Structure-Property Relationships for Nickel Aluminate Catalysts in Polyethylene Hydrogenolysis with Low Methane Selectivity

Brandon C. Vance; Sean Najmi; Pavel A. Kots; Cong Wang; Sungho Jeon; Eric A. Stach; Dmitri N. Zakharov; Nebojsa Marinkovic; Steven N. Ehrlich; Lu Ma; Dionisios G. Vlachos

doi:10.1021/jacsau.3c00232

Structure-Property Relationships for Nickel Aluminate Catalysts in Polyethylene Hydrogenolysis with Low Methane Selectivity

Brandon C. Vance, Sean Najmi, Pavel A. Kots, Cong Wang, Sungho Jeon, Eric A. Stach, Dmitri N. Zakharov, Nebojsa Marinkovic, Steven N. Ehrlich, Lu Ma, Dionisios G. Vlachos

Chemical and Biomolecular Engineering

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

Abstract

Earth-abundant metals have recently been demonstrated as cheap catalyst alternatives to scarce noble metals for polyethylene hydrogenolysis. However, high methane selectivities hinder industrial feasibility. Herein, we demonstrate that low-temperature ex-situ reduction (350 °C) of coprecipitated nickel aluminate catalysts yields a methane selectivity of <5% at moderate polymer deconstruction (25-45%). A reduction temperature up to 550 °C increases the methane selectivity nearly sevenfold. Catalyst characterization (XRD, XAS, ²⁷Al MAS NMR, H₂ TPR, XPS, and CO-IR) elucidates the complex process of Ni nanoparticle formation, and air-free XPS directly after reaction reveals tetrahedrally coordinated Ni²⁺ cations promote methane production. Metallic and the specific cationic Ni appear responsible for hydrogenolysis of internal and terminal C-C scissions, respectively. A structure-methane selectivity relationship is discovered to guide the design of Ni-based catalysts with low methane generation. It paves the way for discovering other structure-property relations in plastics hydrogenolysis. These catalysts are also effective for polypropylene hydrogenolysis.

Original language	English (US)
Pages (from-to)	2156-2165
Number of pages	10
Journal	JACS Au
Volume	3
Issue number	8
DOIs	https://doi.org/10.1021/jacsau.3c00232
State	Published - Aug 28 2023

Keywords

catalyst restructuring
circular economy
earth-abundant metals
nickel
plastics waste

ASJC Scopus subject areas

Analytical Chemistry
Chemistry (miscellaneous)
Physical and Theoretical Chemistry
Organic Chemistry

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10.1021/jacsau.3c00232

Cite this

@article{39feb8f7d9794ee1a8b05f58f9fccfbb,

title = "Structure-Property Relationships for Nickel Aluminate Catalysts in Polyethylene Hydrogenolysis with Low Methane Selectivity",

abstract = "Earth-abundant metals have recently been demonstrated as cheap catalyst alternatives to scarce noble metals for polyethylene hydrogenolysis. However, high methane selectivities hinder industrial feasibility. Herein, we demonstrate that low-temperature ex-situ reduction (350 °C) of coprecipitated nickel aluminate catalysts yields a methane selectivity of <5% at moderate polymer deconstruction (25-45%). A reduction temperature up to 550 °C increases the methane selectivity nearly sevenfold. Catalyst characterization (XRD, XAS, 27Al MAS NMR, H2 TPR, XPS, and CO-IR) elucidates the complex process of Ni nanoparticle formation, and air-free XPS directly after reaction reveals tetrahedrally coordinated Ni2+ cations promote methane production. Metallic and the specific cationic Ni appear responsible for hydrogenolysis of internal and terminal C-C scissions, respectively. A structure-methane selectivity relationship is discovered to guide the design of Ni-based catalysts with low methane generation. It paves the way for discovering other structure-property relations in plastics hydrogenolysis. These catalysts are also effective for polypropylene hydrogenolysis.",

keywords = "catalyst restructuring, circular economy, earth-abundant metals, nickel, plastics waste",

author = "Vance, {Brandon C.} and Sean Najmi and Kots, {Pavel A.} and Cong Wang and Sungho Jeon and Stach, {Eric A.} and Zakharov, {Dmitri N.} and Nebojsa Marinkovic and Ehrlich, {Steven N.} and Lu Ma and Vlachos, {Dionisios G.}",

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year = "2023",

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doi = "10.1021/jacsau.3c00232",

language = "English (US)",

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T1 - Structure-Property Relationships for Nickel Aluminate Catalysts in Polyethylene Hydrogenolysis with Low Methane Selectivity

AU - Vance, Brandon C.

AU - Najmi, Sean

AU - Kots, Pavel A.

AU - Wang, Cong

AU - Jeon, Sungho

AU - Stach, Eric A.

AU - Zakharov, Dmitri N.

AU - Marinkovic, Nebojsa

AU - Ehrlich, Steven N.

AU - Ma, Lu

AU - Vlachos, Dionisios G.

PY - 2023/8/28

Y1 - 2023/8/28

N2 - Earth-abundant metals have recently been demonstrated as cheap catalyst alternatives to scarce noble metals for polyethylene hydrogenolysis. However, high methane selectivities hinder industrial feasibility. Herein, we demonstrate that low-temperature ex-situ reduction (350 °C) of coprecipitated nickel aluminate catalysts yields a methane selectivity of <5% at moderate polymer deconstruction (25-45%). A reduction temperature up to 550 °C increases the methane selectivity nearly sevenfold. Catalyst characterization (XRD, XAS, 27Al MAS NMR, H2 TPR, XPS, and CO-IR) elucidates the complex process of Ni nanoparticle formation, and air-free XPS directly after reaction reveals tetrahedrally coordinated Ni2+ cations promote methane production. Metallic and the specific cationic Ni appear responsible for hydrogenolysis of internal and terminal C-C scissions, respectively. A structure-methane selectivity relationship is discovered to guide the design of Ni-based catalysts with low methane generation. It paves the way for discovering other structure-property relations in plastics hydrogenolysis. These catalysts are also effective for polypropylene hydrogenolysis.

AB - Earth-abundant metals have recently been demonstrated as cheap catalyst alternatives to scarce noble metals for polyethylene hydrogenolysis. However, high methane selectivities hinder industrial feasibility. Herein, we demonstrate that low-temperature ex-situ reduction (350 °C) of coprecipitated nickel aluminate catalysts yields a methane selectivity of <5% at moderate polymer deconstruction (25-45%). A reduction temperature up to 550 °C increases the methane selectivity nearly sevenfold. Catalyst characterization (XRD, XAS, 27Al MAS NMR, H2 TPR, XPS, and CO-IR) elucidates the complex process of Ni nanoparticle formation, and air-free XPS directly after reaction reveals tetrahedrally coordinated Ni2+ cations promote methane production. Metallic and the specific cationic Ni appear responsible for hydrogenolysis of internal and terminal C-C scissions, respectively. A structure-methane selectivity relationship is discovered to guide the design of Ni-based catalysts with low methane generation. It paves the way for discovering other structure-property relations in plastics hydrogenolysis. These catalysts are also effective for polypropylene hydrogenolysis.

KW - catalyst restructuring

KW - circular economy

KW - earth-abundant metals

KW - nickel

KW - plastics waste

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Structure-Property Relationships for Nickel Aluminate Catalysts in Polyethylene Hydrogenolysis with Low Methane Selectivity

Abstract

Keywords

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