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Metallic bonds are maintained more or less instantaneously on mechanical deformation of a metal, unless the deformation is so severe that the piece of metal being deformed is broken. Since metallic bonding extends throughout a single piece of metal, it does not need to be "renewed" after deformation.
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Ductile deformation is observed by folding of rock layers. Ductile deformation can take place by plastic flow of hot, weak rock.
Internal Controlling Factors: Strength: The strength of the rock determines the amount of deformation that can occur before it fractures. Different types of rocks have different strengths, so the amount of deformation that can occur will vary depending on the type of rock. 2. Temperature: The temperature of the rock determines the amount of deformation that can occur. When rocks are heated, they become more ductile and can deform more easily than when they are cold. 3. Composition: The chemical composition of the rock can also influence its ability to deform. Rocks with higher amounts of silica tend to deform more easily than rocks with lower amounts. External Controlling Factors: Pressure: The external pressure applied to the rock can influence the amount of deformation it can endure. Higher pressures tend to cause rocks to deform more easily than lower pressures. 2. Stress: The type of stress applied to the rock can also influence how much deformation it can endure. Different types of stresses can cause different amounts of deformation. 3. Time: The amount of time over which the deformation takes place can also influence the amount of deformation that can occur. Deformation can occur over
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In general, mechanical deformation is structural on a large scale; as opposed to the components of the object being inherently wrong, their assemblage is merely distorted. In order for a more specific answer I would have to know the context.
Yes
Yield strength is the stress at which a specified amount of permanent deformation of a material occurs. When we apply stress to a material, it deforms. Some of the deformation is plastic and the material can recover when the stress is relieved. But some deformation is permanent and the material cannot recover from it. As we apply more stress, there is more deformation. This plots on a curve in a somewhat linear, or proportional, way. But at some point, a bit more stress results in a lot more deformation, and this is the proportional limit of the material. Stress applied beyond this causes an increasing rate of deformation until the maximum or ultimate strength of the material is reached. (Beyond that it will fail completely.) Somewhere between the proportional limit and the ultimate strength of the material is the yield strength. The yield strength of a material cannot be calculated for any material. It must be arrived at through (repeated) experiment and statistical analysis. Use the link below to the related question, and the other links to related articles that explain more about yield strength.
deformation
No