Unveiling oxidation mechanism of bulk ZrS2

Liqiu Yang; Subodh C. Tiwari; Seong Soon Jo; Sungwook Hong; Ankit Mishra; Aravind Krishnamoorthy; Rajiv K. Kalia; Aiichiro Nakano; R. Jaramillo; Priya Vashishta

doi:10.1557/s43580-021-00007-2

Unveiling oxidation mechanism of bulk ZrS₂

Liqiu Yang
, Subodh C. Tiwari
, Seong Soon Jo
, Sungwook Hong
, Ankit Mishra
, Aravind Krishnamoorthy
, Rajiv K. Kalia
, Aiichiro Nakano
, R. Jaramillo
, Priya Vashishta

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

Abstract

Transition metal dichalcogenides have shown great potential for next-generation electronic and optoelectronic devices. However, native oxidation remains a major issue in achieving their long-term stability, especially for Zr-containing materials such as ZrS2. Here, we develop a first principles-informed reactive forcefield for Zr/O/S to study oxidation dynamics of ZrS2. Simulation results reveal anisotropic oxidation rates between (210) and (001) surfaces. The oxidation rate is highly dependent on the initial adsorption of oxygen molecules on the surface. Simulation results also provide reaction mechanism for native oxide formation with atomistic details.

Original language	English
Pages (from-to)	303-306
Number of pages	4
Journal	MRS Advances
Volume	6
Issue number	11
DOIs	https://doi.org/10.1557/s43580-021-00007-2
State	Published - May 2021
Externally published	Yes

ASJC Scopus Subject Areas

General Materials Science
Condensed Matter Physics
Mechanics of Materials
Mechanical Engineering

Keywords

Oxidation dynamics
Reactive force field
Reactive molecular dynamics simulation
ZrO

Access to Document

10.1557/s43580-021-00007-2

Cite this

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title = "Unveiling oxidation mechanism of bulk ZrS2",

abstract = "Transition metal dichalcogenides have shown great potential for next-generation electronic and optoelectronic devices. However, native oxidation remains a major issue in achieving their long-term stability, especially for Zr-containing materials such as ZrS2. Here, we develop a first principles-informed reactive forcefield for Zr/O/S to study oxidation dynamics of ZrS2. Simulation results reveal anisotropic oxidation rates between (210) and (001) surfaces. The oxidation rate is highly dependent on the initial adsorption of oxygen molecules on the surface. Simulation results also provide reaction mechanism for native oxide formation with atomistic details.",

keywords = "Oxidation dynamics, Reactive force field, Reactive molecular dynamics simulation, ZrO",

author = "Liqiu Yang and Tiwari, \{Subodh C.\} and Jo, \{Seong Soon\} and Sungwook Hong and Ankit Mishra and Aravind Krishnamoorthy and Kalia, \{Rajiv K.\} and Aiichiro Nakano and R. Jaramillo and Priya Vashishta",

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doi = "10.1557/s43580-021-00007-2",

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TY - JOUR

T1 - Unveiling oxidation mechanism of bulk ZrS2

AU - Yang, Liqiu

AU - Tiwari, Subodh C.

AU - Jo, Seong Soon

AU - Hong, Sungwook

AU - Mishra, Ankit

AU - Krishnamoorthy, Aravind

AU - Kalia, Rajiv K.

AU - Nakano, Aiichiro

AU - Jaramillo, R.

AU - Vashishta, Priya

PY - 2021/5

Y1 - 2021/5

N2 - Transition metal dichalcogenides have shown great potential for next-generation electronic and optoelectronic devices. However, native oxidation remains a major issue in achieving their long-term stability, especially for Zr-containing materials such as ZrS2. Here, we develop a first principles-informed reactive forcefield for Zr/O/S to study oxidation dynamics of ZrS2. Simulation results reveal anisotropic oxidation rates between (210) and (001) surfaces. The oxidation rate is highly dependent on the initial adsorption of oxygen molecules on the surface. Simulation results also provide reaction mechanism for native oxide formation with atomistic details.

AB - Transition metal dichalcogenides have shown great potential for next-generation electronic and optoelectronic devices. However, native oxidation remains a major issue in achieving their long-term stability, especially for Zr-containing materials such as ZrS2. Here, we develop a first principles-informed reactive forcefield for Zr/O/S to study oxidation dynamics of ZrS2. Simulation results reveal anisotropic oxidation rates between (210) and (001) surfaces. The oxidation rate is highly dependent on the initial adsorption of oxygen molecules on the surface. Simulation results also provide reaction mechanism for native oxide formation with atomistic details.

KW - Oxidation dynamics

KW - Reactive force field

KW - Reactive molecular dynamics simulation

KW - ZrO

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