Qudit

A qudit, characterized by d = 2 states is a qubit.^[1]

Qudits with d states greater than 2 can provide a larger Hilbert space, providing more ways to store and process quantum information.^[2][3]

• Qubit – Qudit with d = 2 states
• Qutrit – Qudit with d = 3 states

Quantum decoherence is the natural process where quantum information is lost due to environmental interaction and quantum error correction is a technique that actively combats decoherence.

In a paper published by Nature on May 2025 researchers at Yale first demonstrate quantum error correction past the break-even point for higher dimensional qudit systems. The team used GKP bosonic codes to encode qudrits with d = 3 and d = 4 in superconducting cavities and optimized the protocol using reinforcement learning.^[4] These findings are regarded as a significant step in the creation of more efficient quantum computers and opens new paths for hardware-lean quantum architectures, fault tolerant computation, and compact error protected memories.^[5]

In a paper published September 2025, researchers demonstrate a new hybrid method that encodes information in both light and matter using a cat state qudit with d > 2, which allows for the detection of photon loss through the parity syndrome by entangling a light pulse with ancillary qubits. This method achieves parallel Bell-pair generation by leveraging the multi-level nature of the qudit.^[6]

The first open source qudit stabilizer simulator named "Sdim" was announced November 2025 in a pre-print paper on arXiv.^[7]

A qudit logic gate (or simply qudit gate) is a basic quantum circuit that acts on a qudit.

To achieve a universal qudit gate, (a gate that can be used to approximate any unitary transformation on a quantum computer to an arbitrary degree of accuracy) a set of gates must include a finite set of single qudit gates and at least one two qudit entangling gate that can create entanglement between qudits.

Qudit control is the precise navigation of a qudit's quantum state through engineered signals to perform quantum computations.

In a paper published December 2025 a team of researchers achieved a breakthrough in qudit control by engineering five level qudits through individually addressable transitions between Zeeman sublevels (see also Zeeman Effect), achieved by combining a large linear Zeeman shift with a state-dependent light shift. Simulations predict state-preparation fidelities of F ≃ 0.99 within ∽1 μs, single-qudit gate fidelities of F ≃ 0.99 with π pulse durations of ∽2.5 μs, and fast destructive imaging with durations below 10 μs. These results establish a broadly applicable framework for high-fidelity control of Zeeman sublevel-encoded qudits and a promising platform for scalable qudit-based quantum technologies.^[8]

Quantum information is traditionally used in Ramsey interferometry, a technique used for precise measurement across various areas of science and technology.

Qudits with d > 2 have shown to increase precision and resolution of quantum measurements. Qutrits, for example, have shown to achieve a twofold increase in resolution compared to qubits without any reduction in measurement contrast.^[9]