Integrated Quantum Optical Circuits Market was valued at US$ 674.44 Mn in 2022 and is expected to reach US$ 1970.3 Mn by 2029 at a CAGR of 16.55% during a forecast period.
The report includes the analysis of the impact of COVID-19 lockdown on the revenue of market leaders, followers, and disruptors. Since the lockdown was implemented differently in various regions and countries; the impact of the same is also seen differently by regions and segments. The report has covered the current short-term and long-term impact on the market, and it would help the decision-makers to prepare the outline and strategies for companies by region.To Know About The Research Methodology :- Request Free Sample Report Integrated Quantum Optical Circuit is a device that combines multiple optical devices to form a single photonic circuit. This device takes light instead of electricity for signal processing and computing. It consists of a complex circuit design due to the integration of various optical devices including a multiplexer, amplifier, modulator, and other into a small compact circuit. Usually, integrated circuits work by directing electricity whereas the photonic circuit uses quantum lights for signal processing. Hybrid photonic and monolithic integration are the two different kinds of photonic integration methods. The hybrid photonic circuit consists of a package of photonic devices, which are used for the same function whereas a lot of optical devices of different functions are integrated to form a single IC. The application of Integrated Quantum Optical Circuits includes fiber-optic communication, biomedical, computing, and optical sensors.
Integrated Quantum Optical Circuits Market Dynamics:
An increase in demand for high-speed internet connectivity, multiplication of app-based solution in personal & professional services, and an increase in demand for powerful and enhanced alternatives for usual technology are key factors that drive the growth of the globally integrated quantum optical circuits market. Currently, developing countries such as India, China, Brazil, and others are focusing on constructing a high-speed internet infrastructure. Hence, an increase in investment by the IT & telecom industry over these countries is expected to raise the demand for high-speed internet connectivity. Therefore, diverse developed economies are investing in these countries to build their business globally. Although, the high initial cost and design complexity associated with the fabrication of circuits are expected to restrain the growth of the global market. Also, the rise in investment in building a 5G network is anticipated to provide gainful growth opportunities for the global integrated quantum optical circuits market in the near future.Integrated Quantum Optical Circuits Market Segment Analysis:
The optical fiber sensors segment dominated the global integrated quantum fiber circuits market in 2018 and is expected to continue dominant during the forecast period. Optical sensors application is the other hopeful application in this market. It is used in fields like defense, aerospace, energy, transportation, medicine, and further appearing fields. Quantum computing is another application of Photonic Integrated circuits (PICs) which is forecasted to be commercialized in 2019. This technology is expected to entirely transform the computing industry. PICs are also used in the biomedical field. In 2019, the silicon photonics segment generated the highest revenue in the globally integrated quantum optical circuits market. It is expected to remain dominant during the forecast period because it’s easy to fabricate and multiple functions can be combined in the chip. The Indium Phosphide segment is also expected to dominate globally integrated quantum optical circuits market during the forecast period as Indium Phosphide has the capability of cost-productive mass production using standard high-yield, batch semiconductor forming processes.Integrated Quantum Optical Circuits Market Regional Insights:
In 2022, North America generated the highest revenue in the globally integrated quantum optical circuits market and it is expected to dominate during the forecast period, due to the fact that at present North America has the largest market for PIC-based products, especially in data centers and WAN applications of optical fiber communication. However, Asia Pacific (APAC) is the main player in the access network application of optical fiber communications right now. North America is the leader in a PIC market with a 49% market share still it is estimated that APAC will appear as the market leader by 2026 growing at a CAGR of 35.9% from 2019 to 2026.Integrated Quantum Optical Circuits Market, Key Highlights:
• Integrated Quantum Optical Circuits Market analysis and forecast, in terms of value. • Comprehensive study and analysis of market drivers, restraints, and opportunities influencing the growth of the Integrated Quantum Optical Circuits Market • Integrated Quantum Optical Circuits Market segmentation on the basis of type, source, end-user, and region (country-wise) has been provided. • Integrated Quantum Optical Circuits Market strategic analysis with respect to individual growth trends, future prospects along with the contribution of various sub-market stakeholders have been considered under the scope of study. • Integrated Quantum Optical Circuits Market analysis and forecast for five major regions namely North America, Europe, Asia Pacific, the Middle East & Africa (MEA), and Latin America along with country-wise segmentation. • Profiles of key industry players, their strategic perspective, market positioning, and analysis of core competencies are further profiled. • Competitive developments, investments, strategic expansion, and competitive landscape of the key players operating in the Integrated Quantum Optical Circuits Market are also profiled.Integrated Quantum Optical Circuits Market Scope: Inquire before buying
Integrated Quantum Optical Circuits Market Report Coverage Details Base Year: 2022 Forecast Period: 2023-2029 Historical Data: 2017 to 2022 Market Size in 2022: US $ 674.44 Mn. Forecast Period 2023 to 2029 CAGR: 16.55% Market Size in 2029: US $ 1970.3 Mn. Segments Covered: by Material • Indium Phosphide • Silica Glass • Silicon Photonics • Lithium Niobate • Gallium Arsenide Integrated Quantum Optical Circuits Market, by Region
• North America (United States, Canada and Mexico) • Europe (UK, France, Germany, Italy, Spain, Sweden, Austria and Rest of Europe) • Asia Pacific (China, South Korea, Japan, India, Australia, Indonesia, Malaysia, Vietnam, Taiwan, Bangladesh, Pakistan and Rest of APAC) • Middle East and Africa (South Africa, GCC, Egypt, Nigeria and Rest of ME&A) • South America (Brazil, Argentina Rest of South America)Integrated Quantum Optical Circuits Market Key Players:
• Infinera (U.S.) • Alcatel Liucent (U.S.) • Neophotonics (U.S.) • JDSU (U.S.) Kotura (U.S.) • Aifotec AG • Ciena Corporation • Finisar Corporation • Intel Corporation • Infinera Corporation • Lumentum Operations Llc • Neophotonics Corporation • TE Connectivity • Oclaro Inc. • Luxtera, Inc. • Emcore Corporation Frequently Asked Questions: 1. Which region has the largest share in Global Integrated Quantum Optical Circuits Market? Ans: North America region held the highest share in 2022. 2. What is the growth rate of Global Integrated Quantum Optical Circuits Market? Ans: The Global Integrated Quantum Optical Circuits Market is growing at a CAGR of 16.55% during forecasting period 2023-2029. 3. What is scope of the Global Integrated Quantum Optical Circuits Market report? Ans: Global Integrated Quantum Optical Circuits Market report helps with the PESTEL, PORTER, COVID-19 Impact analysis, Recommendations for Investors & Leaders, and market estimation of the forecast period. 4. Who are the key players in Global Integrated Quantum Optical Circuits Market? Ans: The important key players in the Global Integrated Quantum Optical Circuits Market are – Infinera (U.S.), Alcatel Liucent (U.S.), Neophotonics (U.S.), JDSU (U.S.) Kotura (U.S.), Aifotec AG, Ciena Corporation, Finisar Corporation, Intel Corporation, Infinera Corporation, Lumentum Operations Llc, Neophotonics Corporation, TE Connectivity, Oclaro Inc., Luxtera, Inc., Emcore Corporation. 5. What is the study period of this Market? Ans: The Global Integrated Quantum Optical Circuits Market is studied from 2022 to 2029.
Global Integrated Quantum Optical Circuits Market
1. Preface 1.1. Research Objectives 1.2. Report Scope and Market Segmentation 2. Assumptions and Research Methodology 2.1. Abbreviations 3. Executive Summary 3.1. Global Integrated Quantum Optical Circuits Market Size, by Market Value (US$ Mn) and Market 4. Market Overview 4.1. Introduction 4.2. Market Dynamics 4.2.1. Drivers and Restraints Snapshot Analysis 4.2.2. Drivers 4.2.3. Restraints 4.2.4. Opportunities 4.2.5. Porter’s Analysis 4.2.6. Value Chain Analysis 4.2.7. SWOT Analysis 4.3. Global Integrated Quantum Optical Circuits Market Industry Trends 5. Global Integrated Quantum Optical Circuits Market Analysis and Forecast 5.1. Global Integrated Quantum Optical Circuits Market Size& Y-o-Y Growth Analysis 5.1.1. North America 5.1.2. Europe 5.1.3. Asia Pacific 5.1.4. Middle East & Africa 5.1.5. South America 6. Global Integrated Quantum Optical Circuits Market Analysis and Forecast, by Material Type 6.1. Introduction and Definition 6.2. Global Integrated Quantum Optical Circuits Market Value Share Analysis, by Material Type 6.3. Global Integrated Quantum Optical Circuits Market Size (US$ Mn) Forecast, by Material Type 6.4. Global Integrated Quantum Optical Circuits Market Analysis, by Material Type 6.5. Global Integrated Quantum Optical Circuits Market Attractiveness Analysis, by Material Type 6.6. Key Trends 6.6.1. Key Developments 7. Global Integrated Quantum Optical Circuits Market Analysis and Forecast, by Application 7.1. Introduction and Definition 7.2. Global Integrated Quantum Optical Circuits Market Value Share Analysis, by Application 7.3. Global Integrated Quantum Optical Circuits Market Size (US$ Mn) Forecast, by Application 7.4. Global Integrated Quantum Optical Circuits Market Analysis, by Application 7.5. Global Integrated Quantum Optical Circuits Market Attractiveness Analysis, by Application 7.6. Key Trends 7.6.1. Key Developments 8. Global Integrated Quantum Optical Circuits Market Analysis, by Region 8.1. Global Integrated Quantum Optical Circuits Market Value Share Analysis, by Region 8.2. Global Integrated Quantum Optical Circuits Market Size (US$ Mn) Forecast, by Region 8.3. Global Integrated Quantum Optical Circuits Market Attractiveness Analysis, by Region 8.4. Key Trends 8.4.1. Key Developments 9. North America Integrated Quantum Optical Circuits Market Analysis 9.1. North America Integrated Quantum Optical Circuits Market Overview 9.2. North America Integrated Quantum Optical Circuits Market Value Share Analysis, by Material Type 9.3. North America Integrated Quantum Optical Circuits Market Forecast, by Material Type 9.3.1. Indium Phosphide 9.3.2. Silica Glass 9.3.3. Silicon Photonics 9.3.4. Lithium Niobate 9.3.5. Gallium Arsenide 9.4. North America Integrated Quantum Optical Circuits Market Value Share Analysis, by Application 9.5. North America Integrated Quantum Optical Circuits Market Forecast, by Application 9.5.1. Optical Fiber Communication 9.5.2. Optical Sensors 9.5.3. Bio Medical 9.5.4. Quantum Computing 9.6. North America Integrated Quantum Optical Circuits Market Value Share Analysis, by Country 9.7. North America Integrated Quantum Optical Circuits Market Forecast, by Country 9.7.1. U.S. 9.7.2. Canada 9.8. North America Integrated Quantum Optical Circuits Market Analysis, by Country 9.9. U.S. Integrated Quantum Optical Circuits Market Forecast, by Material Type 9.9.1. Indium Phosphide 9.9.2. Silica Glass 9.9.3. Silicon Photonics 9.9.4. Lithium Niobate 9.9.5. Gallium Arsenide 9.10. U.S. Integrated Quantum Optical Circuits Market Forecast, by Application 9.10.1. Optical Fiber Communication 9.10.2. Optical Sensors 9.10.3. Bio Medical 9.10.4. Quantum Computing 9.11. Canada Integrated Quantum Optical Circuits Market Forecast, by Material Type 9.11.1. Indium Phosphide 9.11.2. Silica Glass 9.11.3. Silicon Photonics 9.11.4. Lithium Niobate 9.11.5. Gallium Arsenide 9.12. Canada Integrated Quantum Optical Circuits Market Forecast, by Application 9.12.1. Optical Fiber Communication 9.12.2. Optical Sensors 9.12.3. Bio Medical 9.12.4. Quantum Computing 9.13. North America Integrated Quantum Optical Circuits Market Attractiveness Analysis 9.13.1. By Material Type 9.13.2. By Application 9.14. PEST Analysis 9.15. Key Trends 9.15.1. Key Developments 10. Europe Integrated Quantum Optical Circuits Market Analysis 10.1. Europe Integrated Quantum Optical Circuits Market Overview 10.2. Europe Integrated Quantum Optical Circuits Market Value Share Analysis, by Material Type 10.3. Europe Integrated Quantum Optical Circuits Market Forecast, by Material Type 10.3.1. Indium Phosphide 10.3.2. Silica Glass 10.3.3. Silicon Photonics 10.3.4. Lithium Niobate 10.3.5. Gallium Arsenide 10.4. Europe Integrated Quantum Optical Circuits Market Value Share Analysis, by Application 10.5. Europe Integrated Quantum Optical Circuits Market Forecast, by Application 10.5.1. Optical Fiber Communication 10.5.2. Optical Sensors 10.5.3. Bio Medical 10.5.4. Quantum Computing 10.6. Europe Integrated Quantum Optical Circuits Market Value Share Analysis, by Country 10.7. Europe Integrated Quantum Optical Circuits Market Forecast, by Country 10.7.1. Germany 10.7.2. U.K. 10.7.3. France 10.7.4. Italy 10.7.5. Spain 10.7.6. Rest of Europe 10.8. Europe Integrated Quantum Optical Circuits Market Analysis, by Country/ Sub-region 10.9. Germany Integrated Quantum Optical Circuits Market Forecast, by Material Type 10.9.1. Indium Phosphide 10.9.2. Silica Glass 10.9.3. Silicon Photonics 10.9.4. Lithium Niobate 10.9.5. Gallium Arsenide 10.10. Germany Integrated Quantum Optical Circuits Market Forecast, by Application 10.10.1. Optical Fiber Communication 10.10.2. Optical Sensors 10.10.3. Bio Medical 10.10.4. Quantum Computing 10.11. U.K. Integrated Quantum Optical Circuits Market Forecast, by Material Type 10.11.1. Indium Phosphide 10.11.2. Silica Glass 10.11.3. Silicon Photonics 10.11.4. Lithium Niobate 10.11.5. Gallium Arsenide 10.12. U.K. Integrated Quantum Optical Circuits Market Forecast, by Application 10.12.1. Optical Fiber Communication 10.12.2. Optical Sensors 10.12.3. Bio Medical 10.12.4. Quantum Computing 10.13. France Integrated Quantum Optical Circuits Market Forecast, by Material Type 10.13.1. Indium Phosphide 10.13.2. Silica Glass 10.13.3. Silicon Photonics 10.13.4. Lithium Niobate 10.13.5. Gallium Arsenide 10.14. France Integrated Quantum Optical Circuits Market Forecast, by Application 10.14.1. Optical Fiber Communication 10.14.2. Optical Sensors 10.14.3. Bio Medical 10.14.4. Quantum Computing 10.15. Italy Integrated Quantum Optical Circuits Market Forecast, by Material Type 10.15.1. Indium Phosphide 10.15.2. Silica Glass 10.15.3. Silicon Photonics 10.15.4. Lithium Niobate 10.15.5. Gallium Arsenide 10.16. Italy Integrated Quantum Optical Circuits Market Forecast, by Application 10.16.1. Optical Fiber Communication 10.16.2. Optical Sensors 10.16.3. Bio Medical 10.16.4. Quantum Computing 10.17. Spain Integrated Quantum Optical Circuits Market Forecast, by Material Type 10.17.1. Indium Phosphide 10.17.2. Silica Glass 10.17.3. Silicon Photonics 10.17.4. Lithium Niobate 10.17.5. Gallium Arsenide 10.18. Spain Integrated Quantum Optical Circuits Market Forecast, by Application 10.18.1. Optical Fiber Communication 10.18.2. Optical Sensors 10.18.3. Bio Medical 10.18.4. Quantum Computing 10.19. Rest of Europe Integrated Quantum Optical Circuits Market Forecast, by Material Type 10.19.1. Indium Phosphide 10.19.2. Silica Glass 10.19.3. Silicon Photonics 10.19.4. Lithium Niobate 10.19.5. Gallium Arsenide 10.20. Rest of Europe Integrated Quantum Optical Circuits Market Forecast, by Application 10.20.1. Optical Fiber Communication 10.20.2. Optical Sensors 10.20.3. Bio Medical 10.20.4. Quantum Computing 10.21. Europe Integrated Quantum Optical Circuits Market Attractiveness Analysis 10.21.1. By Material Type 10.21.2. By Application 10.22. PEST Analysis 10.23. Key Trends 10.23.1. Key Developments 11. Asia Pacific Integrated Quantum Optical Circuits Market Analysis 11.1. Key Findings 11.2. Asia Pacific Integrated Quantum Optical Circuits Market Overview 11.3. Asia Pacific Integrated Quantum Optical Circuits Market Value Share Analysis, by Material Type 11.4. Asia Pacific Integrated Quantum Optical Circuits Market Forecast, by Material Type 11.4.1. Indium Phosphide 11.4.2. Silica Glass 11.4.3. Silicon Photonics 11.4.4. Lithium Niobate 11.4.5. Gallium Arsenide 11.5. Asia Pacific Integrated Quantum Optical Circuits Market Value Share Analysis, by Application 11.6. Asia Pacific Integrated Quantum Optical Circuits Market Forecast, by Application 11.6.1. Optical Fiber Communication 11.6.2. Optical Sensors 11.6.3. Bio Medical 11.6.4. Quantum Computing 11.7. Asia Pacific Integrated Quantum Optical Circuits Market Value Share Analysis, by Country 11.8. Asia Pacific Integrated Quantum Optical Circuits Market Forecast, by Country 11.8.1. China 11.8.2. India 11.8.3. Japan 11.8.4. ASEAN 11.8.5. Rest of Asia Pacific 11.9. Asia Pacific Integrated Quantum Optical Circuits Market Analysis, by Country/ Sub-region 11.10. China Integrated Quantum Optical Circuits Market Forecast, by Material Type 11.10.1. Indium Phosphide 11.10.2. Silica Glass 11.10.3. Silicon Photonics 11.10.4. Lithium Niobate 11.10.5. Gallium Arsenide 11.11. China Integrated Quantum Optical Circuits Market Forecast, by Application 11.11.1. Optical Fiber Communication 11.11.2. Optical Sensors 11.11.3. Bio Medical 11.11.4. Quantum Computing 11.12. India Integrated Quantum Optical Circuits Market Forecast, by Material Type 11.12.1. Indium Phosphide 11.12.2. Silica Glass 11.12.3. Silicon Photonics 11.12.4. Lithium Niobate 11.12.5. Gallium Arsenide 11.13. India Integrated Quantum Optical Circuits Market Forecast, by Application 11.13.1. Optical Fiber Communication 11.13.2. Optical Sensors 11.13.3. Bio Medical 11.13.4. Quantum Computing 11.14. Japan Integrated Quantum Optical Circuits Market Forecast, by Material Type 11.14.1. Indium Phosphide 11.14.2. Silica Glass 11.14.3. Silicon Photonics 11.14.4. Lithium Niobate 11.14.5. Gallium Arsenide 11.15. Japan Integrated Quantum Optical Circuits Market Forecast, by Application 11.15.1. Optical Fiber Communication 11.15.2. Optical Sensors 11.15.3. Bio Medical 11.15.4. Quantum Computing 11.16. ASEAN Integrated Quantum Optical Circuits Market Forecast, by Material Type 11.16.1. Indium Phosphide 11.16.2. Silica Glass 11.16.3. Silicon Photonics 11.16.4. Lithium Niobate 11.16.5. Gallium Arsenide 11.17. ASEAN Integrated Quantum Optical Circuits Market Forecast, by Application 11.17.1. Optical Fiber Communication 11.17.2. Optical Sensors 11.17.3. Bio Medical 11.17.4. Quantum Computing 11.18. Rest of Asia Pacific Integrated Quantum Optical Circuits Market Forecast, by Material Type 11.18.1. Indium Phosphide 11.18.2. Silica Glass 11.18.3. Silicon Photonics 11.18.4. Lithium Niobate 11.18.5. Gallium Arsenide 11.19. Rest of Asia Pacific Integrated Quantum Optical Circuits Market Forecast, by Application 11.19.1. Optical Fiber Communication 11.19.2. Optical Sensors 11.19.3. Bio Medical 11.19.4. Quantum Computing 11.20. Asia Pacific Integrated Quantum Optical Circuits Market Attractiveness Analysis 11.20.1. By Material Type 11.20.2. By Application 11.21. PEST Analysis 11.22. Key Trends 11.22.1. Key Developments 12. Middle East & Africa Integrated Quantum Optical Circuits Market Analysis 12.1. Key Findings 12.2. Middle East & Africa Integrated Quantum Optical Circuits Market Overview 12.3. Middle East & Africa Integrated Quantum Optical Circuits Market Value Share Analysis, by Material Type 12.4. Middle East & Africa Integrated Quantum Optical Circuits Market Forecast, by Material Type 12.4.1. Indium Phosphide 12.4.2. Silica Glass 12.4.3. Silicon Photonics 12.4.4. Lithium Niobate 12.4.5. Gallium Arsenide 12.5. Middle East & Africa Integrated Quantum Optical Circuits Market Value Share Analysis, by Application 12.6. Middle East & Africa Integrated Quantum Optical Circuits Market Forecast, by Application 12.6.1. Optical Fiber Communication 12.6.2. Optical Sensors 12.6.3. Bio Medical 12.6.4. Quantum Computing 12.7. Middle East & Africa Integrated Quantum Optical Circuits Market Value Share Analysis, by Country 12.8. Middle East & Africa Integrated Quantum Optical Circuits Market Forecast, by Country 12.8.1. GCC 12.8.2. South Africa 12.8.3. Rest of Middle East & Africa 12.9. Middle East & Africa Integrated Quantum Optical Circuits Market Analysis, by Country/ Sub-region 12.10. GCC Integrated Quantum Optical Circuits Market Forecast, by Material Type 12.10.1. Indium Phosphide 12.10.2. Silica Glass 12.10.3. Silicon Photonics 12.10.4. Lithium Niobate 12.10.5. Gallium Arsenide 12.11. GCC Integrated Quantum Optical Circuits Market Forecast, by Application 12.11.1. Optical Fiber Communication 12.11.2. Optical Sensors 12.11.3. Bio Medical 12.11.4. Quantum Computing 12.12. South Africa Integrated Quantum Optical Circuits Market Forecast, by Material Type 12.12.1. Indium Phosphide 12.12.2. Silica Glass 12.12.3. Silicon Photonics 12.12.4. Lithium Niobate 12.12.5. Gallium Arsenide 12.13. South Africa Integrated Quantum Optical Circuits Market Forecast, by Application 12.13.1. Optical Fiber Communication 12.13.2. Optical Sensors 12.13.3. Bio Medical 12.13.4. Quantum Computing 12.14. Rest of Middle East & Africa Integrated Quantum Optical Circuits Market Forecast, by Material Type 12.14.1. Indium Phosphide 12.14.2. Silica Glass 12.14.3. Silicon Photonics 12.14.4. Lithium Niobate 12.14.5. Gallium Arsenide 12.15. Rest of Middle East & Africa Integrated Quantum Optical Circuits Market Forecast, by Application 12.15.1. Optical Fiber Communication 12.15.2. Optical Sensors 12.15.3. Bio Medical 12.15.4. Quantum Computing 12.16. Middle East & Africa Integrated Quantum Optical Circuits Market Attractiveness Analysis 12.16.1. By Material Type 12.16.2. By Application 12.17. PEST Analysis 12.18. Key Trends 12.18.1. Key Developments 13. South America Integrated Quantum Optical Circuits Market Analysis 13.1. Key Findings 13.2. South America Integrated Quantum Optical Circuits Market Overview 13.3. South America Integrated Quantum Optical Circuits Market Value Share Analysis, by Material Type 13.4. South America Integrated Quantum Optical Circuits Market Forecast, by Material Type 13.4.1. Indium Phosphide 13.4.2. Silica Glass 13.4.3. Silicon Photonics 13.4.4. Lithium Niobate 13.4.5. Gallium Arsenide 13.5. South America Integrated Quantum Optical Circuits Market Value Share Analysis, by Application 13.6. South America Integrated Quantum Optical Circuits Market Forecast, by Application 13.6.1. Optical Fiber Communication 13.6.2. Optical Sensors 13.6.3. Bio Medical 13.6.4. Quantum Computing 13.7. South America Integrated Quantum Optical Circuits Market Value Share Analysis, by Country 13.8. South America Integrated Quantum Optical Circuits Market Forecast, by Country 13.8.1. Brazil 13.8.2. Mexico 13.8.3. Rest of South America 13.9. South America Integrated Quantum Optical Circuits Market Analysis, by Country/ Sub-region 13.10. Brazil Integrated Quantum Optical Circuits Market Forecast, by Material Type 13.10.1. Indium Phosphide 13.10.2. Silica Glass 13.10.3. Silicon Photonics 13.10.4. Lithium Niobate 13.10.5. Gallium Arsenide 13.11. Brazil Integrated Quantum Optical Circuits Market Forecast, by Application 13.11.1. Optical Fiber Communication 13.11.2. Optical Sensors 13.11.3. Bio Medical 13.11.4. Quantum Computing 13.12. Mexico Integrated Quantum Optical Circuits Market Forecast, by Material Type 13.12.1. Indium Phosphide 13.12.2. Silica Glass 13.12.3. Silicon Photonics 13.12.4. Lithium Niobate 13.12.5. Gallium Arsenide 13.13. Mexico Integrated Quantum Optical Circuits Market Forecast, by Application 13.13.1. Optical Fiber Communication 13.13.2. Optical Sensors 13.13.3. Bio Medical 13.13.4. Quantum Computing 13.14. Rest of South America Integrated Quantum Optical Circuits Market Forecast, by Material Type 13.14.1. Indium Phosphide 13.14.2. Silica Glass 13.14.3. Silicon Photonics 13.14.4. Lithium Niobate 13.14.5. Gallium Arsenide 13.15. Rest of South America Integrated Quantum Optical Circuits Market Forecast, by Application 13.15.1. Optical Fiber Communication 13.15.2. Optical Sensors 13.15.3. Bio Medical 13.15.4. Quantum Computing 13.16. South America Integrated Quantum Optical Circuits Market Attractiveness Analysis 13.16.1. By Material Type 13.16.2. By Application 13.17. PEST Analysis 13.18. Key Trends 13.18.1. Key Developments 14. Competitive Landscape 14.1. Market Share Analysis, by Company 14.2. Competition Matrix 14.3. Competitive Benchmarking of Company and Services 14.4. Company Profiles: Key Players 14.4.1. Infinera (U.S.) 14.4.1.1. Company Overview 14.4.1.2. Financial Overview 14.4.1.3. Business Strategy 14.4.1.4. Recent Developments 14.4.1.5. Development Footprint 14.4.2. Alcatel Liucent (U.S.) 14.4.3. Neophotonics (U.S.) 14.4.4. JDSU (U.S.) Kotura (U.S.) 14.4.5. Aifotec AG 14.4.6. Ciena Corporation 14.4.7. Finisar Corporation 14.4.8. Intel Corporation 14.4.9. Infinera Corporation 14.4.10. Neophotonics Corporation 14.4.11. TE Connectivity 14.4.12. Oclaro Inc. 14.4.13. Luxtera, Inc. 14.4.14. Emcore Corporation 15. Primary Key Insights