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Quantum Computing

Qubits Applications of Quantum Computing Quantum Networking Nobel Prize in Physics Quantum Internet Superconducting Circuits Josephson Junctions Nobel Prize Superconducting Qubits Nuclear-Spin Dark State Bolometers Room-Temperature Quantum Computing Artificial Intelligence Quantum Annealing Quantum Information Encoding Topological Quantum Computers Quantum Information Processing Measurement Techniques Qubit Measurements Single-Shot Fidelity Research Groups Measurement Devices Experimental Research Entangled States Quantum Entanglement Probabilistic Computers Error Correction Silicon-28 Enrichment Quantum Sensors Magic State Distillation Topological Superconductors Quantum Materials Quantum Error Correction Quantum Bits Antimatter Qubits Quantum Memory Quantum Simulation Topological Quantum Computing Quantum Networks Cryogenic Technologies Macroscopic Quantum Tunneling Tunneling Effect Time Crystals Quantum Communication Experimental Physics Error Correction Techniques Qubit Formation Quantum Circuits Thermoelectric Conversion Optical Fibers Cold Atoms Trapped Ions Multiverse Theory Quantum States

Clarke, Devoret and Martinis Win Nobel Physics Prize for Macroscopic Quantum Effects in Circuits

The committee spotlighted decades-old experiments whose insights underpin today’s superconducting qubits.

Caltech Assembles Record 6,100-Qubit Neutral-Atom Array With High Coherence

Single Neglecton Unlocks Universal Braiding-Based Quantum Computing

Oxford Physicists Set Record-Low 0.000015% Error Rate in Single-Qubit Operation

Novel STM Technique Confirms UTe₂ as Topological Superconductor for Quantum Chips

Solitons enable room-temperature superfluorescence in hybrid perovskites