355403 Negative of work done by the conservative forces on a system is equal to :

355404 Work done by a conservative force

355405 If \(W_{1}, W_{2}\) and \(W_{3}\) represent the work done in moving a particle from \(A\) to \(B\) along three different paths 1,2 and 3 respectively in the gravitational field of a point mass \(m\). Find the correct relation between \(W_{1}, W_{2}\) and \(W_{3}\).

355406 Statement A :
In the absence of nonconservative forces total mechanical energy is conserved.
Statement B :
Total energy of an isolated system remains constant.

355407 Assertion :
In case of conservative forces, the work done during a round trip is always zero.
Reason :
No force is required to move a body in its round trip in any situation.

355403 Negative of work done by the conservative forces on a system is equal to :

355404 Work done by a conservative force

355405 If \(W_{1}, W_{2}\) and \(W_{3}\) represent the work done in moving a particle from \(A\) to \(B\) along three different paths 1,2 and 3 respectively in the gravitational field of a point mass \(m\). Find the correct relation between \(W_{1}, W_{2}\) and \(W_{3}\).

355406 Statement A :
In the absence of nonconservative forces total mechanical energy is conserved.
Statement B :
Total energy of an isolated system remains constant.

355407 Assertion :
In case of conservative forces, the work done during a round trip is always zero.
Reason :
No force is required to move a body in its round trip in any situation.

355403 Negative of work done by the conservative forces on a system is equal to :

355404 Work done by a conservative force

355405 If \(W_{1}, W_{2}\) and \(W_{3}\) represent the work done in moving a particle from \(A\) to \(B\) along three different paths 1,2 and 3 respectively in the gravitational field of a point mass \(m\). Find the correct relation between \(W_{1}, W_{2}\) and \(W_{3}\).

355406 Statement A :
In the absence of nonconservative forces total mechanical energy is conserved.
Statement B :
Total energy of an isolated system remains constant.

355407 Assertion :
In case of conservative forces, the work done during a round trip is always zero.
Reason :
No force is required to move a body in its round trip in any situation.

355403 Negative of work done by the conservative forces on a system is equal to :

355404 Work done by a conservative force

355405 If \(W_{1}, W_{2}\) and \(W_{3}\) represent the work done in moving a particle from \(A\) to \(B\) along three different paths 1,2 and 3 respectively in the gravitational field of a point mass \(m\). Find the correct relation between \(W_{1}, W_{2}\) and \(W_{3}\).

355406 Statement A :
In the absence of nonconservative forces total mechanical energy is conserved.
Statement B :
Total energy of an isolated system remains constant.

355407 Assertion :
In case of conservative forces, the work done during a round trip is always zero.
Reason :
No force is required to move a body in its round trip in any situation.

355403 Negative of work done by the conservative forces on a system is equal to :

355404 Work done by a conservative force

355405 If \(W_{1}, W_{2}\) and \(W_{3}\) represent the work done in moving a particle from \(A\) to \(B\) along three different paths 1,2 and 3 respectively in the gravitational field of a point mass \(m\). Find the correct relation between \(W_{1}, W_{2}\) and \(W_{3}\).

355406 Statement A :
In the absence of nonconservative forces total mechanical energy is conserved.
Statement B :
Total energy of an isolated system remains constant.

355407 Assertion :
In case of conservative forces, the work done during a round trip is always zero.
Reason :
No force is required to move a body in its round trip in any situation.