Gram-Scale Synthesis of High-Loading Single-Atomic-Site Fe Catalysts for Effective Epoxidation of Styrene

Yu Xiong; Wenming Sun; Pingyu Xin; Wenxing Chen; Xusheng Zheng; Wensheng Yan; Lirong Zheng; Juncai Dong; Jian Zhang; Dingsheng Wang; Yadong Li

doi:10.1002/adma.202000896

Gram-Scale Synthesis of High-Loading Single-Atomic-Site Fe Catalysts for Effective Epoxidation of Styrene

Yu Xiong, Wenming Sun, Pingyu Xin, Wenxing Chen, Xusheng Zheng, Wensheng Yan, Lirong Zheng, Juncai Dong, Jian Zhang, Dingsheng Wang^*, Yadong Li

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

201 Citations (Scopus)

Abstract

Single-atomic-site (SAS) catalysts, a new frontier of catalysts, always show extremely high atom efficiency and unexpected catalytic properties. Herein, a pyrolyzing coordinated polymer (PCP) strategy is developed, which is facile and widely applicable in the synthesis of a series of SAS catalysts including SAS-Fe, SAS-Ni, SAS-Cu, SAS-Zn, SAS-Ru, SAS-Rh, SAS-Pd, SAS-Pt, and SAS-Ir. The as-obtained SAS catalysts can be easily synthesized at gram scale and the metal loading of SAS-Fe catalysts achieves a record value of 30 wt%, which meets the requirement of practical applications. Moreover, it is discovered that SAS-Fe catalysts show unprecedented catalytic performance for epoxidation of styrene using O₂ as the only oxidant (yield: 64%; selectivity: 89%), while Fe nanoparticles and ironporphyrin are inactive. This discovery is believed to pave the way for exploiting the unparalleled properties of SAS catalysts and promoting their industrial applications.

Original language	English
Article number	2000896
Journal	Advanced Materials
Volume	32
Issue number	34
DOIs	https://doi.org/10.1002/adma.202000896
Publication status	Published - 1 Aug 2020
Externally published	Yes

Keywords

epoxidation of styrene
gram-scale synthesis
high-loading
single-atomic-site catalyst

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title = "Gram-Scale Synthesis of High-Loading Single-Atomic-Site Fe Catalysts for Effective Epoxidation of Styrene",

abstract = "Single-atomic-site (SAS) catalysts, a new frontier of catalysts, always show extremely high atom efficiency and unexpected catalytic properties. Herein, a pyrolyzing coordinated polymer (PCP) strategy is developed, which is facile and widely applicable in the synthesis of a series of SAS catalysts including SAS-Fe, SAS-Ni, SAS-Cu, SAS-Zn, SAS-Ru, SAS-Rh, SAS-Pd, SAS-Pt, and SAS-Ir. The as-obtained SAS catalysts can be easily synthesized at gram scale and the metal loading of SAS-Fe catalysts achieves a record value of 30 wt%, which meets the requirement of practical applications. Moreover, it is discovered that SAS-Fe catalysts show unprecedented catalytic performance for epoxidation of styrene using O2 as the only oxidant (yield: 64%; selectivity: 89%), while Fe nanoparticles and ironporphyrin are inactive. This discovery is believed to pave the way for exploiting the unparalleled properties of SAS catalysts and promoting their industrial applications.",

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author = "Yu Xiong and Wenming Sun and Pingyu Xin and Wenxing Chen and Xusheng Zheng and Wensheng Yan and Lirong Zheng and Juncai Dong and Jian Zhang and Dingsheng Wang and Yadong Li",

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year = "2020",

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doi = "10.1002/adma.202000896",

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AU - Xiong, Yu

AU - Sun, Wenming

AU - Xin, Pingyu

AU - Chen, Wenxing

AU - Zheng, Xusheng

AU - Yan, Wensheng

AU - Zheng, Lirong

AU - Dong, Juncai

AU - Zhang, Jian

AU - Wang, Dingsheng

AU - Li, Yadong

PY - 2020/8/1

Y1 - 2020/8/1

N2 - Single-atomic-site (SAS) catalysts, a new frontier of catalysts, always show extremely high atom efficiency and unexpected catalytic properties. Herein, a pyrolyzing coordinated polymer (PCP) strategy is developed, which is facile and widely applicable in the synthesis of a series of SAS catalysts including SAS-Fe, SAS-Ni, SAS-Cu, SAS-Zn, SAS-Ru, SAS-Rh, SAS-Pd, SAS-Pt, and SAS-Ir. The as-obtained SAS catalysts can be easily synthesized at gram scale and the metal loading of SAS-Fe catalysts achieves a record value of 30 wt%, which meets the requirement of practical applications. Moreover, it is discovered that SAS-Fe catalysts show unprecedented catalytic performance for epoxidation of styrene using O2 as the only oxidant (yield: 64%; selectivity: 89%), while Fe nanoparticles and ironporphyrin are inactive. This discovery is believed to pave the way for exploiting the unparalleled properties of SAS catalysts and promoting their industrial applications.

AB - Single-atomic-site (SAS) catalysts, a new frontier of catalysts, always show extremely high atom efficiency and unexpected catalytic properties. Herein, a pyrolyzing coordinated polymer (PCP) strategy is developed, which is facile and widely applicable in the synthesis of a series of SAS catalysts including SAS-Fe, SAS-Ni, SAS-Cu, SAS-Zn, SAS-Ru, SAS-Rh, SAS-Pd, SAS-Pt, and SAS-Ir. The as-obtained SAS catalysts can be easily synthesized at gram scale and the metal loading of SAS-Fe catalysts achieves a record value of 30 wt%, which meets the requirement of practical applications. Moreover, it is discovered that SAS-Fe catalysts show unprecedented catalytic performance for epoxidation of styrene using O2 as the only oxidant (yield: 64%; selectivity: 89%), while Fe nanoparticles and ironporphyrin are inactive. This discovery is believed to pave the way for exploiting the unparalleled properties of SAS catalysts and promoting their industrial applications.

KW - epoxidation of styrene

KW - gram-scale synthesis

KW - high-loading

KW - single-atomic-site catalyst

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ER -

Gram-Scale Synthesis of High-Loading Single-Atomic-Site Fe Catalysts for Effective Epoxidation of Styrene

Abstract

Keywords

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