Report Description Table of Contents The floating offshore wind market size is growing rapidly and is expected to grow at a CAGR of 88.37% during the forecast period. The surging demand for renewable energy sources, driven by climate change concerns and energy security needs, is propelling the rapid growth of the floating offshore wind market. Floating-offshore-wind is a sort of wind energy technology that entails building and installing wind turbines on floating platforms in deep water, usually more than 60 meters. This device is intended to harness the powerful and regular offshore winds, which are stronger and more reliable than onshore winds. Floating offshore wind is one of the most rapidly increasing technologies driving the global green energy transformation. The 232 MW capacity of the floating offshore wind farms is now being established, and with more creative ideas in the sector, the industry is expected to produce about 12.3 GW of clean energy by 2030. Global energy efficiency can be raised and millions of homes' energy needs can be met by utilizing wind energy from deepwater environments. The ability to build floating offshore wind technology in locations where traditional fixed-bottom offshore wind turbines cannot be erected because of geological limitations or water depths is one of its main advantages. This can contribute to raising the total capacity of renewable energy generation by creating new opportunities for wind energy development. One of the main advantages of floating offshore wind technology is its ability to be used in locations where geological features or sea depths prevent the installation of standard fixed-bottom offshore wind turbines. This can contribute to raising the total capacity of renewable energy generation by creating new opportunities for wind energy development. Floating offshore wind technology presents a promising area of growth for the building and construction sector. Floating offshore wind offers enormous potential to deliver clean electricity to millions of Americans while also assisting the country in meeting greenhouse gas emission reduction targets to mitigate the worst effects of climate change. President Biden's aim of cutting greenhouse gas emissions by 50% by 2030 can only be possible if we increase our usage of clean energy technology, such as offshore wind. Floating wind energy with a capacity of 232 MW will be operational worldwide by 2024. Furthermore, by 2030, 2.3GW of floating wind energy should be operational. Grant programmes The government offers the following assistance programs as well: Eleven floating offshore wind projects received £60 million in combined public and industry funding as part of the Net Zero Innovation Portfolio, in January 2022. The government launched the Floating Offshore Wind Manufacturing Investment Scheme (FLOWMIS) in March 2023 to finance vital port infrastructure that would make it possible to deploy floating offshore wind. This is a £160 million funding program. Market Drivers (The Winds of Change: Renewable Energy, Government Support, and Innovation Fueling Floating Wind Market) Transition toward renewable energy sources is driven by growing concerns about climate change & the depletion of fossil resources. Floating wind provides a clean and environmentally friendly approach to generate electricity. Floating wind farms are able to generate more electricity since offshore winds are typically stronger and more reliable than onshore winds. The International Energy Agency projects that by 2050, renewable energy sources will produce 80% of the world's electricity. Fossil fuels have a clean substitute in floating wind. The output of power can be enhanced by up to 20% when wind speeds are higher offshore than onshore. Many countries have established high standards for renewable energy, and floating wind is seen as a crucial technology to help them meet these objectives. A lot of governments have set high goals for renewable energy, and one important technology to help them reach these targets is floating wind. By 2035, the US Department of Energy wants to have installed 15 GW of floating offshore wind. Governments will occasionally provide tax discounts or subsidies to developers of floating wind turbines, increasing their financial appeal. Technological advancements in wind turbines and floating platform designs are reducing project costs overall and increasing wind energy capture efficiency. The cost of floating platforms is decreasing because to technological developments, which is important for project viability. By 2030, projections indicate a 30–50% decline. The increased efficiency with which wind energy is being captured by newly designed offshore wind turbines is contributing to their increased economic viability. Market Restraints Beyond the Cost Horizon: Obstacles to Wider Adoption of Floating Wind Farms One of the most significant obstacles is technological complexity in terms of stability, mooring systems, and dynamic reaction to waves and currents. Another difficult factor is cost, since floating wind facilities is more costly than conventional onshore and fixed-bottom offshore wind farms. In contrast to fixed bottom offshore wind, floating wind projects have a different cost distribution, with the foundation bearing a larger share of the cost than the turbine. The expense of installation, operation, and maintenance increases as the distance from the shore increases since these tasks are harder to complete. Strong maintenance plans and accompanying infrastructure are required for operating and maintaining offshore floating wind farms in remote areas due to logistical issues with access, transportation, and severe marine environments. Market Opportunity (Floating Wind Power Set to Surge towards a Sustainable Future) Floating offshore wind has enormous potential, with capacity expected to reach 250 gigawatts by 2050, significantly contributing to carbon emissions reduction and energy transition initiatives. Projects such as Hywind Tampen have already demonstrated that floating wind is growing from one-off pilot projects to full-scale wind farms. Key elements to overcoming the upcoming issues include supply chain development and innovations in design, production, and materials. Governments, industrial players, and research institutions must work together to expedite technological development and cut costs, since this will enable us to get closer to the goal of scaling up deployment. The growing capacity of FOW farms and the infrastructural investments made to enable project scaling are unquestionably signs of the initiative and interest. This collaborative initiative is laying the groundwork for an exciting future for floating offshore wind. Market Segmentation: Unraveling the Floating Offshore Wind Landscape The global floating offshore wind market segmentation is done on the basis of component, location, application, and region. By Component Turbines Floating Structures Subsea Cables Others By Location Deep Water Transitional Water Shallow Water By Application Commercial Power Generation Research and Development Others By Region: A Geographical Breakdown of the Market North America US Mexico Canada Rest of North America Europe Switzerland Russia France Germany U.K Finland Turkey Netherlands Belgium Spain Italy Rest of Europe Asia Pacific China India South Korea Japan Singapore Thailand Indonesia Malaysia Philippines Australia Rest of Asia-Pacific LAMEA Brazil Saudi Arabia Argentina Uruguay Rest of LAMEA Deep Water Dominates: Location-Based Market Dynamics On the basis of location, the deep water segment led the market with largest revenue share. The segment is dominating due to its ability to access stronger and more consistent wind resources that are typically found farther from the shore. Unlike fixed-bottom turbines, which are limited to shallow waters, floating wind turbines can be deployed in deep waters where wind speeds are higher and more stable, resulting in greater energy production. Deepwater installations are now more economically feasible due to technological developments and falling floating platform design costs. This has drawn large investments and contributed to the segment's market domination. The transitional water segment is expected to grow at a significant rate during the forecast period. Transitional water located between shallow coastal areas and deeper ocean waters are ideal locations for floating offshore wind projects because of their reasonably stable conditions and closeness to onshore infrastructure. Commercial Power Generation: The Market's Primary Application On the basis of application, the commercial power generation segment dominated the market. Commercial power generation is the dominating segment due to the substantial demand for large-scale, renewable energy solutions to meet global energy needs and reduce carbon emissions. Additionally, technological advancements and cost reductions in floating wind technology have enhanced the feasibility and economic viability of commercial-scale projects, further driving the dominance of this segment. Europe: A Pioneering Force in Floating Offshore Wind Europe is the largest floating offshore wind market and is expected to hold 50% of market share by 2035. The existence of significant energy corporations and committed funding for R&D strengthen Europe's position as a leader in this field. According to industry group WindEurope, floating offshore wind generation with a capacity of up to 10 GW is expected to come online in Europe alone by 2030. This is sufficient to power over three million homes. Furthermore, the deployment and upkeep of floating wind turbines are made easier by the developed offshore technical skills and established maritime industries of European nations. Key Players: Shaping the Floating Offshore Wind Industry BW Ideol AS Siemens Gamesa Renewable Energy, S.A. General Electric Company Vestas Wind Systems A/S Doosan Enerbility Co. Ltd. MHI Vestas (Denmark) (Now part of Vestas) FlowOcean (Sweden) Engie Energy (France) ABB Ltd. (Switzerland) Ming Yang Smart Energy Group Co. (China) Nordex SE (Germany) GoldWind (China) Envision Energy (China) Suzlon Energy Limited (India) Hitachi Ltd. Floating Offshore Wind Market Report Coverage Report Attribute Details Forecast Period 2024 – 2032 Market Size Value in 2024 USD 1.36 Billion Revenue Forecast by 2030 USD 60.59 Billion Overall Growth Rate CAGR of 88.37% (2024 – 2030) Base Year for Estimation 2023 Historical Data 2017 – 2021 Unit USD Billion, CAGR (2024 – 2030) Segmentation By Components, By Location, By Application, By Geography By Components Turbines, Floating Structures, Subsea Cables, Others By Location Shallow Water, Deep Water, Transitional Water By Application Commercial Power Generation, Research and Development, Others By Region North America, Europe, Asia-Pacific, Latin America, Middle East & Africa Country Scope U.S., Canada, UK, Norway, France, China, Japan, South Korea, Brazil, etc. Market Drivers Surge in renewable energy adoption, favorable government policies, expansion of deepwater wind installations Customization Option Available on request Recent Developments: Driving the Floating Offshore Wind Market Forward In July 2024, a mooring system dubbed C-Dart, developed by UK-based Blackfish Engineering, removes the need for operating staff to handle heavy mooring lines directly. According to the company, the system is made to quickly connect a variety of floating assets and structures, such as offshore wind, wave and tidal energy converters, floating solar platforms, aquaculture, and more. The C-Dart system makes use of the concepts of gravity, buoyancy, and rope tension to enable a quick and easy automated connecting process that quickly and securely secures equipment. In July 2024, The OceanX platform, developed by Mingyang Smart Energy in China, is said to be the largest single-capacity floating wind turbine platform in the world. It is equipped with two 8.3 MW MySE8.3-180 hybrid drive wind turbines. It is believed that pre-tensioned guy ropes are utilized to distribute the tower's gravity load, allowing for a lightweight construction. With two turbines per platform, OceanX has a 16.6 MW overall capacity. The yearly production capacity of the technology is 54 million kWh, which is sufficient to power 30,000 dwellings. Frequently Asked Question About This Report . . TABLE OF CONTENTS 1. EXECUTIVE SUMMARY –GLOBAL FLOATING OFFSHORE WIND MARKET 1.1. Market Attractiveness 1.2. Understanding the Target Customers 1.3. Key Highlights 1.4. CXO perspective 1.5. Global Floating Offshore Wind Market, Historical Market Size & Future Projections Analysis (2017-2023) 1.6. Global Floating Offshore Wind Market, By Components 1.7. Global Floating Offshore Wind Market, By Location 1.8. Global Floating Offshore Wind Market, By Application 1.9. Global Solvent Recovery and Recycling Market, By Region 2. MARKET INTRODUCTION 2.1. Definition 2.2. Scope of the Study 2.3. Market Structure 2.4. Market Trends 2.5. Macro Factor Indicator Analysis 2.6. Key findings 2.6.1. Top investment pockets 3. MARKET DYNAMICS 3.1. Introduction 3.2. Potential Installed Capacity Forecast in GW till 2030 3.3. Key Projects Information 3.3.1. Major Existing Projects 3.3.2. Upcoming Projects 3.4. Government Policies and Regulations 3.5. Recent Developments 3.6. Drivers 3.6.1. Technological Advancements 3.6.2. Renewable Energy Targets 3.6.3. Abundant Offshore Wind Resources 3.6.4. Cost Competitiveness 3.6.5. Energy Security 3.7. Restraints 3.7.1. High Initial Costs 3.7.2. Technological Maturity 3.7.3. Installation and Maintenance Challenges 3.7.4. Environmental Concerns 3.7.5. Grid Connection Challenges 3.8. Opportunities 3.8.1. Global Expansion 3.8.2. Job Creation 3.8.3. Innovation and Collaboration 3.8.4. Hybrid Projects 3.8.5. Offshore Development Zones 3.9. Challenges 3.9.1. Regulatory Frameworks 3.9.2. Financial Support 3.9.3. Supply Chain Constraints 3.9.4. Public Acceptance 3.9.5. Weather Risks 4. MARKET SHARE ANALYSIS 4.1. Top 10 Players with Revenue and Sales 4.2. Market Share, 2023 4.3. Market Entry and Expansion Strategies 4.4. Go To Market Strategy 4.5. Competitive Landscape 4.6. Analyst Perspective 5. GLOBAL FLOATING OFFSHORE WIND MARKET ANALYSIS BY SEGMENT (COUNTRY LEVEL ANALYSIS) 5.1. Overview 5.2. Global Floating Offshore Wind Market Size ($BILLION), (2017 – 2023) 5.3. Global Floating Offshore Wind Market Size ($BILLION), and Forecasts (2024 – 2030) 5.4. Global Floating Offshore Wind Market Size ($BILLION), and Forecasts (2024 – 2030), By Components 5.4.1. Turbines 5.4.2. Floating Structures 5.4.3. Subsea Cables 5.4.4. Others 5.5. Global Floating Offshore Wind Market Size ($BILLION), and Forecasts (2024 – 2030), By Location 5.5.1. Shallow Water 5.5.2. Deep Water 5.5.3. Transitional Water 5.6. Global Floating Offshore Wind Market Size ($BILLION), and Forecasts (2024 – 2030), Application 5.6.1. Commercial Power Generation 5.6.2. Research and Development 5.6.3. Others 5.7. Global Floating Offshore Wind Market Size ($BILLION), and Forecasts (2024 – 2030), By Geography 5.7.1. North America 5.7.2. Europe 5.7.3. APAC 5.7.4. LAMEA 6. NORTH AMERICA FLOATING OFFSHORE WIND MARKET ANALYSIS BY SEGMENT (COUNTRY LEVEL ANALYSIS) 6.1. Overview 6.2. North America Floating Offshore Wind Market Size ($BILLION), (2017 – 2023) 6.3. North America Floating Offshore Wind Market Size ($BILLION), and Forecasts (2024 – 2030) 6.4. North America Floating Offshore Wind Market Size ($BILLION), and Forecasts (2024 – 2030), By Components 6.4.1. Turbines 6.4.2. Floating Structures 6.4.3. Subsea Cables 6.4.4. Others 6.5. North America Floating Offshore Wind Market Size ($BILLION), and Forecasts (2024 – 2030), By Location 6.5.1. Shallow Water 6.5.2. Deep Water 6.5.3. Transitional Water 6.6. North America Floating Offshore Wind Market Size ($BILLION), and Forecasts (2024 – 2030), Application 6.6.1. Commercial Power Generation 6.6.2. Research and Development 6.6.3. Others 6.7. North America Floating Offshore Wind Market Size ($BILLION), and Forecasts (2024 – 2030), By Geography 6.7.1. United States of America 6.7.2. Canada 6.7.3. Mexico 7. EUROPE FLOATING OFFSHORE WIND MARKET ANALYSIS BY SEGMENT (COUNTRY LEVEL ANALYSIS) 7.1. Overview 7.2. Europe Floating Offshore Wind Market Size ($BILLION), (2017 – 2023) 7.3. Europe Floating Offshore Wind Market Size ($BILLION), and Forecasts (2024 – 2030) 7.4. Europe Floating Offshore Wind Market Size ($BILLION), and Forecasts (2024 – 2030), By Components 7.4.1. Turbines 7.4.2. Floating Structures 7.4.3. Subsea Cables 7.4.4. Others 7.5. Europe Floating Offshore Wind Market Size ($BILLION), and Forecasts (2024 – 2030), By Location 7.5.1. Shallow Water 7.5.2. Deep Water 7.5.3. Transitional Water 7.6. Europe Floating Offshore Wind Market Size ($BILLION), and Forecasts (2024 – 2030), Application 7.6.1. Commercial Power Generation 7.6.2. Research and Development 7.6.3. Others 7.7. Europe Floating Offshore Wind Market Size ($BILLION), and Forecasts (2024 – 2030), By Geography 7.7.1. Norway 7.7.2. United Kingdom 7.7.3. Portugal 7.7.4. Germany 7.7.5. France 7.7.6. Denmark 7.7.7. Rest of the Europe 8. APAC FLOATING OFFSHORE WIND MARKET ANALYSIS BY SEGMENT (COUNTRY LEVEL ANALYSIS) 8.1. Overview 8.2. APAC Floating Offshore Wind Market Size ($BILLION), (2017 – 2023) 8.3. APAC Floating Offshore Wind Market Size ($BILLION), and Forecasts (2024 – 2030) 8.4. APAC Floating Offshore Wind Market Size ($BILLION), and Forecasts (2024 – 2030), By Components 8.4.1. Turbines 8.4.2. Floating Structures 8.4.3. Subsea Cables 8.4.4. Others 8.5. APAC Floating Offshore Wind Market Size ($BILLION), and Forecasts (2024 – 2030), By Location 8.5.1. Shallow Water 8.5.2. Deep Water 8.5.3. Transitional Water 8.6. APAC Floating Offshore Wind Market Size ($BILLION), and Forecasts (2024 – 2030), Application 8.6.1. Commercial Power Generation 8.6.2. Research and Development 8.6.3. Others 8.7. APAC Floating Offshore Wind Market Size ($BILLION), and Forecasts (2024 – 2030), By Geography 8.7.1. China 8.7.2. South Korea 8.7.3. Japan 8.7.4. India 8.7.5. Rest of the APAC 9. LAMEA FLOATING OFFSHORE WIND MARKET ANALYSIS BY SEGMENT (COUNTRY LEVEL ANALYSIS) 9.1. Overview 9.2. LAMEA Floating Offshore Wind Market Size ($BILLION), (2017 – 2023) 9.3. LAMEA Floating Offshore Wind Market Size ($BILLION), and Forecasts (2024 – 2030) 9.4. LAMEA Floating Offshore Wind Market Size ($BILLION), and Forecasts (2024 – 2030), By Components 9.4.1. Turbines 9.4.2. Floating Structures 9.4.3. Subsea Cables 9.4.4. Others 9.5. LAMEA Floating Offshore Wind Market Size ($BILLION), and Forecasts (2024 – 2030), By Location 9.5.1. Shallow Water 9.5.2. Deep Water 9.5.3. Transitional Water 9.6. LAMEA Floating Offshore Wind Market Size ($BILLION), and Forecasts (2024 – 2030), Application 9.6.1. Commercial Power Generation 9.6.2. Research and Development 9.6.3. Others 9.7. LAMEA Floating Offshore Wind Market Size ($BILLION), and Forecasts (2024 – 2030), By Geography 9.7.1. Brazil 9.7.2. South Africa 9.7.3. Rest of the LAMEA 10. COMPANY PROFILES 10.1. EQUINOR ASA (NORWAY) 10.1.1. Company Overview 10.1.2. Company Snapshot 10.1.3. Operating business segments 10.1.4. Product Offered and Revenue from Floating Offshore Wind Business 10.1.5. Key business performances, strategies and developments 10.1.6. Strategy towards Floating Offshore Wind & Revenue Projection 10.2. ORSTED A/S (DENMARK) 10.2.1. Company Overview 10.2.2. Company Snapshot 10.2.3. Operating business segments 10.2.4. Product Offered and Revenue from Floating Offshore Wind Business 10.2.5. Key business performances, strategies and developments 10.2.6. Strategy towards Floating Offshore Wind & Revenue Projection 10.3. SHELL NEW ENERGIES (NETHERLANDS) 10.3.1. Company Overview 10.3.2. Company Snapshot 10.3.3. Operating business segments 10.3.4. Product Offered and Revenue from Floating Offshore Wind Business 10.3.5. Key business performances, strategies and developments 10.3.6. Strategy towards Floating Offshore Wind & Revenue Projection 10.4. PRINCIPLE POWER INC. (UNITED STATES) 10.4.1. Company Overview 10.4.2. Company Snapshot 10.4.3. Operating business segments 10.4.4. Product Offered and Revenue from Floating Offshore Wind Business 10.4.5. Key business performances, strategies and developments 10.4.6. Strategy towards Floating Offshore Wind & Revenue Projection 10.5. IDEOL S.A. (FRANCE) 10.5.1. Company Overview 10.5.2. Company Snapshot 10.5.3. Operating business segments 10.5.4. Product Offered and Revenue from Floating Offshore Wind Business 10.5.5. Key business performances, strategies and developments 10.5.6. Strategy towards Floating Offshore Wind & Revenue Projection 10.6. SSE RENEWABLES (UNITED KINGDOM) 10.6.1. Company Overview 10.6.2. Company Snapshot 10.6.3. Operating business segments 10.6.4. Product Offered and Revenue from Floating Offshore Wind Business 10.6.5. Key business performances, strategies and developments 10.6.6. Strategy towards Floating Offshore Wind & Revenue Projection 10.7. FLOATING POWER PLANT A/S (DENMARK 10.7.1. Company Overview 10.7.2. Company Snapshot 10.7.3. Operating business segments 10.7.4. Product Offered and Revenue from Floating Offshore Wind Business 10.7.5. Key business performances, strategies and developments 10.7.6. Strategy towards Floating Offshore Wind & Revenue Projection 10.8. BLUEFLOAT ENERGY (SPAIN) 10.8.1. Company Overview 10.8.2. Company Snapshot 10.8.3. Operating business segments 10.8.4. Product Offered and Revenue from Floating Offshore Wind Business 10.8.5. Key business performances, strategies and developments 10.8.6. Strategy towards Floating Offshore Wind & Revenue Projection 10.9. OTHERS (TOTAL 20 KEY PLAYERS DEPENDING ON CLIENT’S LOCATION AND PRODUCT SPECIFICATION REQUEST) 11. RESEARCH METHODOLOGY 11.1. Research Process 11.2. Primary Research 11.3. Secondary Research 11.4. Market Size Estimation 11.5. Forecast Model LIST OF TABLES 1. TABLE: GLOBAL FLOATING OFFSHORE WIND MARKET, 2023-2030 (USD BILLION) 2. TABLE: GLOBAL FLOATING OFFSHORE WIND MARKET, BY COMPONENTS, 2023-2030 (USD BILLION) 3. TABLE: GLOBAL FLOATING OFFSHORE WIND MARKET, BY LOCATION, 2023-2030 (USD BILLION) 4. TABLE: GLOBAL FLOATING OFFSHORE WIND MARKET, BY APPLIACTION, 2023-2030 (USD BILLION) 5. TABLE: USA FLOATING OFFSHORE WIND MARKET, 2023-2030 (USD BILLION) 6. TABLE: USA FLOATING OFFSHORE WIND MARKET, BY COMPONENTS, 2023-2030 (USD BILLION) 7. TABLE: USA FLOATING OFFSHORE WIND MARKET, BY LOCATION, 2023-2030 (USD BILLION) 8. TABLE: USA FLOATING OFFSHORE WIND MARKET, BY APPLIACTION, 2023-2030 (USD BILLION) 9. TABLE: CANADA FLOATING OFFSHORE WIND MARKET, 2023-2030 (USD BILLION) 10. TABLE: CANADA FLOATING OFFSHORE WIND MARKET, BY COMPONENTS, 2023-2030 (USD BILLION) 11. TABLE: CANADA FLOATING OFFSHORE WIND MARKET, BY LOCATION, 2023-2030 (USD BILLION) 12. TABLE: CANADA FLOATING OFFSHORE WIND MARKET, BY APPLIACTION, 2023-2030 (USD BILLION) 13. TABLE: NORWAY FLOATING OFFSHORE WIND MARKET, 2023-2030 (USD BILLION) 14. TABLE: NORWAY FLOATING OFFSHORE WIND MARKET, BY COMPONENTS, 2023-2030 (USD BILLION) 15. TABLE: NORWAY FLOATING OFFSHORE WIND MARKET, BY LOCATION, 2023-2030 (USD BILLION) 16. TABLE: NORWAY FLOATING OFFSHORE WIND MARKET, BY APPLIACTION, 2023-2030 (USD BILLION) 17. TABLE: UK FLOATING OFFSHORE WIND MARKET, 2023-2030 (USD BILLION) 18. TABLE: UK FLOATING OFFSHORE WIND MARKET, BY COMPONENTS, 2023-2030 (USD BILLION) 19. TABLE: UK FLOATING OFFSHORE WIND MARKET, BY LOCATION, 2023-2030 (USD BILLION) 20. TABLE: UK FLOATING OFFSHORE WIND MARKET, BY APPLIACTION, 2023-2030 (USD BILLION) 21. TABLE: GERMANY FLOATING OFFSHORE WIND MARKET, 2023-2030 (USD BILLION) 22. TABLE: GERMANY FLOATING OFFSHORE WIND MARKET, BY COMPONENTS, 2023-2030 (USD BILLION) 23. TABLE: GERMANY FLOATING OFFSHORE WIND MARKET, BY LOCATION, 2023-2030 (USD BILLION) 24. TABLE: GERMANY FLOATING OFFSHORE WIND MARKET, BY APPLIACTION, 2023-2030 (USD BILLION) 25. TABLE: FRANCE FLOATING OFFSHORE WIND MARKET, 2023-2030 (USD BILLION) 26. TABLE: FRANCE FLOATING OFFSHORE WIND MARKET, BY COMPONENTS, 2023-2030 (USD BILLION) 27. TABLE: FRANCE FLOATING OFFSHORE WIND MARKET, BY LOCATION, 2023-2030 (USD BILLION) 28. TABLE: FRANCE FLOATING OFFSHORE WIND MARKET, BY APPLIACTION, 2023-2030 (USD BILLION) 29. TABLE: CHINA FLOATING OFFSHORE WIND MARKET, 2023-2030 (USD BILLION) 30. TABLE: CHINA FLOATING OFFSHORE WIND MARKET, BY COMPONENTS, 2023-2030 (USD BILLION) 31. TABLE: CHINA FLOATING OFFSHORE WIND MARKET, BY LOCATION, 2023-2030 (USD BILLION) 32. TABLE: CHINA FLOATING OFFSHORE WIND MARKET, BY APPLIACTION, 2023-2030 (USD BILLION) 33. TABLE: SOUTH KOREA FLOATING OFFSHORE WIND MARKET, 2023-2030 (USD BILLION) 34. TABLE: SOUTH KOREA FLOATING OFFSHORE WIND MARKET, BY COMPONENTS, 2023-2030 (USD BILLION) 35. TABLE: SOUTH KOREA FLOATING OFFSHORE WIND MARKET, BY LOCATION, 2023-2030 (USD BILLION) 36. TABLE: SOUTH KOREA FLOATING OFFSHORE WIND MARKET, BY APPLIACTION, 2023-2030 (USD BILLION) 37. TABLE: JAPAN FLOATING OFFSHORE WIND MARKET, 2023-2030 (USD BILLION) 38. TABLE: JAPAN FLOATING OFFSHORE WIND MARKET, BY COMPONENTS, 2023-2030 (USD BILLION) 39. TABLE: JAPAN FLOATING OFFSHORE WIND MARKET, BY LOCATION, 2023-2030 (USD BILLION) 40. TABLE: JAPAN FLOATING OFFSHORE WIND MARKET, BY APPLIACTION, 2023-2030 (USD BILLION) 41. TABLE: INDIA FLOATING OFFSHORE WIND MARKET, 2023-2030 (USD BILLION) 42. TABLE: INDIA FLOATING OFFSHORE WIND MARKET, BY COMPONENTS, 2023-2030 (USD BILLION) 43. TABLE: INDIA FLOATING OFFSHORE WIND MARKET, BY LOCATION, 2023-2030 (USD BILLION) 44. TABLE: INDIA FLOATING OFFSHORE WIND MARKET, BY APPLIACTION, 2023-2030 (USD BILLION) 45. TABLE: BRAZIL FLOATING OFFSHORE WIND MARKET, 2023-2030 (USD BILLION) 46. TABLE: BRAZIL FLOATING OFFSHORE WIND MARKET, BY COMPONENTS, 2023-2030 (USD BILLION) 47. TABLE: BRAZIL FLOATING OFFSHORE WIND MARKET, BY LOCATION, 2023-2030 (USD BILLION) 48. TABLE: BRAZIL FLOATING OFFSHORE WIND MARKET, BY APPLIACTION, 2023-2030 (USD BILLION) 49. TABLE: SOUTH AFRICA FLOATING OFFSHORE WIND MARKET, 2023-2030 (USD BILLION) 50. TABLE: SOUTH AFRICA FLOATING OFFSHORE WIND MARKET, BY COMPONENTS, 2023-2030 (USD BILLION) 51. TABLE: SOUTH AFRICA FLOATING OFFSHORE WIND MARKET, BY LOCATION, 2023-2030 (USD BILLION) 52. TABLE: SOUTH AFRICA FLOATING OFFSHORE WIND MARKET, BY APPLIACTION, 2023-2030 (USD BILLION) 53. TABLE: COMPANY PROFILE: EQUINOR ASA 54. TABLE: COMPANY KEY PRODUCT ANALYSIS: EQUINOR ASA 55. TABLE: COMPANY PROFILE: ORSTED A/S 56. TABLE: COMPANY KEY PRODUCT ANALYSIS: ORSTED A/S 57. TABLE: COMPANY PROFILE: SHELL NEW ENERGIES 58. TABLE: COMPANY KEY PRODUCT ANALYSIS: SHELL NEW ENERGIES 59. TABLE: COMPANY PROFILE: PRINCIPLE POWER INC. 60. TABLE: COMPANY KEY PRODUCT ANALYSIS: PRINCIPLE POWER INC. 61. TABLE: COMPANY PROFILE: IDEOL S.A. 62. TABLE: COMPANY KEY PRODUCT ANALYSIS: IDEOL S.A. 63. TABLE: COMPANY PROFILE: SSE RENEWABLES 64. TABLE: COMPANY KEY PRODUCT ANALYSIS: SSE RENEWABLES 65. TABLE: COMPANY PROFILE: FLOATING POWER PLANT A/S 66. TABLE: COMPANY KEY PRODUCT ANALYSIS: FLOATING POWER PLANT A/S 67. TABLE: COMPANY PROFILE: BLUEFLOAT ENERGY 68. TABLE: COMPANY KEY PRODUCT ANALYSIS: BLUEFLOAT ENERGY LIST OF FIGURES 1. FIGURE: MARKET: RESEARCH METHODOLOGY STEPS 2. FIGURE: RESEARCH DESIGN 3. FIGURE: BREAKDOWN OF PRIMARIES MARKET 4. FIGURE: RESEARCH METHODOLOGY: HYPOTHESIS BUILDING 5. FIGURE: GROWTH STRATEGIES ADOPTED BY THE KEY PLAYERS 6. FIGURE: DATA TRIANGULATION METHODOLOGY 7. FIGURE: GLOBAL DOMINATING MARKET SHARE, BY COMONENTS, 2023 VS. 2030 (USD BILLION) 8. FIGURE: GLOBAL DOMINATING MARKET SHARE, BY LOCATION, 2023 VS. 2030 (USD BILLION) 9. FIGURE: GLOBAL DOMINATING MARKET SHARE, BY APPLICATION, 2023 VS. 2030 (USD BILLION) 10. FIGURE: NORTH AMERICA DOMINATING MARKET SHARE, BY COMONENTS, 2023 VS. 2030 (USD BILLION) 11. FIGURE: NORTH AMERICA DOMINATING MARKET SHARE, BY LOCATION, 2023 VS. 2030 (USD BILLION) 12. FIGURE: NORTH AMERICA DOMINATING MARKET SHARE, BY APPLICATION, 2023 VS. 2030 (USD BILLION) 13. FIGURE: EUROPE DOMINATING MARKET SHARE, BY COMONENTS, 2023 VS. 2030 (USD BILLION) 14. FIGURE: EUROPE DOMINATING MARKET SHARE, BY LOCATION, 2023 VS. 2030 (USD BILLION) 15. FIGURE: EUROPE DOMINATING MARKET SHARE, BY APPLICATION, 2023 VS. 2030 (USD BILLION) 16. FIGURE: APAC DOMINATING MARKET SHARE, BY COMONENTS, 2023 VS. 2030 (USD BILLION) 17. FIGURE: APAC DOMINATING MARKET SHARE, BY LOCATION, 2023 VS. 2030 (USD BILLION) 18. FIGURE: APAC DOMINATING MARKET SHARE, BY APPLICATION, 2023 VS. 2030 (USD BILLION) 19. FIGURE: LAMEA DOMINATING MARKET SHARE, BY COMONENTS, 2023 VS. 2030 (USD BILLION) 20. FIGURE: LAMEA DOMINATING MARKET SHARE, BY LOCATION, 2023 VS. 2030 (USD BILLION) 21. FIGURE: LAMEA DOMINATING MARKET SHARE, BY APPLICATION, 2023 VS. 2030 (USD BILLION) 22. FIGURE: GEOGRAPHICAL SNAPSHOT OF THE MARKET 23. FIGURE: MARKET: DRIVERS, RESTRAINTS, OPPORTUNITIES, AND CHALLENGES 24. FIGURE: COMPETITIVE BENCHMARKING 25. FIGURE: MARKET SHARE ANALYSIS 26. FIGURE: DEMAND BY APPLICATION