Nord Quantique’s Quantum Leap with Multimode Encoding

North Quantique

Nord Quantique, a quantum error correction company, demonstrated multimode encoding with QEC. This breakthrough can lower the number of physical qubits needed to build fault-tolerant quantum computers.

Quantum error correction is an accepted part of fault-tolerant quantum computing (FTQC). It shields logical quantum information from quantum system physical noise during computation. The typical QEC approach distributes logical qubits among many physical two-level systems for redundancy. However, this strategy builds large, inefficient, complicated, and energy-intensive devices, which hinders quantum computing.

Nord Quantique uses bosonic qubits and multimode encoding in its innovative technique. Error correction using quantum oscillators' vast Hilbert space may make bosonic codes more hardware-efficient for FTQC. Multimode encoding encodes qubits simultaneously utilising many quantum modes.

Each mode in an aluminium cavity has a unique resonance frequency, adding redundancy to quantum data. This strategy increases error correction and detection without increasing physical qubits.

The technology being shown is the complex bosonic Tesseract algorithm. Tesseract, a two-mode grid code, includes capabilities not seen in single-mode implementations.

This multimode encoding method has many advantages:

Many fewer physical qubits needed for QEC.

Protection against control errors, phase flips, and bit flips.

Ability to detect leakage errors that single-mode encodings may miss.

Improved error detection and tools while retaining a consistent amount of physical qubits.

Greater robustness to transmon and auxiliary control system errors. The Tesseract code, a multimode code, can push the state out of the logical space to measure "silent logical errors" caused by auxiliary faults during stabilisation in single-mode grid state encoding.

In particular, the Tesseract code's isthmus reduces auxiliary decay faults. It ensures that logical errors leave signatures for identification and mitigation, unlike single-mode grid code implementations where auxiliary degradation may cause undiscovered faults.

Silent fault suppression improves logic.

Extracting “confidence information” from data improves error detection and rectification.

Increased system scale benefits fault-tolerant quantum computing.

This discovery is noteworthy, according to Nord Quantique CEO Julien Camirand Lemyre: “It sector has long had a significant challenge regarding the quantity of physical qubits devoted to quantum error correction. The system becomes enormous, inefficient, and complex when physical qubits are used for redundancy, increasing energy needs.

He said multimode encoding lets us build quantum computers with better error correction without all those physical qubits. Our machines will be more compact and functional and use less energy, which HPC facilities, where energy costs are important, will like.

The demonstration is the first multimode grid code experiment. The project used a single-unit prototype for a scalable multimode logical qubit. One auxiliary transmon qubit controls two oscillator modes in a superconducting multimode 3D cavity in this prototype.

This design controls several bosonic modes without hardware overhead, enabling scalability. The procedure relies on the multimode Echoed Conditional Displacement (ECD) gate for bosonic mode entangling.

The experiment successfully demonstrated how to prepare Tesseract code logical states like |± ¯Z⟩, |± ¯X⟩, and |± ¯Y⟩. These states were created using two-mode ECD gates and supplementary rotations. The prepared logical states averaged two photons per mode and 0.86 fidelity.

After state preparation, Nord Quantique created a fully autonomous Tesseract logical qubit QEC protocol. Two-mode enhancement of the sBs protocol with an autonomous auxiliary reset.

To calculate logical qubit confidence, the protocol used mid-circuit measurements. This data can be used to improve error correction, even if the auxiliary qubit is reset after each measurement to retain protocol autonomy. Erasure-based error suppression discards mid-circuit reading-identified experimental runs.

A 12.6% rejection probability was found in the complete erasing limit, where all shots with at least one reported inaccuracy are destroyed. Despite 32 QEC rounds, no logical degradation was seen. This is much better than earlier single-mode grid code implementations, when a full erasure limit only slightly reduced logical errors.

Nord Quantique's implementation lost no statistically significant logical information after 32 QEC rounds. Using mid-circuit measurements, the logical error per round without erasure was 3.5(3) × 10−2. This rate was identical to that without mid-circuit measurements, demonstrating that they did not significantly reduce performance.

This experiment shows that multimode bosonic codes, which increase the number of modes per logical qubit, provide a complementary “scaling axis”. This expanded encoding method expands fault-tolerant quantum computing and error correction.

The isthmus property, confidence information extraction, and suppression of silent errors that lengthen logical lifetimes are benefits of the Tesseract code. Unlike past grid-state implementations, the Tesseract algorithm guarantees that a single auxiliary decay cannot cause unanticipated logical errors, improving fault tolerance.

This study follows Nord Quantique's hardware-efficient bosonic code technique for scalable fault-tolerant quantum computing. As systems evolve, the approach can produce a roughly 1:1 ratio of logical qubits to physical cavities. This creates smaller, more useful systems. Nord Quantique estimates that a 1,000-qubit quantum computer might fit in a data centre and take up 20 square meters. Energy efficiency is great using the procedure. Nord Quantique predicts that solving RSA-830 will take 120 kWh per hour and 280,000 kWh over nine days for HPC.

I admire these results and their multimode logical qubit encoding. Principal Yvonne Gao noted Tesseract states rectify mistakes well. National University of Singapore Assistant Professor and Centre for Quantum Technologies Investigator. It's a big step towards utility-scale quantum computing.

Nord Quantique believes this scientific discovery will enable utility-scale fault-tolerance. The team plans to use devices with extra modes to push quantum error correction farther and improve results. The company plans to build utility-scale quantum computers with over 100 logical qubits by 2029.