán)境工程. 2014.8: 80-84.

34.田穎,徐期勇^*. 生物反應(yīng)器填埋場(chǎng)原位脫氮技術(shù)的分析. 環(huán)境衛(wèi)生工程.2014. 22:1-4.

35.馬澤宇,金瀟,Ko,J.,徐期勇^*.模擬生物反應(yīng)器加速產(chǎn)甲烷過程研究.環(huán)境工程學(xué)報(bào).2014.8(4): 1647-1652.

36.馬澤宇,金瀟, Ko,J.,徐期勇^*.好氧生物反應(yīng)器加速滲濾液及垃圾穩(wěn)定進(jìn)程研究.環(huán)境科學(xué)與技術(shù). 2013,10: 90-95.

37.田穎,馬澤宇,徐期勇^*, 閔澤清.生物質(zhì)-垃圾混合燃燒特性及其環(huán)境分析.中國(guó)農(nóng)學(xué)通報(bào). 2013,31: 87-92.

38.夏旦凌,馬澤宇,金瀟,徐期勇^*.城市垃圾填埋場(chǎng)滲濾液中氨氮濃度影響因素分析.環(huán)境衛(wèi)生工程.2013,21(6): 27-32.

39.金瀟,馬澤宇,徐期勇^*.填埋氣中二氧化碳凈化技術(shù)及研究進(jìn)展. 可再生能源. 2013,1: 87-92.

授權(quán)專利

1,一種餐廚垃圾厭氧消化處理方法和系統(tǒng).發(fā)明授權(quán)(ZL 2012 1 0236223.9)

2.一種垃圾處理的方法及系統(tǒng).發(fā)明授權(quán)(ZL 2013 1 0748313.0)

3.一種硫化氫和飛灰的無害化聯(lián)合處理方法及系統(tǒng).發(fā)明授權(quán)(ZL 2012 1 0236461.X)

4.一種滲濾液和填埋氣的動(dòng)態(tài)雙向?qū)�排控制方�? 發(fā)明授權(quán)(ZL 201611103988X)

5.一種利用群體感應(yīng)淬滅固定化菌株控制膜污染的方法.發(fā)明授權(quán) (ZL 201710173911.8)

6.利用爐渣與填埋氣防治填埋場(chǎng)結(jié)垢堵塞的方法及裝置.發(fā)明授權(quán) (ZL 2018 1 0108187.5)..

7.一種甲烷減排結(jié)構(gòu)及其在填埋場(chǎng)氣體凈化領(lǐng)域的應(yīng)用. 發(fā)明授權(quán)(ZL 2019 1 0720410.6)

8.炭微球及其制備方法. 發(fā)明授權(quán) (ZL 2022 1 0170265.0)

9.Dynamic Two-way Guide and Drainage Control Method for Leachate and Landfill Gas. (US 10,279,382 B2) Date of Patent: May 7, 2019

學(xué)術(shù)著作

1.徐期勇, 吳華南, 黃丹丹, 王前. 垃圾填埋技術(shù)進(jìn)展與污染控制. 2020.科學(xué)出版社.ISBN 978-7-03-065072-6

2.Townsend, T., Powell, J., Jain, P., Xu, Q., Tolaymat, T., and Reinhart, R. Sustainable Practices for Landfill Design and Operation. 2015. Springer. ISBN 978-1-4939-2661-9