Riverlane Research

Parallel window decoding enables scalable fault tolerant quantum computation

A real-time, scalable, fast and highly resource efficient decoder for a quantum computer

Ben Barber, Kenton M. Barnes, Tomasz Bialas, Okan Buğdaycı, Earl T. Campbell, Neil I. Gillespie, Kauser Johar, Ram Rajan, Adam W. Richardson, Luka Skoric, Canberk Topal, Mark L. Turner, Abbas B. Ziad

Publication

Nature Electronics

Demonstrating real-time and low-latency quantum error correction with superconducting qubits

Authors

Laura Caune, Luka Skoric, Nick S. Blunt, Archibald Ruban, Jimmy McDaniel, Joseph A. Valery, Andrew D. Patterson, Alexander V. Gramolin, Joonas Majaniemi, Kenton M. Barnes, Tomasz Bialas, Okan Buğdaycı, Ophelia Crawford, György P. Gehér, Hari Krovi, Elisha Matekole, Canberk Topal, Stefano Poletto, Michael Bryant, Kalan Snyder, Neil I. Gillespie, Glenn Jones, Kauser Johar, Earl T. Campbell, Alexander D. Hill

We partner with leading quantum hardware companies and university labs to advance the design, engineering and benchmarking of quantum computers, with a core focus on quantum error correction.

We work with leading industry partners in the pharmaceutical, climate science, advanced materials and aerospace sectors to identify specific areas where quantum computing will drive the greatest advances in human progress.

Viewing:

Quantum Error Correction Research

Applied Quantum Error Correction

Reset filters

Post-selection-free preparation of high-quality physical qubits

Authors

Ben Barber, Neil Gillespie, Jake Taylor

Nature

Multi-qubit entanglement and algorithms on a neutral atom quantum computer

Authors

Ophelia Crawford, Ben Rogers and Nick Blunt, with researchers from Cold Quanta and University of Wisconsin-Madison

Publication

Nature

Quantum computing in pharma – a multi-layer embedding approach for near future applications

Authors

Róbert Izsák, Christoph Riplinger (FAccTs), Nick Blunt, Bernardo de Souza (FAccTs), Nicole Holzmann, Ophelia Crawford, Joan Camps, Frank Neese (Max-Planck-Institut für Kohlenforschung), Patrick Schopf (Astex)

Compilation and scaling strategies for a silicon quantum processor with sparse two-dimensional connectivity

Authors

Ophelia Crawford, James Cruise, Normann Mertig (Hitachi Cambridge Laboratory), Fernando Gonzalez-Zalba (Hitachi Cambridge Laboratory)

Research

Parallel window decoding enables scalable fault tolerant quantum computation

A real-time, scalable, fast and highly resource efficient decoder for a quantum computer

Demonstrating real-time and low-latency quantum error correction with superconducting qubits

Post-selection-free preparation of high-quality physical qubits

Multi-qubit entanglement and algorithms on a neutral atom quantum computer

Quantum computing in pharma – a multi-layer embedding approach for near future applications

Compilation and scaling strategies for a silicon quantum processor with sparse two-dimensional connectivity

Distributed quantum computing and network control for accelerated VQE

Practical quantum computing: the value of local computation

Efficient quantum measurement of Pauli operators

Variational quantum computation of excited states

Accelerated variational quantum eigensolver