部分研究论文如下,全部研究论文见:https://www.researchgate.net/profile/Rui-Zhai-8
[1] X.X. Chen#, R. Zhai#, Y. Li, X. Yuan, Z.-H. Liu, M. Jin, Understanding the structural characteristics of water-soluble phenolic compounds from four pretreatments of corn stover and their inhibitory effects on enzymatic hydrolysis and fermentation, Biotechnology for Biofuels 13 (2020) 44.
[2] R. Zhai, X.X. Chen, M.J. Jin, J.G. Hu, Synthesis of a polydopamaine nanoparticle/bacterial cellulose composite for use as a biocompatible matrix for laccase immobilization, Cellulose 26 (2019) 8337-8349
[3] Y. Li#, R. Zhai#, X.X. Jiang, X.X. Chen, X.C. Yuan, Z.H. Liu, M.J. Jin, Boosting ethanol productivity of zymomonas mobilis 8b in enzymatic hydrolysate of dilute acid and ammonia pretreated corn stover through medium optimization, high cell density fermentation and cell recycling, Frontiers in Microbiology 10 (2019)
[4] Z. Xu, P. Lei, R. Zhai, Z. Wen, M. Jin, Recent advances in lignin valorization with bacterial cultures: microorganisms, metabolic pathways, and bio-products, Biotechnology for Biofuels 12 (2019) 32.10.1186/s13068-019-1376-0
[5] J. Hu, R. Zhai, D. Tian, J.N. Saddler, Substrate factors that influence cellulase accessibility and catalytic activity during the enzymatic hydrolysis of lignocellulosic biomass, in: X. Fang, Y. Qu (Eds.) Fungal Cellulolytic Enzymes: Microbial Production and Application, Springer Singapore, Singapore, 2018, pp. 239-256.
[6] Y. Yuan#, R. Zhai#, Y. Li, X.X. Chen, M.J. Jin, Developing fast enzyme recycling strategy through elucidating enzyme adsorption kinetics on alkali and acid pretreated corn stover, Biotechnology for Biofuels 11 (2018)
[7] X.X. Chen#, R. Zhai#, K.Q. Shi, Y. Yuan, B.E. Dale, Z. Gao, M.J. Jin, Mixing alkali pretreated and acid pretreated biomass for cellulosic ethanol production featuring reduced chemical use and decreased inhibitory effect, Industrial Crops and Products 124 (2018) 719-725
[8] R. Zhai, J. Hu, J.N. Saddler, The inhibition of hemicellulosic sugars on cellulose hydrolysis are highly dependant on the cellulase productive binding, processivity, and substrate surface charges, Bioresource Technology 258 (2018) 79-87.
[9] L.F. Long, D. Tian, R. Zhai, X. Li, Y. Zhang, J.G. Hu, F. Wang, J. Saddler, Thermostable xylanase-aided two-stage hydrolysis approach enhances sugar release of pretreated lignocellulosic biomass, Bioresource Technology 257 (2018) 334-338
[10] R. Zhai, J. Hu, J.N. Saddler, Minimizing cellulase inhibition of whole slurry biomass hydrolysis through the addition of carbocation scavengers during acid-catalyzed pretreatment, Bioresource Technology 258 (2018) 12-17.
[11] R. Zhai, J. Hu, J.N. Saddler, Extent of enzyme inhibition by phenolics derived from pretreated biomass is significantly influenced by the size and carbonyl group content of the phenolics, Acs Sustainable Chemistry & Engineering 6 (2018) 3823-3829.
[12] R. Zhai, J. Hu, J.N. Saddler, Understanding the slowdown of whole slurry hydrolysis of steam pretreated lignocellulosic woody biomass catalyzed by an up-to-date enzyme cocktail, Sustainable Energy & Fuels 2 (2018) 1048-1056.
[13] R. Zhai, J. Hu, J.N. Saddler, What are the major components in steam pretreated lignocellulosic biomass that inhibit the efficacy of cellulase enzyme mixtures?, Acs Sustainable Chemistry & Engineering 4 (2016) 3429-3436.