Modelling amorphous materials via a joint solid-state NMR and X-ray absorption spectroscopy and DFT approach: application to alumina

Angela F. Harper; Steffen P. Emge; Pieter C.M.M. Magusin; Clare P. Grey; Andrew Morris

doi:10.1039/D2SC04035B

Modelling amorphous materials via a joint solid-state NMR and X-ray absorption spectroscopy and DFT approach: application to alumina

Angela F. Harper, Steffen P. Emge, Pieter C.M.M. Magusin, Clare P. Grey, Andrew Morris^*

^*Corresponding author for this work

Metallurgy and Materials

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Abstract

Understanding a material's electronic structure is crucial to the development of many functional devices from semiconductors to solar cells and Li-ion batteries. A material's properties, including electronic structure, are dependent on the arrangement of its atoms. However, structure determination (the process of uncovering the atomic arrangement), is impeded, both experimentally and computationally, by disorder. The lack of a verifiable atomic model presents a huge challenge when designing functional amorphous materials. Such materials may be characterised through their local atomic environments using, for example, solid-state NMR and XAS. By using these two spectroscopy methods to inform the sampling of configurations from ab initio molecular dynamics we devise and validate an amorphous model, choosing amorphous alumina to illustrate the approach due to its wide range of technological uses. Our model predicts two distinct geometric environments of AlO₅ coordination polyhedra and determines the origin of the pre-edge features in the Al K-edge XAS. From our model we construct an average electronic density of states for amorphous alumina, and identify localized states at the conduction band minimum (CBM). We show that the presence of a pre-edge peak in the XAS is a result of transitions from the Al 1s to Al 3s states at the CBM. Deconvoluting this XAS by coordination geometry reveals contributions from both AlO₄ and AlO₅ geometries at the CBM give rise to the pre-edge, which provides insight into the role of AlO₅ in the electronic structure of alumina. This work represents an important advance within the field of solid-state amorphous modelling, providing a method for developing amorphous models through the comparison of experimental and computationally derived spectra, which may then be used to determine the electronic structure of amorphous materials.

Original language	English
Pages (from-to)	1155-1167
Number of pages	13
Journal	Chemical Science
Volume	14
Issue number	5
Early online date	21 Dec 2022
DOIs	https://doi.org/10.1039/D2SC04035B
Publication status	Published - 7 Feb 2023

Bibliographical note

Acknowledgments:
The authors thank Steve Haws (Henry Royce Institute, Cambridge) for assistance with the ALD and Richard Chen (University of Cambridge, Chemistry) for NMR sample preparation. The authors also thank Dr Trent Franks and the UK High-Field Solid-State NMR Facility Warwick for measurements on the 1 GHz magnet. Funding: AFH acknowledges the financial support of the Gates Cambridge Trust and the Winton Programme for the Physics of Sustainability, University of Cambridge, UK. AJM acknowledges funding from EPSRC (EP/P003532/1). The authors acknowledge networking support via the EPSRC Collaborative Computational Projects, CCP9 (EP/M022595/1) and CCP-NC (EP/T026642/1). This work was performed using resources provided by the Cambridge Service for Data Driven Discovery (CSD3) operated by the University of Cambridge Research Computing Service (https://dirac.ac.uk/), provided by Dell EMC and Intel using Tier-2 funding from the EPSRC (capital grant EP/P020259/1), and DiRAC funding from the Science and Technology Facilities Council (https://dirac.ac.uk/). SPE acknowledges funding via an EPSRC iCASE (Award 1834544) and via the Royal Society (RP\R1\180147). For ALD sample preparation, use of the Ambient Processing Cluster Tool, part of Sir Henry Royce Institute–Cambridge Equipment, EPSRC grant EP/P024947/1 is gratefully acknowledged.

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Collaborative Computational Project in NMR Crystallography
Morris, A.
Engineering & Physical Science Research Council
6/05/20 → 5/05/25
Project: Research Councils

Cite this

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title = "Modelling amorphous materials via a joint solid-state NMR and X-ray absorption spectroscopy and DFT approach: application to alumina",

abstract = "Understanding a material's electronic structure is crucial to the development of many functional devices from semiconductors to solar cells and Li-ion batteries. A material's properties, including electronic structure, are dependent on the arrangement of its atoms. However, structure determination (the process of uncovering the atomic arrangement), is impeded, both experimentally and computationally, by disorder. The lack of a verifiable atomic model presents a huge challenge when designing functional amorphous materials. Such materials may be characterised through their local atomic environments using, for example, solid-state NMR and XAS. By using these two spectroscopy methods to inform the sampling of configurations from ab initio molecular dynamics we devise and validate an amorphous model, choosing amorphous alumina to illustrate the approach due to its wide range of technological uses. Our model predicts two distinct geometric environments of AlO5 coordination polyhedra and determines the origin of the pre-edge features in the Al K-edge XAS. From our model we construct an average electronic density of states for amorphous alumina, and identify localized states at the conduction band minimum (CBM). We show that the presence of a pre-edge peak in the XAS is a result of transitions from the Al 1s to Al 3s states at the CBM. Deconvoluting this XAS by coordination geometry reveals contributions from both AlO4 and AlO5 geometries at the CBM give rise to the pre-edge, which provides insight into the role of AlO5 in the electronic structure of alumina. This work represents an important advance within the field of solid-state amorphous modelling, providing a method for developing amorphous models through the comparison of experimental and computationally derived spectra, which may then be used to determine the electronic structure of amorphous materials.",

author = "Harper, {Angela F.} and Emge, {Steffen P.} and Magusin, {Pieter C.M.M.} and Grey, {Clare P.} and Andrew Morris",

note = "Acknowledgments: The authors thank Steve Haws (Henry Royce Institute, Cambridge) for assistance with the ALD and Richard Chen (University of Cambridge, Chemistry) for NMR sample preparation. The authors also thank Dr Trent Franks and the UK High-Field Solid-State NMR Facility Warwick for measurements on the 1 GHz magnet. Funding: AFH acknowledges the financial support of the Gates Cambridge Trust and the Winton Programme for the Physics of Sustainability, University of Cambridge, UK. AJM acknowledges funding from EPSRC (EP/P003532/1). The authors acknowledge networking support via the EPSRC Collaborative Computational Projects, CCP9 (EP/M022595/1) and CCP-NC (EP/T026642/1). This work was performed using resources provided by the Cambridge Service for Data Driven Discovery (CSD3) operated by the University of Cambridge Research Computing Service (https://dirac.ac.uk/), provided by Dell EMC and Intel using Tier-2 funding from the EPSRC (capital grant EP/P020259/1), and DiRAC funding from the Science and Technology Facilities Council (https://dirac.ac.uk/). SPE acknowledges funding via an EPSRC iCASE (Award 1834544) and via the Royal Society (RP\R1\180147). For ALD sample preparation, use of the Ambient Processing Cluster Tool, part of Sir Henry Royce Institute–Cambridge Equipment, EPSRC grant EP/P024947/1 is gratefully acknowledged. ",

year = "2023",

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doi = "10.1039/D2SC04035B",

language = "English",

volume = "14",

pages = "1155--1167",

journal = "Chemical Science",

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AU - Harper, Angela F.

AU - Emge, Steffen P.

AU - Magusin, Pieter C.M.M.

AU - Grey, Clare P.

AU - Morris, Andrew

N1 - Acknowledgments: The authors thank Steve Haws (Henry Royce Institute, Cambridge) for assistance with the ALD and Richard Chen (University of Cambridge, Chemistry) for NMR sample preparation. The authors also thank Dr Trent Franks and the UK High-Field Solid-State NMR Facility Warwick for measurements on the 1 GHz magnet. Funding: AFH acknowledges the financial support of the Gates Cambridge Trust and the Winton Programme for the Physics of Sustainability, University of Cambridge, UK. AJM acknowledges funding from EPSRC (EP/P003532/1). The authors acknowledge networking support via the EPSRC Collaborative Computational Projects, CCP9 (EP/M022595/1) and CCP-NC (EP/T026642/1). This work was performed using resources provided by the Cambridge Service for Data Driven Discovery (CSD3) operated by the University of Cambridge Research Computing Service (https://dirac.ac.uk/), provided by Dell EMC and Intel using Tier-2 funding from the EPSRC (capital grant EP/P020259/1), and DiRAC funding from the Science and Technology Facilities Council (https://dirac.ac.uk/). SPE acknowledges funding via an EPSRC iCASE (Award 1834544) and via the Royal Society (RP\R1\180147). For ALD sample preparation, use of the Ambient Processing Cluster Tool, part of Sir Henry Royce Institute–Cambridge Equipment, EPSRC grant EP/P024947/1 is gratefully acknowledged.

PY - 2023/2/7

Y1 - 2023/2/7

N2 - Understanding a material's electronic structure is crucial to the development of many functional devices from semiconductors to solar cells and Li-ion batteries. A material's properties, including electronic structure, are dependent on the arrangement of its atoms. However, structure determination (the process of uncovering the atomic arrangement), is impeded, both experimentally and computationally, by disorder. The lack of a verifiable atomic model presents a huge challenge when designing functional amorphous materials. Such materials may be characterised through their local atomic environments using, for example, solid-state NMR and XAS. By using these two spectroscopy methods to inform the sampling of configurations from ab initio molecular dynamics we devise and validate an amorphous model, choosing amorphous alumina to illustrate the approach due to its wide range of technological uses. Our model predicts two distinct geometric environments of AlO5 coordination polyhedra and determines the origin of the pre-edge features in the Al K-edge XAS. From our model we construct an average electronic density of states for amorphous alumina, and identify localized states at the conduction band minimum (CBM). We show that the presence of a pre-edge peak in the XAS is a result of transitions from the Al 1s to Al 3s states at the CBM. Deconvoluting this XAS by coordination geometry reveals contributions from both AlO4 and AlO5 geometries at the CBM give rise to the pre-edge, which provides insight into the role of AlO5 in the electronic structure of alumina. This work represents an important advance within the field of solid-state amorphous modelling, providing a method for developing amorphous models through the comparison of experimental and computationally derived spectra, which may then be used to determine the electronic structure of amorphous materials.

AB - Understanding a material's electronic structure is crucial to the development of many functional devices from semiconductors to solar cells and Li-ion batteries. A material's properties, including electronic structure, are dependent on the arrangement of its atoms. However, structure determination (the process of uncovering the atomic arrangement), is impeded, both experimentally and computationally, by disorder. The lack of a verifiable atomic model presents a huge challenge when designing functional amorphous materials. Such materials may be characterised through their local atomic environments using, for example, solid-state NMR and XAS. By using these two spectroscopy methods to inform the sampling of configurations from ab initio molecular dynamics we devise and validate an amorphous model, choosing amorphous alumina to illustrate the approach due to its wide range of technological uses. Our model predicts two distinct geometric environments of AlO5 coordination polyhedra and determines the origin of the pre-edge features in the Al K-edge XAS. From our model we construct an average electronic density of states for amorphous alumina, and identify localized states at the conduction band minimum (CBM). We show that the presence of a pre-edge peak in the XAS is a result of transitions from the Al 1s to Al 3s states at the CBM. Deconvoluting this XAS by coordination geometry reveals contributions from both AlO4 and AlO5 geometries at the CBM give rise to the pre-edge, which provides insight into the role of AlO5 in the electronic structure of alumina. This work represents an important advance within the field of solid-state amorphous modelling, providing a method for developing amorphous models through the comparison of experimental and computationally derived spectra, which may then be used to determine the electronic structure of amorphous materials.

U2 - 10.1039/D2SC04035B

DO - 10.1039/D2SC04035B

M3 - Article

SN - 2041-6520

VL - 14

SP - 1155

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JO - Chemical Science

JF - Chemical Science

IS - 5

ER -

Modelling amorphous materials via a joint solid-state NMR and X-ray absorption spectroscopy and DFT approach: application to alumina

Abstract

Bibliographical note

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Collaborative Computational Project in NMR Crystallography

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