A `1000 m` long rod of density `10.0 xx 10^(4) kg//m^(3)` and having young's modulus `Y=10^(11) Pa`, is clamped at one end. It is hammered at the other free end as shown in the figure. The logitudinal pulse goes to right end, gets reflected and again returns to the left end. How much time (in sec) the pulse take to go back to initial point ?
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A 100 - m long rod of density 10.0 xx 10^(4) kg//m^(3) and having Young's modulus Y = 10^(11) Pa , is clamped at one end . It is hammered at the other free end. The longitudinal pulse goes to right end , gets reflected and again returns to the left end . How much time the pulse take to go back to initial point.

Young.s modulus of a wire is 2 xx 10^(11)N//m^(2) . If a stress of 2 x 108 N/m2 is applied at the free end of a wire, find the strain in the wire.

A string that is 10 cm long is fixed at both ends. At t=0, a pulse travelling from left to right at 1cm//s is 4.0 cm from the right end as shown in figure. Determine the next two times when the pulse will be at that point again. State in each case whether the pulse is upright or inverted . .

A rectangular metallic bar one metre long, one cm deep and one cm broad is placed on a smooth table. The Young's modulus and modulus of rigidity of metal of the bar are 2 xx 10^(11) N//m^(2) and 8 xx 10^(10) N //m^(2) respectively. If the bar is rigidity clamped at one end is pulled at the other end with a force 5000 N applied normaly to its end cross-section, calculate the elongation of the bar and the work done in elongating the bar.

The axle of a pulley of mass 1 kg is attached to the end of an elastic string of length 1m , cross- sectional area 10^(-3) m^(2) and young's modulus 2xx10^(5) Nm^(-2) ,whose other end is fixed to the ceiling. A rope of negligible mass is placed on the pulley such that its left end is fixed to the ground and its right end is hanging freely , from the pulley which is at rest in equilibrium . Now, the rope and the pulley can be neglected. (Given, g = 10 ms^(-2) ) The elongation of the string before applying force is

The axle of a pulley of mass 1 kg is attached to the end of an elastic string of length 1m , cross- sectional area 10^(-3) m^(2) and young's modulus 2xx10^(5) Nm^(-2) ,whose other end is fixed to the ceiling. A rope of negligible mass is placed on the pulley such that its left end is fixed to the ground and its right end is hanging freely , from the pulley which is at rest in equilibrium . Now, the rope and the pulley can be neglected. (Given, g = 10 ms^(-2) ) The elongation of the string before applying force is

The axle of a pulley of mass 1 kg is attached to the end of an elastic string of length 1m , cross- sectional area 10^(-3) m^(2) and young's modulus 2xx10^(5) Nm^(-2) ,whose other end is fixed to the ceiling. A rope of negligible mass is placed on the pulley such that its left end is fixed to the ground and its right end is hanging freely , from the pulley which is at rest in equilibrium . Now, the rope and the pulley can be neglected. (Given, g = 10 ms^(-2) ) The elongation of the string before applying force is

A string of length 0.4 m and mass 10 ^(-2) kg is tightly clamped at its ends. The tension in the string is 1. 6 N. identical wave pulses are produced at one end at equal intervals of time Delta t . The value of Delta t which allows construction interference between successive pulses is

A string of length 40 cm and weighing 10 g is attached to a spring at one end and to a fixed wall at the other end. The spring has a spring constant of 160 N m^-1 and is stretched by 1.0 cm. If a wave pulse is produced on the string near the wall, how much time will it take to reach the spring ?

A string of length 40 cm and weighing 10 g is attached to a spring at one end and to a fixed wall at the other end. The spring has a spring constant of 160 N m^-1 and is stretched by 1.0 cm. If a wave pulse is produced on the string near the wall, how much time will it take to reach the spring ?