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The potential energy U of a body of unit...

The potential energy U of a body of unit mass moving in one dimensional conservative force field is given by `U=x^2-4x+3`. All units are is SI. For this situation mark out the correct statement (s).

A

The body will perform simple harmonic motion about `x=2` units.

B

The body will perform oscillatory motion but not simple harmonic motion.

C

The body will perform simple harmonic motion with time period `sqrt2pis`.

D

If speed of the body at equilibrium position is `4(m)/(s)`, then the amplitude of oscillation would be `2sqrt2`m

Text Solution

Verified by Experts

The correct Answer is:
A, C, D
`U=x^2-4x+3` and `F=-(dU)/(dx)=-(2x-4)`
At equilibrium position `F=0`, so `x=2cm`
Let the particle is displaced by `trianglex` from equilibrium position i.e, from `x=2`, then restoring force on body is
`F=-2(2+trianglex)+4=-2trianglex`
i.e., `Falpha-trianglex`, so performs simple harmonic motion about `x=2m`
Time period `T=2pisqrt((m)/(k))=2pisqrt((1)/(2))=sqrt2pis`
From energy conservation, `(mv_(max)^2)/(2)+U_(min)=U_(max)`
`(1xx4^2)/(2)+(2^2-4xx2+3)=(A+2)^2-4(A+2)+3`
Where A is amplitude solving the above equation we get `A=2sqrt2m`.
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