Find the temperature at which the fundamental frequency of an organ pipe is independent of small variation in temperature in terms of the coefficient of linear expansion ( `alpha`) of the material of the tube.

if the temperature is increased then the fundamental frequency of an open pipe is [ neglect any expansion]

When temperature is increases, the frequency of organ pipe

Let gamma : coefficient of volume expansion of the liquid and alpha : coefficient of linear expansion of the material of the tube

The ratio of fundamental frequencies of an open organ pipe and a cloed organ pipe of same length at same temperature is

Organisms which can tolerate only small variations in temperature are called

The variation of length of two metal rods A and B with change in temperature is shown in Fig. the coefficient of linear expansion alpha_A for the metal A and the temperature T will be

With the increase in temperature, the frequency of the sound from an organ pipe

A thread of liquid is in a uniform capillary tube of length L. As measured by a ruler. The temperature of the tube and thread of liquid is raised by DeltaT . If gamma be the coefficient of volume expansion of the liquid and alpha be the coefficient of linear expansion of the material of the tube, then the increase DeltaL in the length of the thread, again measured by the ruler will be

A thread of liquid is in a uniform capillary tube of length L. As measured by a ruler. The temperature of the tube and thread of liquid is raised by DeltaT . If gamma be the coefficient of volume expansion of the liquid and alpha be the coefficient of linear expansion of the material of the tube, then the increase DeltaL in the length of the thread, again measured by the ruler will be

Assertion: The fundamental frequency of an open organ pipe increases as the temperature is increased. Reason: As the temperature increases, the velocity of sound increases more rapidly than length of the pipe.