Ultralow loading ruthenium on alumina monoliths for facile, highly recyclable reduction of p-nitrophenol

Lorianne R. Shultz; Corbin Feit; Jordan Stanberry; Zhengning Gao; Shaohua Xie; Vasileios A. Anagnostopoulos; Fudong Liu; Parag Banerjee; Titel Jurca

doi:10.3390/catal11020165

Ultralow loading ruthenium on alumina monoliths for facile, highly recyclable reduction of p-nitrophenol

Lorianne R. Shultz
, Corbin Feit
, Jordan Stanberry
, Zhengning Gao
, Shaohua Xie
, Vasileios A. Anagnostopoulos
, Fudong Liu
, Parag Banerjee
, Titel Jurca

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

8 Scopus citations

Abstract

The pervasive use of toxic nitroaromatics in industrial processes and their prevalence in industrial effluent has motivated the development of remediation strategies, among which is their catalytic reduction to the less toxic and synthetically useful aniline derivatives. While this area of research has a rich history with innumerable examples of active catalysts, the majority of systems rely on expensive precious metals and are submicron- or even a few-nanometer-sized colloidal particles. Such systems provide invaluable academic insight but are unsuitable for practical application. Herein, we report the fabrication of catalysts based on ultralow loading of the semiprecious metal ruthenium on 2-4 mm diameter spherical alumina monoliths. Ruthenium loading is achieved by atomic layer deposition (ALD) and catalytic activity is benchmarked using the ubiquitous para-nitrophenol, NaBH₄ aqueous reduction protocol. Recyclability testing points to a very robust catalyst system with intrinsic ease of handling.

Original language	English
Article number	165
Pages (from-to)	1-10
Number of pages	10
Journal	Catalysts
Volume	11
Issue number	2
DOIs	https://doi.org/10.3390/catal11020165
State	Published - Feb 2021
Externally published	Yes

Funding

Authors acknowledge the NSF MRI: ECCS: 1726636 and MCF-AMPAC facility, MSE and CECS. Z.G. acknowledges support from the Preeminent Postdoctoral Program (P3) fellowship at the University of Central Florida. P.B. and C.F. acknowledge support from the National Science Foundation (NSF) under Award No. 1808625. Acknowledgments: Authors acknowledge the NSF MRI: ECCS: 1726636 and MCF-AMPAC facility, MSE and CECS. Z.G. acknowledges support from the Preeminent Postdoctoral Program (P3) fellowship at the University of Central Florida. P.B. and C.F. acknowledge support from the National Science Foundation (NSF) under Award No. 1808625.

Keywords

Alumina support
Aqueous pollutant degradation
Nitrophenol reduction
Rutheniumcatalysis

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10.3390/catal11020165

Cite this

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title = "Ultralow loading ruthenium on alumina monoliths for facile, highly recyclable reduction of p-nitrophenol",

abstract = "The pervasive use of toxic nitroaromatics in industrial processes and their prevalence in industrial effluent has motivated the development of remediation strategies, among which is their catalytic reduction to the less toxic and synthetically useful aniline derivatives. While this area of research has a rich history with innumerable examples of active catalysts, the majority of systems rely on expensive precious metals and are submicron- or even a few-nanometer-sized colloidal particles. Such systems provide invaluable academic insight but are unsuitable for practical application. Herein, we report the fabrication of catalysts based on ultralow loading of the semiprecious metal ruthenium on 2-4 mm diameter spherical alumina monoliths. Ruthenium loading is achieved by atomic layer deposition (ALD) and catalytic activity is benchmarked using the ubiquitous para-nitrophenol, NaBH4 aqueous reduction protocol. Recyclability testing points to a very robust catalyst system with intrinsic ease of handling.",

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AU - Shultz, Lorianne R.

AU - Feit, Corbin

AU - Stanberry, Jordan

AU - Gao, Zhengning

AU - Xie, Shaohua

AU - Anagnostopoulos, Vasileios A.

AU - Liu, Fudong

AU - Banerjee, Parag

AU - Jurca, Titel

PY - 2021/2

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N2 - The pervasive use of toxic nitroaromatics in industrial processes and their prevalence in industrial effluent has motivated the development of remediation strategies, among which is their catalytic reduction to the less toxic and synthetically useful aniline derivatives. While this area of research has a rich history with innumerable examples of active catalysts, the majority of systems rely on expensive precious metals and are submicron- or even a few-nanometer-sized colloidal particles. Such systems provide invaluable academic insight but are unsuitable for practical application. Herein, we report the fabrication of catalysts based on ultralow loading of the semiprecious metal ruthenium on 2-4 mm diameter spherical alumina monoliths. Ruthenium loading is achieved by atomic layer deposition (ALD) and catalytic activity is benchmarked using the ubiquitous para-nitrophenol, NaBH4 aqueous reduction protocol. Recyclability testing points to a very robust catalyst system with intrinsic ease of handling.

AB - The pervasive use of toxic nitroaromatics in industrial processes and their prevalence in industrial effluent has motivated the development of remediation strategies, among which is their catalytic reduction to the less toxic and synthetically useful aniline derivatives. While this area of research has a rich history with innumerable examples of active catalysts, the majority of systems rely on expensive precious metals and are submicron- or even a few-nanometer-sized colloidal particles. Such systems provide invaluable academic insight but are unsuitable for practical application. Herein, we report the fabrication of catalysts based on ultralow loading of the semiprecious metal ruthenium on 2-4 mm diameter spherical alumina monoliths. Ruthenium loading is achieved by atomic layer deposition (ALD) and catalytic activity is benchmarked using the ubiquitous para-nitrophenol, NaBH4 aqueous reduction protocol. Recyclability testing points to a very robust catalyst system with intrinsic ease of handling.

KW - Alumina support

KW - Aqueous pollutant degradation

KW - Nitrophenol reduction

KW - Rutheniumcatalysis

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M3 - Article

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SN - 2073-4344

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ER -

Ultralow loading ruthenium on alumina monoliths for facile, highly recyclable reduction of p-nitrophenol

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Keywords

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