Most of the materials can be considered elastic at least for a specific range. For example, Wood is elastic when we compare it with glass. Their modulus of elasticity cannot be calculate. However;It is anisotropic material. (its elasticity will be change if your loading parallel to its fibers or perpendicular.)
Yes, wood is harder than rubber. Wood is a natural material known for its density and durability, while rubber is a synthetic material that is much softer and more elastic in comparison.
Rubber is the most elastic material among steel, copper, wood, and rubber. Rubber can stretch significantly before breaking, making it highly elastic compared to the other materials listed.
Copper is the most elastic material among iron, copper, quartz, and wood. It can be stretched significantly without breaking and able to return to its original shape.
why is yew wood elastic? cheers desperately need this info for my physics coursework!
Elastic bands.
Factors that affect elastic energy include the material's elastic modulus (stiffness), the amount of deformation or stretching applied to the material, and the shape or configuration of the material. Additionally, temperature can also affect the elastic properties of a material.
The relationship between stiffness and elastic modulus in materials is that the elastic modulus is a measure of a material's stiffness. A higher elastic modulus indicates a stiffer material, while a lower elastic modulus indicates a more flexible material. In other words, stiffness and elastic modulus are directly related in that a higher elastic modulus corresponds to a higher stiffness in a material.
it is stretchy
Weight causes the elastic material to stretch. The material may be stretched beyond its elastic limit. If this happens, then the material rips or tears, or it does not return to its original size.
Elastic potential energy is stored in stretched or compressed elastic materials, such as a rubber band or a spring. When the material is deformed, this energy is stored in the material and can be released when the material returns to its original shape.
Elastic force is the force exerted by a stretched or compressed elastic material to return to its original shape. Elastic potential energy is the energy stored in an elastic material when it is stretched or compressed. The elastic force is responsible for restoring the material to its original shape, converting the stored elastic potential energy back to kinetic energy.
In stretched elastic, the primary forms of energy present are elastic potential energy, which is the energy stored in the elastic material due to its deformation, and kinetic energy, if the elastic material is moving.