2013 Physical Metallurgy GRC; University of New England; Biddeford, Maine; July 28 -August 2, 2013

2013 物理冶金GRC；

• 批准号: 1249334
• 负责人: Michael Mills
• 金额: $ 1万
• 依托单位: Gordon Research Conferences
• 依托单位国家: 美国
• 项目类别: Standard Grant
• 财政年份: 2012
• 资助国家: 美国
• 起止时间: 2012-09-01 至 2013-08-31
• 项目状态: 已结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=1249334&HistoricalAwards=false
• 关键词: 2013; Physical; Metallurgy; GRC; University

TECHNICAL SUMMARY:Technological development is paced by the creation and putting into service of materials that are ever-more capable of withstanding extreme conditions, such as high stress, temperature, radiation and long-term service. This Gordon Research Conference on Physical Metallurgy provides a forum for the presentation of cutting-edge experimental and modeling research on materials at extremes, such materials with ultra-high strengths relative to their ideal strengths and materials that can operate at high temperatures relative to their melting points. Understanding the effects of extremes in the physical size-scale and microstructure is critical to advancing the performance of materials under demanding conditions. Presentations will describe developments in state-of-the-art experimental techniques for evaluating material behavior and microstructure, and complementary computational and modeling efforts aimed at fundamental understanding of materials under these extreme conditions.NON-TECHNICAL SUMMARY:Technological development is paced by the creation and putting into service of materials that are ever-more capable of withstanding extreme conditions, such as high stress, temperature, radiation and long-term service. This Gordon Research Conference on Physical Metallurgy provides a forum for the presentation of cutting-edge experimental and modeling research on materials at extremes, such materials with ultra-high strengths relative to their ideal strengths and materials that can operate at high temperatures relative to their melting points. Understanding the effects of extremes in the physical size-scale and microstructure is critical to advancing the performance of materials under demanding conditions. Presentations will describe developments in state-of-the-art experimental techniques for evaluating material behavior and microstructure, and complementary computational and modeling efforts aimed at fundamental understanding of materials under these extreme conditions.

技术摘要：技术发展的步伐取决于材料的创造和投入使用，这些材料越来越能够承受极端条件，例如高应力、温度、辐射和长期使用。本次戈登物理冶金研究会议为展示极端材料的尖端实验和建模研究提供了一个论坛，这些极端材料具有相对于其理想强度的超高强度，以及可以在相对于其熔点的高温下工作的材料。了解物理尺寸和微观结构的极端影响对于提高材料在苛刻条件下的性能至关重要。演讲将描述用于评估材料行为和微观结构的最先进实验技术的发展，以及旨在从根本上了解这些极端条件下材料的补充计算和建模工作。非技术摘要：技术发展的步伐是通过创造和投入更能够承受极端条件（如高应力、温度、辐射和长期使用）的材料来实现的。本次戈登物理冶金研究会议为展示极端材料的尖端实验和建模研究提供了一个论坛，这些极端材料具有相对于其理想强度的超高强度，以及可以在相对于其熔点的高温下工作的材料。了解物理尺寸和微观结构的极端影响对于提高材料在苛刻条件下的性能至关重要。演讲将描述用于评估材料行为和微观结构的最先进实验技术的发展，以及旨在基本了解这些极端条件下材料的补充计算和建模工作。