PH5202 : Advanced Statistical Mechanics (Spring 2014)

Details of PH5202 (Spring 2014)

Level: 5

Type: Theory

Credits: 3.0

Course Code	Course Name	Instructor(s)
PH5202	Advanced Statistical Mechanics	Subhasis Sinha

Syllabus
Phase Transitions: General concepts of phase transitions, order parameter, continuous transition, Landau-Ginzburg (L-G) theory, concept of critical phenomena, critical exponents, Examples: mean field treatment of Ising model, etc. ., L-G theory for 1st order transition. Models: Exact solution of 1D Ising model by transfer matrix method, Discussion of 2D Ising, Potts model, etc. Partition function and etc: Partition function and L-G theory from the point of view of functional integral ( An example can be given in the context of Ising model) Symmetry breaking: Continuous symmetry breaking and sound mode, correlation function and correlation length, Example: Heisenberg system, O(N) model Fluctuations: Fluctuation phenomena: Gaussian fluctuations, Ginzburg criteria, upper and lower critical dimensions, Mermin-Wagner theorem. BKT transition in 2D, x-y model Liquids: pair correlation function, structure factor, etc. Linear response theory: Introduction, diffusion, fluctuation-dissipation Applications: Phase transition in liquid crystal, polymer physics, colloids, Superfluidity and L-G theory of superconductivity

Syllabus

Phase Transitions: General concepts of phase transitions, order parameter, continuous transition, Landau-Ginzburg (L-G) theory, concept of critical phenomena, critical exponents, Examples: mean field treatment of Ising model, etc.
., L-G theory for 1st order transition.
Models: Exact solution of 1D Ising model by transfer matrix method, Discussion of 2D Ising, Potts model, etc.
Partition function and etc: Partition function and L-G theory from the point of view of functional integral ( An example can be given in the context of Ising model)
Symmetry breaking: Continuous symmetry breaking and sound mode, correlation function and correlation length, Example: Heisenberg system, O(N) model
Fluctuations: Fluctuation phenomena: Gaussian fluctuations, Ginzburg criteria, upper and lower critical dimensions, Mermin-Wagner theorem.
BKT transition in 2D, x-y model
Liquids: pair correlation function, structure factor, etc.
Linear response theory: Introduction, diffusion, fluctuation-dissipation
Applications: Phase transition in liquid crystal, polymer physics, colloids, Superfluidity and L-G theory of superconductivity

Prerequisite
Intermediate Classical Mechanics, Intermediate Quantum Mechanics, Statistical Mechanics

References
Phase Transitions: General concepts of phase transitions, order parameter, continuous transition, Landau-Ginzburg (L-G) theory, concept of critical phenomena, critical exponents, Examples: mean field treatment of Ising model, etc. ., L-G theory for 1st order transition. Models: Exact solution of 1D Ising model by transfer matrix method, Discussion of 2D Ising, Potts model, etc. Partition function and etc: Partition function and L-G theory from the point of view of functional integral ( An example can be given in the context of Ising model) Su=ymmetry breaking: Continuous symmetry breaking and sound mode, correlation function and correlation length, Example: Heisenberg system, O(N) model Fluctuations: Fluctuation phenomena: Gaussian fluctuations, Ginzburg criteria, upper and lower critical dimensions, Mermin-Wagner theorem. BKT transition in 2D, x-y model Liquids: pair correlation function, structure factor, etc. Linear response theory: Introduction, diffusion, fluctuation-dissipation Applications: Phase transition in liquid crystal, polymer physics, colloids, Superfluidity and L-G theory of superconductivity

References

Phase Transitions: General concepts of phase transitions, order parameter, continuous transition, Landau-Ginzburg (L-G) theory, concept of critical phenomena, critical exponents, Examples: mean field treatment of Ising model, etc.
., L-G theory for 1st order transition.
Models: Exact solution of 1D Ising model by transfer matrix method, Discussion of 2D Ising, Potts model, etc.
Partition function and etc: Partition function and L-G theory from the point of view of functional integral ( An example can be given in the context of Ising model)
Su=ymmetry breaking: Continuous symmetry breaking and sound mode, correlation function and correlation length, Example: Heisenberg system, O(N) model
Fluctuations: Fluctuation phenomena: Gaussian fluctuations, Ginzburg criteria, upper and lower critical dimensions, Mermin-Wagner theorem.
BKT transition in 2D, x-y model
Liquids: pair correlation function, structure factor, etc.
Linear response theory: Introduction, diffusion, fluctuation-dissipation
Applications: Phase transition in liquid crystal, polymer physics, colloids, Superfluidity and L-G theory of superconductivity

Sl. No.	Programme	Semester No	Course Choice
1	IP	2	Not Allowed
2	IP	4	Not Allowed
3	MR	2	Not Allowed
4	MR	4	Not Allowed
5	MS	10	Elective
6	RS	1	Not Allowed
7	RS	2	Not Allowed