MCQEasyJEE 2026Wave Motion Basics

JEE Physics 2026 Question with Solution

Two strings (AA, BB) having linear densities μA=2×104kg/m\mu_A = 2 \times 10^{-4} \, \text{kg/m} and, μB=4×104kg/m\mu_B = 4 \times 10^{-4} \, \text{kg/m} and lengths LA=2.5mL_A = 2.5 \, \text{m} and LB=1.5mL_B = 1.5 \, \text{m} respectively are joined. Free ends of AA and BB are tied to two rigid supports CC and DD, respectively creating a tension of 500N500 \, \text{N} in the wire. Two identical pulses, sent from CC and DD ends, take time tAt_A and tBt_B, respectively, to reach the joint. The ratio tA/tBt_A/t_B is:

  • A

    1.081.08

  • B

    1.901.90

  • C

    1.181.18

  • D

    1.671.67

Answer

Correct answer:C

Step-by-step solution

Standard Method

Given: Two joined strings are under the same tension T=500NT = 500 \, \text{N} with μA=2×104kg/m\mu_A = 2 \times 10^{-4} \, \text{kg/m}, μB=4×104kg/m\mu_B = 4 \times 10^{-4} \, \text{kg/m}, LA=2.5mL_A = 2.5 \, \text{m} and LB=1.5mL_B = 1.5 \, \text{m}.

Find: The ratio tA/tBt_A/t_B.

The speed of a transverse wave on a string is

v=Tμv = \sqrt{\frac{T}{\mu}}

So the time taken by a pulse to travel length LL is

t=Lv=LμTt = \frac{L}{v} = L\sqrt{\frac{\mu}{T}}

Hence,

tA=LAμATt_A = L_A\sqrt{\frac{\mu_A}{T}}

and

tB=LBμBTt_B = L_B\sqrt{\frac{\mu_B}{T}}

Taking the ratio,

tAtB=LAμA/TLBμB/T=LALBμAμB\frac{t_A}{t_B} = \frac{L_A\sqrt{\mu_A/T}}{L_B\sqrt{\mu_B/T}} = \frac{L_A}{L_B}\sqrt{\frac{\mu_A}{\mu_B}}

Substituting the given values,

tAtB=2.51.52×1044×104=251524=5312\frac{t_A}{t_B} = \frac{2.5}{1.5}\sqrt{\frac{2 \times 10^{-4}}{4 \times 10^{-4}}} = \frac{25}{15}\sqrt{\frac{2}{4}} = \frac{5}{3}\sqrt{\frac{1}{2}}

Thus,

tAtB=532\frac{t_A}{t_B} = \frac{5}{3\sqrt{2}}

Using 21.414\sqrt{2} \approx 1.414,

tAtB53×1.414=54.2421.1786\frac{t_A}{t_B} \approx \frac{5}{3 \times 1.414} = \frac{5}{4.242} \approx 1.1786

Therefore, the ratio is approximately 1.181.18, so the correct option is C.

Use cancellation in the ratio

Given: Both strings are under the same tension.

Find: tA/tBt_A/t_B.

Since t=Lμ/Tt = L\sqrt{\mu/T}, the common tension cancels immediately in the ratio:

tAtB=LALBμAμB\frac{t_A}{t_B} = \frac{L_A}{L_B}\sqrt{\frac{\mu_A}{\mu_B}}

Now use only lengths and linear densities:

tAtB=2.51.524=5321.18\frac{t_A}{t_B} = \frac{2.5}{1.5}\sqrt{\frac{2}{4}} = \frac{5}{3\sqrt{2}} \approx 1.18

Therefore, the correct option is C. This shortcut works because wave speed depends on T/μ\sqrt{T/\mu}, and the same tension acts in both parts of the joined string.

Common mistakes

  • Using tT/μt \propto \sqrt{T/\mu} instead of tμ/Tt \propto \sqrt{\mu/T} is incorrect because time is length divided by speed. First write t=L/vt = L/v, then substitute v=T/μv = \sqrt{T/\mu}.

  • Forgetting to include the lengths LAL_A and LBL_B gives a wrong ratio because the pulses travel different distances before reaching the joint. Use both length and linear density in the expression for time.

  • Not cancelling the common tension in the ratio leads to unnecessary calculation. Since both string segments are under the same tension, TT cancels when forming tA/tBt_A/t_B.

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