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author Croot, Xanthe
Nowrouzi, Kasra
Spitzer, Christopher
Almudever, Carmen G.
Blais, Alexandre
Carroll, Malcolm
Chow, Jerry
Friedman, Daniel
Tokunari, Masao
Charbon, Edoardo
Chidambaram, Vivek
Cleland, Andrew N.
Danovitch, David
Emerson, Joseph
Gunnarsson, David
Laflamme, Raymond
Martinis, John
McDermott, Robert
Oliver, William D.
Pioro-Ladriere, Michel
Sato, Yoshiaki
Ohata, Hidenori
Semba, Kouichi
Siddiqi, Irfan
author_facet Croot, Xanthe
Nowrouzi, Kasra
Spitzer, Christopher
Almudever, Carmen G.
Blais, Alexandre
Carroll, Malcolm
Chow, Jerry
Friedman, Daniel
Tokunari, Masao
Charbon, Edoardo
Chidambaram, Vivek
Cleland, Andrew N.
Danovitch, David
Emerson, Joseph
Gunnarsson, David
Laflamme, Raymond
Martinis, John
McDermott, Robert
Oliver, William D.
Pioro-Ladriere, Michel
Sato, Yoshiaki
Ohata, Hidenori
Semba, Kouichi
Siddiqi, Irfan
contents Experiments with superconducting quantum processors have successfully demonstrated the basic functions needed for quantum computation and evidence of utility, albeit without a sizable array of error-corrected qubits. The realization of the full potential of quantum computing centers on achieving large scale fault-tolerant quantum computers. Science, engineering and industry advances are needed to robustly generate, sustain, and efficiently manipulate an exponentially large computational (Hilbert) space as well as supply the number and quality components needed for such a scaled system. In this article, we suggest critical areas of quantum system and ecosystem development, with respect to the handling and transmission of quantum information within and out of a cryogenic environment, that would accelerate the development of quantum computers based on superconducting circuits.
format Preprint
id arxiv_https___arxiv_org_abs_2512_15001
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Enabling Technologies for Scalable Superconducting Quantum Computing
Croot, Xanthe
Nowrouzi, Kasra
Spitzer, Christopher
Almudever, Carmen G.
Blais, Alexandre
Carroll, Malcolm
Chow, Jerry
Friedman, Daniel
Tokunari, Masao
Charbon, Edoardo
Chidambaram, Vivek
Cleland, Andrew N.
Danovitch, David
Emerson, Joseph
Gunnarsson, David
Laflamme, Raymond
Martinis, John
McDermott, Robert
Oliver, William D.
Pioro-Ladriere, Michel
Sato, Yoshiaki
Ohata, Hidenori
Semba, Kouichi
Siddiqi, Irfan
Quantum Physics
Experiments with superconducting quantum processors have successfully demonstrated the basic functions needed for quantum computation and evidence of utility, albeit without a sizable array of error-corrected qubits. The realization of the full potential of quantum computing centers on achieving large scale fault-tolerant quantum computers. Science, engineering and industry advances are needed to robustly generate, sustain, and efficiently manipulate an exponentially large computational (Hilbert) space as well as supply the number and quality components needed for such a scaled system. In this article, we suggest critical areas of quantum system and ecosystem development, with respect to the handling and transmission of quantum information within and out of a cryogenic environment, that would accelerate the development of quantum computers based on superconducting circuits.
title Enabling Technologies for Scalable Superconducting Quantum Computing
topic Quantum Physics
url https://arxiv.org/abs/2512.15001