Thermodynamics 101 Aiko Huckauf Preface Introduction What’s it all about? Classical Thermodynamics Statistical Thermodynamics Fundamental Laws 0. Thermodynamic Equilibrium 1. Conservation of Energy 2. Increase of Entropy 3. Zero Temperature Ecosystem Relevance Closing Remark References Thermodynamics 101 Presentation given in the course of the Master’s Programme Environmental Management – Module 2.1.1 “Ecosystem Analysis” – Aiko Huckauf Ecology Centre Kiel 2006-05-24
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Thermodynamics 101
Aiko Huckauf
Preface
IntroductionWhat’s it all about?
Classical Thermodynamics
Statistical Thermodynamics
Fundamental Laws0. Thermodynamic Equilibrium
1. Conservation of Energy
2. Increase of Entropy
3. Zero Temperature
Ecosystem Relevance
Closing Remark
References
Thermodynamics 101Presentation given in the course of the
Master’s Programme Environmental Management– Module 2.1.1 “Ecosystem Analysis” –
Aiko Huckauf
Ecology Centre Kiel
2006-05-24
Thermodynamics 101
Aiko Huckauf
Preface
IntroductionWhat’s it all about?
Classical Thermodynamics
Statistical Thermodynamics
Fundamental Laws0. Thermodynamic Equilibrium
1. Conservation of Energy
2. Increase of Entropy
3. Zero Temperature
Ecosystem Relevance
Closing Remark
References
Preface
Thermodynamics is a terrible game:
0. You have to play.
1. You cannot win.
2. You cannot break even—except on a very cold day.
3. It does not get that cold.
Thermodynamics 101
Aiko Huckauf
Preface
IntroductionWhat’s it all about?
Classical Thermodynamics
Statistical Thermodynamics
Fundamental Laws0. Thermodynamic Equilibrium
1. Conservation of Energy
2. Increase of Entropy
3. Zero Temperature
Ecosystem Relevance
Closing Remark
References
Preface
Thermodynamics is a terrible game:
0. You have to play.
1. You cannot win.
2. You cannot break even—except on a very cold day.
3. It does not get that cold.
Thermodynamics 101
Aiko Huckauf
Preface
IntroductionWhat’s it all about?
Classical Thermodynamics
Statistical Thermodynamics
Fundamental Laws0. Thermodynamic Equilibrium
1. Conservation of Energy
2. Increase of Entropy
3. Zero Temperature
Ecosystem Relevance
Closing Remark
References
IntroductionWhat’s it all about?
There are two different approaches to thermodynamics:
Classical Thermodynamics is the branch ofphysics concerned with the conversion ofdifferent forms of energy.
Statistical thermodynamics is the branch ofphysics that describes the thermodynamicbehavior of macroscopic systems on basis ofthe properties of their molecular constituents.
Thermodynamics 101
Aiko Huckauf
Preface
IntroductionWhat’s it all about?
Classical Thermodynamics
Statistical Thermodynamics
Fundamental Laws0. Thermodynamic Equilibrium
1. Conservation of Energy
2. Increase of Entropy
3. Zero Temperature
Ecosystem Relevance
Closing Remark
References
IntroductionClassical Thermodynamics: How does it work?
As a phenomenological theory, it deals withI macroscopic objects (which contain a large
number of particles) and theirI macroscopic properties (state variables like mass,
volume, pressure, temperature, energy, entropy,and enthalpy)
I that can be observed and measured in experimentsI from which one can abstract and set up axioms
based on the empirical findings (phenomenology).
Thermodynamics 101
Aiko Huckauf
Preface
IntroductionWhat’s it all about?
Classical Thermodynamics
Statistical Thermodynamics
Fundamental Laws0. Thermodynamic Equilibrium
1. Conservation of Energy
2. Increase of Entropy
3. Zero Temperature
Ecosystem Relevance
Closing Remark
References
IntroductionClassical Thermodynamics: How does it work?
As a phenomenological theory, it deals withI macroscopic objects (which contain a large
number of particles) and theirI macroscopic properties (state variables like mass,
volume, pressure, temperature, energy, entropy,and enthalpy)
I that can be observed and measured in experimentsI from which one can abstract and set up axioms
based on the empirical findings (phenomenology).
Thermodynamics 101
Aiko Huckauf
Preface
IntroductionWhat’s it all about?
Classical Thermodynamics
Statistical Thermodynamics
Fundamental Laws0. Thermodynamic Equilibrium
1. Conservation of Energy
2. Increase of Entropy
3. Zero Temperature
Ecosystem Relevance
Closing Remark
References
IntroductionClassical Thermodynamics: What is it good for?
At its origins, during theIndustrial Revolution,thermodynamics wasconcerned with (steam)engines and their efficiency.
Thermodynamics 101
Aiko Huckauf
Preface
IntroductionWhat’s it all about?
Classical Thermodynamics
Statistical Thermodynamics
Fundamental Laws0. Thermodynamic Equilibrium
1. Conservation of Energy
2. Increase of Entropy
3. Zero Temperature
Ecosystem Relevance
Closing Remark
References
IntroductionClassical Thermodynamics: Its Fathers
Sadi Carnot’s Reflections on the Motive Power ofFire (1824) analyse the efficiency of steam enginesand mark the start of thermodynamics as a modern
science.
William Thomson (1st Baron Kelvin aka LordKelvin) invents the absolute temperature scale in1848 and coins the term “thermodynamics” in1849.
Rudolf Clausius’ Über die bewegende Kraft derWärme (1850) serves as a milestone of
thermodynamics. Clausius specifies the second lawidea of Carnot and later, in 1865, introduces the
macroscopic concept of entropy.
Thermodynamics 101
Aiko Huckauf
Preface
IntroductionWhat’s it all about?
Classical Thermodynamics
Statistical Thermodynamics
Fundamental Laws0. Thermodynamic Equilibrium
1. Conservation of Energy
2. Increase of Entropy
3. Zero Temperature
Ecosystem Relevance
Closing Remark
References
IntroductionClassical Thermodynamics: What Are Its Limits?
Problems with classical thermodynamics:I Many questions remain open:
I Why do all gases behave similarly?I Can temperature be negative?I What is this entropy thing, by the way?
I All constants and parameters have to be derivedfrom experiments. We have no clue about theirpossible values.
I It provides no information about the states or eventhe existence of molecules.
I It has only weak if any predictive power: We canbuild a refrigerator, but we cannot design a propercooling fluid for it—we can only choose from thosewe know.
Thermodynamics 101
Aiko Huckauf
Preface
IntroductionWhat’s it all about?
Classical Thermodynamics
Statistical Thermodynamics
Fundamental Laws0. Thermodynamic Equilibrium
1. Conservation of Energy
2. Increase of Entropy
3. Zero Temperature
Ecosystem Relevance
Closing Remark
References
IntroductionClassical Thermodynamics: What Are Its Limits?
Problems with classical thermodynamics:I Many questions remain open:
I Why do all gases behave similarly?I Can temperature be negative?I What is this entropy thing, by the way?
I All constants and parameters have to be derivedfrom experiments. We have no clue about theirpossible values.
I It provides no information about the states or eventhe existence of molecules.
I It has only weak if any predictive power: We canbuild a refrigerator, but we cannot design a propercooling fluid for it—we can only choose from thosewe know.
Thermodynamics 101
Aiko Huckauf
Preface
IntroductionWhat’s it all about?
Classical Thermodynamics
Statistical Thermodynamics
Fundamental Laws0. Thermodynamic Equilibrium
1. Conservation of Energy
2. Increase of Entropy
3. Zero Temperature
Ecosystem Relevance
Closing Remark
References
IntroductionStatistical Thermodynamics in a Nutshell
The statistical approach is a first principle theory thatI derives macroscopic properties (state variables and
functions)I from the constituent particles and the interactions
between themI by connecting thermodynamic functions to
atomistic phenomena (including quantummechanics).
It thusI gives thermodynamics a molecular interpretation
andI serves as a bridge between macroscopic and
microscopic system properties.
Thermodynamics 101
Aiko Huckauf
Preface
IntroductionWhat’s it all about?
Classical Thermodynamics
Statistical Thermodynamics
Fundamental Laws0. Thermodynamic Equilibrium
1. Conservation of Energy
2. Increase of Entropy
3. Zero Temperature
Ecosystem Relevance
Closing Remark
References
IntroductionStatistical Thermodynamics in a Nutshell
The statistical approach is a first principle theory thatI derives macroscopic properties (state variables and
functions)I from the constituent particles and the interactions
between themI by connecting thermodynamic functions to
atomistic phenomena (including quantummechanics).
It thusI gives thermodynamics a molecular interpretation
andI serves as a bridge between macroscopic and
microscopic system properties.
Thermodynamics 101
Aiko Huckauf
Preface
IntroductionWhat’s it all about?
Classical Thermodynamics
Statistical Thermodynamics
Fundamental Laws0. Thermodynamic Equilibrium
1. Conservation of Energy
2. Increase of Entropy
3. Zero Temperature
Ecosystem Relevance
Closing Remark
References
IntroductionStatistical Thermodynamics in a Nutshell
The statistical approach is a first principle theory thatI derives macroscopic properties (state variables and
functions)I from the constituent particles and the interactions
between themI by connecting thermodynamic functions to
atomistic phenomena (including quantummechanics).
It thusI gives thermodynamics a molecular interpretation
andI serves as a bridge between macroscopic and
microscopic system properties.
Thermodynamics 101
Aiko Huckauf
Preface
IntroductionWhat’s it all about?
Classical Thermodynamics
Statistical Thermodynamics
Fundamental Laws0. Thermodynamic Equilibrium
1. Conservation of Energy
2. Increase of Entropy
3. Zero Temperature
Ecosystem Relevance
Closing Remark
References
IntroductionStatistical Thermodynamics in a Nutshell
The statistical approach is a first principle theory thatI derives macroscopic properties (state variables and
functions)I from the constituent particles and the interactions
between themI by connecting thermodynamic functions to
atomistic phenomena (including quantummechanics).
It thusI gives thermodynamics a molecular interpretation
andI serves as a bridge between macroscopic and
microscopic system properties.
Thermodynamics 101
Aiko Huckauf
Preface
IntroductionWhat’s it all about?
Classical Thermodynamics
Statistical Thermodynamics
Fundamental Laws0. Thermodynamic Equilibrium
1. Conservation of Energy
2. Increase of Entropy
3. Zero Temperature
Ecosystem Relevance
Closing Remark
References
IntroductionStatistical Thermodynamics: Its Fathers
James Clerk Maxwell describes the velocitydistribution of molecules in 1860, laying the
foundation for what is nowadays known as“Maxwell-Boltzmann kinetic theory of
gases”.
In 1877, Ludwig Boltzmann shows thelogarithmic connection between entropy andprobability—which is still the best definitionof entropy we have.
Thermodynamics 101
Aiko Huckauf
Preface
IntroductionWhat’s it all about?
Classical Thermodynamics
Statistical Thermodynamics
Fundamental Laws0. Thermodynamic Equilibrium
1. Conservation of Energy
2. Increase of Entropy
3. Zero Temperature
Ecosystem Relevance
Closing Remark
References
The Fundamental Laws of ThermodynamicsPreliminary Remark
Classical thermodynamics is, like plane geometry, basedon axioms and postulates.Only, in thermodynamics these are called laws.
Thermodynamics 101
Aiko Huckauf
Preface
IntroductionWhat’s it all about?
Classical Thermodynamics
Statistical Thermodynamics
Fundamental Laws0. Thermodynamic Equilibrium
1. Conservation of Energy
2. Increase of Entropy
3. Zero Temperature
Ecosystem Relevance
Closing Remark
References
The Fundamental Laws of ThermodynamicsZeroth Law: Thermodynamic Equilibrium
When two systems are each in thermalequilibrium with a third, they are in thermalequilibrium with each other.
I “Thermal equilibrium” means: The temperature gradientbetween the two systems is zero, i. e. both systems are at thesame temperature.
Thermodynamics 101
Aiko Huckauf
Preface
IntroductionWhat’s it all about?
Classical Thermodynamics
Statistical Thermodynamics
Fundamental Laws0. Thermodynamic Equilibrium
1. Conservation of Energy
2. Increase of Entropy
3. Zero Temperature
Ecosystem Relevance
Closing Remark
References
The Fundamental Laws of ThermodynamicsZeroth Law: Thermodynamic Equilibrium
When two systems are each in thermalequilibrium with a third, they are in thermalequilibrium with each other.
I “Thermal equilibrium” means: The temperature gradientbetween the two systems is zero, i. e. both systems are at thesame temperature.
Thermodynamics 101
Aiko Huckauf
Preface
IntroductionWhat’s it all about?
Classical Thermodynamics
Statistical Thermodynamics
Fundamental Laws0. Thermodynamic Equilibrium
1. Conservation of Energy
2. Increase of Entropy
3. Zero Temperature
Ecosystem Relevance
Closing Remark
References
The Fundamental Laws of ThermodynamicsFirst Law: Conservation of Energy
Energy (and hence matter) can neither becreated nor destroyed.
I Energy can be transferred from one system to another.
I Energy can be transformed from one manifestation intoanother: chemical, mechanical, thermal, electrical,gravitational potential energy etc.
I The internal energy of an isolated system is constant: dU = 0.
I The internal energy of a closed system can only be changedthrough heat transfer or work: dU = δq + δw.
Thermodynamics 101
Aiko Huckauf
Preface
IntroductionWhat’s it all about?
Classical Thermodynamics
Statistical Thermodynamics
Fundamental Laws0. Thermodynamic Equilibrium
1. Conservation of Energy
2. Increase of Entropy
3. Zero Temperature
Ecosystem Relevance
Closing Remark
References
The Fundamental Laws of ThermodynamicsFirst Law: Conservation of Energy
Energy (and hence matter) can neither becreated nor destroyed.
I Energy can be transferred from one system to another.
I Energy can be transformed from one manifestation intoanother: chemical, mechanical, thermal, electrical,gravitational potential energy etc.
I The internal energy of an isolated system is constant: dU = 0.
I The internal energy of a closed system can only be changedthrough heat transfer or work: dU = δq + δw.
Thermodynamics 101
Aiko Huckauf
Preface
IntroductionWhat’s it all about?
Classical Thermodynamics
Statistical Thermodynamics
Fundamental Laws0. Thermodynamic Equilibrium
1. Conservation of Energy
2. Increase of Entropy
3. Zero Temperature
Ecosystem Relevance
Closing Remark
References
The Fundamental Laws of ThermodynamicsSecond Law: Increase of Entropy
The total entropy change (system +surroundings) is always greater than or equalto zero for any change of state of the system:∆S > 0.
I The entropy of an isolated system never decreases.
I Heat does not spontaneously flow from colder into warmersystems (but always in the opposite direction).
I Energy of all types spontaneously flows from being localised orconcentrated to becoming more dispersed or spread out, if it isnot hindered.
I There are as many variations of the second law as there arethermodynamicists.
Thermodynamics 101
Aiko Huckauf
Preface
IntroductionWhat’s it all about?
Classical Thermodynamics
Statistical Thermodynamics
Fundamental Laws0. Thermodynamic Equilibrium
1. Conservation of Energy
2. Increase of Entropy
3. Zero Temperature
Ecosystem Relevance
Closing Remark
References
The Fundamental Laws of ThermodynamicsSecond Law: Increase of Entropy
The total entropy change (system +surroundings) is always greater than or equalto zero for any change of state of the system:∆S > 0.
I The entropy of an isolated system never decreases.
I Heat does not spontaneously flow from colder into warmersystems (but always in the opposite direction).
I Energy of all types spontaneously flows from being localised orconcentrated to becoming more dispersed or spread out, if it isnot hindered.
I There are as many variations of the second law as there arethermodynamicists.
Thermodynamics 101
Aiko Huckauf
Preface
IntroductionWhat’s it all about?
Classical Thermodynamics
Statistical Thermodynamics
Fundamental Laws0. Thermodynamic Equilibrium
1. Conservation of Energy
2. Increase of Entropy
3. Zero Temperature
Ecosystem Relevance
Closing Remark
References
The Fundamental Laws of ThermodynamicsWhat Is Entropy Anyway?
Classically, entropy measures the spontaneous dispersalof energy: how much energy is spread out in a process(and cannot be used to do thermodynamic work), orhow widely spread out it becomes—at a specifictemperature: dS > δq/T.
Statistically, it measures the amount of uncertainty thatwould remain about the exact microscopic state of thesystem, given a description of its macroscopic properties:S = −k
∑i Pi ln(Pi), where k is the Boltzmann constant
and Pi the probability of the ith microstate to beoccupied).
I Entropy is not disorder or a measure thereof. Rearranging objects doesnot change their entropy.
I Classical entropy is always connected with energy in general, andspecifically with energy that is being or has been dispersed.
I Statistical entropy is not defined in terms of energy (nor vice versa),but in terms of probability spread out in state-space.
Thermodynamics 101
Aiko Huckauf
Preface
IntroductionWhat’s it all about?
Classical Thermodynamics
Statistical Thermodynamics
Fundamental Laws0. Thermodynamic Equilibrium
1. Conservation of Energy
2. Increase of Entropy
3. Zero Temperature
Ecosystem Relevance
Closing Remark
References
The Fundamental Laws of ThermodynamicsWhat Is Entropy Anyway?
Classically, entropy measures the spontaneous dispersalof energy: how much energy is spread out in a process(and cannot be used to do thermodynamic work), orhow widely spread out it becomes—at a specifictemperature: dS > δq/T.
Statistically, it measures the amount of uncertainty thatwould remain about the exact microscopic state of thesystem, given a description of its macroscopic properties:S = −k
∑i Pi ln(Pi), where k is the Boltzmann constant
and Pi the probability of the ith microstate to beoccupied).
I Entropy is not disorder or a measure thereof. Rearranging objects doesnot change their entropy.
I Classical entropy is always connected with energy in general, andspecifically with energy that is being or has been dispersed.
I Statistical entropy is not defined in terms of energy (nor vice versa),but in terms of probability spread out in state-space.
Thermodynamics 101
Aiko Huckauf
Preface
IntroductionWhat’s it all about?
Classical Thermodynamics
Statistical Thermodynamics
Fundamental Laws0. Thermodynamic Equilibrium
1. Conservation of Energy
2. Increase of Entropy
3. Zero Temperature
Ecosystem Relevance
Closing Remark
References
The Fundamental Laws of ThermodynamicsThird Law: Zero Temperature
Absolute zero cannot be reached by anyprocedure in a finite number of steps.
I All processes cease as temperature approaches zero.
I As temperature approaches zero, so does the entropy.
Thermodynamics 101
Aiko Huckauf
Preface
IntroductionWhat’s it all about?
Classical Thermodynamics
Statistical Thermodynamics
Fundamental Laws0. Thermodynamic Equilibrium
1. Conservation of Energy
2. Increase of Entropy
3. Zero Temperature
Ecosystem Relevance
Closing Remark
References
The Fundamental Laws of ThermodynamicsThird Law: Zero Temperature
Absolute zero cannot be reached by anyprocedure in a finite number of steps.
I All processes cease as temperature approaches zero.
I As temperature approaches zero, so does the entropy.
Thermodynamics 101
Aiko Huckauf
Preface
IntroductionWhat’s it all about?
Classical Thermodynamics
Statistical Thermodynamics
Fundamental Laws0. Thermodynamic Equilibrium
1. Conservation of Energy
2. Increase of Entropy
3. Zero Temperature
Ecosystem Relevance
Closing Remark
References
Ecosystem RelevanceWhy Bother?
Based on the macroscopic flow of energy (and matter),thermodynamics is considered to be well suited todescribe ecosystems from an holistic point of view.
Ecosystem Thermodynamics will be the subject of thesecond part of this presentation, to be given on2006-07-05.
Thermodynamics 101
Aiko Huckauf
Preface
IntroductionWhat’s it all about?
Classical Thermodynamics
Statistical Thermodynamics
Fundamental Laws0. Thermodynamic Equilibrium
1. Conservation of Energy
2. Increase of Entropy
3. Zero Temperature
Ecosystem Relevance
Closing Remark
References
“Thermodynamics is a funny subject. The firsttime you go through it, you don’t understand itat all. The second time you go through it, youthink you understand it, except for one or twosmall points. The third time you go through it,you know you don’t understand it, but by thattime you are so used to it, it doesn’t botheryou any more.”Ascribed to Arnold Sommerfeld (Germanphysicist and teacher, 1868–1951)
Thank you for your attention!
Thermodynamics 101
Aiko Huckauf
Preface
IntroductionWhat’s it all about?
Classical Thermodynamics
Statistical Thermodynamics
Fundamental Laws0. Thermodynamic Equilibrium
1. Conservation of Energy
2. Increase of Entropy
3. Zero Temperature
Ecosystem Relevance
Closing Remark
References
ReferencesFor Further Reading. . .
I Sven Erik Jørgensen and Felix Müller (Ed.): Handbook ofEcosystem Theories and Management. CRC Press, BocaRaton, 2000.
I Sven Erik Jørgensen: Integration of Ecosystem Theories:A Pattern. Kluwer Academic Publishers, Dordrecht,1992.
I Folke Günthe: The Laws of Thermodynamics. Availableonline at http://www.holon.se/folke/kurs/Distans/Ekofys/fysbas/LOT/LOT.shtml.
I David Watson: Energy Concepts for Educators andStudents. Available online athttp://www.ftexploring.com/energy/energy.html.
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