Advanced Materials Research

This cluster investigates nanostructured alloys, particularly high-entropy alloys, and their unique characteristics and applications. The goal is to develop advanced materials with enhanced properties for various engineering sectors.

161057 papers

This cluster focuses on the study of fracture mechanics and ductile failure in materials, examining the phenomena of rupture and the mechanics behind void nucleation and growth. It aims to establish principles that describe how materials can withstand or fail under stress.

137889 papers

Research in this cluster centers around the synthesis, characterization, and understanding of high entropy alloys and multi-component alloys, which offer promising mechanical properties and potential applications in various fields. It encompasses fundamental studies as well as reviews of existing literature to foster advancements in alloy design.

79424 papers

Research in this cluster is dedicated to the dynamics of microstructures and their evolution during processes such as crystal growth. It covers theoretical and experimental approaches to understand how microstructural changes affect material behavior and properties.

78046 papers

This cluster examines various indentation techniques to assess the mechanical properties of materials. The research provides insights into hardness, elasticity, and contact mechanics through experimental and theoretical frameworks.

62007 papers

The research in this cluster explores nanostructured materials, investigating their unique properties and phenomena at the nanoscale. Topics include the structural characteristics, magnetoresistance effects, and emerging applications of such materials in technology.

52037 papers

This area investigates the mechanical, electronic, and thermal properties of two-dimensional materials such as graphene and transition metal dichalcogenides. Research aims to uncover new applications of these novel materials in technology.

49001 papers

Research in this cluster examines the kinetics of phase changes and the associated microstructural development. It focuses on material behavior during phase transitions and how microstructures influence performance.

43063 papers

This cluster deals with the elastic behavior of various materials, focusing on theories of deformation and the relationships between elastic moduli and plastic properties. It aims to develop fundamental models that describe the mechanical response of materials under stress.

33703 papers

Research in this cluster focuses on the development and characterization of nanostructured materials suitable for electronic applications. Emphasis is placed on the unique mechanical and electrical properties that arise from their nanoscale structures.

33603 papers

This cluster explores innovative processing techniques for developing advanced materials, including cellular metals and metal foams. Research seeks to relate processing methods to enhanced material properties and applications.

31882 papers

Research in this cluster focuses on theoretical modeling techniques to predict the behavior of solid materials under various conditions. This includes innovative approaches to understanding material properties at multiple scales.

22996 papers

This cluster is dedicated to the study of mechanical properties in a range of advanced materials, including their response to loading conditions and deformation patterns. The objective is to establish fundamental relationships governing material strength and behavior.

19401 papers

Research in this area delves into the mechanical behavior of composite materials and their applications in advanced technologies. The focus is on understanding composite mechanics and the interplay of different material phases.

17333 papers

This cluster focuses on modeling and understanding the plastic deformation mechanisms in polycrystalline materials, examining how sample dimensions affect mechanical properties and texture development.

14570 papers

This cluster investigates the elastic properties and stability conditions of various crystal structures. It aims to provide insights into elastic stability and anisotropic behavior in crystalline materials, critical for various applications.

13593 papers

This research area studies the mechanisms of crystal deformation and the resultant elastic properties, particularly under mechanical stress. It involves examining the rate dependence and localized deformation phenomena within crystalline solids.

8168 papers

This cluster focuses on the thermodynamic principles that govern material properties and phase behavior, utilizing advanced computational techniques such as machine learning for predictive modeling. The research aims to develop consistent thermodynamic data sets applicable to various material types.

6323 papers

This research area explores the mechanical behavior of crystalline materials, focusing on plastic deformation and crystal plasticity mechanisms. The studies aim to understand how stress influences the performance and durability of these materials.

6273 papers

This cluster investigates defect behavior and interface dynamics within various materials, including non-crystalline structures. The research examines how defects influence electrical and mechanical properties and the mechanisms that drive defect formation.

2083 papers

This research area focuses on the micromechanical behavior of heterogeneous materials, including alloys and granular materials. It aims to develop models that describe the interactions and mechanics at the micro-scale.

1984 papers

This cluster is focused on advanced techniques for characterizing material surfaces at the atomic level, including scanning tunneling microscopy. Research aims to better understand surface structures, defects, and their impact on material properties.

1714 papers