Assertion: Between two thermodynamic states, the value of (Q-W) is constant for any process.
Reason: Q and W are path functions.

Assertion(A) : q is a state function. Reason(R ) : q is a path function.

q=-w is not true for :-

An ideal gas after going through a series of four thermodynamic states in order, reaches the initial state again (cyclic process). The amounts of heat (Q) and work (W) involved in the states are, Q_(1) = 6000J, Q_(2)= -5500 J, Q_(3)=-3000 J, Q_(4)=3500 J W_(1)=2500J, W_(2)=-1000 J, W_(3)=-1200 J, W_(4)=xxJ The ratio of net work done by the gas to the total heat absorbed by the gas in η. The value of x and eta are nearly :-

A: q and w are path function R: q + w is a state function

Assertion :- -q=-W for cyclic process. Reason :- Temperature remain constant during cyclic process.

Assertion: The graph between P and Q is straight line, when P//Q is constant. Reason: The straight line graph means that P proportional to Q or P is equal to constant multiplied by Q

Assertion: Work and internal energy are not state functions. Reason: The sum of q+w is a state function.

An ideal gas is subjected to cyclic process involving four thermodynamics thates, the amounts of heat (Q) and work (W) involved in each of these states. Q_1=6000J,Q_2=-5500J,Q_3=-3000J,Q_4=3500J W_1=2500J,W_2=-1000J,W_3=-1200J,W_4=xJ The ratio of the net work done by the gas to the total heat absorbed by the gas is eta . The values of x and eta respectively are

In changing the state of thermodynamics from A to B state, the heat required is Q and the work done by the system is W. The change in its internal energy is