양자 센서 시장(2026-2046년)

Quantum sensing represents a new generation of precision measurement technologies that exploit second-generation quantum mechanical phenomena - superposition, entanglement, and quantum coherence - to surpass the fundamental limits of classical measurement systems. By using quantum particles such as photons or atoms as sensing elements, these devices detect extraordinarily small changes in physical quantities including magnetic fields, gravity, rotation, temperature, time, and electromagnetic spectra, often at the nanoscale and frequently through non-invasive means.

The quantum sensors landscape encompasses a diverse range of device types, including atomic clocks, superconducting quantum interference devices (SQUIDs), optically pumped magnetometers (OPMs), nitrogen-vacancy (NV) centre diamond sensors, quantum gravimeters, quantum gyroscopes and accelerometers, single photon detectors, and quantum radio frequency (RF) sensors. Each platform offers distinct advantages across a broad spectrum of end-use industries spanning healthcare and life sciences, defence and military, environmental monitoring, telecommunications, oil and gas exploration, financial services, and autonomous navigation.

The market is currently transitioning from an emerging phase to an active growth phase, a shift expected to consolidate over the next five to ten years. Sensors are achieving improved precision, stability, and form factors suitable for commercial deployment, while economies of scale and advances in integrated photonics, MEMS vapour cell fabrication, and solid-state laser technologies are steadily reducing costs. Industry roadmaps project that commercial unit prices will fall below $10,000 by approximately 2027-2028, with costs dropping below $5,000 per unit by 2030, enabling wider industrial adoption and integration into high-end commercial equipment.

Miniaturisation is a defining trend. Quantum RF sensors are approaching smartphone-sized packages, and prototype chip-scale atomic magnetometers have already demonstrated volumes below 100 cm3. Further reductions to credit card-sized packages are anticipated by 2030, with fully integrated chip-scale solutions below 1 cm3 projected by the mid-2030s. These advances are underpinned by the transition from discrete optical components to integrated photonic circuits, which significantly reduces both size and manufacturing cost.

The atomic clocks segment is the most commercially mature category. Growth across the broader market is driven by 5G and future 6G infrastructure expansion demanding precision synchronisation, autonomous vehicle deployment requiring quantum-enhanced LiDAR and GPS-independent navigation, defence applications in GPS-denied environments, and emerging quantum technology ecosystems that create synergies between quantum sensing, computing, and communication. Major technology firms including IBM, Google, Microsoft, and Intel continue to dedicate substantial in-house R&D budgets to quantum initiatives, while government programmes worldwide provide critical support for both fundamental research and commercialisation efforts.

Key challenges remain. Manufacturing at scale requires extreme nanoscale precision, high-purity materials with precisely controlled defects, and complex integration of quantum components with control electronics. Competition from well-established conventional sensors, regulatory uncertainty, security and privacy concerns, and the high cost of early-stage systems all present headwinds.

Looking ahead, the medium-term outlook (2028-2031) anticipates expansion into industrial process control and environmental monitoring, integration with 5G/6G networks, and the establishment of quantum sensing industry standards. The longer-term vision (2032 and beyond) encompasses widespread adoption in automotive and aerospace sectors, the emergence of quantum sensing as a service, integration into consumer electronics and IoT devices, and ultimately the development of global quantum sensing networks for applications ranging from climate monitoring to personalised medicine.

The global quantum sensors market is poised for significant growth over the next two decades as miniaturisation, falling costs, and expanding end-use applications accelerate adoption across defence, healthcare, telecommunications, oil and gas, environmental monitoring, transportation, and financial services. This comprehensive market research report provides detailed technology analysis, market forecasts, company profiles, and strategic roadmaps covering the quantum sensors industry from 2026 through 2046.

Report contents include:

• In-depth executive summary covering the first and second quantum revolutions, the current quantum technology market landscape, key developments, and industry developments 2024-2026
• Detailed investment landscape analysis including quantum technology investments from 2012 to 2025 and major funding rounds in 2024-2025
• Global government initiatives and national quantum programmes driving market growth
• Comprehensive market drivers, technology challenges, and SWOT analyses for the quantum sensors market and individual sensor types
• Technology trends and innovations including miniaturisation roadmaps, cost reduction trajectories, and chip-scale quantum sensor development
• Market forecasts and future outlook segmented into short-term (2025-2027), medium-term (2028-2031), and long-term (2032-2046) projections
• Global market forecasts for quantum sensors by sensor type, volume, sensor price, and end-use industry from 2018 to 2046
• Detailed technology overviews, operating principles, applications, roadmaps, and market forecasts for atomic clocks (including bench/rack-scale and chip-scale), quantum magnetic field sensors (SQUIDs, optically pumped magnetometers, tunnelling magnetoresistance sensors, and nitrogen-vacancy centre diamond sensors), quantum gravimeters, quantum gyroscopes and accelerometers, quantum image sensors, quantum radar, quantum chemical sensors, quantum RF field sensors (including Rydberg atom and NV centre diamond platforms), and quantum NEMS and MEMS
• Benchmarking of quantum sensor technologies including technology readiness levels, comparative performance metrics, and current R&D focus areas
• Analysis of quantum sensing components including vapour cells, VCSELs, control electronics, and integrated photonic technologies
• International standardisation landscape covering ISO/IEC, CEN-CENELEC, IEEE, and national metrology institutes
• Emerging applications and use cases including quantum navigation, quantum sensing as a service, and integration with 5G/6G networks
• End-use industry analysis spanning healthcare and life sciences, defence and military, environmental monitoring, oil and gas, transportation and automotive, finance, agriculture, construction, and mining
• Case studies in healthcare early disease detection, military navigation systems, environmental monitoring, high-frequency trading, and quantum internet secure communication networks
• Over 85 company profiles and 89 tables and 50 figures

Companies profiled in this report include Aegiq, Airbus, Aquark Technologies, Artilux, Atomionics, Beyond Blood Diagnostics, Bosch Quantum Sensing, BT, Cerca Magnetics, Chipiron, Chiral Nano AG, Covesion, Delta g, DeteQt, Diatope GmbH, Diffraqtion, Digistain, Element Six, Ephos, EuQlid, Exail Quantum Sensors, Genesis Quantum Technology, ID Quantique, Infleqtion, Ligentec, M Squared Lasers, Mag4Health, Menlo Systems GmbH, Mesa Quantum, Miraex, Munich Quantum Instruments GmbH, NeoCrystech, Neuranics, NIQS Technology Ltd, Nomad Atomics, Nu Quantum, NVision, Phasor Innovation, Photon Force, Polariton Technologies, PsiQuantum, Q.ANT, Qaisec, Q-CTRL, Qingyuan Tianzhiheng Sensing Technology Co. Ltd, QLM Technology, Qnami, QSENSATO, QT Sense B.V., QuantaMap, QuantCAD LLC, Quan2D Technologies, Quantum Brilliance, Quantum Catalyzer (Q-Cat) 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 2024-2026
• 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
• 1.17 International Standardization Landscape
  • 1.17.1 ISO/IEC JTC 3 - Quantum Technologies
  • 1.17.2 CEN-CENELEC JTC 22 - Quantum Technologies (Europe)
  • 1.17.3 IEEE Standards Association
  • 1.17.4 Standardization Gaps Identified for Quantum Sensors
  • 1.17.5 National Metrology Institutes (NMIs)

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 SPECTROSCOPIC MEASUREMENT USING ENTANGLED PHOTONS

• 11.1 Technology overview
• 11.2 Key techniques
• 11.3 Market size and growth outlook
• 11.4 Key companies and commercial activities
• 11.5 Growth drivers and challenges
• 11.6 Market forecast

12 QUANTUM RADIO FREQUENCY (RF) FIELD SENSORS

• 12.1 Overview
• 12.2 Types of Quantum RF Sensors
• 12.3 Rydberg Atom Based Electric Field Sensors and Radio Receivers
  • 12.3.1 Principles
  • 12.3.2 Commercialization
• 12.4 Nitrogen-Vacancy Centre Diamond Electric Field Sensors and Radio Receivers
  • 12.4.1 Principles
  • 12.4.2 Applications
• 12.5 Market and applications
• 12.6 Market forecast

13 QUANTUM NEMS AND MEMS

• 13.1 Technology overview
• 13.2 Types
• 13.3 Applications
• 13.4 Challenges

14 CASE STUDIES

• 14.1 Quantum Sensors in Healthcare: Early Disease Detection
• 14.2 Military Applications: Enhanced Navigation Systems
• 14.3 Environmental Monitoring
• 14.4 Financial Sector: High-Frequency Trading
• 14.5 Quantum Internet: Secure Communication Networks

15 END-USE INDUSTRIES

• 15.1 Healthcare and Life Sciences
  • 15.1.1 Medical Imaging
  • 15.1.2 Drug Discovery
  • 15.1.3 Biosensing
• 15.2 Defence and Military
  • 15.2.1 Navigation Systems
  • 15.2.2 Underwater Detection
  • 15.2.3 Communication Systems
• 15.3 Environmental Monitoring
  • 15.3.1 Climate Change Research
  • 15.3.2 Geological Surveys
  • 15.3.3 Natural Disaster Prediction
  • 15.3.4 Other Applications
• 15.4 Oil and Gas
  • 15.4.1 Exploration and Surveying
  • 15.4.2 Pipeline Monitoring
  • 15.4.3 Other Applications
• 15.5 Transportation and Automotive
  • 15.5.1 Autonomous Vehicles
  • 15.5.2 Aerospace Navigation
  • 15.5.3 Other Applications
• 15.6 Other Industries
  • 15.6.1 Finance and Banking
  • 15.6.2 Agriculture
  • 15.6.3 Construction
  • 15.6.4 Mining

16 COMPANY PROFILES 224 (86 company profiles)

17 APPENDICES

• 17.1 Research Methodology
• 17.2 Glossary of Terms
• 17.3 List of Abbreviations

18 REFERENCES