148144 Work done in an isothermal change of a gas depends:

148145 Amount of work which can be obtained from 200 cal heat, will be

148148 If system $A$ is in thermal equilibrium with $B$ and $B$ is separately in thermal equilibrium with $C$, then $A$ and $C$ are in thermal equilibrium. From which thermodynamics law, does this follow?

148149 In a given process, for an ideal gas, $\Delta W=0$ and $\Delta Q \lt 0$. Then for the gas.

148162 Starting with the same initial conditions, and ideal gas expands form volume $V_{1}$ to $V_{2}$ in three different ways. The work done by the gas is $W_{1}$ if the process is purely isothermal $W_{2}$ if the process is purely adiabatic and $W_{3}$ if the process is purely isobaric then, choose the correct option.

148144 Work done in an isothermal change of a gas depends:

148145 Amount of work which can be obtained from 200 cal heat, will be

148148 If system $A$ is in thermal equilibrium with $B$ and $B$ is separately in thermal equilibrium with $C$, then $A$ and $C$ are in thermal equilibrium. From which thermodynamics law, does this follow?

148149 In a given process, for an ideal gas, $\Delta W=0$ and $\Delta Q \lt 0$. Then for the gas.

148162 Starting with the same initial conditions, and ideal gas expands form volume $V_{1}$ to $V_{2}$ in three different ways. The work done by the gas is $W_{1}$ if the process is purely isothermal $W_{2}$ if the process is purely adiabatic and $W_{3}$ if the process is purely isobaric then, choose the correct option.

148144 Work done in an isothermal change of a gas depends:

148145 Amount of work which can be obtained from 200 cal heat, will be

148148 If system $A$ is in thermal equilibrium with $B$ and $B$ is separately in thermal equilibrium with $C$, then $A$ and $C$ are in thermal equilibrium. From which thermodynamics law, does this follow?

148149 In a given process, for an ideal gas, $\Delta W=0$ and $\Delta Q \lt 0$. Then for the gas.

148162 Starting with the same initial conditions, and ideal gas expands form volume $V_{1}$ to $V_{2}$ in three different ways. The work done by the gas is $W_{1}$ if the process is purely isothermal $W_{2}$ if the process is purely adiabatic and $W_{3}$ if the process is purely isobaric then, choose the correct option.

148144 Work done in an isothermal change of a gas depends:

148145 Amount of work which can be obtained from 200 cal heat, will be

148148 If system $A$ is in thermal equilibrium with $B$ and $B$ is separately in thermal equilibrium with $C$, then $A$ and $C$ are in thermal equilibrium. From which thermodynamics law, does this follow?

148149 In a given process, for an ideal gas, $\Delta W=0$ and $\Delta Q \lt 0$. Then for the gas.

148162 Starting with the same initial conditions, and ideal gas expands form volume $V_{1}$ to $V_{2}$ in three different ways. The work done by the gas is $W_{1}$ if the process is purely isothermal $W_{2}$ if the process is purely adiabatic and $W_{3}$ if the process is purely isobaric then, choose the correct option.

148144 Work done in an isothermal change of a gas depends:

148145 Amount of work which can be obtained from 200 cal heat, will be

148148 If system $A$ is in thermal equilibrium with $B$ and $B$ is separately in thermal equilibrium with $C$, then $A$ and $C$ are in thermal equilibrium. From which thermodynamics law, does this follow?

148149 In a given process, for an ideal gas, $\Delta W=0$ and $\Delta Q \lt 0$. Then for the gas.

148162 Starting with the same initial conditions, and ideal gas expands form volume $V_{1}$ to $V_{2}$ in three different ways. The work done by the gas is $W_{1}$ if the process is purely isothermal $W_{2}$ if the process is purely adiabatic and $W_{3}$ if the process is purely isobaric then, choose the correct option.