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A constant fo...

Question

A constant force $F = \frac{m_{2} g}{2}$ is applied on the block of mass $m_{1}$ as shown in fig. The string and the pulley are light and the surface of the table is smooth. The acceleration of $m_{1}$ is

\frac{m_{2} g}{2 (m_{1} + m_{2})}

towards right

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\frac{m_{2} g}{2 (m_{1} - m_{2})}

towards left

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\frac{m_{2} g}{2 (m_{2} - m_{1})}

towards right

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\frac{m_{2} g}{2 (m_{2} - m_{1})}

towards left

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Solution

The correct option is A $\frac{m_{2} g}{2 (m_{1} + m_{2})}$ towards right
Let a be the acceleration of mass $m_{2}$ in the downward direction.
Then for $m_{1}$
$F_{n e t} = m a$
$T - m_{2} (\frac{g}{2}) = m_{1} a . . . . . (i)$

And for $m_{2}$
$F_{n e t} = m a$
and $m_{2} g - T = m_{2} a . . . . . (i i)$
Adding eqs. (1) and (2), we get
$(m_{1} + m_{2}) a = m_{2} g - m_{2} (\frac{g}{2}) = \frac{m_{2} g}{2}$
$∴ a = \frac{m_{2} g}{2 (m_{1} + m_{2})}$

Alter,
$a = \frac{net pulling force}{total mass} = \frac{m_{2} g - \frac{m_{2} g}{2}}{m_{1} + m_{2}}$
$∴ a = \frac{m_{2} g}{2 (m_{1} + m_{2})}$

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