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Transcript 
Inovace bakalářského
studijního oboru Aplikovaná
chemie
Reg. č.: CZ.1.07/2.2.00/15.0247
Introduction to Physical
Chemistry
Lecture 5
• Thermodynamics
– thermodynamic systems, processes
and states
– state variables
– mechanical work of gas
– adiabatic process
Lecture vocabulary:
mechanical work of gas
certain
region
universe
notional
delimiting
surroundings
environment
reservoir
experimentally accessible
internal energy
displace
force field
solely
mass flow
reversible x irreversible
sign
sign convention
expansion
compression
external
at the expense
work obtained
shaft work
cylinder
diminish
net
thermally insulated
heat exchange
steeper
denoted as
stoichiometric
equilibrium
intake
combustion
exhaust
mechanická práce plynu
určitý
oblast
vesmír
hypotetický , teoretický
vymezující
okolí
okolí, prostředí
rezervoár, tepelná lázeň
experimentálně dostupný
vnitřní energie
zaujmout místo
silové pole
výhradně, jedině
tok hmoty
vratný x nevratný
znaménko
znaménková konvence
expanze, rozpínání
komprese, stlačení
vnější
na účet, na úkor (čeho)
získaná práce
shaft=hřídel, jiné označení pro mechanickou práci plynu
válec
snížit se
celkový
tepelně izolovaný
výměna tepla
strmější
označován jako
stechiometrický
rovnováha
sání
spalování, hoření
výfuk
Thermodynamic systems, states and processes
•Thermodynamic
boundary
system
surroundings
system
is
a
certain
macroscopic region of universe
•Thermodynamic system is separated by real or
notional boundary delimiting the system volume
•The space outside the thermodynamic system is
known as the surroundings, the environment,
or a reservoir.
The state of the system is characterised by a set of
thermodynamic parameters the values of which are
experimentally accessible macroscopic properties, such as
volume, pressure, temperature, electric field etc.
System type
Open
Closed
Isolated
Mass flow
YES
NO
NO
Work
YES
YES
NO
Heat
YES
YES
NO
Processes:
Isobaric · Isochoric · Isothermal
Adiabatic · Isoentropic · Isoenthalpic
Quasistatic · Polytropic
Reversible vs. irreversible
State variables
State variables – those which are independent from pathway.
In a thermodynamic system, temperature, pressure, volume,
internal energy, enthalpy, and entropy are state variables.
For this lecture, internal energy of the gas is the most
important state variable
It is the energy needed to create the
system, but excludes the energy to
displace the system's surroundings, any
energy associated with a move as a
whole, or due to external force fields.
Internal
energy
has
two
major
components, kinetic energy and potential
energy.
For ideal gas, it depends solely on
temperature (but not on the volume
of the gas):
dU  nCV dT
Believe it for now, will be explained in the next lecture
Mechanical work of gas
W
Sign convention: work supplied to the
environment is negative (expansion) or
positive in the case of compression
dW   pdV
Work is done at the expense of the thermal
energy of the environment or the internal
energy of the gas (or both)
p
p
External pressure !!!
Work obtained
by expansion
p1
p1
Work required
for
compression
p2
V1
V2
V
p2
V1
V2
V
Processes during which shaft work is done can be divided into:
•irreversible
constant external pressure
•reversible
external pressure is always slightly lower than is the
pressure inside the cylinder
Mechanical work of gas – reversibility
As the number of steps increases, the overal process becomes less
irreversible; that is, the difference between the work done in expansion
and that required to re-compress the gas diminishes.
Isothermal process
p
W
p
nRT
V
p1
T is constant here
surroundings
(thermostatting bath)
p2
V1
 dW  pdV
V2
V2
V2
1
 W   pdV  nRT  dV
V
V1
V1
 W  nRT ln V 
V2
V1
 V2 
 p1 
 nRT ln    nRT ln  
 V1 
 p2 
V
Adiabatic process
Is a thermodynamic process in which there is no net heat transfer to or
from the working gas. Adiabatic process is said to occur when:
•the container of the system has thermally-insulated walls
or
•there is no opportunity for significant heat exchange (the process
occurs in a short time)
•can be reversible or irreversible
Reversible adiabatic process
dU   pexternaldV
ncV dT   pext dV
ncV
nRT  pV 
 nRdT  d  pV   Vdp  pdV
pdV  Vdp
  p ext dV
nR
For reversible process pext=p
and we can rearrange:
cp p

cV  R  dV
dp


p
cV
V
cV V
ln
After integration
we get Poisson eq.
p c p V1

 ln  pV   p1V1
p1 cV V
cp 

   
cV 

p
Adiabatic process
…valid as well,
but T is
changing
Adiabate is steeper than isotherm
p1
isotherms

nRT
p
V
p1V1
p 
V
p2'
p2
V1
V2
V
 1
TV  1  T1V1

T
T1
  1
 1
p
p1
Siméon Denis Poisson (1781-1840)
Adiabatic process
Work is done at the expense of the internal energy of gas. We
can calculate it if we know both initial and final temperatures:
T2
 W  U   nCv dT  nCv T2  T1 
T1
Alternatively, to calculate reversible work, we can integrate
the Poisson eq.:
 dW  pdV
V2
V2
1
 W   pdV  p1V1   dV
V
V1
V1
Real processes are something in
between isothermal and adiabatic,
they are denoted as polytropic

p1V1
W 
V2 1  V1 1
  1


Adiabatic flame temperature
the theoretical temperature of the combustion if no energy is lost to
the outside environment
T2
•Constant volume
H 
 i C p i ( prod .)dT
•Constant pressure
 
T1
the combustion of an organic
compound with n carbons
involves breaking roughly
2n C–H bonds,
n C–C
bonds, and
1.5n O2 bonds to form roughly
n CO2
molecules and
n H2O
molecules.
•AFT is maximum for stoichiometric fueloxidizer mixture
•asssumes equilibrium – AFT can be
exceeded in nonequilibrium conditions
i
Fuel
Acetylene (C2H2)
Acetylene (C2H2)
Butane (C4H10)
Cyanogen (C2N2)
Dicyanoacetylene (C4N2)
Ethane (C2H6)
Hydrogen (H2)
Hydrogen (H2)
Methane (CH4)
Natural gas
Propane (C3H8)
Propane (C3H8)
MAPP gas Methylacetylene (C3H4)
MAPP gas Methylacetylene (C3H4)
Wood
Kerosene
Light fuel oil
Medium fuel oil
Heavy fuel oil
Bituminous Coal
Anthracite
Anthracite
Oxidizer
air
Oxygen
air
Oxygen
Oxygen
air
air
Oxygen
air
air
air
Oxygen
air
Oxygen
air
air
air
air
air
air
air
Oxygen
Tad (°C)
2500
3480
1970
4525
4990
1955
2210
3200
1950
1960
1980
2526
2010
2927
1980
2093
2100
2100
2100
2170
2180
2900
Constant pressure adiabatic flame temp.
Internal combustion engine
Four-stroke cycle (Otto Cycle)
•Intake stroke
•Compression stroke.
•Combustion stroke
•Exhaust stroke
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