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2.Chen, G., … Hu, HY. (2021). Effects of microbial inactivation approaches on quantity and properties of extracellular polymeric substances in the process of wastewater treatment and reclamation. Journal of Hazardous Materials, 413: 125283. (CAS Q1 top, JCR Q1, IF 14.2)
3.Chen, G., Wu, G., Chen, L., Wang, W., Hong, F. F., & J?nsson, L. J. (2019). Performance of nanocellulose-producing bacterial strains in static and agitated cultures with different starting pH. Carbohydrate Polymers, 215: 280-288. (CAS Q1 top, JCR Q1, IF 10.7)
4.Chen, G., … Hu, HY. (2022). Performance of different pretreatment methods on alleviating reverse osmosis membrane fouling caused by soluble microbial products. Journal of Membrane Science, 641: 119850. (CAS Q1 top, JCR Q1, IF 10.5)
5.Chen, G., Wu, YH… Hu, HY. (2022). Enhanced extracellular polymeric substances production and aggravated membrane fouling potential caused by different disinfection treatment. Journal of Membrane Science, 642: 120007. (CAS Q1 top, JCR Q1, IF 10.5)
6.Chen, G., Chen, L., Wang, W., Hong, F. F., & Zhu. Meifang (朱美芳院士) (2019) Manufacture of a novel anisotropic bacterial nanocellulose hydrogel membrane by using a rotary drum bioreactor. Carbohydrate Polymers, 211: 281-288. (CAS Q1 top, JCR Q1, IF 10.7)
7.Chen, G., … Wei, Yen. (2022). Super solvent of cellulose with extra high solubility for tunable cellulose structure with versatile application. Carbohydrate Polymers, 119917. (CAS Q1 top, JCR Q1, IF 10.7)
8.Chen, G., Wu, YH… Hu, HY. (2022). Pretreatment for alleviation of RO membrane fouling in dyeing wastewater reclamation. Chemosphere, 292: 133471. (CAS Q2 top, JCR Q1, IF 8.9)
9.Chen, G., Wu, G., Chen, L., Wang, W., Hong, F. F., & J?nsson, L. J. (2019). Comparison of productivity and quality of bacterial nanocellulose synthesized using culture media based on seven sugars from biomass. Microbial Biotechnology, 12(4): 677-687. (CAS Q2, JCR Q1, IF 6.6)
10.Chen, G., Chen, L., Wang, W., Chen, S., Wang, H., Wei, Yen.(危岩), & Hong, F. F. (2019). Improved bacterial nanocellulose production from glucose without the loss of quality by evaluating thirteen agitator configurations at low speed. Microbial Biotechnology, 12(6): 1387-1402. (CAS Q2, JCR Q1, IF 6.6)
11.Chen, G., Chen, L., Wang, W., & Hong, F. F. (2018). Evaluation of six ionic liquids and use in pretreatment of sweet sorghum bagasse for bacterial nanocellulose production. Journal of Chemical Technology and Biotechnology, 93(12): 3452-3461. (CAS Q2, JCR Q2, IF 3.7)
12.Chen, G., Wu, G., Alriksson, B., Chen, L., Wang, W., Hong, F. F., & J?nsson, L. J. (2018). Scale-up of production of bacterial nanocellulose using submerged cultivation. Journal of Chemical Technology and Biotechnology, 93(12): 3418-3427. (CAS Q2, JCR Q2, IF 3.7)
13.Meng Y.1*, Chen, G. 1*, Huang M. (2022). Nanomaterials for High Temperature Piezoelectric Applications. Nanomaterials, 12(7), 1171. (CAS Q2, JCR Q2, IF 5.7)
14.Chen, G., Wu, G., Alriksson, B., Wang, W., Hong, F. F., & J?nsson, L. J. (2017). Bioconversion of waste fiber sludge to bacterial nanocellulose and use for reinforcement of CTMP paper sheets. Polymers, 9(9): 458. (CAS Q2, JCR Q1, IF 5.0)