The Global Quantum Technology Market 2025-2035

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 2020-2024
• 1.6. Challenges for quantum technologies adoption

2. QUANTUM COMPUTING

• 2.1. What is quantum computing?
  • 2.1.1. Operating principle
  • 2.1.2. Classical vs quantum computing
  • 2.1.3. Quantum computing technology
    • 2.1.3.1. Quantum emulators
    • 2.1.3.2. Quantum inspired computing
    • 2.1.3.3. Quantum annealing computers
    • 2.1.3.4. Quantum simulators
    • 2.1.3.5. Digital quantum computers
    • 2.1.3.6. Continuous variables quantum computers
    • 2.1.3.7. Measurement Based Quantum Computing (MBQC)
    • 2.1.3.8. Topological quantum computing
    • 2.1.3.9. Quantum Accelerator
  • 2.1.4. Competition from other technologies
  • 2.1.5. Quantum algorithms
    • 2.1.5.1. Quantum Software Stack
    • 2.1.5.2. Quantum Machine Learning
    • 2.1.5.3. Quantum Simulation
    • 2.1.5.4. Quantum Optimization
    • 2.1.5.5. Quantum Cryptography
      • 2.1.5.5.1. Quantum Key Distribution (QKD)
      • 2.1.5.5.2. Post-Quantum Cryptography
  • 2.1.6. Hardware
    • 2.1.6.1. Qubit Technologies
      • 2.1.6.1.1. Superconducting Qubits
        • 2.1.6.1.1.1. Technology description
        • 2.1.6.1.1.2. Materials
        • 2.1.6.1.1.3. Market players
        • 2.1.6.1.1.4. Swot analysis
      • 2.1.6.1.2. Trapped Ion Qubits
        • 2.1.6.1.2.1. Technology description
        • 2.1.6.1.2.2. Materials
          • 2.1.6.1.2.2.1. Integrating optical components
          • 2.1.6.1.2.2.2. Incorporating high-quality mirrors and optical cavities
          • 2.1.6.1.2.2.3. Engineering the vacuum packaging and encapsulation
          • 2.1.6.1.2.2.4. Removal of waste heat
        • 2.1.6.1.2.3. Market players
        • 2.1.6.1.2.4. Swot analysis
      • 2.1.6.1.3. Silicon Spin Qubits
        • 2.1.6.1.3.1. Technology description
        • 2.1.6.1.3.2. Quantum dots
        • 2.1.6.1.3.3. Market players
        • 2.1.6.1.3.4. SWOT analysis
      • 2.1.6.1.4. Topological Qubits
        • 2.1.6.1.4.1. Technology description
          • 2.1.6.1.4.1.1. Cryogenic cooling
        • 2.1.6.1.4.2. Market players
        • 2.1.6.1.4.3. SWOT analysis
      • 2.1.6.1.5. Photonic Qubits
        • 2.1.6.1.5.1. Technology description
        • 2.1.6.1.5.2. Market players
        • 2.1.6.1.5.3. Swot analysis
      • 2.1.6.1.6. Neutral atom (cold atom) qubits
        • 2.1.6.1.6.1. Technology description
        • 2.1.6.1.6.2. Market players
        • 2.1.6.1.6.3. Swot analysis
      • 2.1.6.1.7. Diamond-defect qubits
        • 2.1.6.1.7.1. Technology description
        • 2.1.6.1.7.2. SWOT analysis
        • 2.1.6.1.7.3. Market players
      • 2.1.6.1.8. Quantum annealers
        • 2.1.6.1.8.1. Technology description
        • 2.1.6.1.8.2. SWOT analysis
        • 2.1.6.1.8.3. Market players
    • 2.1.6.2. Architectural Approaches
  • 2.1.7. Software
    • 2.1.7.1. Technology description
    • 2.1.7.2. Cloud-based services- QCaaS (Quantum Computing as a Service)
    • 2.1.7.3. Market players
• 2.2. Market challenges
• 2.3. SWOT analysis
• 2.4. Quantum computing value chain
• 2.5. Markets and applications for quantum computing
  • 2.5.1. Pharmaceuticals
    • 2.5.1.1. Market overview
      • 2.5.1.1.1. Drug discovery
      • 2.5.1.1.2. Diagnostics
      • 2.5.1.1.3. Molecular simulations
      • 2.5.1.1.4. Genomics
      • 2.5.1.1.5. Proteins and RNA folding
    • 2.5.1.2. Market players
  • 2.5.2. Chemicals
    • 2.5.2.1. Market overview
    • 2.5.2.2. Market players
  • 2.5.3. Transportation
    • 2.5.3.1. Market overview
    • 2.5.3.2. Market players
  • 2.5.4. Financial services
    • 2.5.4.1. Market overview
    • 2.5.4.2. Market players

3. QUANTUM CHEMISTRY AND ARTIFICAL INTELLIGENCE (AI)

• 3.1. Technology description
• 3.2. Applications
• 3.3. SWOT analysis
• 3.4. Market challenges
• 3.5. Market players

4. QUANTUM COMMUNICATIONS

• 4.1. Technology description
• 4.2. Types
• 4.3. Applications
• 4.4. Quantum Random Numbers Generators (QRNG)
  • 4.4.1. Overview
  • 4.4.2. Applications
    • 4.4.2.1. Encryption for Data Centers
    • 4.4.2.2. Consumer Electronics
    • 4.4.2.3. Automotive/Connected Vehicle
    • 4.4.2.4. Gambling and Gaming
    • 4.4.2.5. Monte Carlo Simulations
  • 4.4.3. Advantages
  • 4.4.4. Principle of Operation of Optical QRNG Technology
  • 4.4.5. Non-optical approaches to QRNG technology
  • 4.4.6. SWOT Analysis
• 4.5. Quantum Key Distribution (QKD)
  • 4.5.1. Overview
  • 4.5.2. Asymmetric and Symmetric Keys
  • 4.5.3. Principle behind QKD
  • 4.5.4. Why is QKD More Secure Than Other Key Exchange Mechanisms?
  • 4.5.5. Discrete Variable vs. Continuous Variable QKD Protocols
  • 4.5.6. Key Players
  • 4.5.7. Challenges
  • 4.5.8. SWOT Analysis
• 4.6. Post-quantum cryptography (PQC)
  • 4.6.1. Overview
  • 4.6.2. Security systems integration
  • 4.6.3. PQC standardization
  • 4.6.4. Transitioning cryptographic systems to PQC
  • 4.6.5. Market players
  • 4.6.6. SWOT Analysis
• 4.7. Quantum homomorphic cryptography
• 4.8. Quantum Teleportation
• 4.9. Quantum Networks
  • 4.9.1. Overview
  • 4.9.2. Advantages
  • 4.9.3. Role of Trusted Nodes and Trusted Relays
  • 4.9.4. Entanglement Swapping and Optical Switches
  • 4.9.5. Multiplexing quantum signals with classical channels in the O-band
    • 4.9.5.1. Wavelength-division multiplexing (WDM) and time-division multiplexing (TDM)
  • 4.9.6. Twin-Field Quantum Key Distribution (TF-QKD)
  • 4.9.7. Enabling global-scale quantum communication
  • 4.9.8. Advanced optical fibers and interconnects
  • 4.9.9. Photodetectors in quantum networks
    • 4.9.9.1. Avalanche photodetectors (APDs)
    • 4.9.9.2. Single-photon avalanche diodes (SPADs)
    • 4.9.9.3. Silicon Photomultipliers (SiPMs)
  • 4.9.10. Cryostats
    • 4.9.10.1. Cryostat architectures
  • 4.9.11. Infrastructure requirements
  • 4.9.12. Global activity
    • 4.9.12.1. China
    • 4.9.12.2. Europe
    • 4.9.12.3. The Netherlands
    • 4.9.12.4. The United Kingdom
    • 4.9.12.5. US
    • 4.9.12.6. Japan
  • 4.9.13. SWOT analysis
• 4.10. Quantum Memory
• 4.11. Quantum Internet
• 4.12. Market challenges
• 4.13. Market players

5. QUANTUM SENSING

• 5.1. Technology description
  • 5.1.1. Quantum Sensing Principles
  • 5.1.2. SWOT analysis
  • 5.1.3. Atomic Clocks
    • 5.1.3.1. High frequency oscillators
      • 5.1.3.1.1. Emerging oscillators
    • 5.1.3.2. Caesium atoms
    • 5.1.3.3. Self-calibration
    • 5.1.3.4. Optical atomic clocks
      • 5.1.3.4.1. Chip-scale optical clocks
    • 5.1.3.5. Companies
    • 5.1.3.6. SWOT analysis
  • 5.1.4. Quantum Magnetic Field Sensors
    • 5.1.4.1. Introduction
    • 5.1.4.2. Motivation for use
    • 5.1.4.3. Market opportunity
    • 5.1.4.4. Superconducting Quantum Interference Devices (Squids)
      • 5.1.4.4.1. Applications
      • 5.1.4.4.2. Key players
      • 5.1.4.4.3. SWOT analysis
    • 5.1.4.5. Optically Pumped Magnetometers (OPMs)
      • 5.1.4.5.1. Applications
      • 5.1.4.5.2. Key players
      • 5.1.4.5.3. SWOT analysis
    • 5.1.4.6. Tunneling Magneto Resistance Sensors (TMRs)
      • 5.1.4.6.1. Applications
      • 5.1.4.6.2. Key players
      • 5.1.4.6.3. SWOT analysis
    • 5.1.4.7. Nitrogen Vacancy Centers (N-V Centers)
      • 5.1.4.7.1. Applications
      • 5.1.4.7.2. Key players
      • 5.1.4.7.3. SWOT analysis
  • 5.1.5. Quantum Gravimeters
    • 5.1.5.1. Technology description
    • 5.1.5.2. Applications
    • 5.1.5.3. Key players
    • 5.1.5.4. SWOT analysis
  • 5.1.6. Quantum Gyroscopes
    • 5.1.6.1. Technology description
      • 5.1.6.1.1. Inertial Measurement Units (IMUs)
      • 5.1.6.1.2. Atomic quantum gyroscopes
    • 5.1.6.2. Applications
    • 5.1.6.3. Key players
    • 5.1.6.4. SWOT analysis
  • 5.1.7. Quantum Image Sensors
    • 5.1.7.1. Technology description
    • 5.1.7.2. Applications
    • 5.1.7.3. SWOT analysis
    • 5.1.7.4. Key players
  • 5.1.8. Quantum Radar
    • 5.1.8.1. Technology description
    • 5.1.8.2. Applications
  • 5.1.9. Quantum chemical sensors
  • 5.1.10. Quantum NEM and MEMs
    • 5.1.10.1. Technology description
• 5.2. Market and technology challenges

6. QUANTUM BATTERIES

• 6.1. Technology description
• 6.2. Types
• 6.3. Applications
• 6.4. SWOT analysis
• 6.5. Market challenges
• 6.6. Market players

7. MATERIALS FOR QUANTUM TECHNOLOGY

• 7.1. Superconductors
  • 7.1.1. Overview
  • 7.1.2. Types and Properties
  • 7.1.3. Opportunities
• 7.2. Photonics, Silicon Photonics and Optical Components
  • 7.2.1. Overview
  • 7.2.2. Types and Properties
  • 7.2.3. Opportunities
• 7.3. Nanomaterials
  • 7.3.1. Overview
  • 7.3.2. Types and Properties
  • 7.3.3. Opportunities

8. MARKET ANALYSIS

• 8.1. Market map
• 8.2. Key industry players
  • 8.2.1. Start-ups
  • 8.2.2. Tech Giants
  • 8.2.3. National Initiatives
• 8.3. Investment funding
  • 8.3.1. Venture Capital
  • 8.3.2. M&A
  • 8.3.3. Corporate Investment
  • 8.3.4. Government Funding
• 8.4. Global market revenues 2018-2035
  • 8.4.1. Quantum computing
  • 8.4.2. Other segments
    • 8.4.2.1. Quantum sensors
    • 8.4.2.2. QKD systems

9. COMPANY PROFILES

• 9.1. A* Quantum
• 9.2. AbaQus
• 9.3. Absolut System
• 9.4. Adaptive Finance Technologies
• 9.5. Aegiq
• 9.6. Agnostiq GmbH
• 9.7. Algorithmiq Oy
• 9.8. Airbus
• 9.9. Alea Quantum
• 9.10. Alpine Quantum Technologies GmbH (AQT)
• 9.11. Alice&Bob
• 9.12. Aliro Quantum
• 9.13. Anametric, Inc
• 9.14. Anyon Systems Inc
• 9.15. Aqarios GmbH
• 9.16. Aquark Technologies
• 9.17. Archer Materials
• 9.18. Arclight Quantum
• 9.19. Arqit Quantum Inc
• 9.20. ARQUE Systems GmbH
• 9.21. Artificial Brain
• 9.22. Atlantic Quantum
• 9.23. Atom Computing
• 9.24. Atom Quantum Labs
• 9.25. Atomionics
• 9.26. Atos Quantum
• 9.27. Baidu, Inc
• 9.28. BEIT
• 9.29. Bleximo
• 9.30. BlueQubit
• 9.31. Bohr Quantum Technology
• 9.32. Bosch Quantum Sensing
• 9.33. BosonQ Ps
• 9.34. C12 Quantum Electronics
• 9.35. Cambridge Quantum Computing (CQC)
• 9.36. CAS Cold Atom
• 9.37. CEW Systems Canada Inc
• 9.38. Chipiron
• 9.39. Chiral Nano AG
• 9.40. ColibriTD
• 9.41. Classiq Technologies
• 9.42. Crypta Labs Ltd
• 9.43. CryptoNext Security
• 9.44. Crystal Quantum Computing
• 9.45. D-Wave Systems
• 9.46. Dirac
• 9.47. Diraq
• 9.48. Delft Circuits
• 9.49. Delta g
• 9.50. Duality Quantum Photonics
• 9.51. EeroQ
• 9.52. eleQtron
• 9.53. Element Six
• 9.54. Elyah
• 9.55. Entropica Labs
• 9.56. Equal1.labs
• 9.57. EvolutionQ
• 9.58. Exail Quantum Sensors
• 9.59. EYL
• 9.60. First Quantum, Inc
• 9.61. Fujitsu
• 9.62. Genesis Quantum Technology
• 9.63. Good Chemistry
• 9.64. Google Quantum AI
• 9.65. Haiqu
• 9.66. Hefei Wanzheng Quantum Technology Co., Ltd
• 9.67. High Q Technologies Inc
• 9.68. Horizon Quantum Computing
• 9.69. HQS Quantum Simulations
• 9.70. HRL
• 9.71. Huayi Quantum
• 9.72. IBM
• 9.73. Icarus Quantum
• 9.74. Icosa Computing
• 9.75. ID Quantique
• 9.76. InfinityQ
• 9.77. Infineon Technologies AG
• 9.78. Infleqtion
• 9.79. Intel
• 9.80. IonQ
• 9.81. ISARA Corporation
• 9.82. IQM Quantum Computers
• 9.83. JiJ
• 9.84. JoS QUANTUM GmbH
• 9.85. KEEQuant GmbH
• 9.86. KETS Quantum Security
• 9.87. Ki3 Photonics
• 9.88. Kipu Quantum
• 9.89. Kiutra GmbH
• 9.90. Kuano Limited
• 9.91. Kvantify
• 9.92. levelQuantum
• 9.93. Ligentec
• 9.94. LQUOM
• 9.95. Lux Quanta
• 9.96. M Squared Lasers
• 9.97. Materials Nexus
• 9.98. Maybell Quantum Industries
• 9.99. memQ
• 9.100. Menlo Systems GmbH
• 9.101. Menten AI
• 9.102. Microsoft
• 9.103. Miraex
• 9.104. Molecular Quantum Solutions
• 9.105. Montana Instruments
• 9.106. Multiverse Computing
• 9.107. Mycryofirm
• 9.108. Nanofiber Quantum Technologies
• 9.109. NEC Corporation
• 9.110. Next Generation Quantum
• 9.111. Nomad Atomics
• 9.112. Nord Quantique
• 9.113. Nordic Quantum Computing Group AS
• 9.114. NTT
• 9.115. Nu Quantum
• 9.116. NVision
• 9.117. 1Qbit
• 9.118. ORCA Computing
• 9.119. Orange Quantum Systems
• 9.120. Origin Quantum Computing Technology
• 9.121. Oxford Ionics
• 9.122. Oxford Quantum Circuits (OQC)
• 9.123. PacketLight Networks
• 9.124. ParityQC
• 9.125. Pasqal
• 9.126. Peptone
• 9.127. Phasecraft
• 9.128. Photonic, Inc
• 9.129. Pixel Photonics
• 9.130. Planqc GmbH
• 9.131. Planckian
• 9.132. Plassys
• 9.133. Polaris Quantum Biotech (POLARISqb)
• 9.134. Post Quantum
• 9.135. PQSecure
• 9.136. PQShield
• 9.137. ProteinQure
• 9.138. PsiQuantum
• 9.139. Q.ANT
• 9.140. Q* Bird
• 9.141. Qaisec
• 9.142. Qasky (Anhui Wentian Quantum Technology)
• 9.143. QBoson
• 9.144. Qblox
• 9.145. qBraid
• 9.146. Q-CTRL
• 9.147. QC Design
• 9.148. QC Ware
• 9.149. QC82
• 9.150. Quantum Diamond Technologies Inc. (QDTI)
• 9.151. QEDMA
• 9.152. Qilimanjaro Quantum Tech
• 9.153. Qindom
• 9.154. QLM Technology
• 9.155. QMware
• 9.156. Qnami
• 9.157. QphoX
• 9.158. Qrate Quantum Communications
• 9.159. Qpurpose
• 9.160. Quantum Resistant Cryptography (QRC)
• 9.161. Qruise
• 9.162. QSIMPLUS
• 9.163. QSimulate
• 9.164. QTI s.r.l
• 9.165. Quandela
• 9.166. Quanscient Oy
• 9.167. Quantagonia
• 9.168. QuantaMap
• 9.169. QuantCAD LLC
• 9.170. QuantiCor Security GmbH
• 9.171. Qunasys
• 9.172. QUANTier
• 9.173. Quantinuum
• 9.174. QuantrolOx
• 9.175. Quantropi
• 9.176. Quantum Benchmark
• 9.177. Quantum Bridge Technologies
• 9.178. Quantum Brilliance
• 9.179. Quantum Computing Inc
• 9.180. Quantum Circuits Inc
• 9.181. QuantumCTek
• 9.182. Quantum Diamond Technologies, Inc
• 9.183. QuantumDiamonds GmbH
• 9.184. Quantum Dice
• 9.185. Quantum Flytrap
• 9.186. Quantum Generative Materials LLC
• 9.187. Quantum Machines
• 9.188. Quantum Mads
• 9.189. Quantum Motion Technology
• 9.190. Quantum Optics Jena GmbH
• 9.191. Quantum Source
• 9.192. Quantum South
• 9.193. Quantum Systems
• 9.194. Quantum Transistors
• 9.195. Quantum Xchange
• 9.196. QuantrolOx
• 9.197. QuantX
• 9.198. Qubitekk
• 9.199. Qubit Pharmaceuticals
• 9.200. Qubrid LLC
• 9.201. QUDOOR
• 9.202. QUDORA Technologies
• 9.203. QuEL, Inc
• 9.204. QuEra Computing
• 9.205. Quintessence Labs
• 9.206. QuantGates
• 9.207. QuantWare
• 9.208. Quobly
• 9.209. Quoherent
• 9.210. QuiX Quantum
• 9.211. QunaSys
• 9.212. QNu Labs
• 9.213. QuantLR
• 9.214. QuantWare
• 9.215. Qunova Computing
• 9.216. Qunnect
• 9.217. QuSecure
• 9.218. Quside Technologies S.L
• 9.219. Qutronix
• 9.220. Randaemon
• 9.221. Resquant
• 9.222. Rigetti Computing
• 9.223. Riverlane
• 9.224. Rotonium
• 9.225. Safran
• 9.226. Sandbox AQ
• 9.227. SaxonQ
• 9.228. SBQuantum
• 9.229. SCALINQ
• 9.230. SDT, Inc
• 9.231. Seeqc
• 9.232. Senko Advance Components Ltd
• 9.233. SemiQon Technologies Oy
• 9.234. SemiWise
• 9.235. Silent Waves
• 9.236. Silicon Extreme
• 9.237. Silicon Quantum Computing
• 9.238. Solid State AI
• 9.239. softwareQ
• 9.240. Sparrow Quantum ApS
• 9.241. SpeQtral
• 9.242. SpinQ Technology
• 9.243. Stafford Computing
• 9.244. Strangeworks, Inc
• 9.245. Supracon AG
• 9.246. sureCore Ltd
• 9.247. Synergy Quantum SA
• 9.248. Terra Quantum
• 9.249. ThinkQuantum
• 9.250. t0.technology
• 9.251. Tokyo Quantum Computing
• 9.252. Toshiba Digital Solutions
• 9.253. TuringQ
• 9.254. Universal Quantum
• 9.255. Vapor Cell Technologies
• 9.256. VeriQloud
• 9.257. Vexlum Oy
• 9.258. Viqthor
• 9.259. Wave Photonics
• 9.260. Welinq
• 9.261. Xanadu
• 9.262. XeedQ GmbH
• 9.263. Xofia
• 9.264. XT Quantech
• 9.265. Zapata Computing
• 9.266. Zhongwei Daxin Technology

10. RESEARCH METHODOLOGY

11. TERMS AND DEFINITIONS

12. REFERENCES

List of Tables

• Table 1. First and second quantum revolutions
• Table 2. Global government initiatives in quantum technologies
• Table 3. Quantum technologies industry developments 2020-2024
• Table 4. Challenges for quantum technologies adoption
• Table 5. Applications for quantum computing
• Table 6. Comparison of classical versus quantum computing
• Table 7. Key quantum mechanical phenomena utilized in quantum computing
• Table 8. Types of quantum computers
• Table 9. Comparative analysis of quantum computing with classical computing, quantum-inspired computing, and neuromorphic computing
• Table 10. Different computing paradigms beyond conventional CMOS
• Table 11. Applications of quantum algorithms
• Table 12. QML approaches
• Table 13. Coherence times for different qubit implementations
• Table 14. Superconducting qubit market players
• Table 15. Initialization, manipulation and readout for trapped ion quantum computers
• Table 16. Ion trap market players
• Table 17. Initialization, manipulation, and readout methods for silicon-spin qubits
• Table 18. Silicon spin qubits market players
• Table 19. Initialization, manipulation and readout of topological qubits
• Table 20. Topological qubits market players
• Table 21. Pros and cons of photon qubits
• Table 22. Comparison of photon polarization and squeezed states
• Table 23. Initialization, manipulation and readout of photonic platform quantum computers
• Table 24. Photonic qubit market players
• Table 25. Initialization, manipulation and readout for neutral-atom quantum computers
• Table 26. Pros and cons of cold atoms quantum computers and simulators
• Table 27. Neural atom qubit market players
• Table 28. Initialization, manipulation and readout of Diamond-Defect Spin-Based Computing
• Table 29. Key materials for developing diamond-defect spin-based quantum computers
• Table 30. Diamond-defect qubits market players
• Table 31. Pros and cons of quantum annealers
• Table 32. Quantum annealers market players
• Table 33. Quantum computing software market players
• Table 34. Market challenges in quantum computing
• Table 35. Quantum computing value chain
• Table 36. Markets and applications for quantum computing
• Table 37. Market players in quantum technologies for pharmaceuticals
• Table 38. Market players in quantum computing for chemicals
• Table 39. Automotive applications of quantum computing,
• Table 40. Market players in quantum computing for transportation
• Table 41. Market players in quantum computing for financial services
• Table 42. Applications in quantum chemistry and artificial intelligence (AI)
• Table 43. Market challenges in quantum chemistry and Artificial Intelligence (AI)
• Table 44. Market players in quantum chemistry and AI
• Table 45. Main types of quantum communications
• Table 46. Applications in quantum communications
• Table 47. QRNG applications
• Table 48. Key Players Developing QRNG Products
• Table 49. Optical QRNG by company
• Table 50. Market players in post-quantum cryptography
• Table 51. Market challenges in quantum communications
• Table 52. Market players in quantum communications
• Table 53. Comparison between classical and quantum sensors
• Table 54. Applications in quantum sensors
• Table 55. Technology approaches for enabling quantum sensing
• Table 56. Value proposition for quantum sensors
• Table 57. Key challenges and limitations of quartz crystal clocks vs. atomic clocks
• Table 58. New modalities being researched to improve the fractional uncertainty of atomic clocks
• Table 59. Companies developing high-precision quantum time measurement
• Table 60. Key players in atomic clocks
• Table 61. Comparative analysis of key performance parameters and metrics of magnetic field sensors
• Table 62. Types of magnetic field sensors
• Table 63. Market opportunity for different types of quantum magnetic field sensors
• Table 64. Applications of SQUIDs
• Table 65. Market opportunities for SQUIDs (Superconducting Quantum Interference Devices)
• Table 66. Key players in SQUIDs
• Table 67. Applications of optically pumped magnetometers (OPMs)
• Table 68. Key players in Optically Pumped Magnetometers (OPMs)
• Table 69. Applications for TMR (Tunneling Magnetoresistance) sensors
• Table 70. Market players in TMR (Tunneling Magnetoresistance) sensors
• Table 71. Applications of N-V center magnetic field centers
• Table 72. Key players in N-V center magnetic field sensors
• Table 73. Applications of quantum gravimeters
• Table 74. Comparative table between quantum gravity sensing and some other technologies commonly used for underground mapping
• Table 75. Key players in quantum gravimeters
• Table 76. Comparison of quantum gyroscopes with MEMs gyroscopes and optical gyroscopes
• Table 77. Markets and applications for quantum gyroscopes
• Table 78. Key players in quantum gyroscopes
• Table 79. Types of quantum image sensors and their key features/
• Table 80. Applications of quantum image sensors
• Table 81. Key players in quantum image sensors
• Table 82. Comparison of quantum radar versus conventional radar and lidar technologies
• Table 83. Applications of quantum radar
• Table 84. Market and technology challenges in quantum sensing
• Table 85. Comparison between quantum batteries and other conventional battery types
• Table 86. Types of quantum batteries
• Table 87. Applications of quantum batteries
• Table 88. Market challenges in quantum batteries
• Table 89. Market players in quantum batteries
• Table 90. Materials in Quantum Technology
• Table 91. Superconductors in quantum technology
• Table 92. Photonics, silicon photonics and optics in quantum technology
• Table 93. Nanomaterials in quantum technology
• Table 94. Quantum technologies investment funding
• Table 95. Top funded quantum technology companies
• Table 96. Global market for quantum computing-Hardware, Software & Services, 2023-2035 (billions USD)
• Table 97. Markets for quantum sensors, by types, 2018-2035 (Millions USD)
• Table 98. Markets for QKD systems, 2018-2035 (Millions USD)

List of Figures

• Figure 1. Quantum computing development timeline
• Figure 2. Quantum investments 2012-2023 (millions USD)
• Figure 3. National quantum initiatives and funding
• Figure 4. Quantum computing architectures
• Figure 5. An early design of an IBM 7-qubit chip based on superconducting technology
• Figure 6. Various 2D to 3D chips integration techniques into chiplets
• Figure 7. IBM Q System One quantum computer
• Figure 8. Unconventional computing approaches
• Figure 9. 53-qubit Sycamore processor
• Figure 10. Interior of IBM quantum computing system. The quantum chip is located in the small dark square at center bottom
• Figure 11. Superconducting quantum computer
• Figure 12. Superconducting quantum computer schematic
• Figure 13. Components and materials used in a superconducting qubit
• Figure 14. SWOT analysis for superconducting quantum computers:
• Figure 15. Ion-trap quantum computer
• Figure 16. Various ways to trap ions
• Figure 17. Universal Quantum's shuttling ion architecture in their Penning traps
• Figure 18. SWOT analysis for trapped-ion quantum computing
• Figure 19. CMOS silicon spin qubit
• Figure 20. Silicon quantum dot qubits
• Figure 21. SWOT analysis for silicon spin quantum computers
• Figure 22. SWOT analysis for topological qubits
• Figure 23 . SWOT analysis for photonic quantum computers
• Figure 24. Neutral atoms (green dots) arranged in various configurations
• Figure 25. SWOT analysis for neutral-atom quantum computers
• Figure 26. NV center components
• Figure 27. SWOT analysis for diamond-defect quantum computers
• Figure 28. D-Wave quantum annealer
• Figure 29. SWOT analysis for quantum annealers
• Figure 30. Quantum software development platforms
• Figure 31. SWOT analysis for quantum computing
• Figure 32. SWOT analysis for quantum chemistry and AI
• Figure 33. IDQ quantum number generators
• Figure 34. SWOT Analysis of Quantum Random Number Generator Technology
• Figure 35. SWOT Analysis of Quantum Key Distribution Technology
• Figure 36. SWOT Analysis: Post Quantum Cryptography (PQC)
• Figure 37. SWOT analysis for networks
• Figure 38. Q.ANT quantum particle sensor
• Figure 39. SWOT analysis for quantum sensors market
• Figure 40. NIST's compact optical clock
• Figure 41. SWOT analysis for atomic clocks
• Figure 42. Principle of SQUID magnetometer
• Figure 43. SWOT analysis for SQUIDS
• Figure 44. SWOT analysis for OPMs
• Figure 45. Tunneling magnetoresistance mechanism and TMR ratio formats
• Figure 46. SWOT analysis for TMR (Tunneling Magnetoresistance) sensors
• Figure 47. SWOT analysis for N-V Center Magnetic Field Sensors
• Figure 48. Quantum Gravimeter
• Figure 49. SWOT analysis for Quantum Gravimeters
• Figure 50. SWOT analysis for Quantum Gyroscopes
• Figure 51. SWOT analysis for Quantum image sensing
• Figure 52. Principle of quantum radar
• Figure 53. Illustration of a quantum radar prototype
• Figure 54. Schematic of the flow of energy (blue) from a source to a battery made up of multiple cells. (left)
• Figure 55. SWOT analysis for quantum batteries
• Figure 56. Market map for quantum technologies industry
• Figure 57. Tech Giants quantum technologies activities
• Figure 58. Quantum Technology investment by sector, 2023
• Figure 59. Quantum computing public and industry funding to mid-2023, millions USD
• Figure 60. Global market for quantum computing-Hardware, Software & Services, 2023-2035 (billions USD)
• Figure 61. Markets for quantum sensors, by types, 2018-2035 (Millions USD)
• Figure 62. Markets for QKD systems, 2018-2035 (Millions USD)
• Figure 63. Archer-EPFL spin-resonance circuit
• Figure 64. IBM Q System One quantum computer
• Figure 65. ColdQuanta Quantum Core (left), Physics Station (middle) and the atoms control chip (right)
• Figure 66. Intel Tunnel Falls 12-qubit chip
• Figure 67. IonQ's ion trap
• Figure 68. 20-qubit quantum computer
• Figure 69. Maybell Big Fridge
• Figure 70. PsiQuantum's modularized quantum computing system networks
• Figure 71. SemiQ first chip prototype
• Figure 72. Toshiba QKD Development Timeline
• Figure 73. Toshiba Quantum Key Distribution technology