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Papers
20 resultsShowing papers similar to Temperature Dependence of the Deformation Behavior of High-Entropy Alloys Co20Cr20Fe20Mn20Ni20, Co19Cr20Fe20Mn20Ni20С1, and Co17Cr20Fe20Mn20Ni20С3. Mechanical Properties and Temperature Dependence of Yield Stress
ClearTemperature Dependence of the Deformation Behavior of High-entropy Alloys Co20cr20fe20mn20ni20, Co19cr20fe20mn20ni20с1 and Co17cr20fe20mn20ni20с3. Mechanical Properties and Temperature Dependence of Yield Strength
This study examined how temperature affects the deformation behavior of high-entropy metal alloys, finding that adding carbon significantly changed mechanical properties across a wide temperature range — not related to microplastics.
Temperature Dependence of Mechanical Properties and Plastic Flow Behavior of Cast Multicomponent Alloys Fe20Cr20Mn20Ni20Co20-xCx (x = 0, 1, 3, 5)
This materials science paper examines how carbon additions affect the mechanical properties and deformation behavior of high-entropy metal alloys at temperatures ranging from near absolute zero to room temperature. The paper addresses metallic plasticity at a microscale level and is unrelated to environmental microplastic pollution.
A bcc refractory high-entropy alloy: the ideal case of smooth plastic flow
This materials science paper characterizes smooth plastic flow in a body-centered cubic refractory high-entropy alloy, examining dislocation dynamics and deformation mechanisms; it is not directly related to microplastic environmental research.
Effects of Adiabatic Heating and Strain Rate on the Dynamic Response of a CoCrFeMnNi High-Entropy Alloy
This materials science study analyzed how a high-entropy metal alloy responds to high-speed compression, including heat buildup at different strain rates. The research is not directly related to microplastics or human health.
From Micro‐ to Macroplasticity
This materials science perspective discusses the transition from microplastic deformation (below the yield stress) to macroplastic deformation in nanocrystalline metals, noting that the traditional 0.2% yield stress definition does not accurately capture when bulk plastic flow begins. This is a materials physics study on metal deformation behavior with no relevance to environmental microplastics.
Mechanical Spectroscopy Study of CrNiCoFeMn High-Entropy Alloys
This study characterized the mechanical properties of a high-entropy alloy manufactured by both conventional induction melting and selective laser melting (3D printing). The research is focused on advanced materials engineering with limited direct relevance to microplastic pollution.
Microstructural signatures of dislocation avalanches in a high-entropy alloy
This materials physics study traced how individual atomic slip events (dislocation avalanches) produce visible slip lines in a high-entropy alloy under stress. The term 'microplastic events' here refers to a materials science concept about small-scale deformation, not environmental plastic particles.
Dislocation Arrangements and Cyclic Microplasticity Surrounding Stress Concentration in a Ni‐Based Single‐Crystal Superalloy
Not relevant to microplastics — this materials science study examines dislocation behavior and fatigue crack initiation in nickel-based single-crystal superalloys; 'microplasticity' here refers to microscale metal deformation, not plastic particles.
Rate-Controlling Microplastic Processes during Plastic Flow in FCC Metals: Origin of the Variation of Strain Rate Sensitivity in Aluminum from 78 to 300 K
This materials science study examines the temperature dependence of deformation mechanisms in aluminum, specifically how strain rate sensitivity changes from cryogenic to room temperature — not related to microplastics or environmental health.
Variety of scaling behaviors in nanocrystalline plasticity
This is a materials science study examining the variety of scaling behaviors observed in nanocrystalline plasticity, exploring how grain size affects deformation mechanisms in metals. It is not related to environmental microplastics.
Micromechanical aspects of the effect of temperature and local plastic strain magnitude on the fracture toughness of ferrite steels
This materials science study examined how temperature and plastic strain affect the fracture toughness of ferrite steels at the microscopic scale. The term 'microplastic' here refers to microscopic plastic deformation in metal — this is an engineering study unrelated to plastic particle pollution.
Severe Plastic Deformation of Amorphous Alloys
This materials science paper examines how high-pressure torsion affects the structure and properties of metallic glass alloys. The research is not related to microplastics or environmental health.
Transformation Kinetics, Microplasticity and Aging of Martensite in FE-31 Ni.
This materials science study examines microplastic behavior in iron-nickel martensite alloys, finding that stress-induced phase transformation produces unusually large microplastic strains. The term 'microplasticity' refers to small-scale plastic deformation in metals and is not related to environmental plastic pollution.
Hot Deformation Behavior and Processing Maps of a New Ti-6Al-2Nb-2Zr-0.4B Titanium Alloy
This materials science study characterized the high-temperature deformation behavior of a new titanium alloy used in aerospace and industrial applications. It has no direct relevance to microplastic or environmental health research.
Preparation and High‐Temperature Microplastic Forming Performance of Nano‐FeCoNi Medium‐Entropy Alloy Foils
Researchers fabricated nanocrystalline FeCoNi medium-entropy alloy foils using alternating current pulse electrodeposition and characterized their microstructure, crystallographic properties, and mechanical performance. A 45 µm foil was produced and subjected to high-temperature microbulging tests, demonstrating its potential for precision microforming applications at elevated temperatures.
Crystal Plasticity Simulation of Yield Loci Evolution of SUS304 Foil
Researchers used crystal plasticity simulation to study how grain orientation and size affect the deformation of stainless steel foils used in microforming processes. This is a materials engineering study with no direct connection to microplastic contamination.
Quantification of dislocation structures from anelastic deformation behaviour
This materials science study analyzes the pre-yield deformation behavior of iron and low-alloy steel, modeling how dislocations move reversibly before permanent plastic deformation begins. The research is relevant to structural materials engineering but has no connection to microplastics or environmental health.
Fluctuations in crystalline plasticity
This theoretical physics paper reviews the statistical patterns of intermittent plastic deformation events—called dislocation avalanches—in crystalline metals at the micro- and nanoscale. The term 'microplastic' here refers to a materials science concept about deformation behavior, not environmental plastic particles.
Viscosity and transport in a model fragile metallic glass
This paper uses the term 'microplasticity' in the context of metallic glass physics, describing how thermally activated atomic movements drive deformation in amorphous metals at the microscale. This is a materials physics paper unrelated to environmental microplastic pollution.
Electron microscope investigation of the microplastic deformation mechanisms of silicon by indentation
This materials science paper uses electron microscopy to study dislocation structures and phase transformations in silicon crystals under indentation at various temperatures. The term 'microplastic deformation' refers to small-scale plastic deformation in crystalline silicon and is entirely unrelated to environmental plastic pollution.