Basic Information
Superposition Principle and Wave Functions, Density Matrix, Quantum Interference and Duality Principle, Entanglement and Non-locality Including Bell States, The Classic-quantum Boundary, Principles Of Quantum Communication and Quantum Teleportation, Quantum Computing (basic Level) and Quantum Sensing, Limited Aspects of Magnetic Resonance Mainly Related to Two Level System and Bloch Sphere, Quantum Optics and Jaynes Cummings Equations, Lindblad Master Equation, Collective Excitations of Spins in Resonator, Principles And Approaches to Quantum Materials and Molecules to Be Used In Quantum Devices Maintaining Long Coherence Times, Minimization Of Photon/phonon Noise.and Approaches to Quantum Materials and Molecules To Be Used in Quantum Devices Maintaining Long Coherence Times, Minimization of Photon/phonon Noise. Learning Outcomes# at The End Of The Course, The Student Will Be Able To# 1 .realize How Quantum Phenomena Can Be Revealed in Daily Life and in Modern Experiments, Including Some Existing and Future Applications of Quantum Effects. 2. Understand and Describe The Measurement Process and Its Effects On The Measured Object. 3. Understand and Describe in Mathematical Terms Coherent Processes and Loss of Coherence. 4. Describe Mathematically And in Quantum Terms Several Central Experiments, Such As Bell S And Experiments With Two Levels Systems With and Without Resonator. 5. Understand The Challenges Facing The Design of Molecules and Materials For Quantum Technology Devices and The Various Approaches in The Field.
Faculty: Chemistry
|Undergraduate Studies
|Graduate Studies
Pre-required courses
Course with no extra credit
116031 - Int. to Quantum Inf. Computation 236990 - Introduction to Quantum Information
Course with no extra credit (contained)
324272 - Quantum Computing:theory and Practice