Leading the charge toward large-scale, fully fault-tolerant quantum computing
Experience the accuracy, reliability, and performance of the world’s most powerful quantum hardware. Driven by our world-class team of scientists and engineers, we are focused on increasing our computational power year over year to bring large-scale fault-tolerant quantum computing to reality.
We're setting the bar for quantum computing
Meet our world-leading quantum computers
A Technology Roadmap You Can Trust
1
Proven to scale through QCCD architecture:
A quantum charge-coupled device (QCCD) architecture enables a clear path to scaling while maintaining extremely high fidelity operations.
2
Real-time error correction enabled by mid-circuit measurement:
Measure select qubits in real-time and condition future quantum operations all while inadvertently measuring other qubits. This capability is crucial to creating fault-tolerant quantum computers and enabled the first ever demonstration of real-time quantum error correction.
3
Greater control, stronger results:
Moving and regrouping qubits into arbitrary pairs, which we call all-to-all connectivity, with near-perfect fidelity enables users to have maximum flexibility in algorithm design. This enables resource reduction in the computational steps required to executing quantum algorithms, thereby providing higher-fidelity results.
We are working on building the industry’s most capable quantum computing platform, combining high-fidelity trapped-ion hardware, scalable system architecture, and advanced quantum software to unlock commercially useful quantum applications.
We have consistently delivered on our promises, from Quantum Volume results to commercial systems delivered on time and on spec.
What makes our trapped-ion systems so transformative
1
Proven to scale through QCCD architecture:
A quantum charge-coupled device (QCCD) architecture enables a clear path to scaling while maintaining extremely high fidelity operations.
2
Real-time error correction enabled by mid-circuit measurement:
Measure select qubits in real-time and condition future quantum operations all while inadvertently measuring other qubits. This capability is crucial to creating fault-tolerant quantum computers and enabled the first ever demonstration of real-time quantum error correction.
3
Greater control, stronger results:
Moving and regrouping qubits into arbitrary pairs, which we call all-to-all connectivity, with near-perfect fidelity enables users to have maximum flexibility in algorithm design. This enables resource reduction in the computational steps required to executing quantum algorithms, thereby providing higher-fidelity results.
Realizing the world-changing power of quantum computing will require many qubits, high physical fidelity, and fault tolerance. Our systems have unparalleled fidelity, combined with all-to-all connectivity, mid-circuit measurement, and qubit reuse, giving us an unmatched advantage for pushing the field of quantum computing forward. And the results speak for themselves.
Here’s how our trapped-ion systems deliver on the potential of quantum computing:
Start your journey with the world’s highest-performing quantum computers
Purchase a subscription directly with ԹϺ to access our trapped-ion quantum computers, the world’s leading quantum hardware
Perform quantum chemistry research with InQuanto, state of the art platform utilizing ԹϺ systems for complex molecular and materials simulations
Purchase a subscription on Microsoft Azure with access to ԹϺ Systems
Researchers in the United States may apply for a quantum credits grant on ԹϺ systems through their Quantum Computing User Program (QCUP)
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