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oapen-20.500.12657-323212021-11-12T16:22:18Z Chapter 1 Alloy Steel: Properties and Use First-Principles Quantum Mechanical Approach to Stainless Steel Alloys Al-Zoubi, N. Lu, S. Kokko, K. Nurmi, E. Johansson, B. Vitos, L. Ropo, M. Punkkinen, M.P.J. Zhang, H.L. Vitos, L. Zhang, H.L. Lu, S. Al-Zoubi, N. Johansson, B. Nurmi, E. Ropo, M. J. Punkkinen, M. P. Kokko, K. steel stainless steel steel stainless steel Alloy Chromium Crystal structure Cubic crystal system Ferromagnetism Iron Nickel Paramagnetism Surface energy bic Book Industry Communication::P Mathematics & science::PD Science: general issues Accurate description of materials requires the most advanced atomic-scale techniques from both experimental and theoretical areas. In spite of the vast number of available techniques, however, the experimental study of the atomic-scale properties and phenomena even in simple solids is rather difficult. In steels the challenges become more complex due to the interplay between the structural, chemical and magnetic effects. On the other hand, advanced computational methods based on density functional theory ensure a proper platform for studying the fundamental properties of steel materials from first-principles. In 1980’s the first-principles description of the thermodynamic properties of elemental iron was still on the borderline of atomistic simulations. Today the numerous application- oriented activities at the industrial and academic sectors are paired by a rapidly increasing scientific interest. This is reflected by the number of publications on ab initio steel research, which has increased from null to about one thousand within the last two decades. Our research group has a well established position in developing and applying computational codes for steel related applications. Using our ab initio tools, we have presented an insight to the electronic and magnetic structure, and micromechanical properties of austenite and ferrite stainless steel alloys. In the present contribution, we review the most important developments within the ab initio quantum mechanics aided steel design with special emphasis on the role of magnetism on the fundamental properties of alloy steels. 2019-10-04 14:40:07 2020-04-01T14:06:34Z 2016-08-01 23:55 2019-10-04 14:40:07 2020-04-01T14:06:34Z 2016-12-31 23:55:55 2019-10-04 14:40:07 2020-04-01T14:06:34Z 2020-04-01T14:06:34Z 2011 chapter 612638 OCN: 1030819301 http://library.oapen.org/handle/20.500.12657/32321 eng application/pdf n/a 612638.pdf InTechOpen Alloy Steel - Properties and Use 10.5772/26131 10.5772/26131 09f6769d-48ed-467d-b150-4cf2680656a1 2486b1ab-de11-4ac9-a347-0ef0b583469b 7292b17b-f01a-4016-94d3-d7fb5ef9fb79 European Research Council (ERC) 1 228074 FP7 FP7 Ideas: European Research Council FP7-IDEAS-ERC - Specific Programme: "Ideas" Implementing the Seventh Framework Programme of the European Community for Research, Technological Development and Demonstration Activities (2007 to 2013) open access
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Accurate description of materials requires the most advanced atomic-scale techniques from both experimental and theoretical areas. In spite of the vast number of available techniques,
however, the experimental study of the atomic-scale properties and phenomena even in
simple solids is rather difficult. In steels the challenges become more complex due to the
interplay between the structural, chemical and magnetic effects. On the other hand,
advanced computational methods based on density functional theory ensure a proper
platform for studying the fundamental properties of steel materials from first-principles. In
1980’s the first-principles description of the thermodynamic properties of elemental iron
was still on the borderline of atomistic simulations. Today the numerous application-
oriented activities at the industrial and academic sectors are paired by a rapidly increasing
scientific interest. This is reflected by the number of publications on ab initio steel research,
which has increased from null to about one thousand within the last two decades. Our
research group has a well established position in developing and applying computational
codes for steel related applications. Using our ab initio tools, we have presented an insight to
the electronic and magnetic structure, and micromechanical properties of austenite and
ferrite stainless steel alloys. In the present contribution, we review the most important
developments within the ab initio quantum mechanics aided steel design with special emphasis
on the role of magnetism on the fundamental properties of alloy steels.
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