文章信息/Info

Title:

Progress in Computational Simulation of Irradiation Damage in Refractory High-Entropy Alloys for Nulcear Applications

文章編號:

1674-3962(2025)01-0074-10

作者:

李靖; 張晨; 徐西強(qiáng); 魏崢; hehu Adam Ibrahim; 張平; 蘇鉦雄; 施坦; 盧晨陽

西安交通大學(xué)核科學(xué)與技術(shù)學(xué)院,西安710049

Author(s):

LI Jing;  ZHANG Chen;  XU Xiqiang;  WEI Zheng;  ZHANG Yizhuo;  SHEHU Adam Ibrahim;  ZHANG Ping;  SU Zhengxiong;  SHI Tan;  LU Chenyang

Department of Nuclear Science and Technology, Xi’an Jiaotong University, Xi’an 710049, China

關(guān)鍵詞:

難熔高熵合金; 輻照損傷; 缺陷行為; 第一性原理計(jì)算; 分子動(dòng)力學(xué)

Keywords:

refractory high-entropy alloy;  irradiation damage;  defect behavior;  first�瞤rinciples calculations;  molecular dynamics

分類號:

TL341;TG139

DOI:

10.7502/j.issn.1674-3962.202410024

文獻(xiàn)標(biāo)志碼:

A

摘要:

核能具有高能量密度、零碳排放、可持續(xù)性強(qiáng)以及穩(wěn)定供電等優(yōu)點(diǎn)，受到了世界各國的廣泛關(guān)注。然而，關(guān)鍵堆芯材料長時(shí)間暴露在高溫、高劑量的中子輻照環(huán)境下，不可避免地產(chǎn)生各種類型的輻照損傷缺陷，對材料的力學(xué)性能及服役壽命提出了嚴(yán)峻的挑戰(zhàn)。難熔高熵合金具有較高的熔點(diǎn)、良好的高溫力學(xué)性能以及抗輻照性能，在先進(jìn)高溫核反應(yīng)堆結(jié)構(gòu)材料方面具有很大的應(yīng)用潛力。由于難熔高熵合金的多樣性與合金中主元的復(fù)雜性，合金中輻照缺陷的基本熱力學(xué)與動(dòng)力學(xué)性質(zhì)為目前研究的主要方向，對理解合金抗輻照損傷機(jī)理至關(guān)重要。目前的研究主要采用第一性原理和分子動(dòng)力學(xué)等原子尺度模擬計(jì)算方法，隨著研究的深入，在更高空間尺度和更長時(shí)間尺度的輻照損傷演化計(jì)算研究方面也取得了初步進(jìn)展。圍繞近年來核用難熔高熵合金點(diǎn)缺陷與缺陷團(tuán)簇能量性質(zhì)、輻照缺陷的產(chǎn)生與分布、輻照缺陷的擴(kuò)散與演化3個(gè)方面的模擬計(jì)算研究進(jìn)展進(jìn)行了總結(jié)，并在此基礎(chǔ)上對核用難熔高熵合金的下一步輻照損傷模擬研究作出展望。

Abstract:

Nuclear energy, with the advantages of high energy density, zero carbon emission, high sustainability and stable power supply, has received extensive attention from countries around the world. However, the key structural materials are exposed to long-term high-temperature and high neutron dose environment, which inevitably produces various types of irradiation damage defects, posing serious challenges to the mechanical properties and service life of the materials. Refractory high�瞖ntropy alloys, with high melting points, good high-temperature mechanical properties and improved irradiation resistance properties, have good potential for applications in the structural materials of advanced high-temperature nuclear reactors. Due to the diversity of the refractory high-entropy alloys and the complexity of the principal elements in the alloys, the basic thermodynamic and kinetic properties of irradiation defects are the main directions of the current simulation research, which is crucial to the understanding of the irradiation damage resistance mechanisms. The main simulation research methods include atomic simulation methods such as first-principles calculations and molecular dynamics simulations. In recent years, with the deepening of the research, the study of irradiation damage evolution at higher spatial scales and longer time scales has also made progress. In this paper, we summarize the research progress on the energy properties of point defects and defect clusters, the generation and distribution of irradiation defects, and the diffusion and evolution of irradiation defects in refractory high-entropy alloys studied for nuclear applications. Based on the current research progress, we discuss future research directions for the computational simulation of irradiation damage in refractory high-entropy alloys.