量子感测器的全球市场(2026年～2046年)

2025年，全球量子感测器市场发展势头强劲，创纪录的投资浪潮标誌着该技术从实验室研究走向商业化。 2025年第一季，量子技术融资超过12.5亿美元，是前一年的两倍多，其中量子运算公司占了量子相关融资的70%以上。虽然量子运算引起了广泛关注，但量子感测有望在2030年代中期发展成为一个价值数十亿美元的市场，成为量子革命的关键组成部分。

这一成长轨迹反映了该技术独特的价值主张：利用迭加和纠缠等量子力学现象，在从医疗诊断到地质勘探等广泛应用中实现远超传统感测器的测量精度。近期的融资亮点表明，投资者对量子感测应用的信心持续增强。 QSENSATO 是巴里大学的衍生公司，致力于开发基于晶片的量子感测器。该公司于 2025 年 5 月从 LIFTT 和 Quantum Italia 获得了 50 万欧元的种子轮融资，用于推进其微型蒸汽室技术，使其能够应用于脑部造影和地质勘探等应用。 2024-2025 年期间的其他重要投资包括 Q-CTRL 的 5,900 万美元 B-2 轮融资、Aquark Technologies 由北约创新基金领投的 500 万美元种子轮融资，以及学术机构和产业参与者之间的各种合作。 政府措施继续透过战略资助项目推动市场扩张。中国宣布计划在包括量子技术在内的尖端领域投资 1 兆元人民币（1,380.1 亿美元），美国能源部也为量子运算计画拨款 6,500 万美元。 "国家量子计画再授权法案" 授权联邦政府在五年内拨款 27 亿美元，凸显了量子科技的战略重要性。

市场格局揭示了不同成熟度的技术领域。原子钟代表着最成熟的领域，在通讯和导航系统中拥有成熟的应用。磁性感测器，尤其是超量子干涉仪 (SQUID) 和基于 NV 的磁力仪，占了很大的市场占有率，这主要得益于医疗应用和先进材料表征技术的发展。量子重力仪和射频感测器等新技术在专业应用中越来越受欢迎。

主要的市场挑战包括：实现实体封装的小型化以实现量产；降低成本以实现广泛应用；以及开发能够明显展现其优于传统替代方案价值的特定应用解决方案。技术成熟度的提升、企业信誉的提升以及地缘政治的迫切性，这些因素的共同作用，使量子感测器产业处于转折点。随着该技术从概念验证转向商业部署，对量子生态系统的大量投资将使量子感测器处于有利地位，并有望在 2030 年前在各个行业中实现其变革潜力。

本报告探讨了全球量子感测器市场，研究了量子感测器技术在多个产业的变革潜力，并提供了未来 20 年的详细市场预测、竞争分析和策略建议。

目录

第1章 摘要整理

• 第一次与第二次量子革命
• 当前量子技术市场格局
• 投资版图
• 全球政府举措
• 产业趋势 (2024-2025)
• 市场驱动因素
• 市场与技术挑战
• 科技趋势与创新
• 市场预测与未来展望
• 新兴应用程式和用例
• 量子导航
• 量子感测器技术基准
• 潜在的颠覆性技术
• 市场地图
• 全球量子感测器市场
• 量子感测器路线图

第2章 简介

• 什么是量子感测？
• 量子感测器的类型
• 量子感测原理
• 量子现象
• 技术平台
• 量子感测技术与应用
• 量子感测器的价值主张
• SWOT 分析

第3章 量子感测零组件

• 概述
• 专用元件
• 蒸气室
• 垂直腔面发射雷射 (VCSEL)
• 量子感测器的控制电子元件
• 整合光子和半导体技术
• 挑战
• 发展路线图

第4章 原子手錶

• 技术概述
• 市场
• 发展路线图
• 高频振盪器
• 新型原子钟技术
• 光学原子钟
• 原子钟小型化面临的挑战
• 公司
• SWOT 分析
• 市场预测

第5章 量子磁场感测器

• 技术概述
• 市场机遇
• 效能
• 超导量子干涉仪 (Squids)
• 光泵磁强计 (OPM)
• 隧道磁阻感知器 (TMR)
• 氮空位中心 (NV 中心)
• 市场预测

第6章 量子重力计

• 技术概要
• 运行原理
• 用途
• 蓝图
• 企业
• 市场预测
• SWOT分析

第7章 量子陀螺仪

• 技术的说明
• 用途
• 蓝图
• 企业
• 市场预测
• SWOT分析

第8章 量子影像感测器

• 技术概要
• 用途
• SWOT分析
• 市场预测
• 企业

第9章 量子雷达

• 技术概要
• 用途

第10章 量化学感测器

• 技术概要
• 商业活动

第11章 量子RF现场感测器

• 概述
• 量子射频感测器的类型
• 基于里德堡原子的电场感测器和无线接收器
• 氮空位中心钻石电场感测器和无线接收器
• 市场与应用
• 市场预测

第12章 量子NEMS/MEMS

• 技术概要
• 类型
• 用途
• 课题

第13章 案例研究

• 医学中的量子感测器：早期疾病检测
• 军事应用：增强型导航系统
• 环境监测
• 金融领域：高频交易
• 量子互联网：安全通讯网络

第14章 最终用途产业

• 医疗·生命科学
• 防卫·军事
• 环境监测
• 石油、天然气
• 运输·汽车
• 其他的产业

第15章 企业简介(企业82公司的简介)

第16章 附录

第17章 参考文献

The global quantum sensors market is experiencing increased momentum in 2025, riding a wave of record-breaking investment that signals the technology's transition from laboratory research to commercial reality. The first quarter of 2025 witnessed over $1.25 billion raised across quantum technologies-more than double the previous year-with quantum computing companies receiving more than 70% of all quantum-related funding. While quantum computing dominates headlines, quantum sensing could be worth multiple billions by the mid 2030s, establishing it as a critical component of the broader quantum revolution.

This growth trajectory reflects the technology's unique value proposition: leveraging quantum mechanical phenomena such as superposition and entanglement to achieve measurement precision far beyond classical sensor capabilities across applications ranging from medical diagnostics to geological exploration. Recent funding highlights demonstrate sustained investor confidence in quantum sensing applications. QSENSATO, a University of Bari spin-off developing chip-based quantum sensors, raised Euro-500,000 in pre-seed funding from LIFTT and Quantum Italia in May 2025 to advance miniaturized vapor cell technology for applications including brain imaging and geological surveys. Other notable 2024-2025 investments include Q-CTRL's $59 million Series B-2 round, Aquark Technologies' Euro-5 million seed funding led by the NATO Innovation Fund, and various partnerships between academic institutions and industry players.

Government initiatives continue driving market expansion through strategic funding programs. China announced plans to mobilize 1 trillion yuan ($138.01 billion) into cutting-edge fields including quantum technology, while the U.S. Department of Energy allocated $65 million specifically for quantum computing projects. The National Quantum Initiative Reauthorization Act would authorize $2.7 billion in federal funding over five years, underscoring quantum technologies' strategic importance.

The market landscape reveals distinct technology segments with varying maturity levels. Atomic clocks represent the most mature sector, with established applications in telecommunications and navigation systems. Magnetic sensors, particularly SQUIDs and NV-based magnetometers, comprise a significant percentage of the market, driven by healthcare applications and advanced materials characterization. Emerging technologies including quantum gravimeters and RF sensors are gaining traction in specialized applications.

Key market challenges include scaling miniaturized physics packages for mass production, reducing costs for broader adoption, and developing application-specific solutions that clearly demonstrate value over classical alternatives. The convergence of improved technology maturity, enterprise confidence, and geopolitical urgency positions quantum sensors at an inflection point. As the technology transitions from proof-of-concept to commercial deployment, the substantial investment flowing into the broader quantum ecosystem creates favourable conditions for quantum sensors to realize their transformative potential across multiple industries by 2030.

"The Global Quantum Sensors Market 2026-2046" report provides an exhaustive analysis of the rapidly evolving quantum sensing industry, delivering critical insights for stakeholders, investors, and technology developers. This comprehensive market intelligence report examines the transformative potential of quantum sensor technologies across multiple industry verticals, offering detailed market forecasts, competitive landscape analysis, and strategic recommendations for the next two decades.

Quantum sensors represent a paradigm shift in measurement technology, leveraging quantum mechanical principles to achieve unprecedented precision and sensitivity. This report analyzes market dynamics, technological innovations, and commercial opportunities across all major quantum sensor categories, providing stakeholders with essential intelligence for strategic decision-making in this high-growth market segment.

Report contents include:

• Market Size & Growth Projections: Detailed revenue forecasts and volume analysis from 2026-2046 across all quantum sensor categories
• Technology Roadmaps: Comprehensive development timelines for atomic clocks, magnetometers, gravimeters, gyroscopes, and emerging sensor types
• Competitive Intelligence: In-depth profiles of 85+ leading companies and emerging players in the quantum sensing ecosystem
• Application Analysis: Market opportunities across healthcare, defense, automotive, environmental monitoring, and industrial sectors
• Investment Landscape: Analysis of funding trends, government initiatives, and private sector investments driving market growth
• Market Analysis
  • Global market size and growth projections through 2036
  • Investment landscape and funding trends analysis
  • Market segmentation by technology type and end-use industry
  • Government initiatives and policy impact assessment
  • Technology readiness levels across quantum sensor categories
• Technology Segments
  • Atomic clocks market analysis and commercialization status
  • Magnetic sensors (SQUIDs, OPMs, TMRs, NV-centers) competitive landscape
  • Quantum gravimeters development roadmap and applications
  • Emerging technologies: RF sensors, quantum radar, image sensors
  • Component ecosystem analysis: vapor cells, VCSELs, integrated photonics
• Industry Applications
  • Defense and military applications and market opportunities
  • Healthcare and life sciences adoption drivers and barriers
  • Transportation and automotive integration challenges
  • Environmental monitoring use cases and market potential
  • Oil & gas exploration applications and growth drivers
• Competitive Intelligence
  • Company profiles covering startups to established players
  • Technology differentiation strategies and market positioning
  • Partnership dynamics and supply chain relationships
  • Geographic market distribution and regional advantages
  • M&A activity and consolidation trends
• Strategic Analysis
  • Market entry strategies and timing recommendations
  • Technology platform selection criteria
  • Regulatory environment and compliance requirements
  • Supply chain risk factors and mitigation strategies
  • Business model evolution and pricing trends

This report features comprehensive profiles of 82 leading companies and emerging players across the quantum sensing value chain, providing detailed analysis of their technology platforms, market positioning, strategic partnerships, and commercial activities. Companies profiled include established quantum technology leaders, innovative startups, research institutions, and traditional sensor manufacturers expanding into quantum technologies.

Featured Companies include:

and more....

TABLE OF CONTENTS

1. EXECUTIVE SUMMARY

• 1.1. First and second quantum revolutions
• 1.2. Current quantum technology market landscape
  • 1.2.1. Key developments
• 1.3. Investment landscape
• 1.4. Global government initiatives
• 1.5. Industry developments 2024-2025
• 1.6. Market Drivers
• 1.7. Market and technology challenges
• 1.8. Technology trends and innovations
• 1.9. Market forecast and future outlook
  • 1.9.1. Short-term Outlook (2025-2027)
  • 1.9.2. Medium-term Outlook (2028-2031)
  • 1.9.3. Long-term Outlook (2032-2046)
• 1.10. Emerging applications and use cases
• 1.11. Quantum Navigation
• 1.12. Benchmarking of Quantum Sensor Technologies
• 1.13. Potential Disruptive Technologies
• 1.14. Market Map
• 1.15. Global market for quantum sensors
  • 1.15.1. By sensor type
  • 1.15.2. By volume
  • 1.15.3. By sensor price
  • 1.15.4. By end use industry
• 1.16. Quantum Sensors Roadmapping
  • 1.16.1. Atomic clocks
  • 1.16.2. Quantum magnetometers
  • 1.16.3. Quantum gravimeters
  • 1.16.4. Inertial quantum sensors
  • 1.16.5. Quantum RF sensors
  • 1.16.6. Single photon detectors

2. INTRODUCTION

• 2.1. What is quantum sensing?
• 2.2. Types of quantum sensors
  • 2.2.1. Comparison between classical and quantum sensors
• 2.3. Quantum Sensing Principles
• 2.4. Quantum Phenomena
• 2.5. Technology Platforms
• 2.6. Quantum Sensing Technologies and Applications
• 2.7. Value proposition for quantum sensors
• 2.8. SWOT Analysis

3. QUANTUM SENSING COMPONENTS

• 3.1. Overview
• 3.2. Specialized components
• 3.3. Vapor cells
  • 3.3.1. Overview
  • 3.3.2. Manufacturing
  • 3.3.3. Alkali azides
  • 3.3.4. Companies
• 3.4. VCSELs
  • 3.4.1. Overview
  • 3.4.2. Quantum sensor miniaturization
  • 3.4.3. Companies
• 3.5. Control electronics for quantum sensors
• 3.6. Integrated photonic and semiconductor technologies
• 3.7. Challenges
• 3.8. Roadmap

4. ATOMIC CLOCKS

• 4.1. Technology Overview
  • 4.1.1. Hyperfine energy levels
  • 4.1.2. Self-calibration
• 4.2. Markets
• 4.3. Roadmap
• 4.4. High frequency oscillators
  • 4.4.1. Emerging oscillators
• 4.5. New atomic clock technologies
• 4.6. Optical atomic clocks
  • 4.6.1. Chip-scale optical clocks
  • 4.6.2. Rack-sized atomic clocks
• 4.7. Challenge in atomic clock miniaturization
• 4.8. Companies
• 4.9. SWOT analysis
• 4.10. Market forecasts
  • 4.10.1. Total market
  • 4.10.2. Bench/rack-scale atomic clocks
  • 4.10.3. Chip-scale atomic clocks

5. QUANTUM MAGNETIC FIELD SENSORS

• 5.1. Technology overview
  • 5.1.1. Measuring magnetic fields
  • 5.1.2. Sensitivity
  • 5.1.3. Motivation for use
• 5.2. Market opportunity
• 5.3. Performance
• 5.4. Superconducting Quantum Interference Devices (Squids)
  • 5.4.1. Introduction
  • 5.4.2. Operating principle
  • 5.4.3. Applications
  • 5.4.4. Companies
  • 5.4.5. SWOT analysis
• 5.5. Optically Pumped Magnetometers (OPMs)
  • 5.5.1. Introduction
  • 5.5.2. Operating principle
  • 5.5.3. Applications
    • 5.5.3.1. Miniaturization
    • 5.5.3.2. Navigation
  • 5.5.4. MEMS manufacturing
  • 5.5.5. Companies
  • 5.5.6. SWOT analysis
• 5.6. Tunneling Magneto Resistance Sensors (TMRs)
  • 5.6.1. Introduction
  • 5.6.2. Operating principle
  • 5.6.3. Applications
  • 5.6.4. Companies
  • 5.6.5. SWOT analysis
• 5.7. Nitrogen Vacancy Centers (N-V Centers)
  • 5.7.1. Introduction
  • 5.7.2. Operating principle
  • 5.7.3. Applications
  • 5.7.4. Synthetic diamonds
  • 5.7.5. Companies
  • 5.7.6. SWOT analysis
• 5.8. Market forecasts

6. QUANTUM GRAVIMETERS

• 6.1. Technology overview
• 6.2. Operating principle
• 6.3. Applications
  • 6.3.1. Commercial deployment
  • 6.3.2. Comparison with other technologies
• 6.4. Roadmap
• 6.5. Companies
• 6.6. Market forecasts
• 6.7. SWOT analysis

7. QUANTUM GYROSCOPES

• 7.1. Technology description
  • 7.1.1. Inertial Measurement Units (IMUs)
    • 7.1.1.1. Atomic quantum gyroscopes
    • 7.1.1.2. Quantum accelerometers
      • 7.1.1.2.1. Operating Principles
      • 7.1.1.2.2. Grating magneto-optical traps (MOTs)
      • 7.1.1.2.3. Applications
      • 7.1.1.2.4. Companies
• 7.2. Applications
• 7.3. Roadmap
• 7.4. Companies
• 7.5. Market forecasts
• 7.6. SWOT analysis

8. QUANTUM IMAGE SENSORS

• 8.1. Technology overview
  • 8.1.1. Single photon detectors
  • 8.1.2. Semiconductor single photon detectors
  • 8.1.3. Superconducting single photon detectors
• 8.2. Applications
  • 8.2.1. Single Photon Avalanche Diodes with Time-Correlated Single Photon Counting (TCSPC
  • 8.2.2. Bioimaging
• 8.3. SWOT analysis
• 8.4. Market forecast
• 8.5. Companies

9. QUANTUM RADAR

• 9.1. Technology overview
  • 9.1.1. Quantum entanglement
  • 9.1.2. Ghost imaging
  • 9.1.3. Quantum holography
• 9.2. Applications
  • 9.2.1. Cancer detection
  • 9.2.2. Glucose Monitoring

10. QUANTUM CHEMICAL SENSORS

• 10.1. Technology overview
• 10.2. Commercial activities

11. QUANTUM RADIO FREQUENCY (RF) FIELD SENSORS

• 11.1. Overview
• 11.2. Types of Quantum RF Sensors
• 11.3. Rydberg Atom Based Electric Field Sensors and Radio Receivers
  • 11.3.1. Principles
  • 11.3.2. Commercialization
• 11.4. Nitrogen-Vacancy Centre Diamond Electric Field Sensors and Radio Receivers
  • 11.4.1. Principles
  • 11.4.2. Applications
• 11.5. Market and applications
• 11.6. Market forecast

12. QUANTUM NEMS AND MEMS

• 12.1. Technology overview
• 12.2. Types
• 12.3. Applications
• 12.4. Challenges

13. CASE STUDIES

• 13.1. Quantum Sensors in Healthcare: Early Disease Detection
• 13.2. Military Applications: Enhanced Navigation Systems
• 13.3. Environmental Monitoring
• 13.4. Financial Sector: High-Frequency Trading
• 13.5. Quantum Internet: Secure Communication Networks

14. END-USE INDUSTRIES

• 14.1. Healthcare and Life Sciences
  • 14.1.1. Medical Imaging
  • 14.1.2. Drug Discovery
  • 14.1.3. Biosensing
• 14.2. Defence and Military
  • 14.2.1. Navigation Systems
  • 14.2.2. Underwater Detection
  • 14.2.3. Communication Systems
• 14.3. Environmental Monitoring
  • 14.3.1. Climate Change Research
  • 14.3.2. Geological Surveys
  • 14.3.3. Natural Disaster Prediction
  • 14.3.4. Other Applications
• 14.4. Oil and Gas
  • 14.4.1. Exploration and Surveying
  • 14.4.2. Pipeline Monitoring
  • 14.4.3. Other Applications
• 14.5. Transportation and Automotive
  • 14.5.1. Autonomous Vehicles
  • 14.5.2. Aerospace Navigation
  • 14.5.3. Other Applications
• 14.6. Other Industries
  • 14.6.1. Finance and Banking
  • 14.6.2. Agriculture
  • 14.6.3. Construction
  • 14.6.4. Mining

15. COMPANY PROFILES (82 company profiles)

16. APPENDICES

• 16.1. Research Methodology
• 16.2. Glossary of Terms
• 16.3. List of Abbreviations

17. REFERENCES

List of Tables

• Table 1. First and second quantum revolutions
• Table 2. Quantum Sensing Technologies and Applications
• Table 3. Quantum Technology investments 2012-2025 (millions USD), total
• Table 4. Major Quantum Technologies Investments 2024-2025
• Table 5. Global government initiatives in quantum technologies
• Table 6. Quantum Sensor industry developments 2024-2025
• Table 7. Market Drivers for Quantum Sensors
• Table 8. Market and technology challenges in quantum sensing
• Table 9. Technology Trends and Innovations in Quantum Sensors
• Table 10. Emerging Applications and Use Cases
• Table 11. Benchmarking of Quantum Sensing Technologies by Type
• Table 12. Performance Metrics by Application Domain
• Table 13. Technology Readiness Levels (TRL) and Commercialization Status
• Table 14. Comparative Performance Metrics
• Table 15.Current Research and Development Focus Areas
• Table 16. Potential Disruptive Technologies
• Table 17. Global market for quantum sensors, by types, 2018-2046 (Millions USD)
• Table 18. Global market for quantum sensors, by volume (Units), 2018-2046
• Table 19. Global market for quantum sensors, by sensor price, 2025-2046 (Units)
• Table 20. Global market for quantum sensors, by end use industry, 2018-2046 (Millions USD)
• Table 21.Types of Quantum Sensors
• Table 22. Comparison between classical and quantum sensors
• Table 23. Applications in quantum sensors
• Table 24. Technology approaches for enabling quantum sensing
• Table 25. Key technology platforms for quantum sensing
• Table 26. Quantum sensing technologies and applications
• Table 27. Value proposition for quantum sensors
• Table 28. Components for quantum sensing
• Table 29. Specialized components for atomic and diamond-based quantum sensing
• Table 30. Companies in Chip-Scale Vapor Cell Development
• Table 31. Companies in VCSELs for Quantum Sensing
• Table 32. Challenges for Quantum Sensor Components
• Table 33. Key challenges and limitations of quartz crystal clocks vs. atomic clocks
• Table 34. Atomic clocks End users and addressable markets
• Table 35. Key Market Inflection Points and Technology Transitions
• Table 36. New modalities being researched to improve the fractional uncertainty of atomic clocks
• Table 37. Companies developing high-precision quantum time measurement
• Table 38. Key players in atomic clocks
• Table 39. Global market for atomic clocks 2025-2046 (Billions USD)
• Table 40. Global market for Bench/rack-scale atomic clocks, 2026-2046 (Millions USD)
• Table 41. Global market for Chip-scale atomic clocks, 2026-2046 (Millions USD)
• Table 42. Comparative analysis of key performance parameters and metrics of magnetic field sensors
• Table 43. Types of magnetic field sensors
• Table 44. Market opportunity for different types of quantum magnetic field sensors
• Table 45. Performance of magnetic field sensors
• Table 46. Applications of SQUIDs
• Table 47. Market opportunities for SQUIDs (Superconducting Quantum Interference Devices)
• Table 48. Key players in SQUIDs
• Table 49. Applications of optically pumped magnetometers (OPMs)
• Table 50. MEMS Manufacturing Techniques for Miniaturized OPMs
• Table 51. Key players in Optically Pumped Magnetometers (OPMs)
• Table 52. Applications for TMR (Tunneling Magnetoresistance) sensors
• Table 53. Market players in TMR (Tunneling Magnetoresistance) sensors
• Table 54. Applications of N-V center magnetic field centers
• Table 55. Quantum Grade Diamond
• Table 56. Synthetic Diamond Value Chain for Quantum Sensing
• Table 57. Key players in N-V center magnetic field sensors
• Table 58. Global market forecasts for quantum magnetic field sensors, by type, 2025-2046 (Millions USD)
• Table 59. Applications of quantum gravimeters
• Table 60. Comparative table between quantum gravity sensing and some other technologies commonly used for underground mapping
• Table 61. Key players in quantum gravimeters
• Table 62. Global market for Quantum gravimeters 2025-2046 (Millions USD)
• Table 63. Comparison of quantum gyroscopes with MEMs gyroscopes and optical gyroscopes
• Table 64. Comparison of Quantum Gyroscopes with MEMS Gyroscopes and Optical Gyroscopes
• Table 65. Key Players in Quantum Accelerometers
• Table 66. Markets and applications for quantum gyroscopes
• Table 67. Key players in quantum gyroscopes
• Table 68. Global market for for quantum gyroscopes and accelerometers 2026-2046 (millions USD)
• Table 69. Types of quantum image sensors and their key features
• Table 70. Applications of quantum image sensors
• Table 71. SPAD Bioimaging Applications
• Table 72. Global market for quantum image sensors 2025-2046 (Millions USD)
• Table 73. Key players in quantum image sensors
• Table 74. Comparison of quantum radar versus conventional radar and lidar technologies
• Table 75. Applications of quantum radar
• Table 76. Value Proposition of Quantum RF Sensors
• Table 77. Types of Quantum RF Sensors
• Table 78. Markets for Quantum RF Sensors
• Table 79. Technology Transition Milestones
• Table 80. Application-Specific Adoption Timeline
• Table 81. Global market for quantum RF sensors 2026-2046 (Millions USD)
• Table 82.Types of Quantum NEMS and MEMS
• Table 83. Quantum Sensors in Healthcare and Life Sciences
• Table 84. Quantum Sensors in Defence and Military
• Table 85. Quantum Sensors in Environmental Monitoring
• Table 86. Quantum Sensors in Oil and Gas
• Table 87. Quantum Sensors in Transportation
• Table 88.Glossary of terms
• Table 89. List of Abbreviations

List of Figures

• Figure 1. Quantum computing development timeline
• Figure 2. Quantum Technology investments 2012-2025 (millions USD), total
• Figure 3. National quantum initiatives and funding
• Figure 4. Quantum Sensors: Market and Technology Roadmap to 2040
• Figure 5. Quantum sensor industry market map
• Figure 6. Global market for quantum sensors, by types, 2018-2046 (Millions USD)
• Figure 7. Global market for quantum sensors, by volume, 2018-2046
• Figure 8. Global market for quantum sensors, by sensor price, 2025-2046 (Units)
• Figure 9. Global market for quantum sensors, by end use industry, 2018-2046 (Millions USD)
• Figure 10. Atomic clocks roadmap
• Figure 11. Quantum magnetometers roadmap
• Figure 12. Quantum gravimeters roadmap
• Figure 13. Inertial quantum sensors roadmap
• Figure 14. Quantum RF sensors roadmap
• Figure 15. Single photon detectors roadmap
• Figure 16. Q.ANT quantum particle sensor
• Figure 17. SWOT analysis for quantum sensors market
• Figure 18. Roadmap for quantum sensing components and their applications
• Figure 19. Atomic clocks market roadmap
• Figure 20. Strontium lattice optical clock
• Figure 21. NIST's compact optical clock
• Figure 22. SWOT analysis for atomic clocks
• Figure 23. Global market for atomic clocks 2025-2046 (Billions USD)
• Figure 24. Global market for Bench/rack-scale atomic clocks, 2026-2046 (Millions USD)
• Figure 25. Global market for Chip-scale atomic clocks, 2026-2046 (Millions USD)
• Figure 26. Quantum Magnetometers Market Roadmap
• Figure 27.Principle of SQUID magnetometer
• Figure 28. SWOT analysis for SQUIDS
• Figure 29. SWOT analysis for OPMs
• Figure 30. Tunneling magnetoresistance mechanism and TMR ratio formats
• Figure 31. SWOT analysis for TMR (Tunneling Magnetoresistance) sensors
• Figure 32. SWOT analysis for N-V Center Magnetic Field Sensors
• Figure 33. Global market forecasts for quantum magnetic field sensors, by type, 2025-2046 (Millions USD)
• Figure 34. Quantum Gravimeter
• Figure 35. Quantum gravimeters Market roadmap
• Figure 36. Global market for Quantum gravimeters 2025-2046 (Millions USD)
• Figure 37. SWOT analysis for Quantum Gravimeters
• Figure 38. Inertial Quantum Sensors Market roadmap
• Figure 39. Global market for quantum gyroscopes and accelerometers 2026-2046 (millions USD)
• Figure 40. SWOT analysis for Quantum Gyroscopes
• Figure 41. SWOT analysis for Quantum image sensing
• Figure 42. Global market for quantum image sensors 2025-2046 (Millions USD)
• Figure 43. Principle of quantum radar
• Figure 44. Illustration of a quantum radar prototype
• Figure 45. Quantum RF Sensors Market Roadmap (2023-2046)
• Figure 46. Global market for quantum RF sensors 2026-2046 (Millions USD)
• Figure 47. ColdQuanta Quantum Core (left), Physics Station (middle) and the atoms control chip (right)
• Figure 48. PsiQuantum's modularized quantum computing system networks
• Figure 49. Quantum Brilliance device
• Figure 50. SpinMagIC quantum sensor