{"id":52,"date":"2016-09-27T20:02:00","date_gmt":"2016-09-28T03:02:00","guid":{"rendered":"http:\/\/labs.wsu.edu\/lei\/?page_id=52"},"modified":"2021-02-22T19:09:35","modified_gmt":"2021-02-23T03:09:35","slug":"biofuels-bioproducts","status":"publish","type":"page","link":"https:\/\/labs.wsu.edu\/lei\/biofuels-bioproducts\/","title":{"rendered":"Biofuels & Bioproducts"},"content":{"rendered":"
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Biofuels & Bioproducts<\/h2>\n<\/header>\n

Jet Fuels:<\/h4>\n
    \n
  • X. Zhang, H. Lei<\/strong>*, L. Zhu, M. Qian, J. C. Chan, X. Zhu, Y. Liu, G. Yadavalli, D Yan, L. Wang, Q. Bu, Y. Wei,\u00a0J. Wu, S. Chen.\u00a0 2016. Development of a catalytically green route from diverse lignocellulosic biomasses to renewable cycloalkanes for jet fuels. Catalysis Science & Technology<\/em>. doi:<\/strong>10.1039\/C5CY01623A.<\/li>\n
  • X. Zhang, H. Lei<\/strong>*, L. Zhu, M. Qian, X. Zhu J. Wu, S. Chen.\u00a02016.\u00a0Enhancement of jet fuel range alkanes from co-feeding of lignocellulosic biomass with plastics via tandem catalytic conversions. Applied Energy. doi: 10.1016\/j.apenergy.2016.04.071.<\/li>\n
  • X. Zhang, H. Lei<\/strong>*, L. Zhu, Y. Liu, G. Yadavalli, D Yan, X. Zhu, J. Chin, M. Qian.\u00a02016.\u00a0Synthesis of high energy-density jet fuel from plastics via catalytically integral processes. RSC advances,<\/em> 6: 6154-6163. doi: 10.1039\/c5ra25327f.<\/li>\n
  • X. Zhang, H. Lei<\/strong>*, L. Zhu, J. Wu, S. Chen. 2015. From intact biomass to renewable cycloalkanes for jet fuels. Green Chemistry, 17: 4736-4747. doi:<\/strong>10.1039\/C5GC01583A.<\/li>\n
  • X. Zhang, H. Lei<\/strong>*, L. Wang, L. Zhu, Y. Wei, Y. Liu, G. Yadavalli, D. Yan. 2015. Renewable gasoline-range aromatics and hydrogen-enriched fuel gas from biomass via catalytic microwave-induced pyrolysis. Green Chemistry.<\/em> 17: 4029-4036. doi: <\/strong>10.1039\/C5GC00516G.<\/li>\n
  • X. Zhang, H. Lei<\/strong>*, L. Wang, L. Zhu, Y. Wei, Y. Liu, G. Yadavalli, D Yan, J. Wu, S. Chen. 2015. Insight in the integrated catalytic processes of intact biomass for production of renewable jet fuel range paraffins and aromatics. Fuel,<\/em>160:375-385. doi: 10.1016\/j.fuel.2015.08.006.<\/li>\n<\/ul>\n

    Biofuels:<\/h4>\n
      \n
    • S. Ren, H<\/strong>.<\/strong> Lei<\/strong>*, L. Wang, Q. Bu, S. Chen, J. Wu, J. Julson, and R. Ruan. 2012. Biofuel production and kinetics analysis of microwave pyrolysis for Douglas fir sawdust pellet. Journal of Analytic and Applied Pyrolysis<\/em>, 94: 163-169. doi: 10.1016\/j.jaap.2011.12.004.<\/li>\n
    • Q. Bu, H. Lei<\/strong>*, S. Ren, L. Wang, Q. Zhang, J. Tang, and R. Ruan. 2012. Production of phenols and biofuels by catalytic microwave pyrolysis of lignocellulosic biomass. Bioresource Technology<\/em>, 108: 274-279. doi: 10.1016\/j.biortech.2011.12.125.<\/li>\n<\/ul>\n

      Algae and Algae Related Biofuels:<\/h3>\n
        \n
      • Hu, W.\u00a0Zhou, M. Min,\u00a0Z. Du, P. Chen, X.\u00a0Ma, Y.\u00a0 Liu,\u00a0H. Lei<\/strong>, J. Shi, R. \u00a0Ruan. 2013. Development of an effective acidogenically digested swine manure-based algal system for improved wastewater treatment and biofuel and feed production. Applied Energy<\/em>, 107, 255-263. doi:<\/strong>10.1016\/j.apenergy.2013.02.033.<\/li>\n
      • Z. Du, X. Ma, Y. Li, P. Chen, Y. Liu, X. Lin, H. Lei<\/strong>, R. Ruan. 2013. Production of aromatic hydrocarbons by catalytic pyrolysis of microalgae with zeolites: Catalyst screening in a pyroprobe. Bioresource Technology<\/em>, 139, 397-401 doi: 10.1016\/j.biortech.2013.04.053<\/li>\n<\/ul>\n

        Nanocellulose:<\/h4>\n
          \n
        • M. Qian, H. Lei<\/strong>*, Y. Zhao, C. Wang, E. Huo, Q. Zhang, W. Mateo, X. Lin, X. Kong, R. Zou. 2020. High yield production of nanocrystalline cellulose by microwave-assisted dilute-acid pretreatment combined with enzymatic hydrolysis. Chemical Engineering and Processing – Process Intensification<\/em>, 160, 108292. doi: 10.1016\/j.cep.2020.108292.<\/li>\n
        • Y. Zhao, H. Lei<\/strong>*, Y. Liu, R. Ruan, M. Qian, E. Huo, Q. Zhang, Z. Huang, X. Lin, C. Wang, W. Mateo, E. M. Villota. 2020. Microwave-assisted Synthesis of Bifunctional Magnetic Solid Acid for Hydrolyzing Cellulose to Prepare Nanocellulose. Science of the Total Environment<\/em>, 731, 138751. doi: 10.1016\/j.scitotenv.2020.138751.<\/li>\n<\/ul>\n

          Aromatics:<\/h4>\n
            \n
          • H. Lei<\/strong>* and L. Wang. 2014. Filed patent (USPTO 61938416). Aromatic hydrocarbons from lignocellulose biomass.<\/li>\n
          • L. Wang, H. Lei<\/strong>*, Q. Bu, L. Zhu, Y. Wei,\u00a0 X. Zhang, Y. Liu, \u00a0G. Yadavalli, J. Lee, S. Chen, and J. Tang. 2014. \u00a0Aromatic hydrocarbons production from ex-situ catalysis of pyrolysis vapor over Zinc modified ZSM-5 in a packed-bed catalysis coupled with microwave pyrolysis reactor. Fuel<\/em>. Under review.<\/li>\n
          • L. Wang, H. Lei<\/strong>*, J. Lee, S. Chen, J. Tang, B. Ahring. 2013. Aromatic hydrocarbons from packed-bed catalysis coupled with microwave pyrolysis of Douglas fir sawdust pellets. RSC Advances<\/em>, 34, 3, 14609 \u2013 14615. doi:<\/strong>10.1039\/C3RA23104F.<\/li>\n
          • Z. Du, X. Ma, Y. Li, P. Chen, Y. Liu, X. Lin, H. Lei<\/strong>, R. Ruan. 2013. Production of aromatic hydrocarbons by catalytic pyrolysis of microalgae with zeolites: Catalyst screening in a pyroprobe. Bioresource Technology<\/em>, 139, 397-401 doi: 10.1016\/j.biortech.2013.04.053<\/li>\n
          • L. Wang, H. Lei<\/strong>*, S. Ren, Q. Bu, J. Liang, Y. Wei, Y. Liu, G. J. Lee, S. Chen, J. Tang, Q. Zhang, and R. Ruan. 2012. Aromatics and phenols from catalytic pyrolysis of Douglas fir pellets in microwave with ZSM-5 as a catalyst. Journal of Analytic and Applied Pyrolysis<\/em>, 98, 194-200. doi: 10.1016\/j.jaap.2012.08.002.<\/li>\n<\/ul>\n

            Bio-Phenols:<\/h4>\n
              \n
            • H. Lei<\/strong>*, Q. Bu, S. Ren, and L. Wang. 2011. Filed patent (USPTO 61483132). Microwave Assisted Pyrolysis and Phenol Recovery.<\/li>\n
            • Q. Bu, H. Lei<\/strong>*, L. Wang, Y. Wei, L. Zhu, L. Zhu, X. Zhang, Y. Liu, G. Yadavalli and J. Tang. 2014. \u00a0Bio-based phenols and fuel production from catalytic microwave pyrolysis of lignin by activated carbons. Bioresource Technology<\/em>. Under review<\/li>\n
            • Q. Bu, H. Lei<\/strong>*, L. Wang, Y. Liu, J. Liang, Y. Wei, L. Zhu, and J. Tang. 2013. \u00a0Renewable phenols production by catalytic microwave pyrolysis of Douglas fir sawdust pellets with activated carbon catalysts. Bioresource Technology<\/em>, 142: 546-552. doi: 10.1016\/j.biortech.2013.05.073.<\/li>\n
            • Q. Bu, H. Lei<\/strong>*, A. H. Zacher, L. Wang, S. Ren, J. Liang, Y. Wei, Y. Liu, J. Tang, Q. Zhang, and R. Ruan. 2012. A review of catalytic hydrodeoxygenation of lignin-derived phenols from biomass pyrolysis. Bioresource Technology<\/em>, 124, 470-477. doi: 10.1016\/j.biortech.2012.08.089. 07.10.12<\/li>\n
            • Q. Bu, H. Lei<\/strong>*, S. Ren, L. Wang, Q. Zhang, J. Tang, and R. Ruan. 2012. Production of phenols and biofuels by catalytic microwave pyrolysis of lignocellulosic biomass. Bioresource Technology<\/em>, 108: 274-279. doi: 10.1016\/j.biortech.2011.12.125.<\/li>\n
            • Q. Bu, H. Lei<\/strong>*, S. Ren, L. Wang, J. Holladay, Q. Zhang, J. Tang, and R. Ruan. 2011. Phenol and phenolics from lignocellulosic biomass by catalytic microwave pyrolysis. Bioresource Technology<\/em>, 102: 7004-7007. doi:10.1016\/j.biortech.2011.04.025<\/li>\n<\/ul>\n

              Hydrogen:<\/h4>\n
                \n
              • Y. Wei, H. Lei<\/strong>*, Y. Liu, L. Wang, L. Zhu, X. Zhang, G. Yadavalli, B. Ahring, S. Chen. 2014. Renewable hydrogen produced from different renewable feedstocks by aqueous-phase reforming process. Journal of Sustainable Bioenergy Systems. <\/em>In press.<\/li>\n
              • S. Ren, H. Lei<\/strong>*, L. Wang, Q. Bu, S. Chen, J. Wu. 2014. Hydrocarbons and hydrogen-rich syngas production by biomass catalytic pyrolysis and bio-oil upgrading over biochar catalysts. RSC Advances<\/em>, 4 (21), 10731 \u2013 10737.<\/strong>doi: 10.1039\/c4ra00122b.<\/li>\n<\/ul>\n

                Zeolite Catalysts:<\/h4>\n
                  \n
                • L. Wang, H. Lei<\/strong>*<\/strong>, Q. Bu, L. Zhu, Y. Wei,\u00a0 X. Zhang, Y. Liu, \u00a0G. Yadavalli, J. Lee, S. Chen, and J. Tang. 2014. \u00a0Aromatic hydrocarbons production from ex-situ catalysis of pyrolysis vapor over Zinc modified ZSM-5 in a packed-bed catalysis coupled with microwave pyrolysis reactor. Fuel<\/em>. Under review.<\/li>\n
                • L. Wang, H. Lei<\/strong>*<\/strong>, J. Lee, S. Chen, J. Tang, B. Ahring. 2013. Aromatic hydrocarbons from packed-bed catalysis coupled with microwave pyrolysis of Douglas fir sawdust pellets. RSC Advances<\/em>, 34, 3, 14609 \u2013 14615. doi: 10.1039\/C3RA23104F.<\/li>\n
                • Z. Du, X. Ma, Y. Li, P. Chen, Y. Liu, X. Lin, H. Lei<\/strong>, R. Ruan. 2013. Production of aromatic hydrocarbons by catalytic pyrolysis of microalgae with zeolites: Catalyst screening in a pyroprobe. Bioresource Technology<\/em>, 139, 397-401 doi: 10.1016\/j.biortech.2013.04.053<\/li>\n
                • L. Wang, H. Lei<\/strong>*, S. Ren, Q. Bu, J. Liang, Y. Wei, Y. Liu, G. J. Lee, S. Chen, J. Tang, Q. Zhang, and R. Ruan. 2012. Aromatics and phenols from catalytic pyrolysis of Douglas fir pellets in microwave with ZSM-5 as a catalyst. Journal of Analytic and Applied Pyrolysis<\/em>, 98, 194-200. doi: 10.1016\/j.jaap.2012.08.002.<\/li>\n
                • Z. Du, B. Hu, X. Ma, Y. Cheng, Y. Liu, X. Lin, Y. Wan, H. Lei<\/strong>, P. Chen, and R. Ruan*. 2013. Catalytic pyrolysis of microalgae and their three major components: carbohydrates, proteins, and lipids. Bioresource Technology,<\/em>130: 777\u2013782.<\/em> doi: 10.1016\/j.biortech.2012.12.115<\/li>\n<\/ul>\n

                  Biochar Catalysts and Biomass Derived Carbon Catalysts:<\/h4>\n
                    \n
                  • S. Ren, H. Lei<\/strong>**<\/strong>, L. Wang, Q. Bu, S. Chen, J. Wu. 2014. Hydrocarbons and hydrogen-rich syngas production by biomass catalytic pyrolysis and bio-oil upgrading over biochar catalysts. RSC Advances<\/em>, 4 (21), 10731 \u2013 10737.<\/strong>doi: 10.1039\/c4ra00122b.<\/li>\n
                  • L. Zhu, H. Lei<\/strong>*<\/strong>, L. Wang, X. Zhang, Y. Wei, Y Liu, G. Yadavalli. Characterization of surface functional groups in corn stover biochar derived from microwave-assisted pyrolysis. 2014 ASABE International Meeting,Jul 13-16, 2014<\/em>, Montreal, QC, Canada.<\/li>\n
                  • L. Zhu, H. Lei<\/strong>*<\/strong>, L. Wang, Q. Bu, Y. Wei, Y. Liu, and J. Liang. 2013. Carbon catalyst from corn stover and its application to catalytic microwave pyrolysis. American Society of Agricultural and Biological Engineers (ASABE) 2013 Annual International Meeting, 2013(3): 1854-1860. doi: http:\/\/dx.doi.org\/10.13031\/aim.20131594788.<\/li>\n
                  • L. Zhu, H. Lei<\/strong>*<\/strong>, L. Wang, Q. Bu, J. Liang, Y. Wei, Y. Liu. Catalytic Microwave Pyrolysis of Douglas Fir Pellets With Carbon Catalysts Derived From Corn Stover. 2013 AIChE Annual Meeting, San Francisco, California, November 3 \u2013 8, 2013.<\/li>\n<\/ul>\n

                    Activated Carbon Catalysts:<\/h4>\n