Quantum Electronics Certified Course

Course Description:

The Quantum Electronics is a specialized course designed to explore the quantum mechanical principles that govern the behavior of electrons and photons in modern electronic and photonic devices. This course bridges quantum physics and electronic engineering, focusing on applications in semiconductors, lasers, quantum computing, and nanotechnology.

Key Features of Course Divine:

• Collaboration with E‑Cell IIT Tirupati
• 1:1 Online Mentorship Platform
• Credit-Based Certification
• Live Classes Led by Industry Experts
• Live, Real-World Projects
• 100% Placement Support
• Potential Interview Training
• Resume-Building Activities

Career Opportunities After Quantum Electronics Certified Course:

• Quantum Device Engineer
• Quantum Computing Researcher
• Semiconductor Device Engineer
• Optoelectronics Engineer
• Nanotechnology Specialist
• Photonics and Laser Engineer
• Academic or Industrial Research Scientist
• Quantum Systems Architect

Essential Skills you will Develop Quantum Electronics Certified Course:

• Understanding of Quantum Mechanics Fundamentals
• Quantum Statistical Mechanics
• Modeling Quantum Devices
• Solid-State Physics Proficiency
• Laser and Photonic Device Design
• Quantum Circuit Design
• Nanofabrication Basics

Tools Covered:

• MATLAB / Semolina
  For quantum system simulations, numerical analysis, and solving Schrödinger’s equation.
• QuantumATK / Atomistic Toolkit
  For atomic-scale modeling of electronic transport in nanoscale devices.
• COMSOL Metaphysics
  For simulating quantum mechanical behaviors coupled with electrical and optical simulations.

Syllabus:

Module 1: Introduction to Quantum Mechanics History and development of quantum theory Wave-particle duality Schrödinger’s equation (time-independent and dependent) Heisenberg uncertainty principle

Module 2: Quantum States and Operators Quantum states and Dirac notation Operators and observables Commutation relations Eigenvalues and eigenfunctions Measurement and probability in quantum systems

Module 3: Quantum Wells, Wires, and Dots Potential wells: infinite and finite Quantum confinement in nanostructures Quantum dots and energy quantization Application in lasers and photodetectors

Module 4: Electron Transport in Nanostructures Ballistic transport and tunneling Resonant tunneling diodes (RTDs)Single-electron tunneling and Coulomb blockade Lindauer formalism

Module 5: Semiconductor Quantum Devices Band theory and density of states PN junctions under quantum conditions Heterostructures and quantum cascade lasers MOSFETs and quantum tunneling effects

 Module 6: Quantum Optoelectronics Interaction of light with matter Absorption, emission, and stimulated emission Laser operation principles Quantum efficiency and photodetectors

 Module 7: Quantum Circuits and Computing Qubits and superposition Quantum gates and algorithms (Intro to Qi skit) Quantum entanglement and teleportation Real-world applications in quantum processors

 Module 8: Simulation Tools and Techniques MATLAB for solving quantum equations COMSOL and TCAD for device-level simulations Python with Quip for quantum dynamics QuantumATK for material-level modeling

 Module 9: Experimental Quantum Electronics Lab instrumentation overview (oscilloscopes, lasers, STMs) Characterization of quantum devices Quantum optics experiments and photonics lab setups Data acquisition using LabVIEW

Module 10: Applications and Future Trends Quantum communication and cryptography Emerging quantum hardware and architectures Challenges in scaling quantum electronics Research frontiers and industry insights

Industry Projects:

• Simulation of a Quantum Well Structure
• Modeling a Resonant Tunneling Diode (RTD)
• Design of Quantum Dot-Based LED
• Simulation of Quantum Logic Gates Using Visit

Who is this program for?

• Undergraduate and Postgraduate Students
• Researchers and PhD Scholars
• Electronics and Semiconductor Professionals

How To Apply:

Mobile: 9100348679

Email: coursedivine@gmail.com