Quantum computing

We are unlocking the ability to solve problems considered impossible for classical computers.

To reach this goal, IQC researchers are building an essential framework for a new era of computation.

Our work spans from theory to experimentation, designing efficient algorithms and robust hardware architectures.

We focus on making these powerful systems stable and reliable, ensuring we can harness the full potential of quantum information.

Applications

drug discovery and molecular simulation
optimization for logistics, energy and finance
machine learning and data analysis
materials discovery
cryptography and quantum-safe protocols

View "Quantum Computing in 60 seconds" on YouTube

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Workshops, colloquiums, seminars by IQC researchers and visitors

Quantum computing researchers

Research expertise

Experimental quantum many-body physics
Quantum computation with trapped ions
Use of holography and high resolution microscopy to manipulate many-body systems

Research expertise

Quantum-safe cryptography
Quantum algorithms and complexity
Methods for mapping quantum circuits to realistic architectures

Research expertise

Quantum cryptography
Quantum communications
Measurement-based quantum computation
Fault-tolerant quantum computation and error correction

Research expertise

Quantum information theory
Structure of quantum algorithms
Quantum communication complexity theory

Research expertise

Experimental and theoretical physics
Cavity optomechanics
Superconducting circuits
Quantum information
Nanomechanics

Research expertise

Lie theory and algebraic combinatorics
Representation theory in quantum information
Non-local games
Geometry of entanglement

Research expertise
Ultracold atoms and molecules
Quantum chemistry
Quantum information
Precision measurements and quantum-enhanced metrology

Research expertise

Quantum Computing
Quantum Error Correction
Digital Quantum Emulations
Superconducting Quantum Circuits

Research expertise

Quantum networks
Quantum sensing
Quantum simulations
High-energy physics simulation with quantum computers

Research expertise

Error diagnosis and suppression
Validation of circuit performance in quantum computers
Foundations of quantum theory

Research expertise

Manipulation of quantum systems with trapped ions
Quantum computation with trapped ions
Phases and dynamics of interacting spin systems

Research expertise

Clifford circuits
Low-depth circuits (classical and quantum)
Classical simulation of quantum circuits

Research expertise

Quantum algorithms
Classical simulation of quantum computation
Computational complexity of quantum many-body systems

Research expertise

Quantum computation and quantum information
Computational complexity
Design and analysis of algorithms

Research expertise

Magnetic resonance and its applications
Spin-based quantum information processors
Quantum complexity
Neutron interferometry

Research expertise

Classical complexity theory
Quantum complexity theory

Research expertise

Quantum Shannon Theory
Quantum Networks
Mathematical Physics
Physics of Information

Events

Institute for Quantum Computing (IQC) Math and CS seminar

Cloning is as Hard as Learning for Stabilizer State

Location: QNC 4104

Towards sample-optimal learning of bosonic Gaussian quantum states

Location: QNC 4104

Optimal detection of dissipation in Lindbladian dynamics

Location: QNC 4104

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Quantum computing researchers

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