2022.10 —2027.10东北农业大学，“东农学者学术骨干计划”项目

2023.12 中国博士后科学基金面上项目

Zhang C, Ho S-H*, Chen W-H*, Eng CF, Wang C-T. Simultaneous implementation of sludge dewatering and solid biofuel production by microwave torrefaction. Environmental Research. 2021;195:110775.

Zhang C, Ho S-H*, Chen W-H*, Wang R. Comparative indexes, fuel characterization and thermogravimetric- Fourier transform infrared spectrometer-mass spectrogram (TG-FTIR-MS) analysis of microalga Nannochloropsis Oceanica under oxidative and inert torrefaction. Energy. 2021;230:120824.

Zhang C, Ho S-H*, Chen W-H*, Wang R, Show P-L, Ong HC. Oxidative torrefaction performance of microalga Nannochloropsis Oceanica towards an upgraded microalgal solid biofuel. Journal of Biotechnology. 2021;338:81-90.

Zhang C, Yang W, Chen W-H, Ho S-H, Pétrissans A, Pétrissans M. Effect of torrefaction on the structure and reactivity of rice straw as well as life cycle assessment of torrefaction process. Energy. 2021:122470.

Zhang C, Chen W-H*, Ho S-H*. Elemental loss, enrichment, transformation and life cycle assessment of torrefied corncob. Energy.2021:123019.

Zhang C, Li F, Ho S-H*, Chen W-H*, Gunarathne DS, Show PL. Oxidative torrefaction of microalga Nannochloropsis Oceanica activated by potassium carbonate for solid biofuel production. Environmental Research. 2022;212:113389.

Zhang C, Wang M, Chen W-H*, Pétrissans A, Pétrissans M, Ho S-H*. A comparison of conventional and oxidative torrefaction of microalga Nannochloropsis Oceanica through energy efficiency analysis and life cycle assessment. Journal of Cleaner Production. 2022;369:133236.

Zhang C, Chen W-H*, Ho S-H*. Economic feasibility analysis and environmental impact assessment for the comparison of conventional and microwave torrefaction of spent coffee grounds. Biomass and Bioenergy. 2023;168:106652.

Zhang C, Wang M, Chen W-H*, Zhang Y, Pétrissans A, Pétrissans M, et al. Superhydrophobic and superlipophilic biochar produced from microalga torrefaction and modification for upgrading fuel properties. Biochar. 2023;5:18.

Zhang C, Chen W-H*, Zhang Y, Ho S-H*. Influence of microorganisms on the variation of raw and oxidatively torrefied microalgal biomass properties. Energy. 2023;276:127612.

Zhang C, Chen W-H*, Ho S-H, Zhang Y, Lim S. Comparative advantages analysis of oxidative torrefaction for solid biofuel production and property upgrading. Bioresource Technology. 2023;386:129531.

Zhang C, Chen W-H*, Ho S-H, Hoang AT, Zhang Y*. Tetracycline-adsorbed biochar for solid biofuel usage to achieve waste utilization for environmental sustainability. Environmental Research. 2023;237:116959.

Zhang C, Chen W-H, Ho S-H, Park Y-K, Wang C, Zhang Y. Pelletization property analysis of raw and torrefied corn stalks for industrial application to achieve agricultural waste conversion. Energy. 2023;285:129463.

Zhang C, Zhan Y, Chen W-H, Ho S-H, Park Y-K, Culaba AB, et al. Correlations between different fuel property indicators and carbonization degree of oxidatively torrefied microalgal biomass. Energy. 2024;286:129693.

Zhang C, Fang J, Chen W-H, Kwon EE, Zhang Y. Effects of water washing and KOH activation for upgrading microalgal torrefied biochar. Science of The Total Environment. 2024;921:171254.

Zhang C, Chen W-H, Saravanakumar A, Lin K-YA, Zhang Y. Comparison of torrefaction and hydrothermal carbonization of high-moisture microalgal feedstock. Renewable Energy. 2024:120265.