(1) A novel Fe2+/persulfate/tannic acid process with strengthened efficacy on enhancing waste activated sludge dewaterability and mechanism insight, SCIENCE OF THE TOTAL ENVIRONMENT, 733:139146,2020.
(2) Improved removal of phosphorus from incinerated sewage sludge ash by thermo-chemical reduction method with CaCl2 application, JOURNAL OF CLEANER PRODUCTION,258:120779,2020.
(3) Exploring the efficacy and mechanism of tannic acid/Fe3+ conditioning for enhancing waste activated sludge dewaterability, SEPARATION AND PURIFICATION TECHNOLOGY, 240:116643, 2020.
(4) Exploring the efficacy and mechanism of tannic acid/Fe3+ conditioning for enhancing waste activated sludge dewaterability, SEPARATION AND PURIFICATION TECHNOLOGY, 240: 116643, 2020.
(5) Efficient and regenerative near -infrared glass -ceramic photocatalyst fabricated by a facile in -situ etching method,CHEMICAL ENGINEERING JOURNAL, 394:112124877,2020.
(6) Integrated anaerobic digestion and CO2 sequestration for energy recovery from waste activated sludge by calcium addition: Timing matters, ENERGY,199:117421,2020.
(7) An in-depth study on the deep-dewatering mechanism of waste activated sludge by ozonation pre-oxidation and chitosan re-flocculation conditioning, SCIENCE OF THE TOTAL ENVIRONMENT, 714:136627,2020.
(8) Insight into a new two-step approach of ozonation and chitosan conditioning for sludge deep-dewatering, SCIENCE OF THE TOTAL ENVIRONMENT,697:134032,2019.
(9) Pretreatment-promoted sludge fermentation liquor improves biological nitrogen removal: Molecular insight into the role of dissolved organic matter, BIORESOURCE TECHNOLOGY, 293:122082,2019.
(10) Improved sludge dewaterability by tannic acid conditioning: Temperature, thermodynamics and mechanism studies, CHEMOSPHER, 230:14-23,2019.
