Elastic deformation is reversible and occurs when a material is stretched but returns to its original shape once the stress is removed. Ductile deformation, on the other hand, is permanent and occurs when a material is stretched beyond its elastic limit, resulting in plastic deformation that changes the material's shape permanently.
Elasticity refers to a material's ability to return to its original shape after being stretched or deformed, while ductility is a material's ability to be stretched or drawn out without breaking. Elastic materials deform temporarily, while ductile materials can be permanently stretched or shaped without breaking.
Elastic gels have the ability to return to their original shape after being stretched or deformed, while non-elastic gels do not have this property. Elastic gels exhibit more resilience and are typically used in applications where repeated deformation is expected, such as in sports equipment. Non-elastic gels are often used for cushioning or absorbing impact.
Hooke's Law is a principle that describes the relationship between the force applied to a spring and the resulting deformation or stretch of the spring. Elastic potential energy, on the other hand, is the energy stored in a stretched or compressed spring due to its deformation. In simpler terms, Hooke's Law explains how a spring behaves when a force is applied to it, while elastic potential energy refers to the energy stored in the spring when it is stretched or compressed.
Proportionality limit is the point upto which the stress remains directly proportional to strain whereas elastic limit is the point upto which the material remains elastic ie. if the stress is removed within elastic limit, then the material will regain its original shape and size.
An elastic body can deform under stress but will return to its original shape when the stress is removed, while a rigid body does not deform at all. In other words, an elastic body can store and release energy in the form of deformation, while a rigid body cannot.
Ductile deformation is when rock is given enough stress to break. If the stress is less, it will bend but not break.
Elastic collision transfers more energy into motion while inelastic transfers energy into deformation of the objects. Elastic could be called more efficient transfer.
elastic deformation
When rocks bend instead of breaking, it is called ductile deformation. This typically occurs under high pressure and temperature conditions deep within the Earth's crust where rocks are able to deform and flow rather than fracture.
Elastic deformation is recoverable deformation. As such, when the load that caused the deformation is removed the material will return to it's original shape.
difference between elastic and inelastic demand
The types of rock deformation include folding, faulting, and shearing. Folding occurs when rocks bend due to compressional forces, faulting involves the movement of rocks along fractures or faults, and shearing is the sliding of rock layers past each other horizontally.
Young Modulus is the slope of the stress-strain diagram in the linear elastic region. This is the most common use of modulus. As the material goes non-linear in the stress strain curve, thre slope will get increasingly lower. In this case one connects the end points of the stress strain diagram at the point of interest with a straight line. The slope of that straight line is the secant modulus.
after the removal of load if the object regains its original position is called elastic deformation ....If the object cant regain its original position even after the removal of applied load is called plastic deformation...
Mechanical energy (that causes the elastic deformation).
Elastic deformation is the temporary distortion experienced by a material under stress, where the material returns to its original shape once the stress is removed. This deformation is reversible and does not cause permanent changes to the material's structure.
Elastic collision transfers more energy into motion while inelastic transfers energy into deformation of the objects. Elastic could be called more efficient transfer.