Peoperty which is independent of mass of System are
a:intensive
b:enitensive
c:State function
d:adiabatic
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Select correct statement(s) among the following.
Missing: adiabatic | Must include: adiabatic
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The statements A, B and D are correct.(A) Change in state function between two states is a definite quantity and does not depend on the path.Thus, the ... More
Answer:
independent of mass of System are The properties like volume, which depend on the size of the system are called extensive properties. The properties, like temperature and pressure which are independent of the mass of the system are called intensive properties.
intensive The ratio between two extensive properties is an intensive property. For example, mass and volume are extensive properties, but their ratio (density) is an intensive property of matter.
extensive. extensive properties such as the mass, volume and entropy of systems are additive for subsystems.[3]
state functions
In the thermodynamics of equilibrium, a state function, function of state, or point function is a function defined for a system relating several state variables or state quantities that depends only on the current equilibrium thermodynamic state of the system[1] (e.g. gas, liquid, solid, crystal, or emulsion), not the path which the system took to reach its present state. A state function describes the equilibrium state of a system, thus also describing the type of system. For example, a state function could describe an atom or molecule in a gaseous, liquid, or solid form; a heterogeneous or homogeneous mixture; and the amounts of energy required to create such systems or change them into a different equilibrium state.
adiabatic
adiabatic process is a type of thermodynamic process which occurs without transferring heat or mass between the system and its surroundings. Unlike an isothermal process, an adiabatic process transfers energy to the surroundings only as work.[1][2] It also conceptually supports the theory used to explain the first law of thermodynamics and is therefore a key thermodynamic concept.
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