A thin rod of length L and mass M is ben...

A thin rod of length `L` and mass `M` is bent at its midpoint into two halves so that the angle between them is `90^@`. The moment of inertia of the bent rod about an axis passing through the bending point and perpendicular to the plane defined by the two halves of the rod is.

`(ML^(2))/24`

`(ML^(2))/12`

`(ML^(2))/6`

`(sqrt(2)ML^(2))/24`

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Verified by Experts

The correct Answer is:

Since rod is bent at the middle , so each part of it will have same length `(L/2)` and msss `(M/2)` as shown .

The moment of inertia of each part through its one end =`1/3 (M/2)(L/2)^(2)` , Hence , net moment pof inrtia through its middle point O is
`I= 1/3 (M/2)(L/2)^(2)+1/3(M/2)(L/2)^(2)`
` =1/3 [(ML^(2))/8 + (ML^(2))/8] = (ML^(2))/12 `

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