Affiliation:
1. Blackett Laboratory, Imperial College London , SW7 2AZ London, United Kingdom
Abstract
There is a growing demand for quantum computing across various sectors, including finance, materials, and studying chemical reactions. A promising implementation involves semiconductor qubits utilizing quantum dots within transistors. While academic research labs currently produce their own devices, scaling this process is challenging, requires expertise, and results in devices of varying quality. Some initiatives are exploring the use of commercial transistors, offering scalability, improved quality, affordability, and accessibility for researchers. This paper delves into potential realizations and the feasibility of employing off-the-shelf commercial devices for qubits. It addresses challenges such as noise, coherence, limited customizability in large industrial fabs, and scalability issues. The exploration includes discussions on potential manufacturing approaches for early versions of small qubit chips. The use of state-of-the-art transistors as hosts for quantum dots, incorporating readout techniques based on charge sensing or reflectometry, and methods like electron shuttling for qubit connectivity are examined. Additionally, more advanced designs, including 2D arrays and crossbar or DRAM-like access arrays, are considered for the path toward accessible quantum computing.
Funder
Engineering and Physical Sciences Research Council
Samsung GRC
Reference96 articles.
1. Compilation and scaling strategies for a silicon quantum processor with sparse two-dimensional connectivity;npj Quantum Inf.,2023
2. CloudTern Solutions, see https://www.linkedin.com/pulse/quantum-computing-cloud-services-glimpse-future-cloudtern/ for “
Quantum computing and cloud services: A glimpse into the Future” (2023).
3. Quantum computing and cloud computing,2023
4. Qubits made by advanced semiconductor manufacturing;Nat. Electron.,2022