能源與動力工程學院
                            舊版入口| 學校主頁| 加入收藏 | 設為首頁

                            師資隊伍

                            teaching staff

                            熱點文章

                            站內搜索

                            講師

                            當前位置: 首 頁 > 師資隊伍 > 煤燃燒國家重點實驗室 > 講師 > 正文
                            姓 名 陳應泉 性 別
                            職 稱 畢業學校 華中科技大學
                            個人主頁 http://sklccfbg.www.cafecuruba.com
                            聯系方式
                            郵 箱 chenyingquan@hust.edu.cn
                            通訊地址 華中科技大學煤燃燒國家重點實驗室409
                            個人資料簡介
                            陳應泉,男,工學博士,2007年畢業于華中科技大學能源與動力工程學院,獲學士學位;2014年在華中科技大學煤燃燒國家重點實驗室取得熱能工程專業博士學位。主要從事生物質全組分熱分解機制、生物質熱解多聯產過程調控、生物炭基高性能材料制備及應用等方面的研究。作為第一負責人主持承擔國家自然科學基金面上項目1項、國家重點專項子課題1項、國家自然科學基金青年基金1項、中國博士后科學基金特別資助1項和面上項目2項。作為主要完成人獲得了全球可再生能源領域最具投資價值的領先技術藍天獎1項、中國僑界貢獻獎1項和中國專利優秀獎1項。已發表學術論文60余篇,其中以第一作者/通訊作者發表SCI論文20余篇,3篇入選ESI高引論文。獲得授權專利5項,公開發明專利6項。
                            歡迎能源、材料、化工、環境等專業背景的學生報考本課題組研究生

                            教育及工作經歷

                              2003.09-2007.06    武漢,華中科技大學,熱能工程專業,本科
                              2007.09-2014.01    武漢,華中科技大學,熱能工程專業,博士,導師:陳漢平
                              2014.02-2016.05    武漢,華中科技大學,材料科學專業,博士后,合作導師:黃云輝
                              2016.07-2018.06武漢,華中科技大學,熱能工程專業,博士后,合作導師:陳漢平
                              2018.07-直徑    武漢,華中科技大學煤燃燒國家重點實驗室,講師

                            研究方向

                              1)    生物質基碳材料制備與應用,如超級電容器、非對稱鋰鈉電池等
                              2)    生物質熱解機理
                              3)    生物質熱解多聯產

                            科研項目

                              國家自然科學基金面上項目,生物質選擇性富氮熱解過程中氮素遷徙與功能化調控機制的基礎研究,63萬元,2019.1-2022.12
                              國家重點專項子課題,基于熱解過程調控的熱解殘渣預調質技術,101萬元,2019.1-2022.12
                              國家自科基金青年項目,生物質富氮熱解聯產高值含氮油炭產品的機制研究,25萬元,2015.01-2017.12
                              中國博士后基金特別資助項目,微藻與廢棄塑料混合催化熱解制備高值油炭產品的研究,15萬元,2017.06-2018.06
                              中國博士后基金面上項目,廢塑料熱解催化聯產富氫氣體及碳納米管,5萬元,2016.10-2017.10
                              中國博士后基金面上項目,生物質富氮熱解聯產高值油炭產品的機制研究,5萬元,2014.06-2015.06

                            代表性論文與專利

                              第一作者論文:
                              1.Chen, Y.Q., et al., Biomass Pyrolytic Polygeneration System: Adaptability for Different Feedstocks. Energy & Fuels, 2016. 30(1): p. 414-422.
                              2.Chen, Y.Q., et al., Biomass-based pyrolytic polygeneration system on cotton stalk pyrolysis: Influence of temperature. Bioresource Technology, 2012. 107: p. 411-418.
                              3.Chen, Y., et al., Effect of volatiles interaction during pyrolysis of cellulose, hemicellulose, and lignin at different temperatures. Fuel, 2019. 248: p. 1-7.
                              4.Chen, Y.Q., et al., Evolution of functional groups and pore structure during cotton and corn stalks torrefaction and its correlation with hydrophobicity. Fuel, 2014. 137: p. 41-49.
                              5.Chen, Y.Q., et al., Generalized two-dimensional correlation infrared spectroscopy to reveal the mechanisms of lignocellulosic biomass pyrolysis. Proceedings of the Combustion Institute, 2019. 37(3): p. 3013-3021.
                              6.Chen, Y.Q., et al., The structure evolution of biochar from biomass pyrolysis and its correlation with gas pollutant adsorption performance. Bioresource Technology, 2017. 246: p. 101-109.
                              7.Chen, Y.Q., et al., Torrefaction of agriculture straws and its application on biomass pyrolysis poly-generation. Bioresource Technology, 2014. 156: p. 70-77.
                              通訊作者論文:
                              1.Wang, L., et al., Investigation of the pyrolysis characteristics of guaiacol lignin using combined Py-GC× GC/TOF-MS and in-situ FTIR. Fuel, 2019. 251: p. 496-505.
                              2.Tang, Z.Y., et al., Co-pyrolysis of microalgae and plastic: Characteristics and interaction effects. Bioresource Technology, 2019. 274: p. 145-152.
                              3.Liu, H., et al., Hydrothermal carbonization of natural microalgae containing a high ash content. Fuel, 2019. 249: p. 441-448.
                              4.Xia, S.W., et al., Pyrolysis behavior and economics analysis of the biomass pyrolytic polygeneration of forest farming waste. Bioresource Technology, 2018. 270: p. 189-197.
                              5.Wang, X.H., et al., Comparative study of wet and dry torrefaction of corn stalk and the effect on biomass pyrolysis polygeneration. Bioresource Technology, 2018. 258: p. 88-97.
                              6.Chen, W., et al., Influence of Biochar Addition on Nitrogen Transformation during Copyrolysis of Algae and Lignocellulosic Biomass. Environmental Science & Technology, 2018. 52(16): p. 9514-9521.
                              7.Chen, W., et al., Catalytic deoxygenation co-pyrolysis of bamboo wastes and microalgae with biochar catalyst. Energy, 2018. 157: p. 472-482.
                              8.Zhu, D.C., et al., Fouling and Slagging Characteristics during Co-combustion of Coal and Biomass. Bioresources, 2017. 12(3): p. 6322-6341.
                              9.Wu, K., et al., Characterization of dairy manure hydrochar and aqueous phase products generated by hydrothermal carbonization at different temperatures. Journal of Analytical and Applied Pyrolysis, 2017. 127: p. 335-342.
                              10.Li, J., et al., Correlation of Feedstock and Bio-oil Compound Distribution. Energy & Fuels, 2017. 31(7): p. 7093-7100.
                              11.Hu, J.H., et al., Evolution of char structure during mengdong coal pyrolysis: Influence of temperature and K2CO3. Fuel Processing Technology, 2017. 159: p. 178-186.
                              12.Gao, Y., et al., Pyrolysis of rapeseed stalk: Influence of temperature on product characteristics and economic costs. Energy, 2017. 122: p. 482-491.
                              13.Chen, X., et al., Catalytic fast pyrolysis of biomass to produce furfural using heterogeneous catalysts. Journal of Analytical and Applied Pyrolysis, 2017. 127: p. 292-298.
                              14.Chen, W., et al., Algae pyrolytic poly-generation: Influence of component difference and temperature on products characteristics. Energy, 2017. 131: p. 1-12.
                              15.Chen, W., et al., Transformation of Nitrogen and Evolution of N-Containing Species during Algae Pyrolysis. Environmental Science & Technology, 2017. 51(11): p. 6570-6579.
                              16.Chen, H.P., et al., NOx precursors from biomass pyrolysis: Distribution of amino acids in biomass and Tar-N during devolatilization using model compounds. Fuel, 2017. 187: p. 367-375.
                              17.Yang, H.P., et al., Application of biomass pyrolytic polygeneration technology using retort reactors. Bioresource Technology, 2016. 200: p. 64-71.
                              18.Yang, H.P., et al., Biomass-Based Pyrolytic Polygeneration System for Bamboo Industry Waste: Evolution of the Char Structure and the Pyrolysis Mechanism. Energy & Fuels, 2016. 30(8): p. 6430-6439.
                              19.Gao, Y., et al., Use of Extreme Vertices Method for Analysis of How Proportional Composition Affects Component Interactions and Product Distribution during Hydrothermal Treatment. Bioresources, 2016. 11(2): p. 4899-4920.
                              20.Chen, W., et al., Biomass pyrolysis for nitrogen-containing liquid chemicals and nitrogen-doped carbon materials. Journal Of Analytical And Applied Pyrolysis, 2016. 120: p. 186-193.
                              21.Chen, H.P., et al., Biomass Pyrolytic Polygeneration of Tobacco Waste: Product Characteristics and Nitrogen Transformation. Energy & Fuels, 2016. 30(3): p. 1579-1588.
                              22.Yang, H.P., et al., Influence of Inherent Silicon and Metals in Rice Husk on the Char Properties and Associated Silica Structure. Energy & Fuels, 2015. 29(11): p. 7327-7334.

                            所獲榮譽和獎勵

                              1)    生物質熱解聯產聯供高值化綜合利用技術    全球可再生能源領域最具投資價值的領先技術藍天獎    聯合國工業發展組織    2014年    排名2
                              2)    一種連續式生物質熱解炭氣油多聯產系統    中國專利優秀獎    國家知識產權局    2015年    排名2
                              3)    含碳固體燃料高效低耗綜合利用關鍵技術及應用    中國僑界貢獻獎-創新 成果獎    中國僑聯    2014年    排名7
                            吉利彩票app下载