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Saturday 6 August 2011

Physics GRE - #5

Two equal masses $m_1=m_2=m$ are connected by a spring having Hooke's constant k. If the equilibrium separation is $l_0$ and the spring rests on a frictionless horizontal surface, then the angular frequency $\omega_0$ is:


  • $\sqrt{\frac{k}{m}}$
  • $\sqrt{\frac{2k}{m}}$
  • $\sqrt{\frac{3k}{m}}$
  • $2\sqrt{\frac{k}{m}}$
  • $\sqrt{\frac{g}{l_0}}$

Solution :

Let the length of the stretched spring be $x=x_1-x_2$. From Hooke's Law we know that: \[m\ddot{x_{1}}=-k(x-l_0)\] \[m\ddot{x_{2}}=-k(x-l_0)\] Subtracting the two equations above, we obtain: \[m(\ddot{x_{1}}-\ddot{x_{2}})=m\ddot{x}=-\frac{2k}{m}x\] Thus the solution is: \[\omega_{0}^{2}=\frac{2k}{m}\implies\omega_{0}=\sqrt{\frac{2k}{m}}\]

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