A potential is given by V(x)=k(x+a)^2 / 2 for x < 0 and V(x)=k(x-a)^2 / 2 for x > 0. The schematic variation of oscillation

Q: A potential is given by $V(x)=k(x+a)^2 / 2$ for $x 0$. The schematic variation of oscillation period $T$ for a particle performing periodic motion in this potential as a function of its energy $E$ is

b (b) Given, potential function for the oscillating particle is $V(x)=\left\{\begin{array}{cl}k(x+a)^2, & x 0 \\ \end{array}\right.$ So, potential energy of the particle (mass $m)$ is $U(x)=\left\{\begin{array}{cc}\frac{k m(x+a)^2}{2}, & x 0\end{array}\right.$ If $\frac{d U}{d x}=0$, when $x=\pm a$ Now, $\frac{d^2 U}{d x^2}=k m > 0$ So, particle is in unstable equilibrium at $x=\pm a$. Hence, particle is unbounded for $-a > x$ and $x > a$. In region, $-a \leq x \leq a$, time period of particle reduces from a maximum. So, correct graph is $(b)$.

SECTION - A [PHYSICS - MCQ]

GSEB - English Medium

A potential is given by $V(x)=k(x+a)^2 / 2$ for $x < 0$ and $V(x)=k(x-a)^2 / 2$ for $x > 0$. The schematic variation of oscillation period $T$ for a particle performing periodic motion in this potential as a function of its energy $E$ is

KVPY 2018, Advanced

STD 11 Science
NEET
STD 11 - 13. oscillations
Physics

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