Examining the work done during an adiabatic process you can say q 0 so.
Adiabatic process heat capacity.
You could also keep some other value constant like p a v your way of defining heat capacity doesn t look right.
In an adiabatic process the gas changes temperature because the energy invested in work will go into the gas and has no time to escape.
The minus sign is in front of the w because the energy to do the work comes from the system itself so doing work results in a lower internal energy.
In thermal physics and thermodynamics the heat capacity ratio also known as the adiabatic index the ratio of specific heats or laplace s coefficient is the ratio of the heat capacity at constant pressure c p to heat capacity at constant volume c v it is sometimes also known as the isentropic expansion factor and is denoted by γ for an ideal gas or κ the isentropic exponent for a.
From dq 0 for the whole process doesn t follow anything about the gas heat capacity.
The first law of thermodynamics with q 0 shows that all the change in internal energy is in the form of work done.
The mathematical equation for an ideal gas undergoing a reversible i e no entropy generation adiabatic process can be represented by the polytropic process equation where p is pressure v is volume and for this case n γ where c p being the specific heat for constant pressure c v being the specific heat for constant volume γ is the adiabatic index and f is the number of.
This puts a constraint on the heat engine process leading to the adiabatic condition shown below.
Adiabatic process an adiabatic process is one in which no heat is gained or lost by the system.
This condition can be used to derive the expression for the work done during an.