Assertion (A) is false because the moment of inertia about an axis passing through the center of mass is the minimum, not maximum, for parallel axes (\(I = I_{CM} + Md^2\)).

Reason (R) is false because the parallel axis theorem is applicable to any rigid body, not just 2D bodies of negligible thickness.

Assertion (A) is true; by conservation of angular momentum \(L = I\omega\), if the radius halves, moment of inertia (\(I \propto R^2\)) becomes one-fourth. Thus, angular velocity (\(omega\)) becomes four times, making day length \(24/4 = 6\text{ hours}\).

Reason (R) is true and explains A; moment of inertia depends on mass distribution and size.

In pure rolling, the point of contact is the instantaneous center of rotation. The velocity of any point on the rigid body is given by \(v = r\omega\) where \(r\) is its distance from the ICOR. Pure rolling is essentially rotation about the ICOR.

Assertion (A) is true: For pure rolling, the point of contact velocity is zero, and friction provides the necessary torque.

Reason (R) is false: For a disc rolling without slipping down an inclined plane, friction is present and acts up the incline to provide the torque for rotation. Thus, (A) is true, (R) is false.

Assertion (A) is true: Torque \(\tau = rF\sin\theta\) requires a larger force \(F\) for a smaller lever arm \(r\) (near the hinge). Reason (R) is false: Torque is zero at the hinge (pivot point) as \(r=0\). Thus, (A) is true, (R) is false.

Assertion (A) is true: If no external torque acts, angular momentum \(L\) is conserved. If moment of inertia \(I\) changes, angular velocity \(\omega\) adjusts to keep \(L = I\omega\) constant.

Reason (R) is false: Angular momentum \(L = I\omega\) explicitly depends on the moment of inertia \(I\). Thus, (A) is true, (R) is false.

Assertion (A) is true: Friction acts to prevent slipping, which can be forward or backward depending on the situation (e.g., accelerating or braking).

Reason (R) is true: Angular momentum is conserved when the net external torque (and thus angular impulse) about the point is zero. Both statements are true, but R does not explain A.

Assertion (A) is true: Friction provides the necessary torque to initiate the angular acceleration required for rolling.

Reason (R) is true: In pure rolling, the point of contact is instantaneously at rest, so the work done by static friction is zero. Both statements are true, but R does not explain A.

Assertion (A) is true: If two axes have the same moment of inertia, they must be equidistant from the center of mass. It is possible for them to also be equidistant from the geometrical center (e.g., if the CM coincides with the geometrical center).

Reason (R) is true: The parallel axis theorem states \(I = I_{cm} + md^2\), so if two parallel axes are at the same distance \(d\) from the CM, their moments of inertia will be equal. Both statements are true, but R does not directly explain A.

Assertion (A) is true: A ballet dancer changes her moment of inertia \(I\) by adjusting her body posture. Reason (R) is true: Angular momentum \(L = I\omega\) is conserved in the absence of external torque. Therefore, as \(I\) changes, \(\omega\) must change inversely to keep \(L\) constant. R is the correct explanation of A.