Experimental and Theoretical Confirmation of Covalent Bonding in α-Pu

Alexander R. Muñoz; Matthew S. Cook; David C. Arellano; AM Milinda Abeykoon; Jeremy N. Mitchell; Sarah C. Hernandez; Eric D. Bauer; Christopher A. Mizzi; Boris Maiorov; Neil Harrison; W. Adam Phelan

doi:10.1002/adfm.202501798

Experimental and Theoretical Confirmation of Covalent Bonding in α-Pu

Alexander R. Muñoz
, Matthew S. Cook
, David C. Arellano
, AM Milinda Abeykoon
, Jeremy N. Mitchell
, Sarah C. Hernandez
, Eric D. Bauer
, Christopher A. Mizzi
, Boris Maiorov
, Neil Harrison
, W. Adam Phelan

Correlated Electron Materials

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

Abstract

Plutonium's radioactivity provides functionality for nuclear batteries, nuclear reactors, etc., but its complex electronic properties harbor strongly correlated behavior giving rise to a host of interesting phenomena including the presence of a ca. 25% volume collapse between δ-Pu and α-Pu. The complex bonding environments of the ground state allotrope, α-Pu, serve as a unique testing ground for new computational and experimental approaches within the Pu science community. For the first time, a combination of novel ansatzes is used in all-electron density functional theory (DFT) and pair distribution functions (PDF) obtained from high-Q X-ray diffraction to study the bonding behavior in α-Pu. This first experimental and theoretical co-informed description of local bonding behavior for α-Pu reveals covalent bonds, which is a topic that remains of interest in this allotrope. The covalent bonding present at the atomistic level accounts for several of α-Pu's macropscopic properties (e.g., Poisson's ratio) that in turn explains its physical functionalities relative to other allotropic phases like δ-Pu.

Original language	English
Article number	2501798
Journal	Advanced Functional Materials
Volume	35
Issue number	46
DOIs	https://doi.org/10.1002/adfm.202501798
State	Published - Nov 12 2025

Funding

All authors gratefully acknowledge funding for this work under LANL-LDRD projects 20210001DR, 2023004DR, and 20220538ECR. Further, all authors are grateful to Tomas Martinez, Carlos Archuleta, Christopher Cordova, Derek V. Prada, William S. Ponder, and Paul H. Tobash for sample coordination and preparation. This research used resources provided by the Los Alamos National Laboratory Institutional Computing Program, which is supported by the U.S. Department of Energy National Nuclear Security Administration under Contract No. 89233218CNA000001. Use of the National Synchrotron Light Source-II, Brookhaven National Laboratory, was supported by the U.S. Department of Energy under Contract No. DE-SC0012704. All authors gratefully acknowledge funding for this work under LANL‐LDRD projects 20210001DR, 2023004DR, and 20220538ECR. Further, all authors are grateful to Tomas Martinez, Carlos Archuleta, Christopher Cordova, Derek V. Prada, William S. Ponder, and Paul H. Tobash for sample coordination and preparation. This research used resources provided by the Los Alamos National Laboratory Institutional Computing Program, which is supported by the U.S. Department of Energy National Nuclear Security Administration under Contract No. 89233218CNA000001. Use of the National Synchrotron Light Source‐II, Brookhaven National Laboratory, was supported by the U.S. Department of Energy under Contract No. DE‐SC0012704.

Keywords

bonding
DFT calculations
pair distribution function
plutonium
quantum theory of atoms in molecules

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10.1002/adfm.202501798

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title = "Experimental and Theoretical Confirmation of Covalent Bonding in α-Pu",

abstract = "Plutonium's radioactivity provides functionality for nuclear batteries, nuclear reactors, etc., but its complex electronic properties harbor strongly correlated behavior giving rise to a host of interesting phenomena including the presence of a ca. 25\% volume collapse between δ-Pu and α-Pu. The complex bonding environments of the ground state allotrope, α-Pu, serve as a unique testing ground for new computational and experimental approaches within the Pu science community. For the first time, a combination of novel ansatzes is used in all-electron density functional theory (DFT) and pair distribution functions (PDF) obtained from high-Q X-ray diffraction to study the bonding behavior in α-Pu. This first experimental and theoretical co-informed description of local bonding behavior for α-Pu reveals covalent bonds, which is a topic that remains of interest in this allotrope. The covalent bonding present at the atomistic level accounts for several of α-Pu's macropscopic properties (e.g., Poisson's ratio) that in turn explains its physical functionalities relative to other allotropic phases like δ-Pu.",

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AU - Abeykoon, AM Milinda

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AU - Hernandez, Sarah C.

AU - Bauer, Eric D.

AU - Mizzi, Christopher A.

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AU - Harrison, Neil

AU - Phelan, W. Adam

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AB - Plutonium's radioactivity provides functionality for nuclear batteries, nuclear reactors, etc., but its complex electronic properties harbor strongly correlated behavior giving rise to a host of interesting phenomena including the presence of a ca. 25% volume collapse between δ-Pu and α-Pu. The complex bonding environments of the ground state allotrope, α-Pu, serve as a unique testing ground for new computational and experimental approaches within the Pu science community. For the first time, a combination of novel ansatzes is used in all-electron density functional theory (DFT) and pair distribution functions (PDF) obtained from high-Q X-ray diffraction to study the bonding behavior in α-Pu. This first experimental and theoretical co-informed description of local bonding behavior for α-Pu reveals covalent bonds, which is a topic that remains of interest in this allotrope. The covalent bonding present at the atomistic level accounts for several of α-Pu's macropscopic properties (e.g., Poisson's ratio) that in turn explains its physical functionalities relative to other allotropic phases like δ-Pu.

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KW - quantum theory of atoms in molecules

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Experimental and Theoretical Confirmation of Covalent Bonding in α-Pu

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