Quantum and isotope effects in lithium metal

Graeme J. Ackland; Mihindra Dunuwille; Miguel Martinez-Canales; Ingo Loa; Rong Zhang; Stanislav Sinogeikin; Weizhao Cai; Shanti Deemyad

doi:10.1126/science.aal4886

Quantum and isotope effects in lithium metal

Graeme J. Ackland, Mihindra Dunuwille, Miguel Martinez-Canales, Ingo Loa, Rong Zhang, Stanislav Sinogeikin, Weizhao Cai, Shanti Deemyad^*

^*Corresponding author for this work

School of Physics and Astronomy

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

Abstract

The crystal structure of elements at zero pressure and temperature is the most fundamental information in condensed matter physics. For decades it has been believed that lithium, the simplest metallic element, has a complicated ground-state crystal structure. Using synchrotron x-ray diffraction in diamond anvil cells and multiscale simulations with density functional theory and molecular dynamics, we show that the previously accepted martensitic ground state is metastable. The actual ground state is face-centered cubic (fcc). We find that isotopes of lithium, under similar thermal paths, exhibit a considerable difference in martensitic transition temperature. Lithium exhibits nuclear quantum mechanical effects, serving as a metallic intermediate between helium, with its quantum effect-dominated structures, and the higher-mass elements. By disentangling the quantum kinetic complexities, we prove that fcc lithium is the ground state, and we synthesize it by decompression.

Original language	English
Pages (from-to)	1254-1259
Number of pages	6
Journal	Science
Volume	356
Issue number	6344
DOIs	https://doi.org/10.1126/science.aal4886
Publication status	Published - 23 Jun 2017

Keywords / Materials (for Non-textual outputs)

DENSE LITHIUM
LOW-TEMPERATURES
MARTENSITIC-TRANSFORMATION
PHASE-TRANSFORMATION
ELECTRONIC-STRUCTURE
PRESSURE
TRANSITION
CRYSTAL
HYDROGEN
BCC

Access to Document

10.1126/science.aal4886

Lithium_is_fccAccepted author manuscript, 6.35 MBLicence: Creative Commons: Attribution-NonCommercial-NoDerivatives (CC BY-NC-ND)

Suppport for the UKCP consortium
Ackland, G.
EPSRC
1/04/17 → 31/03/21
Project: Research
HECATE: Hydrogen at Extreme Conditions: Applying Theory to Experiment for creation, verification and understanding
Ackland, G.
EU government bodies
1/10/16 → 31/03/23
Project: Research
Interatomic potentials for oxide - metal interfaces in molecular dynamics
Ackland, G.
UK-based charities
1/05/14 → 30/04/19
Project: Research

Quantum and isotope effects in lithium metal
Martinez-Canales, M. (Creator), Ackland, G. (Creator) & Loa, I. (Creator), Edinburgh DataShare, 29 Jun 2017
DOI: 10.7488/ds/2050
Dataset

Graeme Ackland
- g.j.acklanded.acuk
- School of Physics and Astronomy - Chair in Computer Simulation
Person: Academic: Research Active
Ingo Loa
- i.loaed.acuk
- School of Physics and Astronomy - Reader
Person: Academic: Research Active
Miguel Martinez-Canales
- miguel.martinezed.acuk
- School of Physics and Astronomy - Senior Lecturer
Person: Academic: Research Active

Cite this

@article{a5f99c82ba5b4f0780813c2efb69c449,

title = "Quantum and isotope effects in lithium metal",

abstract = "The crystal structure of elements at zero pressure and temperature is the most fundamental information in condensed matter physics. For decades it has been believed that lithium, the simplest metallic element, has a complicated ground-state crystal structure. Using synchrotron x-ray diffraction in diamond anvil cells and multiscale simulations with density functional theory and molecular dynamics, we show that the previously accepted martensitic ground state is metastable. The actual ground state is face-centered cubic (fcc). We find that isotopes of lithium, under similar thermal paths, exhibit a considerable difference in martensitic transition temperature. Lithium exhibits nuclear quantum mechanical effects, serving as a metallic intermediate between helium, with its quantum effect-dominated structures, and the higher-mass elements. By disentangling the quantum kinetic complexities, we prove that fcc lithium is the ground state, and we synthesize it by decompression.",

keywords = "DENSE LITHIUM, LOW-TEMPERATURES, MARTENSITIC-TRANSFORMATION, PHASE-TRANSFORMATION, ELECTRONIC-STRUCTURE, PRESSURE, TRANSITION, CRYSTAL, HYDROGEN, BCC",

author = "Ackland, {Graeme J.} and Mihindra Dunuwille and Miguel Martinez-Canales and Ingo Loa and Rong Zhang and Stanislav Sinogeikin and Weizhao Cai and Shanti Deemyad",

year = "2017",

month = jun,

day = "23",

doi = "10.1126/science.aal4886",

language = "English",

volume = "356",

pages = "1254--1259",

journal = "Science",

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T1 - Quantum and isotope effects in lithium metal

AU - Ackland, Graeme J.

AU - Dunuwille, Mihindra

AU - Martinez-Canales, Miguel

AU - Loa, Ingo

AU - Zhang, Rong

AU - Sinogeikin, Stanislav

AU - Cai, Weizhao

AU - Deemyad, Shanti

PY - 2017/6/23

Y1 - 2017/6/23

N2 - The crystal structure of elements at zero pressure and temperature is the most fundamental information in condensed matter physics. For decades it has been believed that lithium, the simplest metallic element, has a complicated ground-state crystal structure. Using synchrotron x-ray diffraction in diamond anvil cells and multiscale simulations with density functional theory and molecular dynamics, we show that the previously accepted martensitic ground state is metastable. The actual ground state is face-centered cubic (fcc). We find that isotopes of lithium, under similar thermal paths, exhibit a considerable difference in martensitic transition temperature. Lithium exhibits nuclear quantum mechanical effects, serving as a metallic intermediate between helium, with its quantum effect-dominated structures, and the higher-mass elements. By disentangling the quantum kinetic complexities, we prove that fcc lithium is the ground state, and we synthesize it by decompression.

AB - The crystal structure of elements at zero pressure and temperature is the most fundamental information in condensed matter physics. For decades it has been believed that lithium, the simplest metallic element, has a complicated ground-state crystal structure. Using synchrotron x-ray diffraction in diamond anvil cells and multiscale simulations with density functional theory and molecular dynamics, we show that the previously accepted martensitic ground state is metastable. The actual ground state is face-centered cubic (fcc). We find that isotopes of lithium, under similar thermal paths, exhibit a considerable difference in martensitic transition temperature. Lithium exhibits nuclear quantum mechanical effects, serving as a metallic intermediate between helium, with its quantum effect-dominated structures, and the higher-mass elements. By disentangling the quantum kinetic complexities, we prove that fcc lithium is the ground state, and we synthesize it by decompression.

KW - DENSE LITHIUM

KW - LOW-TEMPERATURES

KW - MARTENSITIC-TRANSFORMATION

KW - PHASE-TRANSFORMATION

KW - ELECTRONIC-STRUCTURE

KW - PRESSURE

KW - TRANSITION

KW - CRYSTAL

KW - HYDROGEN

KW - BCC

U2 - 10.1126/science.aal4886

DO - 10.1126/science.aal4886

M3 - Article

SN - 0036-8075

VL - 356

SP - 1254

EP - 1259

JO - Science

JF - Science

IS - 6344

ER -

Quantum and isotope effects in lithium metal

Abstract

Keywords / Materials (for Non-textual outputs)

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Projects

Suppport for the UKCP consortium

HECATE: Hydrogen at Extreme Conditions: Applying Theory to Experiment for creation, verification and understanding

Interatomic potentials for oxide - metal interfaces in molecular dynamics

Datasets

Quantum and isotope effects in lithium metal

Profiles

Graeme Ackland

Ingo Loa

Miguel Martinez-Canales

Cite this