A New Method of Metallic Alloys Producing with Interphases, which are Formed Coherent Coupling of Compounds’ Atoms

V.A. Mikheev; G.P. Doroshko

doi:10.4028/www.scientific.net/KEM.684.359

Paper Titles

Metal-Polymer-Metal Laminates for Lightweight Application
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Study of Stress Relaxation for 5056 Alloy in Vacuum Conditions
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Research of the Microstructure and Mechanical Properties of Copper and CuZn36 Developing during Deformation into the Equal Channel Speed Matrix with High-Intensity Cooling
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SHS Metallurgy of NiAl-Based Alloy
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A New Method of Metallic Alloys Producing with Interphases, which are Formed Coherent Coupling of Compounds’ Atoms
p.359

Effect of Strain on the Anisotropy Coefficient of Sheet Alloys AA2024, Ti-2Al-1Mn, Titanium Grade 2, STEEL X10CrNiTi18-9
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Fabrication of Aluminum-Ceramic Composites with TiC-Ni Skeleton by SHS Pressing Method
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Study of Possibility of Obtaining Nanopowder Composition of "Aluminum Nitride – Boron Nitride" by Azide SHS Technology
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Characterization Analytic Method Specifying the Steel X10CRNITI18-10 Cylinder Surface Layer Quality Hardened by a Traveling Sphere
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HomeKey Engineering MaterialsKey Engineering Materials Vol. 684A New Method of Metallic Alloys Producing with...

A New Method of Metallic Alloys Producing with Interphases, which are Formed Coherent Coupling of Compounds’ Atoms

Abstract:

A new method of producing metallic alloys with interfacial boundaries formed by the coherent superposition of atoms is based on the internal temperatures of the chemical combination in which substances form a single material. It is based on the theory of thermal analysis through the formation of the Association of the two alternative methods of DTA+IDS studies of the properties of the material.

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Periodical:

Key Engineering Materials (Volume 684)

Pages:

359-365

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.684.359

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Online since:

February 2016

Authors:

V.A. Mikheev*, G.P. Doroshko

Keywords:

Coherent Coupling of the Compounds’ Boundary Atoms, Coherently Cluster Nanocomposite Material, Interphases, Monomolecular Layer, Nanofilm Structure, Physical-Chemical Phenomena, Point Defects, Structurally-Cluster Compound Organization

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