A route to scalable Majorana qubits

by QuTech

A route to scalable Majorana qubits
A scanning electron micrograph of a nanodevice that was measured to obtain results presented in the paper. Credit: QuTech

Researchers at QuTech have found a way to make Majorana particles in a two-dimensional plane. This was achieved by creating devices that exploit the combined material properties of superconductors and semiconductors. The inherent flexibility of this new 2D platform should allow one to perform experiments with Majoranas that were previously inaccessible. The results are published in Nature.

Quantum computers operate fundamentally differently from classical computers. While classical computers use bits as the basic unit of information, which can be either 0 or 1, quantum computers use qubits, which can exist in a state of 0, 1, or both simultaneously.

This principle of superposition, combined with new quantum algorithms could allow quantum computers to solve certain problems much more efficiently than classical computers. However, the qubits that store this quantum information are inherently more fragile than classical bits.

Majorana qubits are based on states of matter that are topologically protected. This means that small local disturbances cannot destroy the state of the qubit. This robustness to external influences makes Majorana qubits highly desirable for quantum computing, since quantum information encoded in these states would remain stable for significantly longer times.

Producing a full Majorana qubit requires several steps. The first of these is the ability to reliably engineer Majoranas and to demonstrate that they indeed possess the special properties that make them promising candidates for qubits.

Previously, researchers at QuTech—a collaboration between the TU Delft and TNO—have used a one-dimensional nanowire to demonstrate a new approach to studying Majoranas by creating a Kitaev chain. In this approach, a chain of semiconductor quantum dots are connected via superconductors to produce Majoranas.

The extension of this result to two dimensions has several important implications. First author Bas ten Haaf explains, “By implementing the Kitaev-chain in two dimensions, we show that the underlying physics is universal and platform independent.”

His colleague and co-first author Qingzheng Wang adds, “Given the long-standing challenges with reproducibility in the Majorana research, our results are really encouraging.”

A route to scalable Majorana qubits
Co-authors Bas ten Haaf and Qingzhen Wang demonstrate protection of Majoranas to a local perturbation. Trying to push one of the Majoranas leaves its partner happily unaffected. Credit: Studio Oostrum for QuTech

The ability to create Kitaev chains in two-dimensional systems opens up several avenues for future Majorana research. Principal investigator Srijit Goswami explains, “I believe we are now in a position where we can do interesting physics with Majoranas in order to probe their fundamental properties. For example, we can increase the number of sites in the Kitaev chain and systematically study the protection of Majorana particles.

“In the longer term, the flexibility and scalability of the 2D platform should allow us to think about concrete strategies to create networks of Majoranas and integrate them with auxiliary elements needed for control and readout of a Majorana qubit.”

More information: Srijit Goswami, A two-site Kitaev chain in a two-dimensional electron gas, Nature (2024). DOI: 10.1038/s41586-024-07434-9www.nature.com/articles/s41586-024-07434-9

Journal information: Nature