Brass is an alloy and as such can very greatly in its properties depending on its content, so there is no single shear modulus for brass. The only way to be certain is to either test it your self or go by data provided by the manufacturer.
If, on the other hand, you are only working theoretically 40GPa is a good estimate for brass in general. Source: http://www.engineeringtoolbox.com/modulus-rigidity-d_946.html
Young's Modulus (modulus of elasticity) describes the stress-strain behavior of a material under monotonic loading. The dynamic modulus of elasticity describes the same behavior under cyclic or vibratory loading.
applications of modulas of elasticity As the term implies, "Modulus of Elasticity" basically relates to the elasticity or "flexibility" of a material. The value of modulus of elasticity are very much significant relating to deflection of certain materials used in the construction industry. Take for example the general E value of mild carbon steel is about 200 GPa compared to about 70 GPa for aluminum. This simply translate that aluminum is 3 times flexible than steel.
According to IS 456-2000 the value is square root of 5700fck
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).
The modulus of elasticity for AI-SI 1020 steel, commonly known as AISI 1020 steel, is approximately 200 GPa (gigapascals) or 29,000 ksi (kilopounds per square inch). This value represents the steel's ability to deform elastically when a tensile or compressive force is applied. AISI 1020 is a low-carbon steel, and its modulus of elasticity is similar to that of other carbon steels.
75gpa
Young's Modulus (modulus of elasticity) describes the stress-strain behavior of a material under monotonic loading. The dynamic modulus of elasticity describes the same behavior under cyclic or vibratory loading.
IN MACHINE design modulus of elasticity place an important role. from the value of modolus of elasticity we come to know about maximum value of load that can be to the given material upto which the material is assume to follow the hook's law.
130 gpa
Metal is not a specific material, how is this ever going to be answered?!
The Young's modulus of Teflon (PTFE) is around 500-650 MPa, indicating its stiffness and resistance to deformation under stress.
applications of modulas of elasticity As the term implies, "Modulus of Elasticity" basically relates to the elasticity or "flexibility" of a material. The value of modulus of elasticity are very much significant relating to deflection of certain materials used in the construction industry. Take for example the general E value of mild carbon steel is about 200 GPa compared to about 70 GPa for aluminum. This simply translate that aluminum is 3 times flexible than steel.
960
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.
According to IS 456-2000 the value is square root of 5700fck
Young's Modulus for brass is typically around 100-125 GPa. This value indicates the material's stiffness and ability to resist deformation under stress. A higher Young's Modulus means that brass is more rigid and less likely to bend or stretch. This property makes brass a suitable material for applications requiring strength and durability, such as in construction or engineering.
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).