A rubber rope of length `8 m` is hung from the ceiling of a room. What is the increase in length of rope due to its own weight? (Given: Young's modulus of elasticity of rubber `= 5 xx 10^(6) N//m` and density of rubber `=1.5xx10^(3)kg//m^(3)`. Take `g=10ms^(-12))`

A rubber rope of length 8 m is hung from the ceiling of a room. What is the increases in length of the rope due to its own weight? (Given, Young's modulus of elasticity of rubber = 5 xx 10^(6) Nm^(-2) and density of rubber = 1.5 xx 10^(6) kg m^(-3) and g = 10 ms^(-2) )

A thick rope of density rho and length L is hung from a rigid support. The increase in length of the rope due to its own weight is ( Y is the Young's modulus)

A thick rope of density rho and length L is hung from a rigid support. The increase in length of the rope due to its own weight is ( Y is the Young's modulus)

A thick rope of density rho and length L is hung from a rigid support. The increase in length of the rope due to its own weight is ( Y is the Young's modulus)

Calculate the speed of longitudinal wave in steel. Young's modulus for steel is 3xx10^(10)N//m^(2) and its density 1.2xx10^(3)kg//m^(3)

Calculate the speed of longitudinal wave in steel. Young's modulus for steel is 3xx10^(10)N//m^(2) and its density 1.2xx10^(3)kg//m^(3)

Calculate the speed of longitudinal wave in steel. Young's modulus for steel is 3xx10^(10)N//m^(2) and its density 1.2xx10^(3)kg//m^(3)

A thick rope of rubber of density 1.5 (kg)/m^3 Young's modulus 5 xx 10^6 N/M^2 and length 8m is hung from the ceiling of a room . The increase in length due to its own weight is