The value for the cleavage plane (100) is 38 GPa and the value for the cleavage plane (001) is 33 GPa.
The modulus of rigidity of a wire is a measure of its resistance to shearing deformation. It is typically represented by the symbol G and is expressed in units of pascals (Pa). The specific value of the modulus of rigidity for a given wire will depend on its material composition and properties.
The known value of Young's modulus for nylon typically ranges from 2 to 6 GPa, depending on the specific type of nylon and its manufacturing process.
The Wikipedia lists a value of 110–128 GPa.
The value of Young's modulus for brass is typically around 100-125 GPa. Young's modulus measures the stiffness of a material, so a higher Young's modulus indicates that the material is stiffer and more resistant to deformation under stress. In the case of brass, a higher Young's modulus means that it is a relatively stiff material, which can make it more suitable for applications requiring strength and durability, such as in engineering and construction.
75gpa
Metal is not a specific material, how is this ever going to be answered?!
Young's modulus
Youngs Modulus
I think you mean "What variables affect young's modulus". Obviously not an english major!
young modulus remain unaffected ...as it depends on change in length ..
Young's modulus is stress/strain. So if the modulus is high, it means that the stress value is greater compare to that of the material where the modulus is low. or in other words, the strain is very less compared to that of the material having low Young's modulus. So it tells that, if a material has high Young's modulus, the material requires more load for deformation of shape (within elastic limit).
Young's modulus-205 kN/mm2 Poisson's ratio = 0.30
The value for the cleavage plane (100) is 38 GPa and the value for the cleavage plane (001) is 33 GPa.
there are different types of modulus it depends on what types of stress is acting on the material if its direct stress then then there is modulus of elasticity,if tis shear stress then its modulus of rigidity and when its volumetric stress it is bulk modulus and so on
Depends on the hardness of the formulation. Poisson's ratio depends mainly on the bulk modulus and slightly on the Youngs modulus at very low strains for the subject compound. If the Youngs modulus lies between 0.92 and 9.40MN/m², Poisson's ratio lies between 0.49930 and 0.49993.
G = E/2(1+u) where G = mod of rigidity and u =poisson ration and E = young modulus