中性原子量子电脑市场

中性原子量子计算机预计将成为 "首选" 量子计算机，既是对主流超导量子计算范式的课题，也是迈向更先进机器的途径。预计2025年中性原子电脑出货量仅8台，但到2035年，预计将有超过7,310台中性原子电脑出货。

本报告 "中性原子量子电脑市场" 分析了全球领先的中性原子量子电脑供应商的产品/市场策略。这些供应商包括Atom Computing、Atom Quantum Labs、Infleqtion、M Squared、OpenQuantum、Pasqal、PlanQC和QuERA。报告还深入探讨了晶片和组件製造商在中性原子计算机中看到的机会。晶片/组件领域的知名厂商包括AMD、Hamamatsu Photonics、NanoQT、Nu Quantum、QBlox和Toptica。

该报告也分析了推动中性原子量子电脑成功的关键技术趋势。这些趋势包括使用光子积体电路 (PIC) 来改善尺寸、重量和功耗，能够最佳支援中性原子机器的新材料平台，以及中性原子机器从大型政府和研究机构应用向高效能运算 (HPC) 和资料中心的过渡。对于中性原子量子电脑而言，真正重要的是每量子位元价格仍然具有吸引力。预计中性原子技术将在量子产业媒体上获得越来越正面的评价。目前，Amazon Braket 和 Azure Quantum 是唯一存取中性原子量子电脑的流行方式。

目录

第1章 中性原子技术与产品

• 科技的演进
  • 所用原子
  • 对中性原子日益正面的评价
  • 可近性
• 中性原子成分
  • 原子控制硬体和读出组件
  • 光子和摄影组件
  • 低温恆温器
• 中性原子相关软体
  • 在研究室的工作

第2章 市场与起源

• 对象用途和使用可能性
  • 利用中性原子计算机进行分散式量子计算
  • 资料中心中的天然原子计算机
  • 中性原子的其他用途计算机
• 关于控制和生态系统
• 中性原子电脑的供应结构
• 国家问题
  • 中性原子电脑的全球市场和国内市场
  • 关税的问题

第3章 中性原子技术

• 中性原子电脑
  • Atom Computing(美国)
  • Atom Quantum Labs(斯洛维尼亚)
  • Infleqtion(美国)
  • M Squared(英国)
  • OpenQuantum(英国)
  • Pasqal(法国)
  • PlanQC(德国)
  • QuEra Computing(美国)
• 中性原子的结构要素和子系统
  • AMD(美国)
  • Hamamatsu(日本)
  • Lake Shore Cryotronics(美国)
  • MenloSystems(德国)
  • NanoQT(日本)
  • Nexus Photonics(美国)
  • Nu Quantum(英国)
  • OpenQuantum(世界)
  • Qblox(荷兰)
  • Quantum Machines(以色列)
  • Sandia National Laboratories(美国)
  • Toptica Photonics(德国)
  • Vescent(美国)
• 软体
  • aAgnostiq(加拿大)
  • DarkStarStrix(用户註册名)(美国)
  • data cybernetics ssc GmbH(德国)
  • Lawrence Berkeley National Laboratory(LBNL)(美国)
  • M-Labs(香港)
  • Microsoft(美国)
  • Q-CTRL(澳洲)
  • QMWare(瑞士)
  • QPerfect(法国)
  • SimuQ(美国)
  • Wolfram(美国)
• 平台
  • Amazon Braket(美国)
  • qBraid(美国)
  • Strangeworks(美国)
• 国内及国际中心
  • Department of Science and Technology(DOST)
  • European Center for Quantum Sciences(CESQ)(法国)
  • Japan Science and Technology Agency(日本)
  • National Quantum Computing Centre (NQCC)(英国)
  • Russian Quantum Center(俄罗斯)

第4章 中性原子电脑的10年预测

IQT Research believes Neutral Atom Quantum Computers are emerging as "workhorse" quantum computers that are both a challenge to the dominant superconducting quantum computing paradigm and a path forward to even more advanced machines. IQT Research believes that in 2025, only eight neutral atom machines will be shipped but this number will grow to more than 7,310 neutral atom machines by 2035.

This report, "Markets for Neutral Atom Quantum Computers" analyzes the product/market strategies of the leading neutral atom quantum computer vendors worldwide. These include Atom Computing, Atom Quantum Labs, Infleqtion, M Squared, OpenQuantum, Pasqal, PlanQC, and QuERA. But we also dig into the opportunities that the chip and component makers have been finding in neutral atom machines. Prominent firms in the chip/component segment include AMD, Hamamatsu, NanoQT, Nu Quantum, QBlox and Toptica.

This report also analyzes the key technological trends that are spurring the success of neutral atom quantum computers. These include the use of photonic integrated circuits (PICs) to improve size, weight, and power consumption; novel materials platforms that can best support neutral atom machines; and the transition of neutral atom machines from large government and research facilities usage to HPC and the data center. What really matters for neutral atom quantum computers is that $/Qubit continues to be attractive. IQT Research notes that neutral atom technology is portrayed increasingly positively in the quantum trade press. For now, Amazon Braket and Azure Quantum are the only public ways to access a neutral atom quantum computer.

Table of Contents

Chapter One: Neutral Atom Technology and Products

• 1.1. Evolution of Technology
  • 1.1.1. Atoms Used
  • 1.1.2. Neutral Atoms Viewed Increasingly Positively
  • 1.1.3. Accessibility
• 1.2. Neutral Atom Components
  • 1.2.1. Atomic Control Hardware and Readout Components
  • 1.2.2. Photonic and Photographic Components
  • 1.2.3. Cryostats
• 1.3. Neutral Atom-related Software
  • 1.3.1. Work in Research Labs

Chapter Two: Markets and Origins

• 2.1. Target Applications and Possible Uses
  • 2.1.1. Distributed Quantum Computing on Neutral Atom Computers
  • 2.1.2. Neutral Atom Computers in the Data Center
  • 2.1.3. Other Uses for Neutral Atom Computers
• 2.2. Of Control and Ecosystems
• 2.3. Supply Structure for Neutral Atom Computers
• 2.4. National Questions
  • 2.4.1. Worldwide and National Markets for Neutral Atom Computers
  • 2.4.2. The Question of Tariffs

Chapter Three: Neutral Atom Technologies

• 3.1. Neutral Atom Computers
  • 3.1.1. Atom Computing (United States)
  • 3.1.2. Atom Quantum Labs (Slovenia)
  • 3.1.3. Infleqtion (United States)
  • 3.1.4. M Squared (United Kingdom)
  • 3.1.5. OpenQuantum (United Kingdom)
  • 3.1.6. Pasqal (France)
  • 3.1.7. PlanQC (Germany)
  • 3.1.8. QuEra Computing (United States)
• 3.2. Neutral Atom Components and Subsystems
  • 3.2.1. AMD (United States)
  • 3.2.2. Hamamatsu (Japan)
  • 3.2.3. Lake Shore Cryotronics (United States)
  • 3.2.4. MenloSystems (Germany)
  • 3.2.5. NanoQT (Japan)
  • 3.2.6. Nexus Photonics (United States)
  • 3.2.7. Nu Quantum (United Kingdom)
  • 3.2.8. OpenQuantum (Global)
  • 3.2.9. Qblox (The Netherlands)
  • 3.2.10. Quantum Machines (Israel)
  • 3.2.11. Sandia National Laboratories (United States)
  • 3.2.12. Toptica Photonics (Germany)
  • 3.2.13. Vescent (United States)
• 3.3. Software
  • 3.3.1. Agnostiq (Canada)
  • 3.3.2. DarkStarStrix (username) (United States)
  • 3.3.3. data cybernetics ssc GmbH (Germany)
  • 3.3.4. Lawrence Berkeley National Laboratory (LBNL) (United States)
  • 3.3.5. M-Labs (Hong Kong)
  • 3.3.6. Microsoft (United States)
  • 3.3.7. Q-CTRL (Australia)
  • 3.3.8. QMWare (Switzerland)
  • 3.3.9. QPerfect (France)
  • 3.3.10. SimuQ (United States)
  • 3.3.11. Wolfram (United States)
• 3.4. Platforms
  • 3.4.1. Amazon Braket (United States)
  • 3.4.2. qBraid (United States)
  • 3.4.3. Strangeworks (United States)
• 3.5. National and International Centers
  • 3.5.1. Department of Science and Technology (DOST) (Philippines)
  • 3.5.2. European Center for Quantum Sciences (CESQ) (France)
  • 3.5.3. Japan Science and Technology Agency (Japan)
  • 3.5.4. National Quantum Computing Centre (NQCC) (United Kingdom)
  • 3.5.5. Russian Quantum Center (Russia)

Chapter Four: Ten-year Forecasts of Neutral Atom Computer

• 4.1. Forecasting Thoughts
• 4.2. Forecasts, their Uses and Uncertainties
• About the Analyst

Exhibit

• Exhibit 4-1: Ten-year Forecasts of Neutral Atom Quantum Computers