Question: In an experiment to measure the speed of sound by a resonating air column, a tuning fork of frequenc...

Question

In an experiment to measure the speed of sound by a resonating air column, a tuning fork of frequency 500Hz is used. The length of the air column is varied by changing the water level in the resonance tube. Two successive resonances are heard at the air column with lengths 50.7 cm and 83.9 cm. Which of the following statements are true?
(This question has multiple answers)
Option A: the speed of sound determined from this experiment is $332m{s^{ - 1}}$
Option B: the end correction in this experiment is $0.9cm$ .
Option C: wavelength of the sound is 66.4 cm.
Option D: the resonance at 50.7 cm corresponds to the fundamental harmonic.

Answer 1

Solution

When two longitudinal waves of same frequency travel through a medium in the opposite directions standing waves are produced.

Complete solution:
In an organ pipe column the sound behaves as a standing wave. The waves resonate harmonically.
There are two types of organ pipes;
Closed organ pipe: One end of the pipe is closed.
Open organ pipe: Both the ends are open.
In an air column filled with water, the conditions are the same as a closed organ pipe.
Hence, we can treat the situation as a closed organ pipe.
Now for standing waves in closed pipe the condition is given by;
$l = (2n + 1)\dfrac{\lambda }{4}$ (equation: 1)
Here l=length of air column, n= 0, 1, 2… $\lambda$ =wavelength of the wave.
The diagram below will help you understand the situation

Now the above figure is just an example but not the actual case, as we do not know the number of harmonics.
Now, let us assume that the two successive harmonics at 50.7 and 83.9 cms be ${n_1}$ and ${n_2}$ respectively.
As the difference in length of two successive resonating air columns is half the wavelength of the wave,
$83.9 - 50.7 = \dfrac{\lambda }{2}$
Thus, $\lambda = 2 \times 33.2 = 66.4$
Hence, wavelength of sound is 66.4cm
Now as $\dfrac{\lambda }{4} = 16.6cm$ , 50.7 is not the fundamental harmonic.
Also, as $\dfrac{{3\lambda }}{4} = 49.8 = e + 50.7cm$ (here, e is the end correction)
50.7 is the third harmonic and so 83.9 will be the fifth harmonic.
Now, $e = 49.8 - 50.7 = - 0.9cm$ .
Hence the end correction is 0.9cm.
Now for the speed of sound $v = \lambda \upsilon$ ( $\lambda$ is the wavelength, $\upsilon$ is the frequency)
$v = 66.4 \times 500 = 33200cm{s^{ - 1}} = 332m{s^{ - 1}}$

Thus option A, option B and option C are correct.

Note:
(1) In the case of air columns, always consider some end correction.
(2) For organ pipe end correction may not be considered.