Global Normal Temperature Superconductor Technology Market Growth (Status and Outlook) 2023-2029
1 Scope of the Report
- 1.1 Market Introduction
- 1.2 Years Considered
- 1.3 Research Objectives
- 1.4 Market Research Methodology
- 1.5 Research Process and Data Source
- 1.6 Economic Indicators
- 1.7 Currency Considered
2 Executive Summary
- 2.1 World Market Overview
- 2.1.1 Global Normal Temperature Superconductor Technology Market Size 2024-2029
- 2.1.2 Normal Temperature Superconductor Technology Market Size CAGR by Region
- 2.2 Normal Temperature Superconductor Technology Segment by Type
- 2.2.1 2.67 Million Atmospheres of Pressure
- 2.2.2 10,000 Atmospheres of Pressure
- 2.2.3 Others
- 2.3 Normal Temperature Superconductor Technology Market Size by Type
- 2.3.1 Global Normal Temperature Superconductor Technology Market Size Market Share by Type (2024-2029)
- 2.3.2 Global Normal Temperature Superconductor Technology Market Size Growth Rate by Type (2024-2029)
- 2.4 Normal Temperature Superconductor Technology Segment by Application
- 2.4.1 Superconducting Electricity
- 2.4.2 Superconducting Resonance Medical
- 2.4.3 Maglev Transportation
- 2.4.4 Others
- 2.5 Normal Temperature Superconductor Technology Market Size by Application
- 2.5.1 Global Normal Temperature Superconductor Technology Market Size Market Share by Application (2024-2029)
- 2.5.2 Global Normal Temperature Superconductor Technology Market Size Growth Rate by Application (2024-2029)
3 Normal Temperature Superconductor Technology Key Players
- 3.1 Date of Key Players Enter into Normal Temperature Superconductor Technology
- 3.2 Key Players Normal Temperature Superconductor Technology Product Offered
- 3.3 Key Players Normal Temperature Superconductor Technology Funding/Investment Analysis
- 3.4 Funding/Investment
- 3.4.1 Funding/Investment by Regions
- 3.4.2 Funding/Investment by End-Industry
- 3.5 Key Players Normal Temperature Superconductor Technology Valuation & Market Capitalization
- 3.6 Key Players Mergers & Acquisitions, Expansion Plans
- 3.7 Market Ranking
- 3.8 New Product/Technology Launches
- 3.9 Partnerships, Agreements, and Collaborations
- 3.10 Mergers and Acquisitions
4 Normal Temperature Superconductor Technology by Regions
- 4.1 Normal Temperature Superconductor Technology Market Size by Regions (2024-2029)
- 4.2 United States Normal Temperature Superconductor Technology Market Size Growth (2024-2029)
- 4.3 China Normal Temperature Superconductor Technology Market Size Growth (2024-2029)
- 4.4 Europe Normal Temperature Superconductor Technology Market Size Growth (2024-2029)
- 4.5 Rest of World Normal Temperature Superconductor Technology Market Size Growth (2024-2029)
5 United States
- 5.1 United States Normal Temperature Superconductor Technology Market Size by Type (2024-2029)
- 5.2 United States Normal Temperature Superconductor Technology Market Size by Application (2024-2029)
6 Europe
- 6.1 Europe Normal Temperature Superconductor Technology Market Size by Type (2024-2029)
- 6.2 Europe Normal Temperature Superconductor Technology Market Size by Application (2024-2029)
7 China
- 7.1 China Normal Temperature Superconductor Technology Market Size by Type (2024-2029)
- 7.2 China Normal Temperature Superconductor Technology Market Size by Application (2024-2029)
8 Rest of World
- 8.1 Rest of World Normal Temperature Superconductor Technology Market Size by Type (2024-2029)
- 8.2 Rest of World Normal Temperature Superconductor Technology Market Size by Application (2024-2029)
- 8.3 Japan
- 8.4 South Korea
- 8.5 Southeast Asia
9 Market Drivers, Challenges and Trends
- 9.1 Market Drivers & Growth Opportunities
- 9.2 Market Challenges & Risks
- 9.3 Industry Trends
10 Key Investors in Normal Temperature Superconductor Technology
- 10.1 Company A
- 10.1.1 Company A Company Details
- 10.1.2 Company Description
- 10.1.3 Companies Invested by Company A
- 10.1.4 Company A Key Development and Market Layout
- 10.2 Company B
- 10.2.1 Company B Company Details
- 10.2.2 Company Description
- 10.2.3 Companies Invested by Company B
- 10.2.4 Company B Key Development and Market Layout
- 10.3 Company C
- 10.3.1 Company C Company Details
- 10.3.2 Company Description
- 10.3.3 Companies Invested by Company C
- 10.3.4 Company C Key Development and Market Layout
- 10.4 Company D
- 10.5 ……
11 Key Players Analysis
- 11.1 Team Ranga Dias, University of Rochester, New York
- 11.1.1 Team Ranga Dias, University of Rochester, New York Company Details
- 11.1.2 Team Ranga Dias, University of Rochester, New York Normal Temperature Superconductor Technology Product Offered
- 11.1.3 Team Ranga Dias, University of Rochester, New York Normal Temperature Superconductor Technology Market Size (2023 VS 2029)
- 11.1.4 Team Ranga Dias, University of Rochester, New York Main Business Overview
- 11.1.5 Team Ranga Dias, University of Rochester, New York News
- 11.2 IBM
- 11.2.1 IBM Company Details
- 11.2.2 IBM Normal Temperature Superconductor Technology Product Offered
- 11.2.3 IBM Normal Temperature Superconductor Technology Market Size (2023 VS 2029)
- 11.2.4 IBM Main Business Overview
- 11.2.5 IBM News
- 11.3 University of Houston
- 11.3.1 University of Houston Company Details
- 11.3.2 University of Houston Normal Temperature Superconductor Technology Product Offered
- 11.3.3 University of Houston Normal Temperature Superconductor Technology Market Size (2023 VS 2029)
- 11.3.4 University of Houston Main Business Overview
- 11.3.5 University of Houston News
- 11.4 University of Tokyo
- 11.4.1 University of Tokyo Company Details
- 11.4.2 University of Tokyo Normal Temperature Superconductor Technology Product Offered
- 11.4.3 University of Tokyo Normal Temperature Superconductor Technology Market Size (2023 VS 2029)
- 11.4.4 University of Tokyo Main Business Overview
- 11.4.5 University of Tokyo News
- 11.5 Los Alamos National Laboratory
- 11.5.1 Los Alamos National Laboratory Company Details
- 11.5.2 Los Alamos National Laboratory Normal Temperature Superconductor Technology Product Offered
- 11.5.3 Los Alamos National Laboratory Normal Temperature Superconductor Technology Market Size (2023 VS 2029)
- 11.5.4 Los Alamos National Laboratory Main Business Overview
- 11.5.5 Los Alamos National Laboratory News
- 11.6 University of Cambridge
- 11.6.1 University of Cambridge Company Details
- 11.6.2 University of Cambridge Normal Temperature Superconductor Technology Product Offered
- 11.6.3 University of Cambridge Normal Temperature Superconductor Technology Market Size (2023 VS 2029)
- 11.6.4 University of Cambridge Main Business Overview
- 11.6.5 University of Cambridge News
- 11.7 University of Maryland
- 11.7.1 University of Maryland Company Details
- 11.7.2 University of Maryland Normal Temperature Superconductor Technology Product Offered
- 11.7.3 University of Maryland Normal Temperature Superconductor Technology Market Size (2023 VS 2029)
- 11.7.4 University of Maryland Main Business Overview
- 11.7.5 University of Maryland News
- 11.8 University of Illinois at Urbana-Champaign
- 11.8.1 University of Illinois at Urbana-Champaign Company Details
- 11.8.2 University of Illinois at Urbana-Champaign Normal Temperature Superconductor Technology Product Offered
- 11.8.3 University of Illinois at Urbana-Champaign Normal Temperature Superconductor Technology Market Size (2023 VS 2029)
- 11.8.4 University of Illinois at Urbana-Champaign Main Business Overview
- 11.8.5 University of Illinois at Urbana-Champaign News
- 11.9 University of Oslo
- 11.9.1 University of Oslo Company Details
- 11.9.2 University of Oslo Normal Temperature Superconductor Technology Product Offered
- 11.9.3 University of Oslo Normal Temperature Superconductor Technology Market Size (2023 VS 2029)
- 11.9.4 University of Oslo Main Business Overview
- 11.9.5 University of Oslo News
- 11.10 University of Geneva
- 11.10.1 University of Geneva Company Details
- 11.10.2 University of Geneva Normal Temperature Superconductor Technology Product Offered
- 11.10.3 University of Geneva Normal Temperature Superconductor Technology Market Size (2023 VS 2029)
- 11.10.4 University of Geneva Main Business Overview
- 11.10.5 University of Geneva News
12 Research Findings and Conclusion
According to this study, the global Normal Temperature Superconductor Technology market size will reach US$ million by 2029.
On March 7th, 2023, Pacific Standard Time, Ranga Dias and his team at the University of Rochester in New York announced a significant breakthrough in the field of room-temperature superconductivity at the American Physical Society conference held in Las Vegas. In their report titled "Superconducting Properties of Hydrides Under Near Room-Temperature and High-Pressure Conditions," the Dias team observed superconductivity in a new material made of hydrogen, nitrogen, and lutetium under 1GPa pressure and near-room-temperature conditions of 294K (21°C).
Normal temperature superconductivity (NTS) refers to the hypothetical ability of a material to conduct electricity with zero resistance at room temperature or higher. Currently, superconductivity is only observed at very low temperatures, typically below -100°C, which limits the practical applications of superconductors.
The development of NTS technology would revolutionize many fields, from power transmission to medical imaging to transportation. However, it is still a highly speculative area of research, and no known material exhibits superconductivity at room temperature or higher.
This report presents a comprehensive overview, market shares, and growth opportunities of Normal Temperature Superconductor Technology market by product type, application, key players and key regions and countries.
Segmentation by product type:
2.67 Million Atmospheres of Pressure
10,000 Atmospheres of Pressure
Others
Segmentation by Application:
Superconducting Electricity
Superconducting Resonance Medical
Maglev Transportation
Others
This report also splits the market by region:
United States
China
Europe
Other regions:
Japan
South Korea
Southeast Asia
Rest of world
The report also presents the market competition landscape and a corresponding detailed analysis of the major players in the market. The key players covered in this report:
Team Ranga Dias, University of Rochester, New York
IBM
University of Houston
University of Tokyo
Los Alamos National Laboratory
University of Cambridge
University of Maryland
University of Illinois at Urbana-Champaign
University of Oslo
University of Geneva