Download SYNOPSES: A gas, completely insulated from its surroundings

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Transcript
SYNOPSES:
A gas, completely insulated from its surroundings inside a closed rigid
container, with fixed values of pressure, volume, temperature, mass and
composition that do not change with time is in a state of thermodynamic
equilibrium.
Zeroth Law of Thermodynamics: ‘Two systems in thermal equilibrium
with a third system are in thermal equilibrium with each other.’
Temperature is the degree of the ‘hotness’ of a body, determining the
direction of flow of heat, when two bodies are placed in thermal contact.
Heat flows from the body at a higher temperature to the one at lower
temperature. The flow stops when the temperatures equalize, the two
bodies are then in thermal equilibrium.
The sum of kinetic energies and potential energies of the molecular
constituents of the system is known as internal energy.
Two modes of energy transfer:
(1) Heat: The energy transfer arising due to temperature difference
between the system and the surroundings.
(2) Work: The energy transfer such as moving the piston of a cylinder
containing the gas, by raising or lowering some weight
connected to it.
First Law of Thermodynamics: ‘The general law of conservation of
energy applied to any system in which energy transfers from or to the
surroundings’.
∆Q = ∆U + ∆W
where: ∆ Q is the heat supplied to the system.
∆ W is the work done by the system.
∆ U is the internal energy of the system.
Every equilibrium state of a thermodynamic system is completely
described by specific values of some macroscopic variables, also called state
variables.
Examples of State Variables:
(1) Pressure (P)
(2) Volume (V)
(3) Temperature (T)
(4) Mass (m).
Calorie is the amount of heat required to raise the temperature of 1 g of
water from 14.5 ° C to 15.5 ° C.
1 cal = 4.186 J.
The pressure-volume curve for a fixed temperature is called an isotherm.
Quasi–static process is an infinitely slow process such that the system
remains in thermal and mechanical equilibrium with the surroundings
throughout.
For an ideal gas, Isothermal expansion is from volume V1 to V2, at
temperature T, the heat absorbed (Q) equals the work done (W) by the gas:
V 
Q = W = µ RT ln  2  .
 V1 
If the system is insulated from the surroundings and no heat flows between
the system and the surroundings, the process is adiabatic.
Work done by an ideal gas in an adiabatic change of state from (P1,V1,T1) to
(P2,V2,T2) is:
W=
µ R(T1 - T2 )
.
r -1
Thermal expansion: The substances increase with increase in temperature
and decrease with decrease in temperature.
Isobaric Process: The process during which pressure of the system remains
constant.
Isochoric process: Volume of a system remains constant during this
process, no work is done during the process.
Isothermal Process: A thermodynamic process during which temperature
of a system remains constant.
Heat engine: A device in which a system undergoes a cyclic process
resulting in conversion of heat into work. The efficiency  of the engine is:
η=
Q
W
= 1- 2
Q1
Q1
where: Q1 is the heat absorbed from the source
Q2 is the heat released to the sink
W is the work output in one cycle.
A thermodynamic process in which system undergoes a series of processes,
starting from some thermodynamic equilibrium state, and finally the system
is brought back to its original state is known as cyclic process.
Kelvin – Planck statement: ‘No process is possible whose sole result is the
absorption of heat from a reservoir and complete conversion of the heat into
work.’
Clausius statement: ‘No process is possible whose sole result is the
transfer of heat from a colder object to a hotter object.’
Second Law of Thermodynamics implies that no heat engine can have
efficiency  equal to 1 or no refrigerator can have co-efficient of
performance α equal to infinity.
Reversible Process: Both the system and the surroundings return to their
original states, with no other change anywhere else in the universe.
Spontaneous processes: The idealized reversible process is a quasi–static
process with no dissipative factors such as friction, viscosity etc.
Isolated system: A system, which does not interact with surrounding.
Statement of Max Planck: ‘It is impossible to construct a heat engine
operating in a cycle that will extract heat from a reservoir and perform an
equivalent amount of work’.
Linear expansion: The increase in the length of a body with increase in
temperature.
Carnot engine: A reversible engine, operating between temperatures T1
(source) and T2 (sink). The Carnot cycle consists of two isothermal processes
connected by two adiabatic processes. The efficiency of a Carnot engine is :
η = 1-
T2
(Carnot engine)
T1
No engine operating between two temperatures can have efficiency greater
than that of the Carnot Engine.
(1) If Q > 0, heat is added to the system.
(2) If Q < 0, heat is removed to the system.
(3) If W > 0, work is done by the system.
(4) If W <0, work is done on the system.