laws of thermodynamics & thermal properties of matter · thermal properties of matter . 1 t=t...
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phase transitions and phase diagrams
diffusion, osmosis
Introduction to Physics I For Biologists, Geoscientists, & Pharmaceutical Scientists
Laws of thermodynamics & thermal properties of matter
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1
T=TH, const. (hot reservoir)
T=TC, const. (cold reservoir) 3
2
4
Reversible heat-work transformation Carnot cycle
Trautwein, Tipler
quasi-static, isothermal absorption of heat from a hot reservoir
quasi-static, adiabatic expansion to a lower temperature
quasi-static, isothermal release of heat to a cold reservoir
quasi-static, adiabatic compression back to the original state
1
3
2
4
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2nd law of thermodynamics
A process whose only net result is to absorb heat from a cold reservoir and release the same amount of heat to a hot reservoir is impossible.
Clausius statement
Tipler
It is impossible for a heat engine working in a cycle to produce only the effect of absorbing heat from a single reservoir and performing an equivalent amount of work.
Heat-Engine statement
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Laws of thermodynamics
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real gas law: van der Waals
Tipler
Van der Waals equation of state
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PV & PT phase diagrams
Uni Bristol
extended PV diagram PT diagram
melting curve
sublimation curve
vapour – pressure vs T curve
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phase transitions
Uni Bristol
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phase transitions… a general class of phenomenon
MIT, mathworld.wolfram
For instance, percolation: phenomenon of a liquid passing through a porous material. Below a certain critical porosity, the material would be unable to allow the liquid to pass - phase transition.
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phase transitions… more For instance, percolation: phenomenon of a liquid passing through a porous material. Below a certain critical porosity, the material would be unable to allow the liquid to pass - phase transition.
https://diracseashore.wordpress.com/2008/09/08/everyday-physics-coffee/
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phase transitions… more
MIT
The boiling of a liquid to a gas exhibits a decrease in order as the molecules are no longer bound and are only weakly interacting The freezing of a liquid to a solid exhibits an increase in order as the atoms occupy locations on a regular crystal lattice The alignment of liquid crystals shows an increase in directional order (although not necessarily spatial order) as the long liquid crystal molecules align and point in the same direction
Kato et al., Chem. Soc. Rev. 2017
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phase transitions… more
MIT
The boiling of a liquid to a gas exhibits a decrease in order as the molecules are no longer bound and are only weakly interacting The freezing of a liquid to a solid exhibits an increase in order as the atoms occupy locations on a regular crystal lattice The alignment of liquid crystals shows an increase in directional order (although not necessarily spatial order) as the long liquid crystal molecules align and point in the same direction The appearance of a permanent magnetic moment in a ferromagnet is an example of an increase in order as the individual magnetic spins point together in the same direction (Curie temperature) The segregation of block copolymers in a polymer melt demonstrates an increase in order as the individual monomer chains separate and aggregate The formation of a Bose Einstein Condensate demonstrates an increase in order as the wavefunctions of the individual atoms become coherent Superconductivity exhibits an increase in order as pairs of electrons (Cooper pairs) act coherently
Phase transitions occur in a variety of materials & systems Phase transition change in constituents' order (order parameter) Different phases variety of properties, technological applications
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entropy during phase transitions
chem.libretexts.org
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vapor pressure
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vapor pressure
Boiling point of water vs pressure
Tipler
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PV diagram
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PVT phase diagram
Uni Bristol
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phase diagrams
Uni Bristol
PV diagram PT diagram
supercritical fluid
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PT phase diagrams
water
NB: The pressure and temperature scales are not linear but are compressed to show the points of interest.
melting curve
sublimation curve
vapour – pressure vs T curve
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scale of things: down to the nanometer
10 cm
x 108
1 nm
7 Carbon atoms
C60
x 108
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surface vs bulk
Atome and der Oberfläche oder tief in Festkörper sind nicht "egal"
?
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at the nanoscale…, the surface becomes more important
1 atom ~ (0.1nm)x(0.1nm)x(0.1nm)
R (micro) ≈ 0.004 %
R (nano) ≈ 40% !
micro
atomsnbtotal
atomssurfacenbR
.
.
100 micrometers (mm)
10 m
m
nano
10 nanometers (nm)
1 n
m
Oberfläche/Volumen
important surface effects
e.g.: lower melting temperature, higher chemical reactivity
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example: melting temperature of nanoparticles
mc /
Lai et al., Phys. Rev. Lett. (1996)
Sn nanoparticles Au nanoparticles
Buffat et al., Phys. A (1976)
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phase diagram: mixing substances
melting curve
sublimation curve
vapour – pressure vs T curve
e.g.: salt in water
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diffusion
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osmosis
Biological physics, P. Nelson
osmotic flow
reverseosmosis
decrease of sugar concentration
increase of sugar solution & heat generation
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osmosis: electrical power generation
Radenovic et al., Nature (2016)
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osmosis: electrical power generation
Radenovic et al., Nature (2016)
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Merry Christmas and
a happy new year!
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Merry Christmas and
a happy new year!
Is the 2nd law of thermodynamics ("law of increasing entropy") driving the origin and evolution of life ? see the article by Natalie Wolchover, Scientific American, Jan. 28, 2014