Application of athermal recombination corrected DPA model in nuclear data processing code NECP-atlas

Wen Yin; Tiejun Zu; Liangzhi Cao

doi:10.1051/epjconf/202124709021

Application of athermal recombination corrected DPA model in nuclear data processing code NECP-atlas

Wen Yin
, Tiejun Zu
, Liangzhi Cao

School of Energy and Power Engineering

Xi'an Jiaotong University

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

Abstract

The Displacement per Atom (DPA) is an important factor used to quantify the irradiation damage of materials. The radiation damage energy production cross section obtained by nuclear data processing code is an essential nuclear data used to calculate the DPA of materials. Nuclear data processing code, such as NJOY, adopts NRT-DPA model to calculate the radiation damage energy production cross section. However, the NRT-DPA model has several well-known limitation. Especially, the number of radiation defects produced in energetic cascades in metals is only ~1/3 the NRT-DPA model prediction. To improve the precision accuracy of DPA calculation, the state-of-the-art Athermal Recombination Corrected DPA (ARC-DPA) model is adopted in heat production and radiation damage energy production cross section module of nuclear data processing code NECP-Atlas. ARC-DPA model can be obtained by simply multiplying with the new efficiency function. The parameters in the new efficiency function are material constants that can be determined for a given material from Molecular Dynamics (MD) simulations or experiments. The material constants of some materials are obtained by MD simulations firstly in this paper. Numerical results show that the radiation damage cross section produced by nuclear data processing code NECP-Atlas adopting NRT-DPA model can agree well with the NJOY code. What's more, the results from NECP-Atlas adopting ARC-DPA model can provide more physically realistic descriptions of primary defect and agree well with the results from MD simulation numerically.

Original language	English
Title of host publication	International Conference on Physics of Reactors
Subtitle of host publication	Transition to a Scalable Nuclear Future, PHYSOR 2020
Editors	Marat Margulis, Partrick Blaise
Publisher	EDP Sciences - Web of Conferences
Pages	1881-1888
Number of pages	8
ISBN (Electronic)	9781713827245
DOIs	https://doi.org/10.1051/epjconf/202124709021
State	Published - 2020
Event	2020 International Conference on Physics of Reactors: Transition to a Scalable Nuclear Future, PHYSOR 2020 - Cambridge, United Kingdom Duration: 28 Mar 2020 → 2 Apr 2020

Publication series

Name	International Conference on Physics of Reactors: Transition to a Scalable Nuclear Future, PHYSOR 2020
Volume	2020-March

Conference

Conference	2020 International Conference on Physics of Reactors: Transition to a Scalable Nuclear Future, PHYSOR 2020
Country/Territory	United Kingdom
City	Cambridge
Period	28/03/20 → 2/04/20

Keywords

ARC-DPA model
DPA
Molecular dynamics simulation
NECP-Atlas
Radiation damage energy production cross section

Access to Document

10.1051/epjconf/202124709021

Cite this

Yin, W., Zu, T., & Cao, L. (2020). Application of athermal recombination corrected DPA model in nuclear data processing code NECP-atlas. In M. Margulis, & P. Blaise (Eds.), International Conference on Physics of Reactors: Transition to a Scalable Nuclear Future, PHYSOR 2020 (pp. 1881-1888). (International Conference on Physics of Reactors: Transition to a Scalable Nuclear Future, PHYSOR 2020; Vol. 2020-March). EDP Sciences - Web of Conferences. https://doi.org/10.1051/epjconf/202124709021

Yin, Wen ; Zu, Tiejun ; Cao, Liangzhi. / Application of athermal recombination corrected DPA model in nuclear data processing code NECP-atlas. International Conference on Physics of Reactors: Transition to a Scalable Nuclear Future, PHYSOR 2020. editor / Marat Margulis ; Partrick Blaise. EDP Sciences - Web of Conferences, 2020. pp. 1881-1888 (International Conference on Physics of Reactors: Transition to a Scalable Nuclear Future, PHYSOR 2020).

@inproceedings{92b341659ffe4f9bafaf5d032218460c,

title = "Application of athermal recombination corrected DPA model in nuclear data processing code NECP-atlas",

abstract = "The Displacement per Atom (DPA) is an important factor used to quantify the irradiation damage of materials. The radiation damage energy production cross section obtained by nuclear data processing code is an essential nuclear data used to calculate the DPA of materials. Nuclear data processing code, such as NJOY, adopts NRT-DPA model to calculate the radiation damage energy production cross section. However, the NRT-DPA model has several well-known limitation. Especially, the number of radiation defects produced in energetic cascades in metals is only \textasciitilde{}1/3 the NRT-DPA model prediction. To improve the precision accuracy of DPA calculation, the state-of-the-art Athermal Recombination Corrected DPA (ARC-DPA) model is adopted in heat production and radiation damage energy production cross section module of nuclear data processing code NECP-Atlas. ARC-DPA model can be obtained by simply multiplying with the new efficiency function. The parameters in the new efficiency function are material constants that can be determined for a given material from Molecular Dynamics (MD) simulations or experiments. The material constants of some materials are obtained by MD simulations firstly in this paper. Numerical results show that the radiation damage cross section produced by nuclear data processing code NECP-Atlas adopting NRT-DPA model can agree well with the NJOY code. What's more, the results from NECP-Atlas adopting ARC-DPA model can provide more physically realistic descriptions of primary defect and agree well with the results from MD simulation numerically.",

keywords = "ARC-DPA model, DPA, Molecular dynamics simulation, NECP-Atlas, Radiation damage energy production cross section",

author = "Wen Yin and Tiejun Zu and Liangzhi Cao",

note = "Publisher Copyright: {\textcopyright} The Authors, published by EDP Sciences. This is an open access article distributed under the terms of the Creative Commons Attribution License 4.0 (http://creativecommons.org/licenses/by/4.0/).; 2020 International Conference on Physics of Reactors: Transition to a Scalable Nuclear Future, PHYSOR 2020 ; Conference date: 28-03-2020 Through 02-04-2020",

year = "2020",

doi = "10.1051/epjconf/202124709021",

language = "英语",

series = "International Conference on Physics of Reactors: Transition to a Scalable Nuclear Future, PHYSOR 2020",

publisher = "EDP Sciences - Web of Conferences",

pages = "1881--1888",

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Yin, W, Zu, T & Cao, L 2020, Application of athermal recombination corrected DPA model in nuclear data processing code NECP-atlas. in M Margulis & P Blaise (eds), International Conference on Physics of Reactors: Transition to a Scalable Nuclear Future, PHYSOR 2020. International Conference on Physics of Reactors: Transition to a Scalable Nuclear Future, PHYSOR 2020, vol. 2020-March, EDP Sciences - Web of Conferences, pp. 1881-1888, 2020 International Conference on Physics of Reactors: Transition to a Scalable Nuclear Future, PHYSOR 2020, Cambridge, United Kingdom, 28/03/20. https://doi.org/10.1051/epjconf/202124709021

Application of athermal recombination corrected DPA model in nuclear data processing code NECP-atlas. / Yin, Wen; Zu, Tiejun; Cao, Liangzhi.
International Conference on Physics of Reactors: Transition to a Scalable Nuclear Future, PHYSOR 2020. ed. / Marat Margulis; Partrick Blaise. EDP Sciences - Web of Conferences, 2020. p. 1881-1888 (International Conference on Physics of Reactors: Transition to a Scalable Nuclear Future, PHYSOR 2020; Vol. 2020-March).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

TY - GEN

T1 - Application of athermal recombination corrected DPA model in nuclear data processing code NECP-atlas

AU - Yin, Wen

AU - Zu, Tiejun

AU - Cao, Liangzhi

N1 - Publisher Copyright: © The Authors, published by EDP Sciences. This is an open access article distributed under the terms of the Creative Commons Attribution License 4.0 (http://creativecommons.org/licenses/by/4.0/).

PY - 2020

Y1 - 2020

N2 - The Displacement per Atom (DPA) is an important factor used to quantify the irradiation damage of materials. The radiation damage energy production cross section obtained by nuclear data processing code is an essential nuclear data used to calculate the DPA of materials. Nuclear data processing code, such as NJOY, adopts NRT-DPA model to calculate the radiation damage energy production cross section. However, the NRT-DPA model has several well-known limitation. Especially, the number of radiation defects produced in energetic cascades in metals is only ~1/3 the NRT-DPA model prediction. To improve the precision accuracy of DPA calculation, the state-of-the-art Athermal Recombination Corrected DPA (ARC-DPA) model is adopted in heat production and radiation damage energy production cross section module of nuclear data processing code NECP-Atlas. ARC-DPA model can be obtained by simply multiplying with the new efficiency function. The parameters in the new efficiency function are material constants that can be determined for a given material from Molecular Dynamics (MD) simulations or experiments. The material constants of some materials are obtained by MD simulations firstly in this paper. Numerical results show that the radiation damage cross section produced by nuclear data processing code NECP-Atlas adopting NRT-DPA model can agree well with the NJOY code. What's more, the results from NECP-Atlas adopting ARC-DPA model can provide more physically realistic descriptions of primary defect and agree well with the results from MD simulation numerically.

AB - The Displacement per Atom (DPA) is an important factor used to quantify the irradiation damage of materials. The radiation damage energy production cross section obtained by nuclear data processing code is an essential nuclear data used to calculate the DPA of materials. Nuclear data processing code, such as NJOY, adopts NRT-DPA model to calculate the radiation damage energy production cross section. However, the NRT-DPA model has several well-known limitation. Especially, the number of radiation defects produced in energetic cascades in metals is only ~1/3 the NRT-DPA model prediction. To improve the precision accuracy of DPA calculation, the state-of-the-art Athermal Recombination Corrected DPA (ARC-DPA) model is adopted in heat production and radiation damage energy production cross section module of nuclear data processing code NECP-Atlas. ARC-DPA model can be obtained by simply multiplying with the new efficiency function. The parameters in the new efficiency function are material constants that can be determined for a given material from Molecular Dynamics (MD) simulations or experiments. The material constants of some materials are obtained by MD simulations firstly in this paper. Numerical results show that the radiation damage cross section produced by nuclear data processing code NECP-Atlas adopting NRT-DPA model can agree well with the NJOY code. What's more, the results from NECP-Atlas adopting ARC-DPA model can provide more physically realistic descriptions of primary defect and agree well with the results from MD simulation numerically.

KW - ARC-DPA model

KW - DPA

KW - Molecular dynamics simulation

KW - NECP-Atlas

KW - Radiation damage energy production cross section

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DO - 10.1051/epjconf/202124709021

M3 - 会议稿件

AN - SCOPUS:85108418559

T3 - International Conference on Physics of Reactors: Transition to a Scalable Nuclear Future, PHYSOR 2020

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BT - International Conference on Physics of Reactors

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ER -

Yin W, Zu T, Cao L. Application of athermal recombination corrected DPA model in nuclear data processing code NECP-atlas. In Margulis M, Blaise P, editors, International Conference on Physics of Reactors: Transition to a Scalable Nuclear Future, PHYSOR 2020. EDP Sciences - Web of Conferences. 2020. p. 1881-1888. (International Conference on Physics of Reactors: Transition to a Scalable Nuclear Future, PHYSOR 2020). doi: 10.1051/epjconf/202124709021

Application of athermal recombination corrected DPA model in nuclear data processing code NECP-atlas

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