Your search keyword '"Wang, Jianji"' showing total 2 results

1. Tailoring delicate pore environment of 2D Covalent organic frameworks for selective palladium recovery.

Author

Zhao, Yuling, Xu, Chang, Qi, Qingling, Qiu, Jikuan, Li, Zhiyong, Wang, Huiyong, and Wang, Jianji

Subjects

*PALLADIUM, *PRINTED circuits, *CRUST of the earth, *HYDROGEN bonding, *AQUEOUS solutions, *COORDINATION polymers

Abstract

• A pore environment tailoring strategy for COFs was proposed to boost Pd(II) capture. • The adsorbent exhibited a high adsorption capacity for Pd(II) (532 mg/g). • Excellent selectivity, fast kinetics, and good reusability for Pd(II) recovery. • The remarkable performances depended on synergistic multiple interactions. Palladium is a rare resource, and its content in the earth's crust is very low. Thus, its selective recovery from a secondary source is of great importance but a challenging task. Herein, we have constructed a series of bipyridine-based two dimensional (2D) covalent organic frameworks (COFs) TFBBPY-COF, TFBBPY-OH-COF and TFBBPY-OMe-COF, and explored their extraction performance towards palladium in aqueous solutions. It is found that by tailoring the pore environment of these COFs, TFBBPY-OMe-COF shows a highly efficient adsorption and excellent selectivity for palladium recovery, and the maximum sorption capacity is up to 532 mg g−1, which is the highest value among the crystalline porous adsorbents reported up to now. Furthermore, TFBBPY-OMe-COF has been successfully employed to capture Pd(II) with a high selectivity (92.3%) in a simulated solution derived from a waste printed circuit boards. Spectral experiments and theoretical calculations reveal that the excellent adsorption of palladium is mainly attributed to the multiple hydrogen bonds of C–H---Cl and coordination of O and pyridine-N to Pd(II). [ABSTRACT FROM AUTHOR]

Published

2022

2. Tailoring delicate pore environment of 2D Covalent organic frameworks for selective palladium recovery.

Author

Zhao, Yuling, Xu, Chang, Qi, Qingling, Qiu, Jikuan, Li, Zhiyong, Wang, Huiyong, and Wang, Jianji

Subjects

*PALLADIUM, *PRINTED circuits, *CRUST of the earth, *HYDROGEN bonding, *AQUEOUS solutions, *COORDINATION polymers

Abstract

• A pore environment tailoring strategy for COFs was proposed to boost Pd(II) capture. • The adsorbent exhibited a high adsorption capacity for Pd(II) (532 mg/g). • Excellent selectivity, fast kinetics, and good reusability for Pd(II) recovery. • The remarkable performances depended on synergistic multiple interactions. Palladium is a rare resource, and its content in the earth's crust is very low. Thus, its selective recovery from a secondary source is of great importance but a challenging task. Herein, we have constructed a series of bipyridine-based two dimensional (2D) covalent organic frameworks (COFs) TFBBPY-COF, TFBBPY-OH-COF and TFBBPY-OMe-COF, and explored their extraction performance towards palladium in aqueous solutions. It is found that by tailoring the pore environment of these COFs, TFBBPY-OMe-COF shows a highly efficient adsorption and excellent selectivity for palladium recovery, and the maximum sorption capacity is up to 532 mg g−1, which is the highest value among the crystalline porous adsorbents reported up to now. Furthermore, TFBBPY-OMe-COF has been successfully employed to capture Pd(II) with a high selectivity (92.3%) in a simulated solution derived from a waste printed circuit boards. Spectral experiments and theoretical calculations reveal that the excellent adsorption of palladium is mainly attributed to the multiple hydrogen bonds of C–H---Cl and coordination of O and pyridine-N to Pd(II). [ABSTRACT FROM AUTHOR]

Published

2022