QuEra Computing
@queracomputing.bsky.social
Based in Boston and built on pioneering research from Harvard University and MIT, QuEra Computing is the leader in developing and productizing quantum computers using neutral atoms, widely recognized as a highly promising quantum computing modality.
Transversal STAR architecture for megaquop-scale quantum simulation with neutral atoms
arxiv.org/abs/2509.18294
Universal fault-tolerant quantum computation requires the synthesis of complex resource states.
arxiv.org/abs/2509.18294
Universal fault-tolerant quantum computation requires the synthesis of complex resource states.
Transversal STAR architecture for megaquop-scale quantum simulation with neutral atoms
Quantum computing experiments have made remarkable progress in demonstrating key components of quantum error correction, a prerequisite for scalable quantum computation. While we anticipate the…
buff.ly
November 7, 2025 at 12:15 PM
Transversal STAR architecture for megaquop-scale quantum simulation with neutral atoms
arxiv.org/abs/2509.18294
Universal fault-tolerant quantum computation requires the synthesis of complex resource states.
arxiv.org/abs/2509.18294
Universal fault-tolerant quantum computation requires the synthesis of complex resource states.
Join us next week for a "Science with QuEra" webinar covering Nature 646, 303–308 (2025), " Low-overhead transversal fault tolerance for universal quantum computation "
Register at: buff.ly/TrtzNWd
Register at: buff.ly/TrtzNWd
November 6, 2025 at 4:47 PM
Join us next week for a "Science with QuEra" webinar covering Nature 646, 303–308 (2025), " Low-overhead transversal fault tolerance for universal quantum computation "
Register at: buff.ly/TrtzNWd
Register at: buff.ly/TrtzNWd
Please join us at the University of Toronto Fields Institute for "Science With Programmable Neutral Atom Quantum Computers" with QuEra's Alexei Bylinskii.
Friday, Nov 7th, 11 AM. Additional information here: www.physics.utoronto.ca/research/qua...
Friday, Nov 7th, 11 AM. Additional information here: www.physics.utoronto.ca/research/qua...
November 5, 2025 at 5:04 PM
Please join us at the University of Toronto Fields Institute for "Science With Programmable Neutral Atom Quantum Computers" with QuEra's Alexei Bylinskii.
Friday, Nov 7th, 11 AM. Additional information here: www.physics.utoronto.ca/research/qua...
Friday, Nov 7th, 11 AM. Additional information here: www.physics.utoronto.ca/research/qua...
Join us on Dec 4th a "Science with QuEra" webinar series. This time, we will be hosting NESRC and University of Toronto researchers to describe our joint work "Quantum criticality and nonequilibrium dynamics with neutral atoms" (arXiv:2509.18294).
Register here: quera.zoom.us/webinar/regi...
Register here: quera.zoom.us/webinar/regi...
Welcome! You are invited to join a webinar: Science with QuEra: Quantum criticality and nonequilibrium dynamics with neutral atoms. After registering, you will receive a confirmation email about joining the webinar.
arXiv:2509.18294
quera.zoom.us
November 4, 2025 at 7:02 PM
Join us on Dec 4th a "Science with QuEra" webinar series. This time, we will be hosting NESRC and University of Toronto researchers to describe our joint work "Quantum criticality and nonequilibrium dynamics with neutral atoms" (arXiv:2509.18294).
Register here: quera.zoom.us/webinar/regi...
Register here: quera.zoom.us/webinar/regi...
Three Harvard researchers presented their work on "Continuous operation of a coherent 3,000-qubit system" [Nature (2025): doi.org/10.1038/s415... ] on a recent "Science with QuEra" webinar. Catch the recording here: youtu.be/wi4ez_TfngM
Science with QuEra: Continuous operation of a coherent 3,000-qubit system
Three of the authors describe this Harvard/MIT work:
Nature (2025): https://doi.org/10.1038/s41586-025-09596-6
youtu.be
November 3, 2025 at 3:04 PM
Three Harvard researchers presented their work on "Continuous operation of a coherent 3,000-qubit system" [Nature (2025): doi.org/10.1038/s415... ] on a recent "Science with QuEra" webinar. Catch the recording here: youtu.be/wi4ez_TfngM
Harvard-led team expands what analog quantum computers can do.
This work demonstrates that with a new methodology for optimal control of global pulses, analog quantum computers can be made far more expressive than their native setting. www.arxiv.org/abs/2508.19075
This work demonstrates that with a new methodology for optimal control of global pulses, analog quantum computers can be made far more expressive than their native setting. www.arxiv.org/abs/2508.19075
Universal Dynamics with Globally Controlled Analog Quantum Simulators
Analog quantum simulators with global control fields have emerged as powerful platforms for exploring complex quantum phenomena. Recent breakthroughs, such as the coherent control of thousands of…
buff.ly
October 31, 2025 at 11:04 AM
Harvard-led team expands what analog quantum computers can do.
This work demonstrates that with a new methodology for optimal control of global pulses, analog quantum computers can be made far more expressive than their native setting. www.arxiv.org/abs/2508.19075
This work demonstrates that with a new methodology for optimal control of global pulses, analog quantum computers can be made far more expressive than their native setting. www.arxiv.org/abs/2508.19075
Join us on Nov 13 for a "Science with QuEra" webinar covering Nature 646, 303–308 (2025), " Low-overhead transversal fault tolerance for universal quantum computation "
Register at: quera.zoom.us/webinar/regi...
Register at: quera.zoom.us/webinar/regi...
October 23, 2025 at 1:04 PM
Join us on Nov 13 for a "Science with QuEra" webinar covering Nature 646, 303–308 (2025), " Low-overhead transversal fault tolerance for universal quantum computation "
Register at: quera.zoom.us/webinar/regi...
Register at: quera.zoom.us/webinar/regi...
Tomorrow at 11 AM ET, researchers from Harvard present in the latest "Science with QuEra" webinar on "Continuous operation of a coherent 3,000-qubit system" - Nature (2025): doi.org/10.1038/s415...
quera.zoom.us/webinar/regi...
quera.zoom.us/webinar/regi...
Continuous operation of a coherent 3,000-qubit system - Nature
Nature - Continuous operation of a coherent 3,000-qubit system
doi.org
October 22, 2025 at 3:04 PM
Tomorrow at 11 AM ET, researchers from Harvard present in the latest "Science with QuEra" webinar on "Continuous operation of a coherent 3,000-qubit system" - Nature (2025): doi.org/10.1038/s415...
quera.zoom.us/webinar/regi...
quera.zoom.us/webinar/regi...
Excited to share new research in collaboration NERSC/LBNL, performed on Aquila.
“Probing emergent prethermal dynamics and resonant melting on a programmable quantum simulator” explores the frontiers of non-equilibrium quantum many-body physics.
arxiv.org/abs/2510.11706
“Probing emergent prethermal dynamics and resonant melting on a programmable quantum simulator” explores the frontiers of non-equilibrium quantum many-body physics.
arxiv.org/abs/2510.11706
Probing emergent prethermal dynamics and resonant melting on a programmable quantum simulator
The dynamics of isolated quantum systems following a sudden quench plays a central role in many areas of material science, high-energy physics, and quantum chemistry. Featuring complex phenomena with…
arxiv.org
October 22, 2025 at 1:04 PM
Excited to share new research in collaboration NERSC/LBNL, performed on Aquila.
“Probing emergent prethermal dynamics and resonant melting on a programmable quantum simulator” explores the frontiers of non-equilibrium quantum many-body physics.
arxiv.org/abs/2510.11706
“Probing emergent prethermal dynamics and resonant melting on a programmable quantum simulator” explores the frontiers of non-equilibrium quantum many-body physics.
arxiv.org/abs/2510.11706
On Thu, Oct 23 at 11 AM ET, researchers from Harvard present in the latest "Science with QuEra" webinar on "Continuous operation of a coherent 3,000-qubit system" - Nature (2025): doi.org/10.1038/s415...
quera.zoom.us/webinar/regi...
quera.zoom.us/webinar/regi...
Continuous operation of a coherent 3,000-qubit system - Nature
Nature - Continuous operation of a coherent 3,000-qubit system
doi.org
October 14, 2025 at 6:03 PM
On Thu, Oct 23 at 11 AM ET, researchers from Harvard present in the latest "Science with QuEra" webinar on "Continuous operation of a coherent 3,000-qubit system" - Nature (2025): doi.org/10.1038/s415...
quera.zoom.us/webinar/regi...
quera.zoom.us/webinar/regi...
Next Monday, Oct 20th at 10 AM ET, we're presenting another webinar in the "Science with QuEra" series. This time, we're covering "An integrated photonics platform for high-speed, ultrahigh-extinction, many-channel quantum control" (arXiv:2508.09920 )
buff.ly/rejY2he
buff.ly/rejY2he
Welcome! You are invited to join a webinar: Science with QuEra: An integrated photonics platform for high-speed, ultrahigh-extinction, many-channel quantum control. After registering, you will receive a confirmation email about joining the webinar.
arXiv:2508.09920
buff.ly
October 13, 2025 at 2:15 PM
Next Monday, Oct 20th at 10 AM ET, we're presenting another webinar in the "Science with QuEra" series. This time, we're covering "An integrated photonics platform for high-speed, ultrahigh-extinction, many-channel quantum control" (arXiv:2508.09920 )
buff.ly/rejY2he
buff.ly/rejY2he
Quantum computers are racing toward the megaquop era — machines that can run millions of reliable operations.
The roadblock? Cost.
Today’s designs burn enormous resources making special “magic states,” slowing progress.
The roadblock? Cost.
Today’s designs burn enormous resources making special “magic states,” slowing progress.
October 2, 2025 at 3:15 PM
Quantum computers are racing toward the megaquop era — machines that can run millions of reliable operations.
The roadblock? Cost.
Today’s designs burn enormous resources making special “magic states,” slowing progress.
The roadblock? Cost.
Today’s designs burn enormous resources making special “magic states,” slowing progress.
Unlock Circuit-Level Noise Modeling for Gemini-Class QPUs
🚀 We’ve just released new circuit-level noise models in Bloqade to accurately emulate how circuits perform on Gemini hardware.👉 buff.ly/BlEWQC5 ..
#QuantumComputing #NoiseModeling #Bloqade #QuantumSoftware #QuantumSimulation #QuantumDevTools
🚀 We’ve just released new circuit-level noise models in Bloqade to accurately emulate how circuits perform on Gemini hardware.👉 buff.ly/BlEWQC5 ..
#QuantumComputing #NoiseModeling #Bloqade #QuantumSoftware #QuantumSimulation #QuantumDevTools
October 1, 2025 at 3:04 PM
Unlock Circuit-Level Noise Modeling for Gemini-Class QPUs
🚀 We’ve just released new circuit-level noise models in Bloqade to accurately emulate how circuits perform on Gemini hardware.👉 buff.ly/BlEWQC5 ..
#QuantumComputing #NoiseModeling #Bloqade #QuantumSoftware #QuantumSimulation #QuantumDevTools
🚀 We’ve just released new circuit-level noise models in Bloqade to accurately emulate how circuits perform on Gemini hardware.👉 buff.ly/BlEWQC5 ..
#QuantumComputing #NoiseModeling #Bloqade #QuantumSoftware #QuantumSimulation #QuantumDevTools
We are delighted to share our new paper on Nature:
Low-Overhead Transversal Fault Tolerance for Universal Quantum Computation
www.nature.com/articles/s41...
Low-Overhead Transversal Fault Tolerance for Universal Quantum Computation
www.nature.com/articles/s41...
September 24, 2025 at 3:05 PM
We are delighted to share our new paper on Nature:
Low-Overhead Transversal Fault Tolerance for Universal Quantum Computation
www.nature.com/articles/s41...
Low-Overhead Transversal Fault Tolerance for Universal Quantum Computation
www.nature.com/articles/s41...
In a new paper, the authors from the Pawsey Supercomputer Centre and QuEra use quantum computers as an "analog" quantum system, matching continuous time quantum walks in independent set subspaces to the dynamical blockade phenomena of the Rydberg atom Hamiltonian. arxiv.org/abs/2509.00386
Continuous-time quantum walk-based ansätze on neutral atom hardware
A key use of near-term quantum computers is as analogue simulators, matching the action of some virtual or abstracted system onto a program executed on physical quantum hardware. This work explores…
arxiv.org
September 12, 2025 at 11:02 AM
In a new paper, the authors from the Pawsey Supercomputer Centre and QuEra use quantum computers as an "analog" quantum system, matching continuous time quantum walks in independent set subspaces to the dynamical blockade phenomena of the Rydberg atom Hamiltonian. arxiv.org/abs/2509.00386
Harry Zhou, our QEC architecture lead gave a keynote at Yale's QED25 on "Transversal architectures for neutral-atom logical quantum computation".
Catch the recording here:
yale.hosted.panopto.com/Panopto/Page...
Catch the recording here:
yale.hosted.panopto.com/Panopto/Page...
QED25 - Int'l Quantum Conf; Day 4, Recording 3
yale.hosted.panopto.com
September 2, 2025 at 3:43 PM
Harry Zhou, our QEC architecture lead gave a keynote at Yale's QED25 on "Transversal architectures for neutral-atom logical quantum computation".
Catch the recording here:
yale.hosted.panopto.com/Panopto/Page...
Catch the recording here:
yale.hosted.panopto.com/Panopto/Page...
🚀 New research: An integrated photonics platform for high-speed, ultrahigh-extinction, many-channel quantum control (arXiv:2508.09920).
A collaboration between QuEra, Sandia NL, MIT, and Univ. of Arizona.
: arxiv.org/abs/2508.09920
A collaboration between QuEra, Sandia NL, MIT, and Univ. of Arizona.
: arxiv.org/abs/2508.09920
An integrated photonics platform for high-speed, ultrahigh-extinction, many-channel quantum control
High-fidelity control of the thousands to millions of programmable qubits needed for utility-scale quantum computers presents a formidable challenge for control systems. In leading atomic systems,…
arxiv.org
August 28, 2025 at 2:30 PM
🚀 New research: An integrated photonics platform for high-speed, ultrahigh-extinction, many-channel quantum control (arXiv:2508.09920).
A collaboration between QuEra, Sandia NL, MIT, and Univ. of Arizona.
: arxiv.org/abs/2508.09920
A collaboration between QuEra, Sandia NL, MIT, and Univ. of Arizona.
: arxiv.org/abs/2508.09920
Excited to share our latest advance in quantum algorithm compiler design:
Research led by Jan Balewski and Anupam Mitra (NERSC / LBNL), in collaboration with teams at UCLA, QuEra Computing, and Harvard.
arxiv.org/abs/2507.10699
Research led by Jan Balewski and Anupam Mitra (NERSC / LBNL), in collaboration with teams at UCLA, QuEra Computing, and Harvard.
arxiv.org/abs/2507.10699
Compilation of QCrank Encoding Algorithm for a Dynamically Programmable Qubit Array Processor
Algorithm and hardware-aware compilation co-design is essential for the efficient deployment of near-term quantum programs. We present a compilation case-study implementing QCrank -- an efficient…
arxiv.org
August 27, 2025 at 2:45 PM
Excited to share our latest advance in quantum algorithm compiler design:
Research led by Jan Balewski and Anupam Mitra (NERSC / LBNL), in collaboration with teams at UCLA, QuEra Computing, and Harvard.
arxiv.org/abs/2507.10699
Research led by Jan Balewski and Anupam Mitra (NERSC / LBNL), in collaboration with teams at UCLA, QuEra Computing, and Harvard.
arxiv.org/abs/2507.10699
Developed in collaboration with our colleagues, we're excited to present:
"Compilation of QCrank Encoding Algorithm for a Dynamically Programmable Qubit Array Processor"
arXiv Publication: arxiv.org/abs/2507.10699
"Compilation of QCrank Encoding Algorithm for a Dynamically Programmable Qubit Array Processor"
arXiv Publication: arxiv.org/abs/2507.10699
Compilation of QCrank Encoding Algorithm for a Dynamically Programmable Qubit Array Processor
Algorithm and hardware-aware compilation co-design is essential for the efficient deployment of near-term quantum programs. We present a compilation case-study implementing QCrank -- an efficient…
arxiv.org
August 22, 2025 at 2:31 PM
Developed in collaboration with our colleagues, we're excited to present:
"Compilation of QCrank Encoding Algorithm for a Dynamically Programmable Qubit Array Processor"
arXiv Publication: arxiv.org/abs/2507.10699
"Compilation of QCrank Encoding Algorithm for a Dynamically Programmable Qubit Array Processor"
arXiv Publication: arxiv.org/abs/2507.10699
pubs.acs.org/doi/10.1021/...
A new paper co-authored by QuEra scientists in The Journal of Physical Chemistry Letters explores how quantum computing can transform the simulation of targeted covalent inhibitors—a promising class of drugs that form precise, durable bonds with disease-related proteins
A new paper co-authored by QuEra scientists in The Journal of Physical Chemistry Letters explores how quantum computing can transform the simulation of targeted covalent inhibitors—a promising class of drugs that form precise, durable bonds with disease-related proteins
August 16, 2025 at 12:16 PM
pubs.acs.org/doi/10.1021/...
A new paper co-authored by QuEra scientists in The Journal of Physical Chemistry Letters explores how quantum computing can transform the simulation of targeted covalent inhibitors—a promising class of drugs that form precise, durable bonds with disease-related proteins
A new paper co-authored by QuEra scientists in The Journal of Physical Chemistry Letters explores how quantum computing can transform the simulation of targeted covalent inhibitors—a promising class of drugs that form precise, durable bonds with disease-related proteins
Researchers from our partners Amazon Web Services (AWS) and JPMorganChase present
"qReduMIS: A Quantum-Informed Reduction Algorithm for the Maximum Independent Set Problem"
🔗 arXiv: arxiv.org/abs/2503.1...
"qReduMIS: A Quantum-Informed Reduction Algorithm for the Maximum Independent Set Problem"
🔗 arXiv: arxiv.org/abs/2503.1...
qReduMIS: A Quantum-Informed Reduction Algorithm for the Maximum...
We propose and implement a quantum-informed reduction algorithm for the maximum independent set problem that integrates classical kernelization techniques with information extracted from quantum...
arxiv.org
April 4, 2025 at 7:09 PM
Researchers from our partners Amazon Web Services (AWS) and JPMorganChase present
"qReduMIS: A Quantum-Informed Reduction Algorithm for the Maximum Independent Set Problem"
🔗 arXiv: arxiv.org/abs/2503.1...
"qReduMIS: A Quantum-Informed Reduction Algorithm for the Maximum Independent Set Problem"
🔗 arXiv: arxiv.org/abs/2503.1...
"Quantum automated learning with provable and explainable trainability"
arxiv.org/abs/2502.0...
This paper proposes a new gradient-free method to train quantum neural networks without separately encoding inputs in independent circuits, potentially leading to a massive saving of shots in practice.
arxiv.org/abs/2502.0...
This paper proposes a new gradient-free method to train quantum neural networks without separately encoding inputs in independent circuits, potentially leading to a massive saving of shots in practice.
Quantum automated learning with provable and explainable trainability
Machine learning is widely believed to be one of the most promising practical applications of quantum computing. Existing quantum machine learning schemes typically employ a quantum-classical...
arxiv.org
March 28, 2025 at 3:36 PM
"Quantum automated learning with provable and explainable trainability"
arxiv.org/abs/2502.0...
This paper proposes a new gradient-free method to train quantum neural networks without separately encoding inputs in independent circuits, potentially leading to a massive saving of shots in practice.
arxiv.org/abs/2502.0...
This paper proposes a new gradient-free method to train quantum neural networks without separately encoding inputs in independent circuits, potentially leading to a massive saving of shots in practice.
QuEra’s Aquila, currently the only neutral-atom quantum processor available on a public cloud, continues to demonstrate its value across various applications. In this work, a team led by George Siopsis showcases how to measure the dynamic structure factor of a magnetic system using Aquila.
1/3
1/3
January 12, 2025 at 7:29 PM
QuEra’s Aquila, currently the only neutral-atom quantum processor available on a public cloud, continues to demonstrate its value across various applications. In this work, a team led by George Siopsis showcases how to measure the dynamic structure factor of a magnetic system using Aquila.
1/3
1/3
A paper that caught our attention: hubs.ly/Q02_Hm8D0
Thanks to coherent atomic shuttling, the exploration space for optimal algorithm compilation in neutral-atom quantum computers remains a promising area of innovation.
1/3
Thanks to coherent atomic shuttling, the exploration space for optimal algorithm compilation in neutral-atom quantum computers remains a promising area of innovation.
1/3
Reuse-Aware Compilation for Zoned Quantum Architectures Based on...
Quantum computing architectures based on neutral atoms offer large scales and high-fidelity operations. They can be heterogeneous, with different zones for storage, entangling operations, and...
hubs.ly
January 3, 2025 at 1:17 PM
A paper that caught our attention: hubs.ly/Q02_Hm8D0
Thanks to coherent atomic shuttling, the exploration space for optimal algorithm compilation in neutral-atom quantum computers remains a promising area of innovation.
1/3
Thanks to coherent atomic shuttling, the exploration space for optimal algorithm compilation in neutral-atom quantum computers remains a promising area of innovation.
1/3
A paper that caught our attention arXiv: hubs.ly/Q02_Hkj00
Most of the anticipated high-impact applications of quantum computing in the field of quantum simulation involve degrees of freedom known as fermions, such as electrons in materials and quarks in high-energy systems.
Most of the anticipated high-impact applications of quantum computing in the field of quantum simulation involve degrees of freedom known as fermions, such as electrons in materials and quarks in high-energy systems.
Fermion-qubit fault-tolerant quantum computing
Simulating the dynamics of electrons and other fermionic particles in quantum chemistry, material science, and high-energy physics is one of the most promising applications of fault-tolerant...
hubs.ly
December 30, 2024 at 3:05 PM
A paper that caught our attention arXiv: hubs.ly/Q02_Hkj00
Most of the anticipated high-impact applications of quantum computing in the field of quantum simulation involve degrees of freedom known as fermions, such as electrons in materials and quarks in high-energy systems.
Most of the anticipated high-impact applications of quantum computing in the field of quantum simulation involve degrees of freedom known as fermions, such as electrons in materials and quarks in high-energy systems.