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Papers
61,005 resultsShowing papers similar to Stability of retained austenite in high carbon steel under compressive stress: an investigation from macro to nano scale
ClearExploring the effect of complex hierarchic microstructure of quenched and partitioned martensitic stainless steels on their high cycle fatigue behaviour
Not relevant to microplastics — this paper investigates high cycle fatigue behavior of quenched-and-partitioned martensitic stainless steels, exploring how their complex retained-austenite microstructure affects fatigue fracture performance.
Dynamic Processes of Substructural Rearrangement under Friction of Carbon Steel
This study examined how heat treatment affects the friction and wear properties of medium carbon steel, linking material microstructure to tribological performance. The research is focused on materials engineering with limited direct relevance to microplastic pollution or human health.
Exploring the effect of complex hierarchic microstructure of quenched and partitioned martensitic stainless steels on their high cycle fatigue behaviour
This study examined the fatigue behavior of quenched and partitioned martensitic stainless steels, finding that their complex microstructure affects how they fail under cyclic loading. This is a materials science paper with no direct relevance 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.
Exploring the effect of complex hierarchic microstructure of quenched and partitioned martensitic stainless steels on their high cycle fatigue behaviour
This materials science study examined the fatigue behavior of quenched and partitioned martensitic stainless steels, finding improved strength-ductility balance. This is a metallurgy paper with no direct relevance to microplastics or environmental health.
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.
Adjusting the very high cycle fatigue properties of a metastable austenitic stainless steel by means of the martensite content
This metallurgy study examined how pre-deforming stainless steel to introduce martensite phase changes its fatigue properties under very high cycle loading. This is a materials engineering study on metal alloys with no relevance to environmental microplastics.
Influence of hard phase size and spacing on the fatigue crack propagation in tool steels—Numerical simulation and experimental validation
Not relevant to microplastics research; this paper investigates how carbide size and spacing in tool steel microstructures affects fatigue crack growth rate, with no connection to plastic pollution.
Mechanical response of stainless steel subjected to biaxial load path changes: Cruciform experiments and multi-scale modeling
This materials science study used multi-scale modeling to predict how stainless steel deforms under complex multi-directional loading. The research is not related to microplastics or environmental health.
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.
Cleavage fracture micromechanisms in thick-section quenched and tempered S690 high-strength steels
Researchers studied how thick, high-strength steel plates crack at the microscale under extreme cold, finding that clusters of niobium-rich inclusions were the key weak points triggering fracture. This materials science research has no direct connection to microplastics but informs structural safety in industrial applications involving heavy steel components.
Material Response to Rolling Contact Loading
This materials science study investigates how rolling contact in ball bearings causes microplastic deformation in steel, leading to crystallographic texture changes, residual stresses, and eventual fatigue failure. The term 'microplastic' in this paper refers to small-scale plastic deformation in metals and has no connection to environmental plastic pollution.
Influence of the pearlite fineness on the mechanical properties, deformation behavior, and fracture characteristics of carbon steel
This metallurgy study compared deformation and fracture behavior of carbon steel with coarse versus fine microstructure, finding that finer pearlite deforms more uniformly while coarser pearlite shows structural discontinuities. This is a materials science study with no relevance to environmental microplastics.
Effect of Cyclic Ice Plug Deformation on Microstructure and Mechanical Behaviors of Nuclear-Grade Low-Carbon Tubular Steel
Not relevant to microplastics — this is a metallurgy study examining how cyclic freeze-thaw ice plugging affects the dislocation microstructure and mechanical properties of nuclear-grade steel pipeline material.
Investigation of Fatigue Damage of Tempered Martensitic Steel during High Cycle Fatigue and Very High Cycle Fatigue Loading Using In Situ Monitoring by Scanning Electron Microscope and High‐Resolution Thermography
This study examined how fatigue damage develops in martensitic steel under high-cycle loading, finding that heat treatment conditions affect the material's failure mechanisms. The research is focused on materials engineering and has limited direct relevance to microplastic pollution.
Toward a New Interpretation of the Mechanical Behaviour of As-quenched Low Alloyed Martensitic Steels
This materials science study revisits the mechanical behavior of as-quenched low-alloy martensitic steels, developing a model to explain their high strain-hardening and Bauschinger effect based on a composite view of the microstructure. This metallurgy research has no connection to microplastics or environmental health.
The quantitative relationship between non-linear stress-strain behaviour and dislocation structure in martensitic stainless steel
Researchers showed that martensitic stainless steel behaves in a more complex, non-linear way at low stresses than previously assumed, and developed a refined model to quantify tiny reversible deformations caused by dislocation movement, with implications for precision industrial applications where small strains matter.
High resolution digital image correlation mapping of strain localization upon room and high temperature, high cycle fatigue of a TiAl intermetallic alloy
This is a materials science study using high-resolution digital image correlation to map how strain localizes during the plastic deformation of metals. It is not related to environmental microplastics.
Atomistic mechanisms of cyclic hardening in metallic glass
This materials science paper investigated atomic-level mechanisms by which metallic glass strengthens under cyclic mechanical loading, using computer simulations to study how structural changes accumulate. This is a condensed matter physics study with no relevance to environmental microplastics.
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.
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.