Reactor Pressure Vessel Steel Smart Behavior as Cause of Instability in Kinetics of Radiation Embrittlement

International journal of nanotechnology and nanomedicine Pub Date : 2019-10-03 DOI:10.33140/ijnn.04.02.04

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Abstract

Fast neutron intensity influence on reactor materials radiation damage is a critically important question in the problem of the correct use of the accelerated irradiation tests data for substantiation of the materials workability in real irradiation conditions that is low neutron intensity. Investigations of the fast neutron intensity (flux) influence on radiation damage and experimental data scattering reveal the existence of non-monotonous sections in kinetics of the reactor pressure vessels (RPV) steel damage. Discovery of the oscillations as indicator of the self-organization processes presence give reasons for new ways searching on reactor pressure vessel (RPV) steel radiation stability increasing and attempt of the self-restoring metal elaboration. Revealing of the wavelike process in the form of non monotonous parts of the kinetics of radiation embrittlement testifies that periodic transformation of the structure take place. This fact actualizes the problem of more precise definition of the RPV materials radiation embrittlement mechanisms and gives reasons for search of the ways to manage the radiation stability (nanostructuring and so on to stimulate the radiation defects annihilation), development of the means for creating of more stableness self recovering smart materials.

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反应堆压力容器钢的智能行为是辐射脆化动力学不稳定的原因

快中子强度对反应堆材料辐射损伤的影响是如何正确利用加速辐照试验数据来证实材料在低中子强度实际辐照条件下的可加工性的关键问题。快中子强度(通量)对辐射损伤和实验数据散射影响的研究揭示了反应堆压力容器(RPV)钢损伤动力学中存在非单调截面。振荡作为自组织过程的标志的发现，为探索反应堆压力容器(RPV)钢辐射稳定性提高的新途径和尝试金属自恢复加工提供了理由。以非单调部分的辐射脆化动力学形式揭示的波状过程证明了结构发生了周期性转变。这一事实实现了对RPV材料辐射脆化机理的更精确定义的问题，并为探索管理辐射稳定性的方法(纳米结构等刺激辐射缺陷湮灭)，开发更稳定的自恢复智能材料的手段提供了理由。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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International journal of nanotechnology and nanomedicine

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