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Isra University Faculty of Arts and science Course Calendar 2016/2017 Department of English /Translation First Semester ************************************************************************************ ***** * Course Title: Quantum mechanics 1 * Course No.: 1102362 * Instructor : * Office hours: * E-mail: * Course Description: (3 credit hours, Prerequisite: 1102261&1102281) Theoretical study of quantity, basic principles, properties of effects, impressive density, transfer polar (dual and quad-polar), Hamiltonian corn, the elements of the matrix and the principle of symmetry, the equations of motion for transitions binaries electrodes and magnetic, vibration operations, the behavior of the case for the transition of dual-electrode, properties, transit behavior for the transition of dualelectrode, the laser and its applications, reverse rehabilitation, Springs Q, laser four levels. * Objectives: To understand the concepts that led to the transition from classical to quantum physics such as the particle properties of radiation, the wave properties of matter and the quantization of physical quantities. To understand symmetries and conservation laws. To understand the concept of wave packets and uncertainty principle to understand Hamiltonian and Lagrangian Mechanics. To be familiar with Schrödinger wave equation and the probability interpretation To solve the Eigen value equation for some simple one dimensional potentials and to generalize the results for the case of three dimensional problems. To learn some operator methods in quantum mechanics and to study the angular momentum operator as an example. To apply the above concepts in studying the energy spectrum and eigenfunctions of the Hydrogen atom. weeks First Dates Ch. & PP. justify the emergence of quantum mechanics and Interpret the uncertainty principle (ch.1&2) Black body radiation. The photoelectric Effect. The Compton Effect. Electron diffraction. The Bohr atom. Second Third & Fourth . Solve quantum mechanical problems (ch.3) The free particle equation. The probability interpretation. Flux conservation. The momentum operator. The expectation values, The equation for particle in a potential. Solve quantum mechanical problems (ch.4) The energy eigenvalue equation. The particle in a box Momentum eigenfunction, Parity Fifth Sixth Seventh The wave-particle problem. Localized wave packets. The propagation of wave packets. From wave packets to the Schrödinger equation. The Heisenberg uncertainty relations. Ninth Tunneling phenomena. Harmonic oscillator. Delta function potentials. Solve quantum mechanical problems (ch.6) Eigenfunctions and eigenvalues. The expansion postulates and the vector analogy. Dirac notation, Tenth Degeneracy and simultaneous observables. Time dependence and the classical limit. Understand the concept of operators in quantum mechanics and their properties (ch.7) Twelfth The first exam Solve quantum mechanical problems (ch.5) The potential step. The potential well and bound states. The potential barrier. Eighth Eleventh Remarks The energy spectrum of the harmonic oscillator, Representation of abstract states: from operators to the Schrödinger equation. The time-development of a system in terms of operators Separation of center-of-mass motion. The radial equation. Fermi energy for three-dimension box. Solve quantum mechanical problems (ch.9&10) Separation of center-of-mass motion. The radial equation. Fermi energy for three-dimension box. The second exam Know the energy spectrum and eigenfunctions of the hydrogen atom(ch.11) Thirteenth Angular momentum operators in spherical variables. The eigenfunctions and eigenvalues of L2 and Lz. Raising and lowering operators, The spherical Harmonics Fourteenth The Final Exam Fifteenth * Assessment instruments 1. Short reports and / or presentation, and / or short research projects. 2. First and second exams 3. Attendance and participations 4. Final exam Grade Distribution Assessment instruments First examination Second Examination Participation Final examination Total * Textbook and Supporting Material Marks 25 25 10 40 100