Programma dei Moduli del Corso:

Quantum Mechanics | Docente:
Daniele Di Castro

1) Elements of Classical Mechanics:

 

    1.1: Material point, degrees of freedom, and generalized coordinates;

         1.2.1: Hamilton’s principle

         1.2.2: inertial systems, properties of space and time, relativity principle of Galileo;

         1.2.3: Lagrangian for a free particle and for a system of non-interacting and interacting     

                   particles (potential energy);

         1.2.4: Lagrangian for a system of interacting particles in generalized coordinates;

         1.2.5: particle in an external field; constraints.

 

    1.3: Conservation laws:

         1.3.1: First integrals from the properties of space and time; cyclic coordinates;

         1.3.2: Conservation of energy; generalized momentum; total energy in generalized coordinates

         1.3.3: conservation of momentum; center of mass;

         1.3.4: conservation of angular momentum;

 

    1.4:

         1.4.1: Integration of the equations of motion, solution from first integrals;

         1.4.2: one-dimensional motions; two-body problem and the reduced mass;

         1.4.3: motion in a central field: the example of Coulomb field; finite and infinite motions;

         1.4.4: free, forced, and forced and damped oscillators;

    

    1.5: Legendre transformations, Hamiltonian, and Hamilton's equations; Hamiltonian of a free a         particle and in a presence of external field.

 

    1.6: Poisson brackets.

 

 

2) Quantum Mechanics

 

     2.1: Basic concepts of quantum mechanics:

uncertainty principle; the configurations space and the wave function; physical quantities (observables), the superposition principle, operators, eigenfunctions and eigenvalues​​(discrete and continuous spectrum), expansion coefficients, the mean value of a physical quantity; transposed operator, Hermitian conjugate operator, inverse operator; Hermitian operators; commutator of two operators and the concept of operators defined simultaneously in a state; characteristics of the continuous spectrum, coordinate operator; the concept of measurement in quantum mechanics.

 

      2.2:

            2.2.1: Classical limit of the wave function;

            2.2.2: Wave equation and Hamiltonian operator;

2.2.3: Derivative of operators with respect to time and conservative physical quantities;

2.2.4: Energy and wave function of the stationary states, discrete and continuous spectrum of energy eigenvalues​​, finite (bound states) and infinite motion.

 

 

     2.3:

2.3.1 Matrices: matrix elements of an operator, Hermitian matrices, the product of       matrices;

2.3.2: Momentum: translation operator, conservation of momentum,  momentum operator, eigenvalues ​​and eigenfunctions.

2.3.3: Eigenvalue equations for a physical quantity in the representation of energy; matrices in diagonal form; complete set of common eigenfunctions.

2.3.4: Transformations of matrices

2.3.4: Uncertainty relations.

 

 

    2.4:

2.4.1: Hamiltonian for a system of free particles, of interacting particles, and of particles in an external field;

2.4.2: Schrödinger equation for a free particle and corresponding eigenfunctions;

2.4.3: classical limit of the Schrödinger equation;

2.4.4: basic properties of the Schrödinger equation and of the wave function solution of the equation; properties of the ground state;

2.4.5: current density vector and continuity equation for the probability density.

 

    2.5: One-dimensional motions:

2.5.1: Schrödinger equation and general principles;

2.5.2: infinite potential well; potential step; coefficients of transmission and reflection (wave character of the particle); finite potential well; potential barrier and tunnel effect;

2.5.3: definition and properties of the Dirac notation: bra and ket; discrete spectrum and the continuous spectrum, position physical quantity and wave functions; measurement process;

2.5.5: Harmonic oscillator: solution by means of the creation and annihilation operators.

 

 

    2.6. Angular momentum:

2.6.1: Rotation operator; conservation of angular momentum; angular momentum operator;

2.6.2: commutation relations;

2.6.3: angular momentum in polar coordinates; eigenvalues ​​and eigenfunctions of the angular momentum along z, ℓz; lowering and raising operators; eigenvalues ​​of the square modulus of the angular momentum ℓ2.

2.6.4: matrix elements of the raising and lowering operators and of the components of the angular momentum.

2.6.5: eigenfunctions of angular momentum: eigenfunctions of â„“z and â„“2 and spherical harmonics.

 

 

     2.7: Motion in a central field:

2.7.1: the two-body problem: the reduced mass; reduction to a motion in a central field; Schrödinger equation for the radial part of the wave function, effective potential (centrifugal barrier);

2.7.2: motion in Coulomb field: hydrogen atom; eigenfunctions and eigenvalues.

 

 

    2.8: Spin:

2.8.1: concept of spin; commutation relations; eigenvalues ​​of Sz and S2; integer or half-  integer spin; spinors; matrix elements of the components of the spin: Pauli matrices for the spin operator in two dimensions; eigenket of Sz as a basis;

2.8.2: total angular momentum (spin plus orbital angular momentum); composition of angular momenta.

 

    2.9: Identical particles:

2.9.1: concepts of indistinguishable particles in quantum mechanics;

2.9.2: spin states for two identical particles of spin 1/2;

2.9.3: exchange operator, the symmetric and antisymmetric states;

2.9.4: fermions and bosons; Pauli principle; state and wave functions of N fermions and N bosons;

 

 

Reference books:

Part 1): L. D. Landau & E. M. Lifshitz, “Mechanics”; H. Goldstein: “Classical Mechanicsa”

Part 2): L. D. Landau & E. M. Lifshitz, “Quantum Mechanics: non relativistic theory”; S. Gasiorowicz, “Quantum Physics”; J. J. Sakurai, “Modern Quantum Mechanics”




Statistical Mechanics | Docente:
Andrey Varlamov
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