Low Loading and High Activity of Platinum Oxide Nanoclusters Formed by Defect Engineering of a Metal-Organic Framework for Formaldehyde Degradation

Lantian Ren; Qinglang Ma; Anxiang Yin; Xiao Feng; Teng Zhang; Bo Wang

doi:10.1002/cssc.202201324

Low Loading and High Activity of Platinum Oxide Nanoclusters Formed by Defect Engineering of a Metal-Organic Framework for Formaldehyde Degradation

Lantian Ren, Qinglang Ma, Anxiang Yin, Xiao Feng, Teng Zhang^*, Bo Wang^*

^*Corresponding author for this work

Beijing Institute of Technology

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

5 Citations (Scopus)

Abstract

A distinct platinum oxide nanocluster (PtO_x) was developed, consisting of only Pt−O bond by a defect-engineered Al metal-organic framework (MOF) (BIT-72) with superior formaldehyde (HCHO) degradation activity and stability. With only 0.015 wt % Pt loading, PtO_x@BIT-72-DE could degrade HCHO with 100 % conversion continuously for at least 200 h under HCHO concentration of 25 ppm and gas hourly space velocity of 60000 mL g⁻¹ h⁻¹ at room temperature. Furthermore, its specific rate (446 mmol_HCHO g_Pt⁻¹ h⁻¹) was higher than for traditional Pt-based catalysts and single-atom Pt catalysts. Moreover, the cost of PtO_x@BIT-72-DE was lowered to 0.0769 $ g⁻¹, which could significantly facilitate its commercial application. This study demonstrates the promising potential of MOFs in the design of HCHO degradation catalysts.

Original language	English
Article number	e202201324
Journal	ChemSusChem
Volume	15
Issue number	24
DOIs	https://doi.org/10.1002/cssc.202201324
Publication status	Published - 20 Dec 2022

Keywords

defect engineering
formaldehyde
heterogeneous catalysis
metal–organic frameworks
nanoclusters

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title = "Low Loading and High Activity of Platinum Oxide Nanoclusters Formed by Defect Engineering of a Metal-Organic Framework for Formaldehyde Degradation",

abstract = "A distinct platinum oxide nanocluster (PtOx) was developed, consisting of only Pt−O bond by a defect-engineered Al metal-organic framework (MOF) (BIT-72) with superior formaldehyde (HCHO) degradation activity and stability. With only 0.015 wt \% Pt loading, PtOx@BIT-72-DE could degrade HCHO with 100 \% conversion continuously for at least 200 h under HCHO concentration of 25 ppm and gas hourly space velocity of 60000 mL g−1 h−1 at room temperature. Furthermore, its specific rate (446 mmolHCHO gPt−1 h−1) was higher than for traditional Pt-based catalysts and single-atom Pt catalysts. Moreover, the cost of PtOx@BIT-72-DE was lowered to 0.0769 \$ g−1, which could significantly facilitate its commercial application. This study demonstrates the promising potential of MOFs in the design of HCHO degradation catalysts.",

keywords = "defect engineering, formaldehyde, heterogeneous catalysis, metal–organic frameworks, nanoclusters",

author = "Lantian Ren and Qinglang Ma and Anxiang Yin and Xiao Feng and Teng Zhang and Bo Wang",

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T1 - Low Loading and High Activity of Platinum Oxide Nanoclusters Formed by Defect Engineering of a Metal-Organic Framework for Formaldehyde Degradation

AU - Ren, Lantian

AU - Ma, Qinglang

AU - Yin, Anxiang

AU - Feng, Xiao

AU - Zhang, Teng

AU - Wang, Bo

PY - 2022/12/20

Y1 - 2022/12/20

N2 - A distinct platinum oxide nanocluster (PtOx) was developed, consisting of only Pt−O bond by a defect-engineered Al metal-organic framework (MOF) (BIT-72) with superior formaldehyde (HCHO) degradation activity and stability. With only 0.015 wt % Pt loading, PtOx@BIT-72-DE could degrade HCHO with 100 % conversion continuously for at least 200 h under HCHO concentration of 25 ppm and gas hourly space velocity of 60000 mL g−1 h−1 at room temperature. Furthermore, its specific rate (446 mmolHCHO gPt−1 h−1) was higher than for traditional Pt-based catalysts and single-atom Pt catalysts. Moreover, the cost of PtOx@BIT-72-DE was lowered to 0.0769 $ g−1, which could significantly facilitate its commercial application. This study demonstrates the promising potential of MOFs in the design of HCHO degradation catalysts.

AB - A distinct platinum oxide nanocluster (PtOx) was developed, consisting of only Pt−O bond by a defect-engineered Al metal-organic framework (MOF) (BIT-72) with superior formaldehyde (HCHO) degradation activity and stability. With only 0.015 wt % Pt loading, PtOx@BIT-72-DE could degrade HCHO with 100 % conversion continuously for at least 200 h under HCHO concentration of 25 ppm and gas hourly space velocity of 60000 mL g−1 h−1 at room temperature. Furthermore, its specific rate (446 mmolHCHO gPt−1 h−1) was higher than for traditional Pt-based catalysts and single-atom Pt catalysts. Moreover, the cost of PtOx@BIT-72-DE was lowered to 0.0769 $ g−1, which could significantly facilitate its commercial application. This study demonstrates the promising potential of MOFs in the design of HCHO degradation catalysts.

KW - defect engineering

KW - formaldehyde

KW - heterogeneous catalysis

KW - metal–organic frameworks

KW - nanoclusters

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ER -

Low Loading and High Activity of Platinum Oxide Nanoclusters Formed by Defect Engineering of a Metal-Organic Framework for Formaldehyde Degradation

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Keywords

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