Quantum information density scaling and qubit operation time constraints of CMOS silicon-based quantum computer architectures

Abstract Even the quantum simulation of an apparently simple molecule such as Fe2S2 requires a considerable number of qubits of the order of 106, while more complex molecules such as alanine (C3H7NO2) require about a hundred times more. In order to assess such a multimillion scale of identical qubit...

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Main Authors: Davide Rotta, Fabio Sebastiano, Edoardo Charbon, Enrico Prati
Format: Article
Language:English
Published: Nature Publishing Group 2017-06-01
Series:npj Quantum Information
Online Access:https://doi.org/10.1038/s41534-017-0023-5
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spelling doaj-a5d67fed2ed349b7acaa148e6c77fa982020-12-08T14:02:57ZengNature Publishing Groupnpj Quantum Information2056-63872017-06-013111410.1038/s41534-017-0023-5Quantum information density scaling and qubit operation time constraints of CMOS silicon-based quantum computer architecturesDavide Rotta0Fabio Sebastiano1Edoardo Charbon2Enrico Prati3Istituto di Fotonica e NanotecnologieFaculty of Electrical Engineering, Delft University of TechnologyFaculty of Electrical Engineering, Delft University of TechnologyIstituto di Fotonica e NanotecnologieAbstract Even the quantum simulation of an apparently simple molecule such as Fe2S2 requires a considerable number of qubits of the order of 106, while more complex molecules such as alanine (C3H7NO2) require about a hundred times more. In order to assess such a multimillion scale of identical qubits and control lines, the silicon platform seems to be one of the most indicated routes as it naturally provides, together with qubit functionalities, the capability of nanometric, serial, and industrial-quality fabrication. The scaling trend of microelectronic devices predicting that computing power would double every 2 years, known as Moore’s law, according to the new slope set after the 32-nm node of 2009, suggests that the technology roadmap will achieve the 3-nm manufacturability limit proposed by Kelly around 2020. Today, circuital quantum information processing architectures are predicted to take advantage from the scalability ensured by silicon technology. However, the maximum amount of quantum information per unit surface that can be stored in silicon-based qubits and the consequent space constraints on qubit operations have never been addressed so far. This represents one of the key parameters toward the implementation of quantum error correction for fault-tolerant quantum information processing and its dependence on the features of the technology node. The maximum quantum information per unit surface virtually storable and controllable in the compact exchange-only silicon double quantum dot qubit architecture is expressed as a function of the complementary metal–oxide–semiconductor technology node, so the size scale optimizing both physical qubit operation time and quantum error correction requirements is assessed by reviewing the physical and technological constraints. According to the requirements imposed by the quantum error correction method and the constraints given by the typical strength of the exchange coupling, we determine the workable operation frequency range of a silicon complementary metal–oxide–semiconductor quantum processor to be within 1 and 100 GHz. Such constraint limits the feasibility of fault-tolerant quantum information processing with complementary metal–oxide–semiconductor technology only to the most advanced nodes. The compatibility with classical complementary metal–oxide–semiconductor control circuitry is discussed, focusing on the cryogenic complementary metal–oxide–semiconductor operation required to bring the classical controller as close as possible to the quantum processor and to enable interfacing thousands of qubits on the same chip via time-division, frequency-division, and space-division multiplexing. The operation time range prospected for cryogenic control electronics is found to be compatible with the operation time expected for qubits. By combining the forecast of the development of scaled technology nodes with operation time and classical circuitry constraints, we derive a maximum quantum information density for logical qubits of 2.8 and 4 Mqb/cm2 for the 10 and 7-nm technology nodes, respectively, for the Steane code. The density is one and two orders of magnitude less for surface codes and for concatenated codes, respectively. Such values provide a benchmark for the development of fault-tolerant quantum algorithms by circuital quantum information based on silicon platforms and a guideline for other technologies in general.https://doi.org/10.1038/s41534-017-0023-5
collection DOAJ
language English
format Article
sources DOAJ
author Davide Rotta
Fabio Sebastiano
Edoardo Charbon
Enrico Prati
spellingShingle Davide Rotta
Fabio Sebastiano
Edoardo Charbon
Enrico Prati
Quantum information density scaling and qubit operation time constraints of CMOS silicon-based quantum computer architectures
npj Quantum Information
author_facet Davide Rotta
Fabio Sebastiano
Edoardo Charbon
Enrico Prati
author_sort Davide Rotta
title Quantum information density scaling and qubit operation time constraints of CMOS silicon-based quantum computer architectures
title_short Quantum information density scaling and qubit operation time constraints of CMOS silicon-based quantum computer architectures
title_full Quantum information density scaling and qubit operation time constraints of CMOS silicon-based quantum computer architectures
title_fullStr Quantum information density scaling and qubit operation time constraints of CMOS silicon-based quantum computer architectures
title_full_unstemmed Quantum information density scaling and qubit operation time constraints of CMOS silicon-based quantum computer architectures
title_sort quantum information density scaling and qubit operation time constraints of cmos silicon-based quantum computer architectures
publisher Nature Publishing Group
series npj Quantum Information
issn 2056-6387
publishDate 2017-06-01
description Abstract Even the quantum simulation of an apparently simple molecule such as Fe2S2 requires a considerable number of qubits of the order of 106, while more complex molecules such as alanine (C3H7NO2) require about a hundred times more. In order to assess such a multimillion scale of identical qubits and control lines, the silicon platform seems to be one of the most indicated routes as it naturally provides, together with qubit functionalities, the capability of nanometric, serial, and industrial-quality fabrication. The scaling trend of microelectronic devices predicting that computing power would double every 2 years, known as Moore’s law, according to the new slope set after the 32-nm node of 2009, suggests that the technology roadmap will achieve the 3-nm manufacturability limit proposed by Kelly around 2020. Today, circuital quantum information processing architectures are predicted to take advantage from the scalability ensured by silicon technology. However, the maximum amount of quantum information per unit surface that can be stored in silicon-based qubits and the consequent space constraints on qubit operations have never been addressed so far. This represents one of the key parameters toward the implementation of quantum error correction for fault-tolerant quantum information processing and its dependence on the features of the technology node. The maximum quantum information per unit surface virtually storable and controllable in the compact exchange-only silicon double quantum dot qubit architecture is expressed as a function of the complementary metal–oxide–semiconductor technology node, so the size scale optimizing both physical qubit operation time and quantum error correction requirements is assessed by reviewing the physical and technological constraints. According to the requirements imposed by the quantum error correction method and the constraints given by the typical strength of the exchange coupling, we determine the workable operation frequency range of a silicon complementary metal–oxide–semiconductor quantum processor to be within 1 and 100 GHz. Such constraint limits the feasibility of fault-tolerant quantum information processing with complementary metal–oxide–semiconductor technology only to the most advanced nodes. The compatibility with classical complementary metal–oxide–semiconductor control circuitry is discussed, focusing on the cryogenic complementary metal–oxide–semiconductor operation required to bring the classical controller as close as possible to the quantum processor and to enable interfacing thousands of qubits on the same chip via time-division, frequency-division, and space-division multiplexing. The operation time range prospected for cryogenic control electronics is found to be compatible with the operation time expected for qubits. By combining the forecast of the development of scaled technology nodes with operation time and classical circuitry constraints, we derive a maximum quantum information density for logical qubits of 2.8 and 4 Mqb/cm2 for the 10 and 7-nm technology nodes, respectively, for the Steane code. The density is one and two orders of magnitude less for surface codes and for concatenated codes, respectively. Such values provide a benchmark for the development of fault-tolerant quantum algorithms by circuital quantum information based on silicon platforms and a guideline for other technologies in general.
url https://doi.org/10.1038/s41534-017-0023-5
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