About the Presentation
In this talk, which was delivered at the
TMS Light Metals Division Awards Ceremony & Special Lecture at TMS2021 Virtual, Easton discussed challenges to the processes of near net shape manufacturing and how some of the themes of this research can travel from one manufacturing technology to the next.
Materials Processing & Manufacturing Division
Presenter:
Co-Author: Tanner Kirk, Texas A&M University
About the Presentation
How big is the available feasible alloy space in high-entropy alloys (HEAs)? That is the question this invited talk from the
Computational Thermodynamics and Kinetics Symposium at TMS2021 Virtual sets out to answer. Applying Additive Manufacturing Itself as a High-throughput Tool to Accelerate Heat Treatment Design of Additively Manufactured Alloys
Politecnico di Milano researchers work on new materials for space engines
These updates are republished press releases and communications from members of the Science|Business Network
The ATLAS project gets underway, its aim being to develop new materials that perform in extreme environmental conditions, enabling important progress in design and construction of space propulsion systems.
ATLAS (Advanced Design of High Entropy Alloys Based Materials for Space Propulsion) is coordinated by the Politecnico di Milano as part of the Horizon 2020-SPACE programme and it has received three million euro in funds. Prof. Mario Guagliano is the project manager.
One of the biggest problems linked to space missions is the need to build systems that will function without failure in extreme environments, at temperatures varying from way below zero to peaks of hundreds of degrees.
News story The Prime Minister has reappointed Professor Brian Cantor CBE and Lopa Patel MBE as Trustees of the Science Museum Group
Professor Cantor CBE and Lopa Patel MBE have been reappointed by the Prime Minister as Trustees of the Science Museum Group for a four year period from 1 December 2020 to 30 November 2024.
From:
1 April 2021
Brian Cantor is Professor of Materials at Oxford and Brunel Universities and an Editor of the journal Progress in Materials Science. He has published over 300 books and papers. He invented the field of High Entropy Alloys and discovered “Cantor alloys”.
In the recent past, he has been Vice-Chancellor of the Universities of Bradford and York, Head of Mathematical and Physical Sciences at Oxford, a research scientist at GE Labs in the USA, a consultant for Alcan, NASA and Rolls-Royce, and Vice-President of the Royal Academy of Engineering. He has worked at other universities such as Sussex, Northeastern, Banaras, Washington State,
Date Time
Professor Brian Cantor CBE and Lopa Patel MBE reappointed as Trustees of Science Museum Group
Brian Cantor is Professor of Materials at Oxford and Brunel Universities and an Editor of the journal Progress in Materials Science. He has published over 300 books and papers. He invented the field of High Entropy Alloys and discovered “Cantor alloys”.
In the recent past, he has been Vice-Chancellor of the Universities of Bradford and York, Head of Mathematical and Physical Sciences at Oxford, a research scientist at GE Labs in the USA, a consultant for Alcan, NASA and Rolls-Royce, and Vice-President of the Royal Academy of Engineering. He has worked at other universities such as Sussex, Northeastern, Banaras, Washington State, IISc Bangalore and the Kobe Institute, and chaired or been on boards such as the Marshall Aid Commission, the UK Universities Pensions Forum, and Bradford, Leeds and York Local Economic Partnerships (LEPs). He founded, chaired and built up the Begb
Defining Pathways for Realizing the Revolutionary Potential of High Entropy Alloys
Scientific exploration in the field of high entropy alloys, known as HEAs, has recently exploded. First reported in about 2004, HEAs were defined originally as a blend of five or more elements with concentrations between 5 to 35 atom percent, and with a strong preference towards single-phase, solid solution metallic alloys. Later, the field branched to include intermetallic and ceramic compounds, alloys with as few as three principle elements, and microstructures with any number and type of phases. Today, researchers face vast combinations of elements with which to work, and they eagerly seek to learn more about HEA compositions, microstructures, promising property combinations, and opportunities for a wide variety of applications in both structural and functional materials. HEA development offers tremendous potential not only for expanding scientific knowledge, but also for creating a broad range of