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- https://eng.libretexts.org/Bookshelves/Mechanical_Engineering/Mechanics_of_Materials_(Roylance)/01%3A_Tensile_Response_of_Materials/1.01%3A_Introduction_to_Elastic_ResponseThis page covers the mechanics of elastic response in materials, focusing on concepts like stress, strain, and ultimate tensile strength (UTS). It details testing methods for material strength, includ...This page covers the mechanics of elastic response in materials, focusing on concepts like stress, strain, and ultimate tensile strength (UTS). It details testing methods for material strength, including the tension test and evaluating rods under load. Key principles such as stiffness, Hooke's Law, and Young's modulus are introduced to understand deformation.
- https://eng.libretexts.org/Workbench/Materials_Science_for_Electrical_Engineering/10%3A_Polymer_Properties/10.04%3A_Polymer_Chemistry/10.4.04%3A_Polymer_Chemistry-_Mechanical_PropertiesThe mechanical properties of a polymer involve its behavior under stress. These properties tell a polymer scientist or engineer many of the things he or she needs to know when considering how a polyme...The mechanical properties of a polymer involve its behavior under stress. These properties tell a polymer scientist or engineer many of the things he or she needs to know when considering how a polymer can be used. How strong is the polymer? How much can you stretch it before it breaks? How stiff is it? How much does it bend when you push on it? Is it brittle? Does it break easily if you hit it hard? Is it hard or soft? Does it hold up well under repeated stress?
- https://eng.libretexts.org/Bookshelves/Mechanical_Engineering/Mechanics_of_Materials_(Roylance)/01%3A_Tensile_Response_of_Materials/1.02%3A_Atomistics_of_ElasticityThis page covers key material properties such as ultimate tensile strength and Young's modulus, emphasizing their significance in mechanical design and relating them to atomic bond energy and stiffnes...This page covers key material properties such as ultimate tensile strength and Young's modulus, emphasizing their significance in mechanical design and relating them to atomic bond energy and stiffness. It discusses ionic, metallic, and covalent bonding effects on material behavior, particularly in elasticity and thermal expansion, notably in polymers and rubber.
- https://eng.libretexts.org/Bookshelves/Mechanical_Engineering/Mechanics_of_Materials_(Roylance)/03%3A_General_Concepts_of_Stress_and_Strain/3.03%3A_Tensor_TransformationsThis page explores the transformation of stress and strain axes in materials, with a focus on composite materials and the application of Mohr's circle for graphical visualization of stress states. It ...This page explores the transformation of stress and strain axes in materials, with a focus on composite materials and the application of Mohr's circle for graphical visualization of stress states. It discusses the transformation of biaxial strains, the concept of pure shear, and the determination of principal stresses in three-dimensional states.
- https://eng.libretexts.org/Bookshelves/Materials_Science/Polymer_Chemistry_(Whisnant)/04%3A_Mechanical_PropertiesThe mechanical properties of a polymer involve its behavior under stress. These properties tell a polymer scientist or engineer many of the things he or she needs to know when considering how a polyme...The mechanical properties of a polymer involve its behavior under stress. These properties tell a polymer scientist or engineer many of the things he or she needs to know when considering how a polymer can be used. How strong is the polymer? How much can you stretch it before it breaks? How stiff is it? How much does it bend when you push on it? Is it brittle? Does it break easily if you hit it hard? Is it hard or soft? Does it hold up well under repeated stress?
