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Papers
61,005 resultsShowing papers similar to Durability Analysis of CFRP Adhesive Joints: A Study Based on Entropy Damage Modelling Using FEM
ClearDurability Analysis of CFRP Adhesive Joints: A Study Based on Entropy Damage Modeling Using FEM
Researchers incorporated an entropy damage model into the finite element method to predict the fatigue durability of carbon fiber-reinforced plastic (CFRP) adhesive joints with varying adhesive layer thicknesses. Findings showed that damage variables peaked at a 0.3 mm adhesive thickness before declining, providing insight into stress behavior at the resin-composite interface under cyclic loading.
Fatigue Failure of Adhesive Joints in Fiber-Reinforced Composite Material Under Step/Variable Amplitude Loading—A Critical Literature Review
This study is not about microplastics; it is a materials engineering review of fatigue failure mechanisms and damage accumulation models for fiber-reinforced polymer composite adhesive joints under variable-amplitude loading conditions.
A continuum damage mechanics model for fatigue and degradation of fiber reinforced materials
This engineering paper presents a mathematical model describing how fiber-reinforced materials degrade under repeated loading, using microplastic deformation as the driving mechanism for damage accumulation. It is a materials science study with no direct relevance to environmental plastic pollution or human health.
A quantitative residual stiffness model for carbon fiber reinforced polymer tendons
Not relevant to microplastics — this engineering study models residual stiffness degradation in carbon fiber-reinforced polymer tendons under fatigue loading, relevant to civil infrastructure but with no connection to microplastic research.
An Entropy-Based Damage Characterization
This paper proposes using entropy — a measure of energy dissipation — as a scientific framework for characterizing damage and degradation in materials under stress. This is a thermodynamics and materials engineering study with no direct connection to microplastics research.
Thermo‐based fatigue life prediction: A review
Not relevant to microplastics — this review covers thermography-based methods for predicting the fatigue life of metals under cyclic stress, with no connection to plastic pollution or environmental health.
A Small-Deformation Rate-Independent Continuous-Flow Model for Elasto-Plastic Frames Allowing Rapid Fatigue Predictions in Metallic Structures
This engineering paper presents a computational model for predicting fatigue behavior in metal frame structures with localized plastic deformation. The study is focused on structural engineering and is unrelated to microplastic pollution research.
On Microplasticity-induced Fatigue Fracture and its Relation to Entropy
Researchers investigated the relationship between microplasticity and fatigue fracture in steel specimens under axial cyclic loading, using fatigue testing machines to identify the stress cycle point at which microplastic deformation becomes detectable and analyzing its relationship to entropy production.
A Review of Damage, Void Evolution, and Fatigue Life Prediction Models
This engineering review summarizes models for predicting how damage, voids, and fatigue cause materials such as metals and composites to fail over time. This materials science paper is not related to microplastic environmental contamination.
Determination of energy dissipation during cyclic loading and its use to predict fatigue life of metal alloys
This paper is not about microplastics — it develops a mathematical method for predicting the fatigue life of metal alloys from energy dissipation during cyclic loading.
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.
A Continuum Damage Mechanics-based Piecewise Fatigue Damage Model for Fatigue Life Prediction of Fiber-Reinforced Laminated Composites
This engineering study developed a mathematical model to predict how fiber-reinforced plastic composite materials accumulate damage and eventually fail under repeated cyclic stress. The model could help engineers design longer-lasting plastic composite structures used in aerospace, automotive, and construction applications.
A Review of Damage, Void Evolution, and Fatigue Life Prediction Models
This review examines empirical and physics-based models for damage evolution, void growth, and fatigue life prediction in engineering materials, covering frameworks including the Gurson-Tvergaard-Needleman model, Johnson-Cook damage model, microplasticity models, and unified mechanics theory using irreversible entropy.
Research Progress on Fatigue Behavior and Life Prediction under Multiaxial Loading for Metals
This Chinese-language review summarizes research on fatigue damage and life prediction of metal structures under complex, multi-directional loading conditions. The research is focused on structural engineering and has no direct relevance to microplastic pollution.
Microplastic Strain Hysteresis Energy as a Criterion for Fatigue Fracture
This materials science paper proposes an energy-based fatigue failure criterion using microplastic strain hysteresis energy, developing a relation between stress amplitude and cycles to failure. 'Microplastic strain' refers to small-scale plastic deformation in metals during cyclic loading and has no connection to environmental plastic pollution.
Characterization of Hybrid FRP Composite Produced from Recycled PET and CFRP
This paper is not about microplastics — it characterizes the mechanical properties of recycled carbon fiber composites made with PET plastic waste for structural applications.
Review on The Prediction of Residual Stress in Welded Steel Components
This review covers empirical, semi-empirical, and simulation-based methods for predicting residual stress in welded steel structures after manufacturing. It is a mechanical engineering paper with no connection to environmental microplastics or human health.
Rapid Fatigue Limit Estimation of Metallic Materials Using Thermography-Based Approach
This paper is not about environmental microplastics; it uses the term "microplastic" in a materials science context to describe microscopic plastic deformation in metals during fatigue testing.
Experiments and Modeling of Fatigue Behavior of Friction Stir Welded Aluminum Lithium Alloy
Researchers conducted experimental and computational studies of fatigue behavior in aluminum-lithium alloy welded joints. This is an aerospace materials engineering paper unrelated to environmental microplastics.
Analysis of fatigue crack initiation in cyclic microplasticity regime
This engineering study analyzed how fatigue cracks begin in metals under cyclic loading, focusing on microscale stress and material defects. It is a materials science paper not related to environmental microplastics.
Probabilistic approach in high‐cycle multiaxial fatigue: volume and surface effects
This engineering paper developed a probabilistic framework for predicting fatigue limits in metals under complex multiaxial loading conditions by combining statistical modeling with microplasticity analysis. This is a mechanical engineering study with no relevance to environmental microplastics.
Energy Dissipation Measurement in Improved Spatial Resolution Under Fatigue Loading
This engineering study used infrared thermography to measure energy dissipation in materials under fatigue loading to quickly predict a material's failure threshold. It is a materials science paper unrelated to environmental microplastics.
Investigation Study of Structure Real Load Spectra Acquisition and Fatigue Life Prediction Based on the Optimized Efficient Hinging Hyperplane Neural Network Model
Not relevant to microplastics — this paper develops an optimized neural network model for predicting real-world load spectra and fatigue life of mechanical structures, achieving a fatigue life prediction accuracy of 93.56% for engineering applications.
Damage evolution in AA2124/SiC metal matrix composites under tension with consecutive unloadings
This engineering study investigated how aluminum-silicon carbide metal matrix composites deform and accumulate damage under tensile loading. It is a materials science paper not related to environmental microplastics.