Longitudinal waves of frequency 400Hz are produced in a rod of material of density `8000 kg//m^3` and Young modulus `7.2 xx 10^(10) N//m^2`. What is the wavelength of the wave?

The density of aluminium is 2.7 xx 10^(3) kg//m^3 and its Young's modulus is 7.0 xx 10^(10)N//m^2 . Calculate the velocity of sound wave in the bar.

The speed of longitudinal mechanical wave in a material is 4300 m/s. young's modulus of the material is 15xx10^(9)N//m^(2) . What is the density of the material?

A granite rod of 60 cm length is clamped at its middle point and is set into longitudinal vibrations. The density of granite is 2.7 xx10^(3) kg//m^(3) and its Young’s modulus is 9.27 xx10^(10) Pa. What will be the fundamental frequency of the longitudinal vibrations ?

An aluminum rod having a length 100 cm is clamped at its middle point and set into longitudinal vibrations. Let the rod vibrate in its fundamental mode. The density of aluminum is 2600 kg//m^(3) and its Young's modulus is 7.8xx10^(10) N//m^(2) . The frequency of the sound produced is :-

(a) In a liquid with density 1300 kg //m^(3) , longitudinal waves frequency 400 H_(Z) are found to have wavelength 8.00 m . Calculate the bulk modulus of the liquid. (b) A metal bar with a length of 1.50 m has density 6400 kg//m^(3) . Longitudinal sound waves take 3.90xx10^(-4) s to travel from one end of the bar to the other. What is young's modulus for this metal?

(a) A longitudinal wave propagating in a water-filled pipe has intensity 3.00xx10^(-6) W//m ^(2) and frequency 3400 H_(Z) . Find the amplitude A and wavelength lambda of the wave . Water has density 1000 kg//m ^(3) and bulk modulus 2.18xx10^(9) Pa . (b) If the pipe is filled with air at pressure 1.00 xx10^(5) Pa and density 1.20 kg//m^(3) , What will be the amplitude A and wavelength lambda of a longitudinal wave the same intensity and frequency as in part (a) ? (c ) In which fluid is the amplitude larger, water or air? What is the ratio of the two amplitude ? Why is this ratio so different from/ Conider air as diatomic.

A steel rod 2.5 m long is rigidly clamped at its centre C and longitudinal waves are set up on both sides of C by rubbing along the rod . Young's modulus for steel = 2 xx 10^(11) N//m^(2) , density of steel = 8000 kg//m^(3) If the clamp of the rod be shifted to its end A and totally four antinodes are observed in the rod when longitudinal waves are set up in it , the frequency of vibration of the rod in this mode is

An aluminium rod having a length of 90.0 cm is clamped at its middle point and is set into longitudinal vibrations by stroking it with a rosined cloth. Assume that the rod vibrates in its fundmental mode of vibration. The density of aluminium is 2600 kgm^-3 and its Young's modulus is 7.80xx10^10 Nm^-2 . Find a. The speed of sound in aluminium, b. The wavelength of sound waves produced in the rod. c. The frequency of the sound produced and d. The wavelength of the sound produced in air. Take the speed of sound in air to be 340 ms^-1 .

The Young's modulus of brass is 9.1 xx 10^(10) N //m^(2) and its rigidity modulus is 3.5 xx 10^(10) N //m^(2) . Calculate its Poisson's ratio ?