Your search keyword '"Sheng, Daopeng"' showing total 2 results

1. Successful Decontamination of 99TcO4− in Groundwater at Legacy Nuclear Sites by a Cationic Metal‐Organic Framework with Hydrophobic Pockets.

Author

Sheng, Daopeng, Zhu, Lin, Dai, Xing, Xu, Chao, Li, Peng, Pearce, Carolyn I., Xiao, Chengliang, Chen, Jing, Zhou, Ruhong, Duan, Tao, Farha, Omar K., Chai, Zhifang, and Wang, Shuao

Subjects

*METAL-organic frameworks, *GROUNDWATER, *LEGACY systems, *RADIOACTIVE wastes, *DECONTAMINATION (From gases, chemicals, etc.)

Abstract

99Tc contamination at legacy nuclear sites is a serious and unsolved environmental issue. The selective remediation of 99TcO4− in the presence of a large excess of NO3− and SO42− from natural waste systems represents a significant scientific and technical challenge, since anions with a higher charge density are often preferentially sorbed by traditional anion‐exchange materials. We present a solution to this challenge based on a stable cationic metal‐organic framework, SCU‐102 (Ni2(tipm)3(NO3)4), which exhibits fast sorption kinetics, a large capacity (291 mg g−1), a high distribution coefficient, and, most importantly, a record‐high TcO4− uptake selectivity. This material can almost quantitatively remove TcO4− in the presence of a large excess of NO3− and SO42−. Decontamination experiments confirm that SCU‐102 represents the optimal Tc scavenger with the highest reported clean‐up efficiency, while first‐principle simulations reveal that the origin of the selectivity is the recognition of TcO4− by the hydrophobic pockets of the structure. Capturing radioactive species: A robust 3D cationic metal‐organic framework material, SCU‐102, exhibits fast sorption kinetics, large uptake capacity, high distribution coefficient, and a record‐high TcO4− uptake selectivity. The material offers a solution to the long‐term challenge of 99Tc decontamination from complex natural water systems at legacy nuclear sites. [ABSTRACT FROM AUTHOR]

Published

2019

2. Boosting Proton Conductivity in Highly Robust 3D Inorganic Cationic Extended Frameworks through Ion Exchange with Dihydrogen Phosphate Anions.

Author

Xiao, Chengliang, Wang, Yaxing, Chen, Lanhua, Yin, Xuemiao, Shu, Jie, Sheng, Daopeng, Chai, Zhifang, Albrecht ‐ Schmitt, Thomas E., and Wang, Shuao

Subjects

FUEL cells, ELECTROLYTES, PROTON conductivity, ANIONS, CHARGE-charge interactions

Abstract

The limited long-term hydrolytic stability of rapidly emerging 3D-extended framework materials (MOFs, COFs, MOPs, etc.) is still one of major barriers for their practical applications as new solid-state electrolytes in fuel cells. To obtain hydrolytically stable materials, two H2PO4−-exchanged 3D inorganic cationic extended frameworks (CEFs) were successfully prepared by a facile anion-exchange method. Both anion-exchanged CEFs (YbO(OH)P and NDTBP) show significantly enhanced proton conductivity when compared with the original materials (YbO(OH)Cl and NDTB) with an increase of up to four orders-of-magnitude, reaching 2.36×10−3 and 1.96×10−2 S cm−1 at 98 % RH and 85 °C for YbO(OH)P and NDTBP, respectively. These values are comparable to the most efficient proton-conducting MOFs. In addition, these two anion-exchanged materials are stable in boiling water, which originates from the strong electrostatic interaction between the H2PO4− anion and the cationic host framework, showing a clear advance over all the acid-impregnated materials (H2SO4@MIL-101, H3PO4@MIL-101, and H3PO4@Tp-Azo) as practical solid-state fuel-cell electrolytes. This work offers a new general and efficient approach to functionalize 3D-extended frameworks through an anion-exchange process and achieves water-stability with ultra-high proton conductivity above 10−2 S cm−1. [ABSTRACT FROM AUTHOR]

Published

2015