PHYSICAL LAYOUTS OF MAJORANA-BASED QUBITS FOR IMPLEMENTATIONS OF PENTAGONAL TILINGS

Organization Name

microsoft technology licensing, llc

Inventor(s)

Parsa Bonderson of Santa Barbara CA (US)

David Alexander Aasen of Santa Barbara CA (US)

Christina Paulsen Knapp of Goleta CA (US)

PHYSICAL LAYOUTS OF MAJORANA-BASED QUBITS FOR IMPLEMENTATIONS OF PENTAGONAL TILINGS - A simplified explanation of the abstract

This abstract first appeared for US patent application 20240119331 titled 'PHYSICAL LAYOUTS OF MAJORANA-BASED QUBITS FOR IMPLEMENTATIONS OF PENTAGONAL TILINGS

Simplified Explanation

The physical layouts of Majorana-based qubits for implementations of pentagonal tilings are described in the patent application. An example quantum device consists of a set of tetrons arranged in a lattice to enable pentagonal tilings associated with the qubits. The vertices of the pentagonal tilings correspond to single qubit operations, while the edges connect different vertices and relate to 2-qubit operations.

• Majorana-based qubits implemented using tetrons in a lattice arrangement for pentagonal tilings
• Vertices of pentagonal tilings correspond to single qubit operations, while edges relate to 2-qubit operations

Potential Applications

The technology could be applied in quantum computing, specifically in the development of quantum devices using Majorana-based qubits arranged in pentagonal tilings.

Problems Solved

This technology addresses the challenge of implementing qubits in a unique physical layout that allows for efficient single qubit and 2-qubit operations.

Benefits

- Enables the implementation of Majorana-based qubits in a novel physical layout - Facilitates single qubit and 2-qubit operations in quantum computing systems

Potential Commercial Applications

• Quantum computing devices utilizing Majorana-based qubits in pentagonal tiling layouts

Possible Prior Art

There may be prior art related to the use of Majorana-based qubits in quantum computing systems, but specific examples would need to be researched further.

Unanswered Questions

How does this technology compare to existing qubit implementations in terms of efficiency and scalability?

The article does not provide a direct comparison to existing qubit implementations, so further research would be needed to understand the advantages and limitations of this technology.

What are the potential challenges in manufacturing quantum devices based on this technology at scale?

The article does not address the potential challenges in manufacturing quantum devices using Majorana-based qubits in pentagonal tiling layouts, so additional investigation would be required to assess the scalability of the technology.

Original Abstract Submitted

physical layouts of majorana-based qubits for implementations of pentagonal tilings are described. an example quantum device comprises a set of tetrons for enabling majorana-based qubits. the set of tetrons is arranged in a lattice to allow pentagonal tilings associated with the set of tetrons. the vertices of the pentagonal tilings relate to the qubits and single qubit operations, and the edges of the pentagonal tilings (connecting different vertices) relate to 2-qubit operations acting on a pair of qubits connected by a given edge. as an example, the 1-qubit pauli measurements relate to the operations performed on the vertices associated with the pentagonal tilings and the 2-qubit measurements relate to the operations performed along the edges of the pentagonal tilings.