Table of Content

Table of Contents
1.0 Executive Summary
1.1 Scope of Research
1.2 Research Methodology
1.3 Research Methodology Explained
1.4 Key Findings - Quantum Electronics Finds Applications in Submarines and Satellites
1.5 Key Findings - Quantum Magnetometers Generate Interest in Navigation

2.0 Quantum Electronics Technology Landscape – Status Review
2.1 Quantum Electronics will Disrupt Industrial, Defense, Security, and Healthcare Markets
2.2 Applications of Different Types of Quantum Electronics
2.3 Factors Driving the Adoption of Quantum Electronics
2.4 Miniaturization is a Major Challenge for Adoption of Quantum Electronics

3.0 Quantum Inertial Sensors
3.1 Quantum Gyroscopes and Accelerometers Provide Enhanced Sensitivity
3.2 Quantum Inertial Sensors Have Opportunities to Disrupt Conventional Navigation Systems and MEMS Sensors
3.3 Application Impact of Quantum Inertial Sensors
3.4 Recent Developments with Stakeholders – Quantum Inertial Sensors
3.5 Quantum Inertial Sensors are Gaining Investments

4.0 Quantum Gravity Sensors
4.1 Quantum Gravity Sensors – Overview
4.2 Gravity Sensing: An Earlier Opportunity for Quantum Accelerometers
4.3 Application Landscape of Quantum Gravity Sensors
4.4 Gap Analysis : Quantum Gravity Sensors Opportunities and Challenges
4.5 Recent Developments with Stakeholders – Quantum Gravity Sensors

5.0 Quantum Magnetometers
5.1 Quantum Magnetometers – Overview
5.2 Application Diversity of Quantum Magnetometers
5.3 Quantum Magnetometers find Applications in Precision Location Detection
5.4 Opportunities Driving Adoption of Quantum Magnetometers
5.5 Factors Hindering Adoption of Quantum Magnetometers
5.6 Stakeholder Developments – Quantum Magnetometers

6.0 Quantum Clocks
6.1 Quantum Clocks Enable Precision Timing
6.2 Opportunities of Quantum Clocks
6.3 Challenges Hindering Adoption of Quantum Atomic Clocks
6.4 Applications for Quantum Atomic Clocks
6.5 Stakeholder Developments – Quantum Magnetometers
6.6 Stakeholders are Collaborating with Universities for Quantum Developments

7.0 Quantum Computing
7.1 Quantum Computers have Unprecedented Computational Power
7.2 Opportunities of Quantum Computing
7.3 Factors Hindering Adoption of Quantum Computing
7.4 Applications of Quantum Computing Across Different Industries
7.5 Stakeholder Developments and Recent Research in Quantum Computing
7.6 Kagome Metal finds Applications in Quantum Computers
7.7 Nitrogen Vacancy Diamonds have the Potential to Retain Quantum Information

8.0 Quantum Communications
8.1 Quantum Repeaters and Quantum Key Distribution play Key Roles in Enabling Quantum Communication
8.2 Opportunities Driving Quantum Communications
8.3 Factors Hindering Adoption of Quantum Communications
8.4 Stakeholder Developments – Quantum Computing
8.5 Recent Research in Quantum Computing Enables Development of Quantum Random Number Generator

9.0 Impact of Quantum Technologies on COVID-19
9.1 Opportunities to Combat Coronavirus (COVID-19)
9.2 Use of Supercomputers to Study COVID-19 Impact Creates Potential Applications of Quantum Computing

10.0 Quantum Electronics Ecosystem and Supply Chain Analysis
10.1 Quantum Technology Ecosystem Components
10.2 Key Types of Participants in the Quantum Supply Chain
10.3 Other Participants in the Quantum Supply Chain

11.0 Industry Best Practices – Assessment of Partnerships/Alliances and Recent Developments
11.1 Advancements in Quantum Entanglement Pave the Way for Quantum Internet
11.2 Recent Partnerships Drive Developments in Quantum Computing

12.0 Technology Roadmap & Growth Opportunities
12.1 Quantum Electronics Roadmap
12.2 Strategic Investments Drive Adoption of Quantum Technologies

13.0 Industry Contacts
13.1 Key Industry Contacts
13.1 Key Industry Contacts (continued)
Legal Disclaimer