Quantum Hardware
Explore physical quantum computers. Learn about superconducting qubits, ion traps, photonic systems, topological qubits, and quantum hardware challenges.
Prerequisites
Complete Level 4: Quantum Programming
🎯What You'll Learn
- ✓Superconducting qubit architectures
- ✓Trapped ion quantum computers
- ✓Photonic quantum computing
- ✓Topological qubits and anyons
- ✓Quantum hardware challenges and limitations
💪Skills You'll Gain
🏆Learning Outcomes
📖Interactive Modules (10)
Quantum Hardware Overview
Overview of quantum hardware platforms, qubit technologies, and physical implementations.
Superconducting Qubits
Learn superconducting qubits used by IBM, Google, and other leading quantum computers.
Trapped Ion Qubits
Understand trapped ion qubits offering long coherence and high gate fidelity.
Topological Qubits
Explore topological qubits (Microsoft) with inherent error protection.
Photonic Quantum Computing
Learn photonic quantum computing using light particles for room-temperature qubits.
Neutral Atom Qubits
Discover neutral atom qubits with reconfigurable geometry and scalability.
Quantum Annealing Hardware
Understand quantum annealing hardware like D-Wave for optimization problems.
Quantum Processor Architecture
Explore quantum processor architecture, control systems, and qubit connectivity.
Dilution Refrigeration
Learn dilution refrigeration, cooling quantum processors to millikelvin temperatures.
Hardware Platform Comparison
Compare quantum hardware platforms across coherence time, gate fidelity, and scalability.