Metamaterials Market: Global Industry Analysis and Forecast (2021-2027) by Product, Application and End User.

Metamaterials Market size was valued at US$ 305 Mn. in 2020 and the total revenue is expected to grow at 36.7 % CAGR through 2021 to 2027, reaching nearly US$ 2720.69 Mn.

Metamaterials Market Overview:

Metamaterials are specially developed composite materials that have improved electromagnetic properties as compared to natural composites. Medical, aerospace and defence, consumer electronics, and automotive are some of the end-use verticals where these technologies have a lot of potential. With product developments in radar and lidar for driverless vehicles, telecommunications antenna, 5G networks, coatings, vibration damping, wireless charging, noise prevention, and more, metamaterials applications will constitute a multi-billion dollar business within the next decade. Global Metamaterials MarketTo know about the Research Methodology :- Request Free Sample Report 2020 is considered as a base year to forecast the Market from 2021 to 2027. 2020’s Market size is estimated on real numbers and outputs of the key players and major players across the globe. Past five years trends are considered while forecasting the Market through 2027. 2020 is a year of exception and analyzed specially with the impact of lockdown by region.

Metamaterials Market Dynamics:

Variety in design functionalities, anti-glare coating application and invisibility cloak for stealth aircraft are major growth drivers of metamaterials market. Escalating demand from the aerospace and defense industry, increasing usage of antennas for communication, growing demand for wireless mobile communication drives the metamaterial market. For instance, Metamaterial Technologies Inc. teamed with ADI Technologies, Inc. in July 2020 to get access to defence markets in the United States, United Kingdom, Europe, and Israel. ADI Technologies helps worldwide companies sell products and services to government agencies by providing marketing and consulting services. High capital investment from public and private sources and highly skilled researchers for product commercialization are several opportunities to metamaterial market. Cost of synthesization of metamaterials hampers the market growth to some extent. Metamaterial usage in the solar power system and metamaterial-based radar for drones poses a lucrative opportunity to metamaterials market. Unavailability of Technology for Mass Production is key challenge to the market. Federal agencies such as the Department of Defense (DOD) and the Defense Advanced Research Projects Agency (DARPA) are spending extensively in metamaterial research and development for aerospace and defence applications. As a result, the demand for metamaterials in many applications is driven by the variety of design features. 5G is a next-generation technology that allows users to connect in a fluid and flexible manner. 5G networks are intended to adapt to applications, and their performance will be adapted to the needs of end users. According to the GSM Association, 5G would have 1.2 billion connections worldwide by 2025. Metamaterial-based antennas or radars can outperform traditional offers in terms of performance and efficiency. As a result, metamaterial-based antennas will benefit from the development and acceptance of 5G. This will provide tremendous opportunities to metamaterial market in coming future.

Metamaterials Market Segment Analysis:

Based on product, Metamaterials Market is segmented into Electromagnetic, Double Negative Metamaterials, Single Negative Metamaterials, Electronic Band gap Metamaterials, Bi-Isotropic and Bi-Anisotropic Metamaterials, Frequency selective surface and others. Frequency selective surface segment to grow at the highest CAGR during the forecast period. Frequency selective surfaces (FSS) are widely used as a spatial filter for the design of absorbers, redome, dichroic plates, and reflector antennas in the microwave and millimetre wave frequency regime. FSS structures are mainly employed to enhance the performance of the device within the specified band and reduce the radar signature outside the band. Based on end user, based on connectivity the Metamaterials Market is segmented into Healthcare, Telecommunication, Aerospace and Defense, Electronics, Optics and Other. Telecommunication industry segment dominated the global market in 2020 and is expected to maintain this trend in the coming years. Rapid industrialization and urbanization has resulted into increased use of metamaterial. Use of electrically small antennas in applications such as telephone network, television network, and satellites boost the rapid use of metamaterial medium in the telecommunication industry. Moreover the optics segment is estimated to exhibit the moderate growth rate during the forecast period. Global Metamaterials Market 1

Metamaterials Market Regional Insights:

Despite the fact that North America leads the worldwide market, followed by Europe, Asia-Pacific is the fastest expanding region and is predicted to surpass North America by 2024. This expansion is mostly attributable to increased investment in the defence sectors of Asian countries. Governments in countries such as China, India, South Korea, Pakistan, and others have consistently increased their national military budgets. China reported an 8.1 % rise in its defence spending in the recently passed budget, bringing it to USD 175 billion, the world's second highest defence expenditure after the United States. China has recently built a satellite to develop quantum communications, which is likely to drive antenna metamaterials. As the number of digital cellular customers in China continues to rise, service providers are becoming increasingly concerned about the infrastructure's limited capacity. As a result, smarter antenna systems are being deployed in China. Over the projected period, China is expected to consolidate its position as one of the world's main metamaterials consumers. The US government (DOD, DARPA, US Navy) and private entities (Bill Gates Foundation, Lux Capital, Kresge Foundation) are sponsoring research institutes, laboratories, and enterprises to improve metamaterial technology or build efficient and cost-effective electronic devices and applications. Kymeta secured USD 85 million in funding in August 2020, led by Bill Gates and members of the leadership team. The funds will mostly be utilized for significant leadership appointments, new product releases, and market momentum in the defence, public safety, and land mobility sectors. Echodyne Inc will release EchoGuard CR with Radar Hub in October 2020. In urban and crowded situations, especially in areas with limited range requirements, the EchoGuard CR provides high-performance active beam steering and 3D radar functionality. Radar Hub makes managing and deploying many radars a breeze. The objective of the report is to present a comprehensive analysis of the Global Metamaterials Market to the stakeholders in the industry. The past and current status of the industry with the forecasted Market size and trends are presented in the report with the analysis of complicated data in simple language. The report covers all the aspects of the industry with a dedicated study of key players that include Market leaders, followers, and new entrants. PORTER, PESTEL analysis with the potential impact of micro-economic factors of the Market have been presented in the report. External as well as internal factors that are supposed to affect the business positively or negatively have been analyzed, which will give a clear futuristic view of the industry to the decision-makers. The report also helps in understanding the Global Metamaterials Market dynamics, structure by analyzing the Market segments and project the Global Metamaterials Market size. Clear representation of competitive analysis of key players by Type, price, financial position, Type portfolio, growth strategies, and regional presence in the Global Metamaterials Market make the report investor’s guide.

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Global Metamaterials Market
Report Coverage Details
Base Year: 2020 Forecast Period: 2021-2027
Historical Data: 2016 to 2020 Market Size in 2020: US $ 305 Mn.
Forecast Period 2021 to 2027 CAGR: 36.7% Market Size in 2027: US $ 2720.69 Mn.
Segments Covered: by Product • Electromagnetic • Terahertz • Tunable • Photonic • Frequency selective surface • Other
by Application • Antenna and Radar • Sensors • Cloaking Devices • Superlens • Light and Sound Filtering • Upcoming Application
by End Use • Healthcare • Telecommunication • Aerospace and Defense • Electronics • Energy & Power • Optics • Other

Global Metamaterials Market, by Region

• North America • Europe • Asia Pacific • Middle East and Africa • South America

Global Metamaterials Market Key Players

Echodyne Inc. • Fractal Antenna Systems • Evolv Technologies • JEM Engineering, LLC. • Kymeta Corporation • Mediwise • Metamaterial Technologies, Inc. • MetaShield LLC. • Multiwave Technologies AG • Opalux, Inc. • Phoebus Optoelectronics, LLC • Plasmonics, Inc. • Teraview • Metamagnetics • Nanohmics Inc. • NKT Photonics • Harris Corporation • Newport Corporation

Frequently Asked Questions:

1] What segments are covered in Global Metamaterials Market report? Ans. The segments covered in Global Metamaterials Market report are based on product, application and end user. 2] Which region is expected to hold the highest share in the Global Metamaterials Market? Ans. Asia Pacific is expected to hold the highest share in the Global Metamaterials Market. 3] What is the Market size of Global Metamaterials Market in 2027? Ans. The Market size of Global Metamaterials Market in the forecast period 2027 is US $ 2720.69 Mn. 4] Who are the top key players in the Global Metamaterials Market? Ans. Echodyne Inc., Fractal Antenna Systems, Evolv Technologies, JEM Engineering, LLC., Kymeta Corporation, Mediwise, Metamaterial Technologies, Inc., MetaShield LLC., Multiwave Technologies AG, Opalux, Inc, LLC, Plasmonics, Inc., Teraview, Metamagnetics 5] What was the Market size of Global Metamaterials Market in 2020? Ans. The Market size of Global Metamaterials Market in 2020 was US $ 305 Mn.

Global Metamaterials Market

1. Preface 1.1. Report Scope and Market Segmentation 1.2. Research Highlights 1.3. Research Objectives 2. Assumptions and Research Methodology 2.1. Report Assumptions 2.2. Abbreviations 2.3. Research Methodology 2.3.1. Secondary Research 2.3.1.1. Secondary data 2.3.1.2. Secondary Sources 2.3.2. Primary Research 2.3.2.1. Data from Primary Sources 2.3.2.2. Breakdown of Primary Sources 3. Executive Summary: Global Metamaterial Size, by Market Value (US$ Mn) and Market Volume (Units) 4. Market Overview 4.1. Introduction 4.2. Market Indicator 4.2.1. Drivers 4.2.2. Restraints 4.2.3. Opportunities 4.2.4. Challenges 4.3. Porter’s Analysis 4.4. Value Chain Analysis 4.5. Market Risk Analysis 4.6. SWOT Analysis 4.7. Industry Trends and Emerging Technologies 5. Supply Side and Demand Side Indicators 6. Global Metamaterial Market Analysis and Forecast 6.1. Global Metamaterial Market Size & Y-o-Y Growth Analysis 6.1.1. North America 6.1.2. Europe 6.1.3. Asia Pacific 6.1.4. Middle East & Africa 6.1.5. South America 7. Global Metamaterial Market Analysis and Forecast, by Product 7.1. Introduction and Definition 7.2. Key Findings 7.3. Global Metamaterial Market Value Share Analysis, by Product 7.4. Global Metamaterial Market Size (US$ Mn) Forecast, by Product 7.5. Global Metamaterial Market Analysis, by Product 7.6. Global Metamaterial Market Attractiveness Analysis, by Product 8. Global Metamaterial Market Analysis and Forecast, by Application 8.1. Introduction and Definition 8.2. Key Findings 8.3. Global Metamaterial Market Value Share Analysis, by Application 8.4. Global Metamaterial Market Size (US$ Mn) Forecast, by Application 8.5. Global Metamaterial Market Analysis, by Application 8.6. Global Metamaterial Market Attractiveness Analysis, by Application 9. Global Metamaterial Market Analysis and Forecast, by End Use 9.1. Introduction and Definition 9.2. Key Findings 9.3. Global Metamaterial Market Value Share Analysis, by End Use 9.4. Global Metamaterial Market Size (US$ Mn) Forecast, by End Use 9.5. Global Metamaterial Market Analysis, by End Use 9.6. Global Metamaterial Market Attractiveness Analysis, by End Use 10. Global Metamaterial Market Analysis, by Region 10.1. Global Metamaterial Market Value Share Analysis, by Region 10.2. Global Metamaterial Market Size (US$ Mn) Forecast, by Region 10.3. Global Metamaterial Market Attractiveness Analysis, by Region 11. North America Metamaterial Market Analysis 11.1. Key Findings 11.2. North America Metamaterial Market Overview 11.3. North America Metamaterial Market Value Share Analysis, by Product 11.4. North America Metamaterial Market Forecast, by Product 11.4.1. Electromagnetic 11.4.1.1. Double Negative Metamaterials 11.4.1.2. Single Negative Metamaterials 11.4.1.3. Electronic Bandgap Metamaterial 11.4.1.4. Double Positive Medium 11.4.1.5. Bi-Isotropic and Bi-Anisotropic Metamaterials 11.4.1.6. Chiral Metamaterials 11.4.2. Terahertz 11.4.3. Tunable 11.4.4. Photonic 11.4.5. Frequency selective surface 11.4.6. Other 11.5. North America Metamaterial Market Value Share Analysis, by Application 11.6. North America Metamaterial Market Forecast, by Application 11.6.1. Antenna and Radar 11.6.2. Sensors 11.6.3. Cloaking Devices 11.6.4. Superlens 11.6.5. Light and Sound Filtering 11.6.6. Upcoming Application 11.6.6.1. Invisible Cloaking 11.6.6.2. Acoustic Cloaking 11.6.6.3. Acoustic Sensor 11.6.6.4. EMC Shielding 11.6.6.5. Superlens 11.6.6.6. Strain Sensor 11.6.6.7. Hyper Spectral Imaging 11.6.6.8. Near-Field Optical Microscopy 11.7. North America Metamaterial Market Value Share Analysis, by End Use 11.8. North America Metamaterial Market Forecast, by End Use 11.8.1. Healthcare 11.8.2. Telecommunication 11.8.3. Aerospace and Defense 11.8.4. Electronics 11.8.5. Energy & Power 11.8.6. Optics 11.8.7. Other 11.9. North America Metamaterial Market Value Share Analysis, by Country 11.10. North America Metamaterial Market Forecast, by Country 11.10.1. U.S. 11.10.2. Canada 11.11. North America Metamaterial Market Analysis, by Country 11.12. U.S. Metamaterial Market Forecast, by Product 11.12.1. Electromagnetic 11.12.1.1. Double Negative Metamaterials 11.12.1.2. Single Negative Metamaterials 11.12.1.3. Electronic Bandgap Metamaterial 11.12.1.4. Double Positive Medium 11.12.1.5. Bi-Isotropic and Bi-Anisotropic Metamaterials 11.12.1.6. Chiral Metamaterials 11.12.2. Terahertz 11.12.3. Tunable 11.12.4. Photonic 11.12.5. Frequency selective surface 11.12.6. Other 11.13. U.S. Metamaterial Market Forecast, by Application 11.13.1. Antenna and Radar 11.13.2. Sensors 11.13.3. Cloaking Devices 11.13.4. Superlens 11.13.5. Light and Sound Filtering 11.13.6. Upcoming Application 11.13.6.1. Invisible Cloaking 11.13.6.2. Acoustic Cloaking 11.13.6.3. Acoustic Sensor 11.13.6.4. EMC Shielding 11.13.6.5. Superlens 11.13.6.6. Strain Sensor 11.13.6.7. Hyper Spectral Imaging 11.13.6.8. Near-Field Optical Microscopy 11.14. U.S. Metamaterial Market Forecast, by End Use 11.14.1. Healthcare 11.14.2. Telecommunication 11.14.3. Aerospace and Defense 11.14.4. Electronics 11.14.5. Energy & Power 11.14.6. Optics 11.14.7. Other 11.15. Canada Metamaterial Market Forecast, by Product 11.15.1. Electromagnetic 11.15.1.1. Double Negative Metamaterials 11.15.1.2. Single Negative Metamaterials 11.15.1.3. Electronic Bandgap Metamaterial 11.15.1.4. Double Positive Medium 11.15.1.5. Bi-Isotropic and Bi-Anisotropic Metamaterials 11.15.1.6. Chiral Metamaterials 11.15.2. Terahertz 11.15.3. Tunable 11.15.4. Photonic 11.15.5. Frequency selective surface 11.15.6. Other 11.16. Canada Metamaterial Market Forecast, by Application 11.16.1. Antenna and Radar 11.16.2. Sensors 11.16.3. Cloaking Devices 11.16.4. Superlens 11.16.5. Light and Sound Filtering 11.16.6. Upcoming Application 11.16.6.1. Invisible Cloaking 11.16.6.2. Acoustic Cloaking 11.16.6.3. Acoustic Sensor 11.16.6.4. EMC Shielding 11.16.6.5. Superlens 11.16.6.6. Strain Sensor 11.16.6.7. Hyper Spectral Imaging 11.16.6.8. Near-Field Optical Microscopy 11.17. Canada Metamaterial Market Forecast, by End Use 11.17.1. Healthcare 11.17.2. Telecommunication 11.17.3. Aerospace and Defense 11.17.4. Electronics 11.17.5. Energy & Power 11.17.6. Optics 11.17.7. Other 11.18. North America Metamaterial Market Attractiveness Analysis 11.18.1. By Product 11.18.2. By Application 11.18.3. By End Use 11.19. PEST Analysis 11.20. Key Trends 11.21. Key Development 12. Europe Metamaterial Market Analysis 12.1. Key Findings 12.2. Europe Metamaterial Market Overview 12.3. Europe Metamaterial Market Value Share Analysis, by Product 12.4. Europe Metamaterial Market Forecast, by Product 12.4.1. Electromagnetic 12.4.1.1. Double Negative Metamaterials 12.4.1.2. Single Negative Metamaterials 12.4.1.3. Electronic Bandgap Metamaterial 12.4.1.4. Double Positive Medium 12.4.1.5. Bi-Isotropic and Bi-Anisotropic Metamaterials 12.4.1.6. Chiral Metamaterials 12.4.2. Terahertz 12.4.3. Tunable 12.4.4. Photonic 12.4.5. Frequency selective surface 12.4.6. Other 12.5. Europe Metamaterial Market Value Share Analysis, by Application 12.6. Europe Metamaterial Market Forecast, by Application 12.6.1. Antenna and Radar 12.6.2. Sensors 12.6.3. Cloaking Devices 12.6.4. Superlens 12.6.5. Light and Sound Filtering 12.6.6. Upcoming Application 12.6.6.1. Invisible Cloaking 12.6.6.2. Acoustic Cloaking 12.6.6.3. Acoustic Sensor 12.6.6.4. EMC Shielding 12.6.6.5. Superlens 12.6.6.6. Strain Sensor 12.6.6.7. Hyper Spectral Imaging 12.6.6.8. Near-Field Optical Microscopy 12.7. Europe Metamaterial Market Value Share Analysis, by End Use 12.8. Europe Metamaterial Market Forecast, by End Use 12.8.1. Healthcare 12.8.2. Telecommunication 12.8.3. Aerospace and Defense 12.8.4. Electronics 12.8.5. Energy & Power 12.8.6. Optics 12.8.7. Other 12.8.8. Europe Metamaterial Market Value Share Analysis, by Country 12.9. Europe Metamaterial Market Forecast, by Country 12.9.1. Germany 12.9.2. U.K. 12.9.3. France 12.9.4. Italy 12.9.5. Spain 12.9.6. Rest of Europe 12.10. Europe Metamaterial Market Analysis, by Country 12.11. Germany Metamaterial Market Forecast, by Product 12.11.1. Electromagnetic 12.11.1.1. Double Negative Metamaterials 12.11.1.2. Single Negative Metamaterials 12.11.1.3. Electronic Bandgap Metamaterial 12.11.1.4. Double Positive Medium 12.11.1.5. Bi-Isotropic and Bi-Anisotropic Metamaterials 12.11.1.6. Chiral Metamaterials 12.11.2. Terahertz 12.11.3. Tunable 12.11.4. Photonic 12.11.5. Frequency selective surface 12.11.6. Other 12.12. Germany Metamaterial Market Forecast, by Application 12.12.1. Antenna and Radar 12.12.2. Sensors 12.12.3. Cloaking Devices 12.12.4. Superlens 12.12.5. Light and Sound Filtering 12.12.6. Upcoming Application 12.12.6.1. Invisible Cloaking 12.12.6.2. Acoustic Cloaking 12.12.6.3. Acoustic Sensor 12.12.6.4. EMC Shielding 12.12.6.5. Superlens 12.12.6.6. Strain Sensor 12.12.6.7. Hyper Spectral Imaging 12.12.6.8. Near-Field Optical Microscopy 12.13. Germany Metamaterial Market Forecast, by End Use 12.13.1. Healthcare 12.13.2. Telecommunication 12.13.3. Aerospace and Defense 12.13.4. Electronics 12.13.5. Energy & Power 12.13.6. Optics 12.13.7. Other 12.14. U.K. Metamaterial Market Forecast, by Product 12.14.1. Electromagnetic 12.14.1.1. Double Negative Metamaterials 12.14.1.2. Single Negative Metamaterials 12.14.1.3. Electronic Bandgap Metamaterial 12.14.1.4. Double Positive Medium 12.14.1.5. Bi-Isotropic and Bi-Anisotropic Metamaterials 12.14.1.6. Chiral Metamaterials 12.14.2. Terahertz 12.14.3. Tunable 12.14.4. Photonic 12.14.5. Frequency selective surface 12.14.6. Other 12.15. U.K. Metamaterial Market Forecast, by Application 12.15.1. Antenna and Radar 12.15.2. Sensors 12.15.3. Cloaking Devices 12.15.4. Superlens 12.15.5. Light and Sound Filtering 12.15.6. Upcoming Application 12.15.6.1. Invisible Cloaking 12.15.6.2. Acoustic Cloaking 12.15.6.3. Acoustic Sensor 12.15.6.4. EMC Shielding 12.15.6.5. Superlens 12.15.6.6. Strain Sensor 12.15.6.7. Hyper Spectral Imaging 12.15.6.8. Near-Field Optical Microscopy 12.16. U.K. Metamaterial Market Forecast, by End Use 12.16.1. Healthcare 12.16.2. Telecommunication 12.16.3. Aerospace and Defense 12.16.4. Electronics 12.16.5. Energy & Power 12.16.6. Optics 12.16.7. Other 12.17. France Metamaterial Market Forecast, by Product 12.17.1. Electromagnetic 12.17.1.1. Double Negative Metamaterials 12.17.1.2. Single Negative Metamaterials 12.17.1.3. Electronic Bandgap Metamaterial 12.17.1.4. Double Positive Medium 12.17.1.5. Bi-Isotropic and Bi-Anisotropic Metamaterials 12.17.1.6. Chiral Metamaterials 12.17.2. Terahertz 12.17.3. Tunable 12.17.4. Photonic 12.17.5. Frequency selective surface 12.17.6. Other 12.18. France Metamaterial Market Forecast, by Application 12.18.1. Antenna and Radar 12.18.2. Sensors 12.18.3. Cloaking Devices 12.18.4. Superlens 12.18.5. Light and Sound Filtering 12.18.6. Upcoming Application 12.18.6.1. Invisible Cloaking 12.18.6.2. Acoustic Cloaking 12.18.6.3. Acoustic Sensor 12.18.6.4. EMC Shielding 12.18.6.5. Superlens 12.18.6.6. Strain Sensor 12.18.6.7. Hyper Spectral Imaging 12.18.6.8. Near-Field Optical Microscopy 12.19. France Metamaterial Market Forecast, by End Use 12.19.1. Healthcare 12.19.2. Telecommunication 12.19.3. Aerospace and Defense 12.19.4. Electronics 12.19.5. Energy & Power 12.19.6. Optics 12.19.7. Other 12.20. Italy Metamaterial Market Forecast, by Product 12.20.1. Electromagnetic 12.20.1.1. Double Negative Metamaterials 12.20.1.2. Single Negative Metamaterials 12.20.1.3. Electronic Bandgap Metamaterial 12.20.1.4. Double Positive Medium 12.20.1.5. Bi-Isotropic and Bi-Anisotropic Metamaterials 12.20.1.6. Chiral Metamaterials 12.20.2. Terahertz 12.20.3. Tunable 12.20.4. Photonic 12.20.5. Frequency selective surface 12.20.6. Other 12.21. Italy Metamaterial Market Forecast, by Application 12.21.1. Antenna and Radar 12.21.2. Sensors 12.21.3. Cloaking Devices 12.21.4. Superlens 12.21.5. Light and Sound Filtering 12.21.6. Upcoming Application 12.21.6.1. Invisible Cloaking 12.21.6.2. Acoustic Cloaking 12.21.6.3. Acoustic Sensor 12.21.6.4. EMC Shielding 12.21.6.5. Superlens 12.21.6.6. Strain Sensor 12.21.6.7. Hyper Spectral Imaging 12.21.6.8. Near-Field Optical Microscopy 12.22. Italy Metamaterial Market Forecast, by End Use 12.22.1. Healthcare 12.22.2. Telecommunication 12.22.3. Aerospace and Defense 12.22.4. Electronics 12.22.5. Energy & Power 12.22.6. Optics 12.22.7. Other 12.23. Spain Metamaterial Market Forecast, by Product 12.23.1. Electromagnetic 12.23.1.1. Double Negative Metamaterials 12.23.1.2. Single Negative Metamaterials 12.23.1.3. Electronic Bandgap Metamaterial 12.23.1.4. Double Positive Medium 12.23.1.5. Bi-Isotropic and Bi-Anisotropic Metamaterials 12.23.1.6. Chiral Metamaterial 12.23.2. Terahertz 12.23.3. Tunable 12.23.4. Photonic 12.23.5. Frequency selective surface 12.23.6. Other 12.24. Spain Metamaterial Market Forecast, by Application 12.24.1. Antenna and Radar 12.24.2. Sensors 12.24.3. Cloaking Devices 12.24.4. Superlens 12.24.5. Light and Sound Filtering 12.24.6. Upcoming Application 12.24.6.1. Invisible Cloaking 12.24.6.2. Acoustic Cloaking 12.24.6.3. Acoustic Sensor 12.24.6.4. EMC Shielding 12.24.6.5. Superlens 12.24.6.6. Strain Sensor 12.24.6.7. Hyper Spectral Imaging 12.24.6.8. Near-Field Optical Microscopy 12.25. Spain Metamaterial Market Forecast, by End Use 12.25.1. Healthcare 12.25.2. Telecommunication 12.25.3. Aerospace and Defense 12.25.4. Electronics 12.25.5. Energy & Power 12.25.6. Optics 12.25.7. Other 12.26. Rest of Europe Metamaterial Market Forecast, by Product 12.26.1. Electromagnetic 12.26.1.1. Double Negative Metamaterials 12.26.1.2. Single Negative Metamaterials 12.26.1.3. Electronic Bandgap Metamaterial 12.26.1.4. Double Positive Medium 12.26.1.5. Bi-Isotropic and Bi-Anisotropic Metamaterials 12.26.1.6. Chiral Metamaterials 12.26.2. Terahertz 12.26.3. Tunable 12.26.4. Photonic 12.26.5. Frequency selective surface 12.26.6. Other 12.27. Rest of Europe Metamaterial Market Forecast, by Application 12.27.1. Antenna and Radar 12.27.2. Sensors 12.27.3. Cloaking Devices 12.27.4. Superlens 12.27.5. Light and Sound Filtering 12.27.6. Upcoming Application 12.27.6.1. Invisible Cloaking 12.27.6.2. Acoustic Cloaking 12.27.6.3. Acoustic Sensor 12.27.6.4. EMC Shielding 12.27.6.5. Superlens 12.27.6.6. Strain Sensor 12.27.6.7. Hyper Spectral Imaging 12.27.6.8. Near-Field Optical Microscopy 12.28. Rest of Europe Metamaterial Market Forecast, by End Use 12.28.1. Healthcare 12.28.2. Telecommunication 12.28.3. Aerospace and Defense 12.28.4. Electronics 12.28.5. Energy & Power 12.28.6. Optics 12.28.7. Other 12.29. Europe Metamaterial Market Attractiveness Analysis 12.29.1. By Product 12.29.2. By Application 12.29.3. By End Use 12.30. PEST Analysis 12.31. Key Trend 12.32. Key Development 13. Asia Pacific Metamaterial Market Analysis 13.1. Key Findings 13.2. Asia Pacific Metamaterial Market Overview 13.3. Asia Pacific Metamaterial Market Value Share Analysis, by Product 13.4. Asia Pacific Metamaterial Market Forecast, by Product 13.4.1. Electromagnetic 13.4.1.1. Double Negative Metamaterials 13.4.1.2. Single Negative Metamaterials 13.4.1.3. Electronic Bandgap Metamaterial 13.4.1.4. Double Positive Medium 13.4.1.5. Bi-Isotropic and Bi-Anisotropic Metamaterials 13.4.1.6. Chiral Metamaterials 13.4.2. Terahertz 13.4.3. Tunable 13.4.4. Photonic 13.4.5. Frequency selective surface 13.4.6. Other 13.5. Asia Pacific Metamaterial Market Value Share Analysis, by Application 13.6. Asia Pacific Metamaterial Market Forecast, by Application 13.6.1. Antenna and Radar 13.6.2. Sensors 13.6.3. Cloaking Devices 13.6.4. Superlens 13.6.5. Light and Sound Filtering 13.6.6. Upcoming Application 13.6.6.1. Invisible Cloaking 13.6.6.2. Acoustic Cloaking 13.6.6.3. Acoustic Sensor 13.6.6.4. EMC Shielding 13.6.6.5. Superlens 13.6.6.6. Strain Sensor 13.6.6.7. Hyper Spectral Imaging 13.6.6.8. Near-Field Optical Microscopy 13.7. Asia Pacific Metamaterial Market Value Share Analysis, by End Use 13.8. Asia Pacific Metamaterial Market Forecast, by End Use 13.8.1. Healthcare 13.8.2. Telecommunication 13.8.3. Aerospace and Defense 13.8.4. Electronics 13.8.5. Energy & Power 13.8.6. Optics 13.8.7. Other 13.9. Asia Pacific Metamaterial Market Value Share Analysis, by Country 13.10. Asia Pacific Metamaterial Market Forecast, by Country 13.10.1. China 13.10.2. India 13.10.3. Japan 13.10.4. ASEAN 13.10.5. Rest of Asia Pacific 13.11. Asia Pacific Metamaterial Market Analysis, by Country 13.12. China Metamaterial Market Forecast, by Product 13.12.1. Electromagnetic 13.12.1.1. Double Negative Metamaterials 13.12.1.2. Single Negative Metamaterials 13.12.1.3. Electronic Bandgap Metamaterial 13.12.1.4. Double Positive Medium 13.12.1.5. Bi-Isotropic and Bi-Anisotropic Metamaterials 13.12.1.6. Chiral Metamaterials 13.12.2. Terahertz 13.12.3. Tunable 13.12.4. Photonic 13.12.5. Frequency selective surface 13.12.6. Other 13.13. China Metamaterial Market Forecast, by Application 13.13.1. Antenna and Radar 13.13.2. Sensors 13.13.3. Cloaking Devices 13.13.4. Superlens 13.13.5. Light and Sound Filtering 13.13.6. Upcoming Application 13.13.6.1. Invisible Cloaking 13.13.6.2. Acoustic Cloaking 13.13.6.3. Acoustic Sensor 13.13.6.4. EMC Shielding 13.13.6.5. Superlens 13.13.6.6. Strain Sensor 13.13.6.7. Hyper Spectral Imaging 13.13.6.8. Near-Field Optical Microscopy 13.14. China Metamaterial Market Forecast, by End Use 13.14.1. Healthcare 13.14.2. Telecommunication 13.14.3. Aerospace and Defense 13.14.4. Electronics 13.14.5. Energy & Power 13.14.6. Optics 13.14.7. Other 13.15. India Metamaterial Market Forecast, by Product 13.15.1. Electromagnetic 13.15.1.1. Double Negative Metamaterials 13.15.1.2. Single Negative Metamaterials 13.15.1.3. Electronic Bandgap Metamaterial 13.15.1.4. Double Positive Medium 13.15.1.5. Bi-Isotropic and Bi-Anisotropic Metamaterials 13.15.1.6. Chiral Metamaterials 13.15.2. Terahertz 13.15.3. Tunable 13.15.4. Photonic 13.15.5. Frequency selective surface 13.15.6. Other 13.16. India Metamaterial Market Forecast, by Application 13.16.1. Antenna and Radar 13.16.2. Sensors 13.16.3. Cloaking Devices 13.16.4. Superlens 13.16.5. Light and Sound Filtering 13.16.6. Upcoming Application 13.16.6.1. Invisible Cloaking 13.16.6.2. Acoustic Cloaking 13.16.6.3. Acoustic Sensor 13.16.6.4. EMC Shielding 13.16.6.5. Superlens 13.16.6.6. Strain Sensor 13.16.6.7. Hyper Spectral Imaging 13.16.6.8. Near-Field Optical Microscopy 13.17. India Metamaterial Market Forecast, by End Use 13.17.1. Healthcare 13.17.2. Telecommunication 13.17.3. Aerospace and Defense 13.17.4. Electronics 13.17.5. Energy & Power 13.17.6. Optics 13.17.7. Other 13.18. Japan Metamaterial Market Forecast, by Product 13.18.1. Electromagnetic 13.18.1.1. Double Negative Metamaterials 13.18.1.2. Single Negative Metamaterials 13.18.1.3. Electronic Bandgap Metamaterial 13.18.1.4. Double Positive Medium 13.18.1.5. Bi-Isotropic and Bi-Anisotropic Metamaterials 13.18.1.6. Chiral Metamaterials 13.18.2. Terahertz 13.18.3. Tunable 13.18.4. Photonic 13.18.5. Frequency selective surface 13.18.6. Other 13.19. Japan Metamaterial Market Forecast, by Application 13.19.1. Antenna and Radar 13.19.2. Sensors 13.19.3. Cloaking Devices 13.19.4. Superlens 13.19.5. Light and Sound Filtering 13.19.6. Upcoming Application 13.19.6.1. Invisible Cloaking 13.19.6.2. Acoustic Cloaking 13.19.6.3. Acoustic Sensor 13.19.6.4. EMC Shielding 13.19.6.5. Superlens 13.19.6.6. Strain Sensor 13.19.6.7. Hyper Spectral Imaging 13.19.6.8. Near-Field Optical Microscopy 13.20. Japan Metamaterial Market Forecast, by End Use 13.20.1. Healthcare 13.20.2. Telecommunication 13.20.3. Aerospace and Defense 13.20.4. Electronics 13.20.5. Energy & Power 13.20.6. Optics 13.20.7. Other 13.21. ASEAN Metamaterial Market Forecast, by Product 13.21.1. Electromagnetic 13.21.1.1. Double Negative Metamaterials 13.21.1.2. Single Negative Metamaterials 13.21.1.3. Electronic Bandgap Metamaterial 13.21.1.4. Double Positive Medium 13.21.1.5. Bi-Isotropic and Bi-Anisotropic Metamaterials 13.21.1.6. Chiral Metamaterials 13.21.2. Terahertz 13.21.3. Tunable 13.21.4. Photonic 13.21.5. Frequency selective surface 13.21.6. Other 13.22. ASEAN Metamaterial Market Forecast, by Application 13.22.1. Antenna and Radar 13.22.2. Sensors 13.22.3. Cloaking Devices 13.22.4. Superlens 13.22.5. Light and Sound Filtering 13.22.6. Other 13.23. ASEAN Metamaterial Market Forecast, by End Use 13.23.1. Healthcare 13.23.2. Telecommunication 13.23.3. Aerospace and Defense 13.23.4. Electronics 13.23.5. Energy & Power 13.23.6. Optics 13.23.7. Other 13.24. Rest of Asia Pacific Metamaterial Market Forecast, by Product 13.24.1. Electromagnetic 13.24.1.1. Double Negative Metamaterials 13.24.1.2. Single Negative Metamaterials 13.24.1.3. Electronic Bandgap Metamaterial 13.24.1.4. Double Positive Medium 13.24.1.5. Bi-Isotropic and Bi-Anisotropic Metamaterials 13.24.1.6. Chiral Metamaterials 13.24.2. Terahertz 13.24.3. Tunable 13.24.4. Photonic 13.24.5. Frequency selective surface 13.24.6. Other 13.25. Rest of Asia Pacific Metamaterial Market Forecast, by Application 13.25.1. Antenna and Radar 13.25.2. Sensors 13.25.3. Cloaking Devices 13.25.4. Superlens 13.25.5. Light and Sound Filtering 13.25.6. Upcoming Application 13.25.6.1. Invisible Cloaking 13.25.6.2. Acoustic Cloaking 13.25.6.3. Acoustic Sensor 13.25.6.4. EMC Shielding 13.25.6.5. Superlens 13.25.6.6. Strain Sensor 13.25.6.7. Hyper Spectral Imaging 13.25.6.8. Near-Field Optical Microscopy 13.26. Rest of Asia Pacific Metamaterial Market Forecast, by End Use 13.26.1. Healthcare 13.26.2. Telecommunication 13.26.3. Aerospace and Defense 13.26.4. Electronics 13.26.5. Energy & Power 13.26.6. Optics 13.26.7. Other 13.27. Asia Pacific Metamaterial Market Attractiveness Analysis 13.27.1. By Product 13.27.2. By Application 13.27.3. By End Use 13.28. PEST Analysis 13.29. Key Trend 13.30. Key Development 14. Middle East & Africa Metamaterial Market Analysis 14.1. Key Findings 14.2. Middle East & Africa Metamaterial Market Overview 14.3. Middle East & Africa Metamaterial Market Value Share Analysis, by Product 14.4. Middle East & Africa Metamaterial Market Forecast, by Product 14.4.1. Electromagnetic 14.4.1.1. Double Negative Metamaterials 14.4.1.2. Single Negative Metamaterials 14.4.1.3. Electronic Bandgap Metamaterial 14.4.1.4. Double Positive Medium 14.4.1.5. Bi-Isotropic and Bi-Anisotropic Metamaterials 14.4.1.6. Chiral Metamaterials 14.4.2. Terahertz 14.4.3. Tunable 14.4.4. Photonic 14.4.5. Frequency selective surface 14.4.6. Other 14.5. Middle East & Africa Metamaterial Market Value Share Analysis, by Application 14.6. Middle East & Africa Metamaterial Market Forecast, by Application 14.6.1. Antenna and Radar 14.6.2. Sensors 14.6.3. Cloaking Devices 14.6.4. Superlens 14.6.5. Light and Sound Filtering 14.6.6. Upcoming Application 14.6.6.1. Invisible Cloaking 14.6.6.2. Acoustic Cloaking 14.6.6.3. Acoustic Sensor 14.6.6.4. EMC Shielding 14.6.6.5. Superlens 14.6.6.6. Strain Sensor 14.6.6.7. Hyper Spectral Imaging 14.6.6.8. Near-Field Optical Microscopy 14.7. Middle East & Africa Metamaterial Market Value Share Analysis, by End Use 14.8. Middle East & Africa Metamaterial Market Forecast, by End Use 14.8.1. Healthcare 14.8.2. Telecommunication 14.8.3. Aerospace and Defense 14.8.4. Electronics 14.8.5. Energy & Power 14.8.6. Optics 14.8.7. Other 14.9. Middle East & Africa Metamaterial Market Value Share Analysis, by Country 14.10. Middle East & Africa Metamaterial Market Forecast, by Country 14.10.1. GCC 14.10.2. South Africa 14.10.3. Rest of Middle East & Africa 14.11. Middle East & Africa Metamaterial Market Analysis, by Country 14.12. GCC Metamaterial Market Forecast, by Product 14.12.1. Electromagnetic 14.12.1.1. Double Negative Metamaterials 14.12.1.2. Single Negative Metamaterials 14.12.1.3. Electronic Bandgap Metamaterial 14.12.1.4. Double Positive Medium 14.12.1.5. Bi-Isotropic and Bi-Anisotropic Metamaterials 14.12.1.6. Chiral Metamaterials 14.12.2. Terahertz 14.12.3. Tunable 14.12.4. Photonic 14.12.5. Frequency selective surface 14.12.6. Other 14.13. GCC Metamaterial Market Forecast, by Application 14.13.1. Antenna and Radar 14.13.2. Sensors 14.13.3. Cloaking Devices 14.13.4. Superlens 14.13.5. Light and Sound Filtering 14.13.6. Upcoming Application 14.13.6.1. Invisible Cloaking 14.13.6.2. Acoustic Cloaking 14.13.6.3. Acoustic Sensor 14.13.6.4. EMC Shielding 14.13.6.5. Superlens 14.13.6.6. Strain Sensor 14.13.6.7. Hyper Spectral Imaging 14.13.6.8. Near-Field Optical Microscopy 14.14. GCC Metamaterial Market Forecast, by End Use 14.14.1. Healthcare 14.14.2. Telecommunication 14.14.3. Aerospace and Defense 14.14.4. Electronics 14.14.5. Energy & Power 14.14.6. Optics 14.14.7. Other 14.15. South Africa Metamaterial Market Forecast, by Product 14.15.1. Electromagnetic 14.15.1.1. Double Negative Metamaterials 14.15.1.2. Single Negative Metamaterials 14.15.1.3. Electronic Bandgap Metamaterial 14.15.1.4. Double Positive Medium 14.15.1.5. Bi-Isotropic and Bi-Anisotropic Metamaterials 14.15.1.6. Chiral Metamaterials 14.15.2. Terahertz 14.15.3. Tunable 14.15.4. Photonic 14.15.5. Frequency selective surface 14.15.6. Other 14.16. South Africa Metamaterial Market Forecast, by Application 14.16.1. Antenna and Radar 14.16.2. Sensors 14.16.3. Cloaking Devices 14.16.4. Superlens 14.16.5. Light and Sound Filtering 14.16.6. Upcoming Application 14.16.6.1. Invisible Cloaking 14.16.6.2. Acoustic Cloaking 14.16.6.3. Acoustic Sensor 14.16.6.4. EMC Shielding 14.16.6.5. Superlens 14.16.6.6. Strain Sensor 14.16.6.7. Hyper Spectral Imaging 14.16.6.8. Near-Field Optical Microscopy 14.17. South Africa Metamaterial Market Forecast, by End Use 14.17.1. Healthcare 14.17.2. Telecommunication 14.17.3. Aerospace and Defense 14.17.4. Electronics 14.17.5. Energy & Power 14.17.6. Optics 14.17.7. Other 14.18. Rest of Middle East & Africa Metamaterial Market Forecast, by Product 14.18.1. Electromagnetic 14.18.2. Terahertz 14.18.3. Tunable 14.18.4. Photonic 14.18.5. Frequency selective surface 14.18.6. Other 14.19. Rest of Middle East & Africa Metamaterial Market Forecast, by Application 14.19.1. Antenna and Radar 14.19.2. Sensors 14.19.3. Cloaking Devices 14.19.4. Superlens 14.19.5. Light and Sound Filtering 14.19.6. Upcoming Application 14.19.6.1. Invisible Cloaking 14.19.6.2. Acoustic Cloaking 14.19.6.3. Acoustic Sensor 14.19.6.4. EMC Shielding 14.19.6.5. Superlens 14.19.6.6. Strain Sensor 14.19.6.7. Hyper Spectral Imaging 14.19.6.8. Near-Field Optical Microscopy 14.20. Rest of Middle East & Africa Metamaterial Market Forecast, by End Use 14.20.1. Healthcare 14.20.2. Telecommunication 14.20.3. Aerospace and Defense 14.20.4. Electronics 14.20.5. Energy & Power 14.20.6. Optics 14.20.7. Other 14.21. Middle East & Africa Metamaterial Market Attractiveness Analysis 14.21.1. By Product 14.21.2. By Application 14.21.3. By End Use 14.22. PEST Analysis 14.23. Key Trend 14.24. Key Development 15. South America Metamaterial Market Analysis 15.1. Key Findings 15.2. South America Metamaterial Market Overview 15.3. South America Metamaterial Market Value Share Analysis, by Product 15.4. South America Metamaterial Market Forecast, by Product 15.4.1. Electromagnetic 15.4.1.1. Double Negative Metamaterials 15.4.1.2. Single Negative Metamaterials 15.4.1.3. Electronic Bandgap Metamaterial 15.4.1.4. Double Positive Medium 15.4.1.5. Bi-Isotropic and Bi-Anisotropic Metamaterials 15.4.1.6. Chiral Metamaterials 15.4.2. Terahertz 15.4.3. Tunable 15.4.4. Photonic 15.4.5. Frequency selective surface 15.4.6. Other 15.5. South America Metamaterial Market Value Share Analysis, by Application 15.6. South America Metamaterial Market Forecast, by Application 15.6.1. Antenna and Radar 15.6.2. Sensors 15.6.3. Cloaking Devices 15.6.4. Superlens 15.6.5. Light and Sound Filtering 15.6.6. Upcoming Application 15.6.6.1. Invisible Cloaking 15.6.6.2. Acoustic Cloaking 15.6.6.3. Acoustic Sensor 15.6.6.4. EMC Shielding 15.6.6.5. Superlens 15.6.6.6. Strain Sensor 15.6.6.7. Hyper Spectral Imaging 15.6.6.8. Near-Field Optical Microscopy 15.7. South America Metamaterial Market Value Share Analysis, by End Use 15.8. South America Metamaterial Market Forecast, by End Use 15.8.1. Healthcare 15.8.2. Telecommunication 15.8.3. Aerospace and Defense 15.8.4. Electronics 15.8.5. Energy & Power 15.8.6. Optics 15.8.7. Other 15.9. South America Metamaterial Market Value Share Analysis, by Country 15.10. South America Metamaterial Market Forecast, by Country 15.10.1. Brazil 15.10.2. Mexico 15.10.3. Rest of South America 15.11. Brazil Metamaterial Market Forecast, by Product 15.11.1. Electromagnetic 15.11.1.1. Double Negative Metamaterials 15.11.1.2. Single Negative Metamaterials 15.11.1.3. Electronic Bandgap Metamaterial 15.11.1.4. Double Positive Medium 15.11.1.5. Bi-Isotropic and Bi-Anisotropic Metamaterials 15.11.1.6. Chiral Metamaterials 15.11.2. Terahertz 15.11.3. Tunable 15.11.4. Photonic 15.11.5. Frequency selective surface 15.11.6. Other 15.12. Brazil Metamaterial Market Forecast, by Application 15.12.1. Antenna and Radar 15.12.2. Sensors 15.12.3. Cloaking Devices 15.12.4. Superlens 15.12.5. Light and Sound Filtering 15.12.6. Upcoming Application 15.12.6.1. Invisible Cloaking 15.12.6.2. Acoustic Cloaking 15.12.6.3. Acoustic Sensor 15.12.6.4. EMC Shielding 15.12.6.5. Superlens 15.12.6.6. Strain Sensor 15.12.6.7. Hyper Spectral Imaging 15.12.6.8. Near-Field Optical Microscopy 15.13. Brazil Metamaterial Market Forecast, by End Use 15.13.1. Healthcare 15.13.2. Telecommunication 15.13.3. Aerospace and Defense 15.13.4. Electronics 15.13.5. Energy & Power 15.13.6. Optics 15.13.7. Other 15.14. Mexico Metamaterial Market Forecast, by Product 15.14.1. Electromagnetic 15.14.1.1. Double Negative Metamaterials 15.14.1.2. Single Negative Metamaterials 15.14.1.3. Electronic Bandgap Metamaterial 15.14.1.4. Double Positive Medium 15.14.1.5. Bi-Isotropic and Bi-Anisotropic Metamaterials 15.14.1.6. Chiral Metamaterials 15.14.2. Terahertz 15.14.3. Tunable 15.14.4. Photonic 15.14.5. Frequency selective surface 15.14.6. Other 15.15. Mexico Metamaterial Market Forecast, by Application 15.15.1. Antenna and Radar 15.15.2. Sensors 15.15.3. Cloaking Devices 15.15.4. Superlens 15.15.5. Light and Sound Filtering 15.15.6. Upcoming Application 15.15.6.1. Invisible Cloaking 15.15.6.2. Acoustic Cloaking 15.15.6.3. Acoustic Sensor 15.15.6.4. EMC Shielding 15.15.6.5. Superlens 15.15.6.6. Strain Sensor 15.15.6.7. Hyper Spectral Imaging 15.15.6.8. Near-Field Optical Microscopy 15.16. Mexico Metamaterial Market Forecast, by End Use 15.16.1. Healthcare 15.16.2. Telecommunication 15.16.3. Aerospace and Defense 15.16.4. Electronics 15.16.5. Energy & Power 15.16.6. Optics 15.16.7. Other 15.17. Rest of South America Metamaterial Market Forecast, by Product 15.17.1. Electromagnetic 15.17.1.1. Double Negative Metamaterials 15.17.1.2. Single Negative Metamaterials 15.17.1.3. Electronic Bandgap Metamaterial 15.17.1.4. Double Positive Medium 15.17.1.5. Bi-Isotropic and Bi-Anisotropic Metamaterials 15.17.1.6. Chiral Metamaterials 15.17.2. Terahertz 15.17.3. Tunable 15.17.4. Photonic 15.17.5. Frequency selective surface 15.17.6. Other 15.18. Rest of South America Metamaterial Market Forecast, by Application 15.18.1. Antenna and Radar 15.18.2. Sensors 15.18.3. Cloaking Devices 15.18.4. Superlens 15.18.5. Light and Sound Filtering 15.18.6. Upcoming Application 15.18.6.1. Invisible Cloaking 15.18.6.2. Acoustic Cloaking 15.18.6.3. Acoustic Sensor 15.18.6.4. EMC Shielding 15.18.6.5. Superlens 15.18.6.6. Strain Sensor 15.18.6.7. Hyper Spectral Imaging 15.18.6.8. Near-Field Optical Microscopy 15.19. Rest of South America Metamaterial Market Forecast, by End Use 15.19.1. Healthcare 15.19.2. Telecommunication 15.19.3. Aerospace and Defense 15.19.4. Electronics 15.19.5. Energy & Power 15.19.6. Optics 15.19.7. Other 15.20. South America Metamaterial Market Attractiveness Analysis 15.20.1. By Product 15.20.2. By Application 15.20.3. By End Use 15.21. PEST Analysis 15.22. Key Trend 15.23. Key Development 16. Company Profiles 16.1. Market Share Analysis, by Company 16.2. Competition Matrix 16.2.1. Competitive Benchmarking of key players by price, presence, market share, Applications and R&D investment 16.2.2. New Product Launches and Product Enhancements 16.2.3. Market Consolidation 16.2.3.1. M&A by Regions, Investment and Applications 16.2.3.2. M&A Key Players, Forward Integration and Backward Integration 16.3. Company Profiles: Key Players 16.4. Echodyne Inc. 16.4.1.1. Company Overview 16.4.1.2. Financial Overview 16.4.1.3. Product Portfolio 16.4.1.4. Business Strategy 16.4.1.5. Recent Developments 1.1.1.1. Manufacturing Footprint 16.5. Fractal Antenna Systems 16.6. Evolv Technologies 16.7. JEM Engineering, LLC. 16.8. Kymeta Corporation 16.9. Mediwise 16.10. Metamaterial Technologies, Inc. 16.11. MetaShield LLC. 16.12. Multiwave Technologies AG 16.13. Opalux, Inc. 16.14. Phoebus Optoelectronics, LLC 16.15. Plasmonics, Inc. 16.16. Teraview 16.17. Metamagnetics 16.18. Nanohmics Inc. 16.19. NKT Photonics 16.20. Harris Corporation 16.21. Newport Corporation 17. Primary Key Insights

About This Report

Report ID24404
Category Material & Chemical
Published DateJAN 2020
Updated DateSept 2021
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