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Papers
61,005 resultsShowing papers similar to Damping behavior of 316L lattice structures produced by Selective Laser Melting
ClearResearch on Residual Stresses and Microstructures of Selective Laser Melted Ti6Al4V Treated by Thermal Vibration Stress Relief
Researchers evaluated thermal-vibration stress relief treatment on titanium alloy parts made by selective laser melting, finding it effectively reduced residual stresses while influencing microstructure — offering a practical method for improving additive manufactured metal components.
Design, Fabrication, and Properties of High Damping Metal Matrix Composites—A Review
This review covers the design and properties of metal matrix composites engineered for high vibration damping capacity, examining how to balance damping ability with mechanical strength. This materials engineering study has no connection to microplastics or environmental health.
Low Amplitude Nonlinear Damping and Effective Modulus in Magnesium Alloys Containing Long-Period Stacking Ordered Structures
Despite its title referencing "microplasticity" (a materials science term for microscale deformation in metals), this paper studies the mechanical damping properties of magnesium alloys — not microplastic pollution. It examines elastic modulus and vibration damping in metal alloys at low temperatures, and is entirely unrelated to microplastics or environmental health.
Effect of Laser Shock Peening on the Microstructure and Properties of the Inconel 625 Surface Layer
Researchers investigated how laser shock peening affects the microstructure and mechanical properties of a high-performance nickel alloy. While unrelated to microplastics directly, understanding metal alloy behavior under stress is relevant to designing durable infrastructure that resists the mechanical wear that generates metal and polymer particles.
Incorporation of Defects in Finite Elements to Model Effective Mechanical Properties of Metamaterial Cells Printed by Selective Laser Melting
This study developed finite element modeling approaches that incorporate manufacturing defects into mechanical metamaterial structures produced by additive manufacturing, enabling more accurate prediction of their effective mechanical properties. The method accounts for the inherent variability introduced by 3D printing processes that otherwise causes discrepancies between idealized models and real printed structures.
Temperature damping capacity and microstructure evolution of Mg–Al–Zn–Sn alloy
Not relevant to microplastics — this paper studies the temperature-dependent vibration-dampening properties of magnesium-aluminum-zinc-tin metal alloys for engineering applications.
Enhancement of the Microstructure and Fatigue Crack Growth Performance of Additive Manufactured Titanium Alloy Parts by Laser-Assisted Ultrasonic Vibration Processing
This paper is not about microplastics. It studied how laser-assisted ultrasonic surface treatment improves the fatigue crack resistance and microstructure of 3D-printed titanium alloy parts. The term 'plastic deformation' here refers to metal deformation processes, not plastic pollution.
Variation of the Vibrational Treatment on Mechanical Properties and Weld Residual Stress
This materials engineering paper examines vibrational treatment as a cost-effective alternative to heat treatment for relieving welding residual stresses in metal structures. The study is unrelated to microplastic pollution research.
Sol–Gel Silica Coatings for Corrosion Protection of Aluminum Parts Manufactured by Selective Laser Melting (SLM) Technology
Not relevant to microplastics — this paper investigates sol-gel silica coatings as a corrosion protection strategy for aluminium parts produced by selective laser melting (3D printing), with no microplastic content.
The Microstructure and Properties of Laser Shock Peened CMSX4 Superalloy
This metallurgy study analyzed how laser shock peening—a surface treatment process—affects the microstructure and properties of a nickel-based superalloy used in jet engines. It has no relevance to microplastic or environmental health research.
Temperature dependence of internal damping of austenitic steel in different states
Researchers investigated the temperature-dependent internal damping behavior of three austenitic stainless steels (AISI 304, 316L, and 316Ti) across 25-400°C, measuring how initial state, heat treatment, and deformation affect energy dissipation. The study provides material characterization data relevant to engineering applications requiring vibration damping performance at elevated temperatures.
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.
About Wave Nature of the Formation of Gradient and Microcomposite Zones Near Non-Metallic Inclusions During Laser Processing of the Steels
This paper is not relevant to microplastics research — it investigates the wave-based formation of gradient and composite zones near non-metallic inclusions during laser processing of steel.
Exploring 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.
Nature-inspired design and implicit modeling for additive manufacturing: Advancing lattice structures for multidisciplinary applications
Researchers developed a nature-inspired 'Dual Curved Cubic' lattice structure for additive manufacturing, demonstrating via quasi-static compressive testing that its curved interwoven design outperformed conventional BCC and Octet lattices by up to 98.68% in compressive strength, while also exploring lattice architectures as a potential strategy for capturing microplastic pollutants.
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.
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.
Influence of Tempering Transformation Induced Plasticity (T-TRIP) on the Evolution of Residual Stresses in Laser Heat Treated 50CrMo4 Steel
Despite its title referencing "plasticity," this paper studies residual stresses in a type of industrial steel (50CrMo4) during laser heat treatment — not plastic pollution or microplastics. It examines how tempering transformation induced plasticity affects metal component stresses and is entirely outside the field of microplastic research.
Microstructure sensitive simulation framework for additively manufactured Hastelloy-X
This study modeled the microstructure of a nickel-based superalloy produced by additive manufacturing to predict its mechanical behavior. The research is focused on aerospace materials engineering and has no direct connection to microplastics or environmental health.
Impact of the Allowed Compositional Range of Additively Manufactured 316L Stainless Steel on Processability and Material Properties
This study examined how slight variations in the chemical composition of 316L stainless steel affect its processability in 3D printing and the properties of the final parts. The findings help manufacturers optimize additive manufacturing processes for medical and industrial applications.
Microplastic response of 2PP‐printed ceramics
Not relevant to microplastics — this study investigates the mechanical behavior of ceramic materials made by two-photon polymerization 3D printing; the term 'microplastic response' here refers to microscale plastic deformation in ceramics, not environmental microplastic particles.
A Study of Thermal Stability of Residual Stresses and Fatigue life of Laser Shock Peened Ti-6Al-2Sn-4Zr-2Mo alloy
This aerospace engineering study examined how laser shock peening—a process that introduces compressive stress into metal surfaces—affects the fatigue life and thermal stability of a titanium alloy used in high-temperature aerospace applications. This is a materials engineering study with no relevance to microplastic pollution.
Micromechanics of small deformations in metal alloys under laser irra diation
This study investigated grain boundary sliding and plastic deformation in metal alloys at the microscale under laser irradiation. Understanding these nanoscale deformation mechanisms is important for predicting material behavior in precision manufacturing applications. The research contributes to materials science for high-performance metal components.
Crystal plasticity in fusion zone of a hybrid laser welded Al alloys joint: From nanoscale to macroscale
This materials science study examined the plasticity of hybrid laser-welded aluminum alloy joints from the nanoscale to the macroscale, developing models based on micropillar compression tests. It is focused on structural materials science rather than environmental plastic pollution.