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Introduction to (Statistical) Thermodynamics

Introduction to (Statistical) Thermodynamics. Molecular Simulations. MD. Molecular dynamics: solve equations of motion Monte Carlo: importance sampling. r 1. r 2. r n. MC. r 1. r 2. r n. Questions. What is the desired distribution?.

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Introduction to (Statistical) Thermodynamics

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  1. Introduction to (Statistical) Thermodynamics

  2. Molecular Simulations MD • Molecular dynamics: solve equations of motion • Monte Carlo: importance sampling r1 r2 rn MC r1 r2 rn

  3. Questions What is the desired distribution? • How can we prove that this scheme generates the desired distribution of configurations? • Why make a random selection of the particle to be displaced? • Why do we need to take the old configuration again? • How large should we take: delx?

  4. Summary Thermodynamics • First law: conservation of energy • Second law: in a closed system entropy increase and takes its maximum value at equilibrium System at constant temperature and volume • Helmholtz free energy decrease and takes its minimum value at equilibrium Equilibrium: • Equal temperature, pressure, and chemical potential

  5. E,V or Temperature Entropy • Closed system: • 1st law: total energy remains constant • 2nd law: entropy increases

  6. Pressure: Energy: Chemical potential: Helmholtz free energy

  7. Statistical Thermodynamics System of N molecules: But how do we obtain the macroscopic properties of this system from this microscopic information?

  8. Outline (2) Statistical Thermodynamics • Basic Assumption • micro-canonical ensemble • relation to thermodynamics • Canonical ensemble • free energy • thermodynamic properties • Other ensembles • constant pressure • grand-canonical ensemble

  9. Statistical Thermodynamics:the basics • Nature is quantum-mechanical • Consequence: • Systems have discrete quantum states. • For finite “closed” systems, the number of states is finite (but usually very large) • Hypothesis: In a closed system, every state is equally likely to be observed. • Consequence: ALL of equilibrium Statistical Mechanics and Thermodynamics

  10. …, but there are not many microstates that give these extreme results Each individual microstate is equally probable Basic assumption If the number of particles is large (>10) these functions are sharply peaked

  11. Does the basis assumption lead to something that is consistent with classical thermodynamics? Systems 1 and 2 are weakly coupled such that they can exchange energy. What will be E1? BA: each configuration is equally probable; but the number of states that give an energy E1 is not know.

  12. Energy is conserved! dE1=-dE2 This can be seen as an equilibrium condition

  13. Entropy and number of configurations Conjecture: • Almost right. • Good features: • Extensivity • Third law of thermodynamics comes for free • Bad feature: • It assumes that entropy is dimensionless but (for unfortunate, historical reasons, it is not…)

  14. We have to live with the past, therefore With kB= 1.380662 10-23 J/K In thermodynamics, the absolute (Kelvin) temperature scale was defined such that But we found (defined):

  15. And this gives the “statistical” definition of temperature: In short: Entropy and temperature are both related to the fact that we can COUNT states. • Basic assumption: • leads to an equilibrium condition: equal temperatures • leads to a maximum of entropy • leads to the third law of thermodynamics

  16. Number of configurations • How large is ? • For macroscopic systems, super-astronomically large. • For instance, for a glass of water at room temperature: • Macroscopic deviations from the second law of thermodynamics are not forbidden, but they are extremely unlikely.

  17. Canonical ensemble 1/kBT Consider a small system that can exchange heat with a big reservoir Hence, the probability to find Ei: Boltzmann distribution

  18. Thermo recall (2) First law of thermodynamics Helmholtz Free energy: Thermodynamics What is the average energy of the system? Compare: Hence:

  19. Volume of phase space (particle in a box) Particles are indistinguishable Remarks (1) We have assume quantum mechanics (discrete states) but we are interested in the classical limit Integration over the momenta can be carried out for most systems:

  20. Remarks (2) Define de Broglie wave length: Partition function:

  21. Thermo recall (3) Helmholtz Free energy: Pressure Energy: Example: ideal gas Free energy: Pressure: Energy:

  22. Chemical potential: Ideal gas (2)

  23. Summary:Canonical ensemble (N,V,T) Partition function: Probability to find a particular configuration Free energy

  24. Summary:micro-canonical ensemble (N,V,E) Partition function: Probability to find a particular configuration Free energy

  25. Probability to find a configuration: Thermodynamic properties Ensemble average: For many properties the momenta do not matter: only the configurational part

  26. Other ensembles? COURSE: MD and MC different ensembles In the thermodynamic limit the thermodynamic properties are independent of the ensemble: so buy a bigger computer … However, it is most of the times much better to think and to carefully select an appropriate ensemble. For this it is important to know how to simulate in the various ensembles. But for doing this wee need to know the Statistical Thermodynamics of the various ensembles.

  27. Measure the composition of the coexisting vapour and liquid phases if we start with a homogeneous liquid of two different compositions: How to mimic this with the N,V,T ensemble? What is a better ensemble? T V L+V L composition Example (1): vapour-liquid equilibrium mixture

  28. Deep in the earth clay layers can swell upon adsorption of water: How to mimic this in the N,V,T ensemble? What is a better ensemble to use? Example (2):swelling of clays

  29. Ensembles • Micro-canonical ensemble: E,V,N • Canonical ensemble: T,V,N • Constant pressure ensemble: T,P,N • Grand-canonical ensemble: T,V,μ

  30. Thermo recall (4) First law of thermodynamics Hence and Constant pressure simulations: N,P,T ensemble 1/kBT p/kBT Consider a small system that can exchange volume and energy with a big reservoir Hence, the probability to find Ei,Vi:

  31. The probability to find a particular configuration: N,P,T ensemble (2) In the classical limit, the partition function becomes

  32. Thermo recall (5) First law of thermodynamics Hence and Grand-canonical simulations: μ,V,T ensemble 1/kBT -μ/kBT Consider a small system that can exchange particles and energy with a big reservoir Hence, the probability to find Ei,Ni:

  33. The probability to find a particular configuration: μ,V,T ensemble (2) In the classical limit, the partition function becomes

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