The Blockchain in Energy Market size was valued at USD 2.07 billion in 2024 and is expected to reach USD 202.71 billion by 2032 and grow at a CAGR of 77.4% over the forecast period 2025-2032.
The Market Trends is disrupting the traditional energy systems and the ways we produce, trade, and consume energy with its principles of transparency, decentralization, and near-real-time data verification. This technology allows peer-to-peer energy trading, efficient grid management, secure transactions, lower cost, and increased reliability in the system. Infrastructure giants such as IBM, Microsoft, and start-ups such as LO3 Energy are leading innovations and are working with utilities and governments to scale pilot projects around the world.
In 2024, LO3 Energy initiated a pilot project for a blockchain-based microgrid in Brooklyn that allowed residents to sell excess solar power to each other. This decentralized energy economy model utilizes the power of real-time data and smart contracts to make digital, green energy more transparent and the grid more efficient while sparking consumer participation in sustainable energy systems.
The U.S. Blockchain in Energy Market size was USD 0.52 billion in 2024 and is expected to reach USD 44 billion by 2032, growing at a CAGR of 74.15% over the forecast period of 2025–2032.
The U.S. dominates the Blockchain in Energy Market due to its advanced digital infrastructure, strong presence of tech giants, and significant investments in renewable energy and smart grid technologies. Collaborations between energy firms and blockchain innovators, Such as Microsoft and IBM, drive rapid adoption. Government support for energy decentralization and carbon tracking also boosts market growth, positioning the U.S. as a global leader in energy blockchain applications and innovation.
Key Drivers:
Increasing Demand for Decentralized and Transparent Energy Systems Accelerates the Growth of Blockchain in the Energy Market
The Blockchain In Energy Market Growth is increasing focus on cost saving and reaching decentralized energy products, and transparency in energy transactions are also some of the factors that are leading the market. As consumers and businesses increasingly flock towards renewable energy blockchain and smart grids, Blockchain provides a way to improve trust and efficiency in energy trading. It is above all due to the request for a secure, automated, and real-time transaction, especially for peer-to-peer energy markets.
Moreover, blockchain allows for safe tracking of renewable energy credits that promote transparency in carbon and emissions credits. With increasing emphasis on sustainability goals by governments and companies, blockchain can be essential to enabling secure, transparent transactions in the future of energy.
Restraint:
High Implementation Costs and Complexity Limit the Widespread Adoption of Blockchain in the Energy Sector
High costs of implementation, as well as the technology complexity of blockchain solutions, are key barriers to mass adoption in the energy industry. Blockchain energy industry systems need infrastructure, robust protection, and a large outlay on technology and the training of those who use it. Most utilities and energy companies are hesitant to spend money on blockchain and are unsure what the return will be for the investment.
Opportunity:
Growing Focus on Renewable Energy and Sustainability Creates Opportunities for Blockchain to Revolutionize Energy Trading and Tracking
The increasing shift towards renewable energy consumption and the emphasis on sustainability provide a vast opportunity for blockchain to redesign the energy trading and tracking mechanisms. As the solution to the world’s clean-energy transition, blockchain presents the trade of renewable energy credits, carbon emissions, and distributed energy resources management in an efficient, secure, and transparent way.
For instance, companies such as WePower are already leveraging blockchain to enable the direct trading of renewable energy, allowing energy producers and consumers to exchange energy in a decentralized manner.
Challenge:
Regulatory Uncertainty and Lack of Standardization Hinder Blockchain’s Full Potential in the Energy Market
Lack of regulatory certainty and absence of standardized architecture for blockchain applications that concentrate on energy is one of the critical issues that the Blockchain in Energy Market analysis faces the lack of well-defined international regulatory standards for the use of blockchain in the energy market is hindering the development of the technology. For example, some regions are more receptive to applications of blockchain in energy markets, while others are still undecided about their legal status.
By Type
The Public segment dominated the market, with a share of 59% in 2024, due to its open-access feature, enabling transparency and trust among different participants in decentralized energy systems. Projects such as Power Ledger in Australia and the Brooklyn Microgrid, operated by LO3 Energy, use public blockchains to enable peer-to-peer trading of energy and provide access to the grid. Another factor driving the market is that the openness of public blockchain is in tune with energy democratization.
The Private segment is expected to grow at the highest CAGR of 80.7% during the forecast period, as utilities and enterprises are focusing on data security, regulatory compliance, and high-speed transactions. IBMs and SAPs have both announced private blockchain networks that allow for data to be shared and trades to be automatically executed in the energy sector.
By End-Use
The Power segment held a major share in the Blockchain in Energy Market in 2024, due to an increase in smart grid deployments and capacity addition of renewable power generation. Notable blockchain solutions for PPAs and energy tokenisation have been developed by key players such as WePower and Electrify. They help to make settlements faster and more transparent, making blockchain consistent with global power sector modernization objectives.
The Oil & Gas segment is estimated to grow at the highest CAGR of 82.07% from 2025 to 2032, owing to the demand to increase transparency, traceability, and veracity of the supply chain. Firms such as Accenture and IBM are developing blockchain technology for tracking oil shipments and managing complex contracts.
By Application
P2P was the largest segment, holding a 33% revenue share in 2024 on account of decentralized energy models that enable energy consumers to be energy producers. Power Ledger and LO3 Energy are blockchain companies that make neighborhood energy sharing possible, which decreases reliance on central utilities. This notion of democratizing energy trade propelled the Blockchain in the Energy Market quite ahead.
The Grid Transactions segment is projected to be the fastest-growing market, at a CAGR of 82.1%, from 2025 to 2023, due to the requirement for automated and real-time settlements of energy in upgraded grids. Microsoft and Siemens bring blockchain to smart grid management and energy trading. These developments enhance grid capacity and stability, marking an evolution of the blockchain’s role in modernizing our energy systems.
North America in the Blockchain in Energy Market share in 2024, with a market share of over 37%, North America emerged as the leading consumer of blockchain in energy, attributed to decentralized energy solutions and next-generation digital infrastructure. The U.S. is ahead in the region thanks to proactive clean energy mandates, big investments from tech firms such as IBM and Microsoft, and strong pilot projects for peer-to-peer energy trading and carbon tracking systems.
The Asia Pacific region is projected to be the fastest-growing market in the Market between 2025 and 2032, with 80.8% of CAGR during the forecast period. China dominates the Blockchain in Energy Market, driven by its massive energy demand, rapid digital transformation, and strong government support for blockchain adoption. China is heavily investing in smart grid infrastructure and renewable energy, where blockchain enhances efficiency and transparency. A State Grid Corporation of China, which in 2024 partnered with tech firms to launch blockchain-based energy trading platforms, improving grid management and enabling real-time, decentralized transactions across provinces.
Europe continued to hold a high market share in the Blockchain in Energy Market in 2024, due to the EU's focus on renewable incorporation, emission reduction, and energy transparency. Germany dominates the Blockchain in the Energy Market due to its advanced renewable energy infrastructure and early adoption of digital technologies in the energy sector. Germany's strong focus on decentralization and its energy transition policy has fueled blockchain experimentation in peer-to-peer energy trading and grid optimization.
The Middle East & Africa and Latin America are showing steady growth in the Blockchain in Energy Market due prevalence of demand for energy transparency, integration of renewable energy, and infrastructure upgradation till 2024. These areas are using blockchain to optimize and secure energy transactions so that grid inefficiencies can be minimized.
The major players operating in the market are BigchainDB GmbH, LO3 Energy, Inc., Deloitte Touche Tohmatsu Limited, Microsoft Corporation, IBM Corporation, WePower UAB, Accenture plc, Oracle Corporation, SAP SE, and Infosys Limited.
In January 2024, LO3 Energy initiated a pilot microgrid project utilizing blockchain for energy distribution. This project aims to enhance local energy trading and grid efficiency, reflecting LO3 Energy's continued commitment to integrating blockchain solutions in the energy sector.
In May 2023, Deloitte joined a consortium of financial and technology firms to launch the Canton Network, a blockchain network designed for secure, interoperable, and privacy-preserving transactions. While primarily focused on financial markets, the network's capabilities have implications for energy trading and resource management, indicating Deloitte's strategic interest in applying blockchain across various sectors, including energy.
| Report Attributes | Details |
|---|---|
| Market Size in 2024 | USD 2.07 Billion |
| Market Size by 2032 | USD 202.71 Billion |
| CAGR | CAGR of 77.4% From 2025 to 2032 |
| Base Year | 2024 |
| Forecast Period | 2025-2032 |
| Historical Data | 2021-2023 |
| Report Scope & Coverage | Market Size, Segments Analysis, Competitive Landscape, Regional Analysis, DROC & SWOT Analysis, Forecast Outlook |
| Key Segments | • By Type (Private, Public) • By Application (Sustainability Attribution, Electric Vehicle, Energy Financing, Grid Transactions, Peer-To-Peer Transaction, Others) • By End-Use (Power, Oil & Gas) |
| Regional Analysis/Coverage | North America (US, Canada, Mexico), Europe (Germany, France, UK, Italy, Spain, Poland, Turkey, Rest of Europe), Asia Pacific (China, India, Japan, South Korea, Singapore, Australia, Rest of Asia Pacific), Middle East & Africa (UAE, Saudi Arabia, Qatar, South Africa, Rest of Middle East & Africa), Latin America (Brazil, Argentina, Rest of Latin America) |
| Company Profiles | BigchainDB GmbH, LO3 Energy, Inc., Deloitte Touche Tohmatsu Limited, Microsoft Corporation, IBM Corporation, WePower UAB, Accenture plc, Oracle Corporation, SAP SE, Infosys Limited. |
Ans: The Blockchain in Energy Market is expected to grow at a CAGR of 77.4% during 2025 to 2032.
Ans: The Blockchain in Energy Market size was USD 2.07 billion in 2024 and is expected to reach USD 202.71 billion by 2032.
Ans: The major growth factor of the Blockchain in the Energy Market is the rising demand for decentralized energy systems and transparent, secure energy transactions.
Ans: The Peer-To-Peer Transaction dominated the Blockchain in Energy Market.
Ans: North America dominated the Blockchain in Energy Market in 2024.
Table of Contents
1. Introduction
1.1 Market Definition
1.2 Scope (Inclusion and Exclusions)
1.3 Research Assumptions
2. Executive Summary
2.1 Market Overview
2.2 Regional Synopsis
2.3 Competitive Summary
3. Research Methodology
3.1 Top-Down Approach
3.2 Bottom-up Approach
3.3. Data Validation
3.4 Primary Interviews
4. Market Dynamics Impact Analysis
4.1 Market Driving Factors Analysis
4.1.1 Drivers
4.1.2 Restraints
4.1.3 Opportunities
4.1.4 Challenges
4.2 PESTLE Analysis
4.3 Porter’s Five Forces Model
5. Statistical Insights and Trends Reporting
5.1 Blockchain-Enabled Grid Stability Index
5.2 Decentralized Energy Trading Participation Rate
5.3 Average Cost Reduction Per Transaction
5.4 Disaster Response Acceleration Score
6. Competitive Landscape
6.1 List of Major Companies, By Region
6.2 Market Share Analysis, By Region
6.3 Product Benchmarking
6.3.1 Product specifications and features
6.3.2 Pricing
6.4 Strategic Initiatives
6.4.1 Marketing and promotional activities
6.4.2 Distribution and Supply Chain Strategies
6.4.3 Expansion plans and new Product launches
6.4.4 Strategic partnerships and collaborations
6.5 Technological Advancements
6.6 Market Positioning and Branding
7. Blockchain In Energy Market Segmentation by Type
7.1 Chapter Overview
7.2 Private
7.2.1 Private Market Trends Analysis (2021-2032)
7.2.2 Private Market Size Estimates and Forecasts to 2032 (USD Billion)
7.3 Public
7.3.1 Public Market Trends Analysis (2021-2032)
7.3.2 Public Market Size Estimates and Forecasts to 2032 (USD Billion)
8. Blockchain In Energy Market Segmentation by Application
8.1 Chapter Overview
8.2 Sustainability Attribution
8.2.1 Sustainability Attribution Market Trend Analysis (2021-2032)
8.2.2 Sustainability Attribution Market Size Estimates and Forecasts to 2032 (USD Billion)
8.3 Electric Vehicle
8.3.1 Electric Vehicle Market Trends Analysis (2021-2032)
8.3.2 Electric Vehicle Market Size Estimates and Forecasts to 2032 (USD Billion)
8.4 Energy Financing
8.4.1 Energy Financing Market Trends Analysis (2021-2032)
8.4.2 Energy Financing Market Size Estimates and Forecasts to 2032 (USD Billion)
8.5 Grid Transactions
8.5.1 Grid Transactions Market Trends Analysis (2021-2032)
8.5.2 Grid Transactions Market Size Estimates and Forecasts to 2032 (USD Billion)
8.6 Peer-To-Peer Transaction
8.6.1 Peer-To-Peer Transaction Market Trends Analysis (2021-2032)
8.6.2 Peer-To-Peer Transaction Market Size Estimates and Forecasts to 2032 (USD Billion)
8.7 Others
8.7.1 Others Market Trends Analysis (2021-2032)
8.7.2 Others Market Size Estimates and Forecasts to 2032 (USD Billion)
9. Blockchain In Energy Market Segmentation by End-Use
9.1 Chapter Overview
9.2 Power
9.2.1 Power Market Trends Analysis (2021-2032)
9.2.2 Power Market Size Estimates and Forecasts to 2032 (USD Billion)
9.3 Oil & Gas
9.3.1 Oil & Gas Market Trends Analysis (2021-2032)
9.3.2 Oil & Gas Market Size Estimates and Forecasts to 2032 (USD Billion)
10. Regional Analysis
10.1 Chapter Overview
10.2 North America
10.2.1 Trends Analysis
10.2.2 North America Blockchain In Energy Market Estimates and Forecasts, by Country (2021-2032) (USD Billion)
10.2.3 North America Blockchain In Energy Market Estimates and Forecasts, by Type (2021-2032) (USD Billion)
10.2.4 North America Blockchain In Energy Market Estimates and Forecasts, by Application (2021-2032) (USD Billion)
10.2.5 North America Blockchain In Energy Market Estimates and Forecasts, by End-Use (2021-2032) (USD Billion)
10.2.6 USA
10.2.6.1 USA Blockchain In Energy Market Estimates and Forecasts, by Type (2021-2032) (USD Billion)
10.2.6.2 USA Blockchain In Energy Market Estimates and Forecasts, by Application (2021-2032) (USD Billion)
10.2.6.3 USA Blockchain In Energy Market Estimates and Forecasts, by End-Use (2021-2032) (USD Billion)
10.2.7 Canada
10.2.7.1 Canada Blockchain In Energy Market Estimates and Forecasts, by Type (2021-2032) (USD Billion)
10.2.7.2 Canada Blockchain In Energy Market Estimates and Forecasts, by Application (2021-2032) (USD Billion)
10.2.7.3 Canada Blockchain In Energy Market Estimates and Forecasts, by End-Use (2021-2032) (USD Billion)
10.2.8 Mexico
10.2.8.1 Mexico Blockchain In Energy Market Estimates and Forecasts, by Type (2021-2032) (USD Billion)
10.2.8.2 Mexico Blockchain In Energy Market Estimates and Forecasts, by Application (2021-2032) (USD Billion)
10.2.8.3 Mexico Blockchain In Energy Market Estimates and Forecasts, by End-Use (2021-2032) (USD Billion)
10.3 Europe
10.3.1 Trends Analysis
10.3.2 Europe Blockchain In Energy Market Estimates and Forecasts, by Country (2021-2032) (USD Billion)
10.3.3 Europe Blockchain In Energy Market Estimates and Forecasts, by Type (2021-2032) (USD Billion)
10.3.4 Europe Blockchain In Energy Market Estimates and Forecasts, by Application (2021-2032) (USD Billion)
10.3.5 Europe Blockchain In Energy Market Estimates and Forecasts, by End-Use (2021-2032) (USD Billion)
10.3.6 Germany
10.3.6.1 Germany Blockchain In Energy Market Estimates and Forecasts, by Type (2021-2032) (USD Billion)
10.3.6.2 Germany Blockchain In Energy Market Estimates and Forecasts, by Application (2021-2032) (USD Billion)
10.3.6.3 Germany Blockchain In Energy Market Estimates and Forecasts, by End-Use (2021-2032) (USD Billion)
10.3.7 France
10.3.7.1 France Blockchain In Energy Market Estimates and Forecasts, by Type (2021-2032) (USD Billion)
10.3.7.2 France Blockchain In Energy Market Estimates and Forecasts, by Application (2021-2032) (USD Billion)
10.3.7.3 France Blockchain In Energy Market Estimates and Forecasts, by End-Use (2021-2032) (USD Billion)
10.3.8 UK
10.3.8.1 UK Blockchain In Energy Market Estimates and Forecasts, by Type (2021-2032) (USD Billion)
10.3.8.2 UK Blockchain In Energy Market Estimates and Forecasts, by Application (2021-2032) (USD Billion)
10.3.8.3 UK Blockchain In Energy Market Estimates and Forecasts, by End-Use (2021-2032) (USD Billion)
10.3.9 Italy
10.3.9.1 Italy Blockchain In Energy Market Estimates and Forecasts, by Type (2021-2032) (USD Billion)
10.3.9.2 Italy Blockchain In Energy Market Estimates and Forecasts, by Application (2021-2032) (USD Billion)
10.3.9.3 Italy Blockchain In Energy Market Estimates and Forecasts, by End-Use (2021-2032) (USD Billion)
10.3.10 Spain
10.3.10.1 Spain Blockchain In Energy Market Estimates and Forecasts, by Type (2021-2032) (USD Billion)
10.3.10.2 Spain Blockchain In Energy Market Estimates and Forecasts, by Application (2021-2032) (USD Billion)
10.3.10.3 Spain Blockchain In Energy Market Estimates and Forecasts, by End-Use (2021-2032) (USD Billion)
10.3.11 Poland
10.3.11.1 Poland Blockchain In Energy Market Estimates and Forecasts, by Type (2021-2032) (USD Billion)
10.3.11.2 Poland Blockchain In Energy Market Estimates and Forecasts, by Application (2021-2032) (USD Billion)
10.3.11.3 Poland Blockchain In Energy Market Estimates and Forecasts, by End-Use (2021-2032) (USD Billion)
10.3.12 Turkey
10.3.12.1 Turkey Blockchain In Energy Market Estimates and Forecasts, by Type (2021-2032) (USD Billion)
10.3.12.2 Turkey Blockchain In Energy Market Estimates and Forecasts, by Application (2021-2032) (USD Billion)
10.3.12.3 Turkey Blockchain In Energy Market Estimates and Forecasts, by End-Use (2021-2032) (USD Billion)
10.3.13 Rest of Europe
10.3.13.1 Rest of Europe Blockchain In Energy Market Estimates and Forecasts, by Type (2021-2032) (USD Billion)
10.3.13.2 Rest of Europe Blockchain In Energy Market Estimates and Forecasts, by Application (2021-2032) (USD Billion)
10.3.13.3 Rest of Europe Blockchain In Energy Market Estimates and Forecasts, by End-Use (2021-2032) (USD Billion)
10.4 Asia Pacific
10.4.1 Trends Analysis
10.4.2 Asia Pacific Blockchain In Energy Market Estimates and Forecasts, by Country (2021-2032) (USD Billion)
10.4.3 Asia Pacific Blockchain In Energy Market Estimates and Forecasts, by Type (2021-2032) (USD Billion)
10.4.4 Asia Pacific Blockchain In Energy Market Estimates and Forecasts, by Application (2021-2032) (USD Billion)
10.4.5 Asia Pacific Blockchain In Energy Market Estimates and Forecasts, by End-Use (2021-2032) (USD Billion)
10.4.6 China
10.4.6.1 China Blockchain In Energy Market Estimates and Forecasts, by Type (2021-2032) (USD Billion)
10.4.6.2 China Blockchain In Energy Market Estimates and Forecasts, by Application (2021-2032) (USD Billion)
10.4.6.3 China Blockchain In Energy Market Estimates and Forecasts, by End-Use (2021-2032) (USD Billion)
10.4.7 India
10.4.7.1 India Blockchain In Energy Market Estimates and Forecasts, by Type (2021-2032) (USD Billion)
10.4.7.2 India Blockchain In Energy Market Estimates and Forecasts, by Application (2021-2032) (USD Billion)
10.4.7.3 India Blockchain In Energy Market Estimates and Forecasts, by End-Use (2021-2032) (USD Billion)
10.4.8 Japan
10.4.8.1 Japan Blockchain In Energy Market Estimates and Forecasts, by Type (2021-2032) (USD Billion)
10.4.8.2 Japan Blockchain In Energy Market Estimates and Forecasts, by Application (2021-2032) (USD Billion)
10.4.8.3 Japan Blockchain In Energy Market Estimates and Forecasts, by End-Use (2021-2032) (USD Billion)
10.4.9 South Korea
10.4.9.1 South Korea Blockchain In Energy Market Estimates and Forecasts, by Type (2021-2032) (USD Billion)
10.4.9.2 South Korea Blockchain In Energy Market Estimates and Forecasts, by Application (2021-2032) (USD Billion)
10.4.9.3 South Korea Blockchain In Energy Market Estimates and Forecasts, by End-Use (2021-2032) (USD Billion)
10.4.10 Singapore
10.4.10.1 Singapore Blockchain In Energy Market Estimates and Forecasts, by Type (2021-2032) (USD Billion)
10.4.10.2 Singapore Blockchain In Energy Market Estimates and Forecasts, by Application (2021-2032) (USD Billion)
10.4.10.3 Singapore Blockchain In Energy Market Estimates and Forecasts, by End-Use (2021-2032) (USD Billion)
10.4.11 Australia
10.4.11.1 Australia Blockchain In Energy Market Estimates and Forecasts, by Type (2021-2032) (USD Billion)
10.4.11.2 Australia Blockchain In Energy Market Estimates and Forecasts, by Application (2021-2032) (USD Billion)
10.4.11.3 Australia Blockchain In Energy Market Estimates and Forecasts, by End-Use (2021-2032) (USD Billion)
10.4.12 Vietnam
10.4.12.1 Vietnam Blockchain In Energy Market Estimates and Forecasts, by Type (2021-2032) (USD Billion)
10.4.12.2 Vietnam Blockchain In Energy Market Estimates and Forecasts, by Application (2021-2032) (USD Billion)
10.4.12.3 Vietnam Blockchain In Energy Market Estimates and Forecasts, by End-Use (2021-2032) (USD Billion)
10.4.13 Rest of Asia Pacific
10.4.13.1 Rest of Asia Pacific Blockchain In Energy Market Estimates and Forecasts, by Type (2021-2032) (USD Billion)
10.4.13.2 Rest of Asia Pacific Blockchain In Energy Market Estimates and Forecasts, by Application (2021-2032) (USD Billion)
10.4.13.3 Rest of Asia Pacific Blockchain In Energy Market Estimates and Forecasts, by End-Use (2021-2032) (USD Billion)
10.5 Middle East and Africa
10.5.1 Trends Analysis
10.5.2 Middle East and Africa Blockchain In Energy Market Estimates and Forecasts, by Country (2021-2032) (USD Billion)
10.5.3 Middle East and Africa Blockchain In Energy Market Estimates and Forecasts, by Type (2021-2032) (USD Billion)
10.5.4 Middle East and Africa Blockchain In Energy Market Estimates and Forecasts, by Application (2021-2032) (USD Billion)
10.5.5 Middle East and Africa Blockchain In Energy Market Estimates and Forecasts, by End-Use (2021-2032) (USD Billion)
10.5.6 UAE
10.5.6.1 UAE Blockchain In Energy Market Estimates and Forecasts, by Type (2021-2032) (USD Billion)
10.5.6.2 UAE Blockchain In Energy Market Estimates and Forecasts, by Application (2021-2032) (USD Billion)
10.5.6.3 UAE Blockchain In Energy Market Estimates and Forecasts, by End-Use (2021-2032) (USD Billion)
10.5.7 Saudi Arabia
10.5.7.1 Saudi Arabia Blockchain In Energy Market Estimates and Forecasts, by Type (2021-2032) (USD Billion)
10.5.7.2 Saudi Arabia Blockchain In Energy Market Estimates and Forecasts, by Application (2021-2032) (USD Billion)
10.5.7.3 Saudi Arabia Blockchain In Energy Market Estimates and Forecasts, by End-Use (2021-2032) (USD Billion)
10.5.8 Qatar
10.5.8.1 Qatar Blockchain In Energy Market Estimates and Forecasts, by Type (2021-2032) (USD Billion)
10.5.8.2 Qatar Blockchain In Energy Market Estimates and Forecasts, by Application (2021-2032) (USD Billion)
10.5.8.3 Qatar Blockchain In Energy Market Estimates and Forecasts, by End-Use (2021-2032) (USD Billion)
10.5.9 South Africa
10.5.9.1 South Africa Blockchain In Energy Market Estimates and Forecasts, by Type (2021-2032) (USD Billion)
10.5.9.2 South Africa Blockchain In Energy Market Estimates and Forecasts by Application (2021-2032) (USD Billion)
10.5.9.3 South Africa Blockchain In Energy Market Estimates and Forecasts, by End-Use (2021-2032) (USD Billion)
10.5.10 Rest of Middle East & Africa
10.5.10.1 Rest of Middle East & Africa Blockchain In Energy Market Estimates and Forecasts, by Type (2021-2032) (USD Billion)
10.5.10.2 Rest of Middle East & Africa Blockchain In Energy Market Estimates and Forecasts, by Application (2021-2032) (USD Billion)
10.5.10.3 Rest of Middle East & Africa Blockchain In Energy Market Estimates and Forecasts, by End-Use (2021-2032) (USD Billion)
10.6 Latin America
10.6.1 Trends Analysis
10.6.2 Latin America Blockchain In Energy Market Estimates and Forecasts, by Country (2021-2032) (USD Billion)
10.6.3 Latin America Blockchain In Energy Market Estimates and Forecasts, by Type (2021-2032) (USD Billion)
10.6.4 Latin America Blockchain In Energy Market Estimates and Forecasts, by Application (2021-2032) (USD Billion)
10.6.5 Latin America Blockchain In Energy Market Estimates and Forecasts, by End-Use (2021-2032) (USD Billion)
10.6.6 Brazil
10.6.6.1 Brazil Blockchain In Energy Market Estimates and Forecasts, by Type (2021-2032) (USD Billion)
10.6.6.2 Brazil Blockchain In Energy Market Estimates and Forecasts, by Application (2021-2032) (USD Billion)
10.6.6.3 Brazil Blockchain In Energy Market Estimates and Forecasts, by End-Use (2021-2032) (USD Billion)
10.6.7 Argentina
10.6.7.1 Argentina Blockchain In Energy Market Estimates and Forecasts, by Type (2021-2032) (USD Billion)
10.6.7.2 Argentina Blockchain In Energy Market Estimates and Forecasts, by Application (2021-2032) (USD Billion)
10.6.7.3 Argentina Blockchain In Energy Market Estimates and Forecasts, by End-Use (2021-2032) (USD Billion)
10.6.8 Rest of Latin America
10.6.8.1 Rest of Latin America Blockchain In Energy Market Estimates and Forecasts, by Type (2021-2032) (USD Billion)
10.6.8.2 Rest of Latin America Blockchain In Energy Market Estimates and Forecasts, by Application (2021-2032) (USD Billion)
10.6.8.3 Rest of Latin America Blockchain In Energy Market Estimates and Forecasts, by End-Use (2021-2032) (USD Billion)
11. Company Profiles
11.1 BigchainDB GmbH
11.1.1 Company Overview
11.1.2 Financial
11.1.3 Product/ Services Offered
11.1.4 SWOT Analysis
11.2 LO3 Energy Inc.
11.2.1 Company Overview
11.2.2 Financial
11.2.3 Product/ Services Offered
11.2.4 SWOT Analysis
11.3 Deloitte Touche Tohmatsu Limited
11.3.1 Company Overview
11.3.2 Financial
11.3.3 Product/ Services Offered
11.3.4 SWOT Analysis
11.4 Microsoft Corporation
11.4.1 Company Overview
11.4.2 Financial
11.4.3 Product/ Services Offered
11.4.4 SWOT Analysis
11.5 IBM Corporation
11.5.1 Company Overview
11.5.2 Financial
11.5.3 Product/ Services Offered
11.5.4 SWOT Analysis
11.6 WePower UAB
11.6.1 Company Overview
11.6.2 Financial
11.6.3 Product/ Services Offered
11.6.4 SWOT Analysis
11.7 Accenture plc
11.7.1 Company Overview
11.7.2 Financial
11.7.3 Product/ Services Offered
11.7.4 SWOT Analysis
11.8 Oracle Corporation
11.8.1 Company Overview
11.8.2 Financial
11.8.3 Product/ Services Offered
11.8.4 SWOT Analysis
11.9 SAP SE
11.9.1 Company Overview
11.9.2 Financial
11.9.3 Product/ Services Offered
11.9.4 SWOT Analysis
11.10 Infosys Limited
11.10.1 Company Overview
11.10.2 Financial
11.10.3 Product/ Services Offered
11.10.4 SWOT Analysis
12. Use Cases and Best Practices
13. Conclusion.
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When we talk about primary research, it is a type of study in which the researchers collect relevant data samples directly, rather than relying on previously collected data. This type of research is focused on gaining content specific facts that can be sued to solve specific problems. Since the collected data is fresh and first hand therefore it makes the study more accurate and genuine.
We at SNS Insider have divided Primary Research into 2 parts.
Part 1 wherein we interview the KOLs of major players as well as the upcoming ones across various geographic regions. This allows us to have their view over the market scenario and acts as an important tool to come closer to the accurate market numbers. As many as 45 paid and unpaid primary interviews are taken from both the demand and supply side of the industry to make sure we land at an accurate judgement and analysis of the market.
This step involves the triangulation of data wherein our team analyses the interview transcripts, online survey responses and observation of on filed participants. The below mentioned chart should give a better understanding of the part 1 of the primary interview.
Part 2: In this part of primary research the data collected via secondary research and the part 1 of the primary research is validated with the interviews from individual consultants and subject matter experts.
Consultants are those set of people who have at least 12 years of experience and expertise within the industry whereas Subject Matter Experts are those with at least 15 years of experience behind their back within the same space. The data with the help of two main processes i.e., FGDs (Focused Group Discussions) and IDs (Individual Discussions). This gives us a 3rd party nonbiased primary view of the market scenario making it a more dependable one while collation of the data pointers.
Step 3: Data Bank Validation
Once all the information is collected via primary and secondary sources, we run that information for data validation. At our intelligence centre our research heads track a lot of information related to the market which includes the quarterly reports, the daily stock prices, and other relevant information. Our data bank server gets updated every fortnight and that is how the information which we collected using our primary and secondary information is revalidated in real time.
Step 4: QA/QC Process
After all the data collection and validation our team does a final level of quality check and quality assurance to get rid of any unwanted or undesired mistakes. This might include but not limited to getting rid of the any typos, duplication of numbers or missing of any important information. The people involved in this process include technical content writers, research heads and graphics people. Once this process is completed the title gets uploader on our platform for our clients to read it.
Step 5: Final QC/QA Process:
This is the last process and comes when the client has ordered the study. In this process a final QA/QC is done before the study is emailed to the client. Since we believe in giving our clients a good experience of our research studies, therefore, to make sure that we do not lack at our end in any way humanly possible we do a final round of quality check and then dispatch the study to the client.
Key Segments:
By Type
Private
Public
By Application
Sustainability Attribution
Electric Vehicle
Energy Financing
Grid Transactions
Peer-To-Peer Transaction
Others
By End-Use
Power
Oil & Gas
Request for Segment Customization as per your Business Requirement: Segment Customization Request
Regional Coverage:
North America
US
Canada
Mexico
Europe
Germany
France
UK
Italy
Spain
Poland
Turkey
Rest of Europe
Asia Pacific
China
India
Japan
South Korea
Singapore
Australia
Rest of Asia Pacific
Middle East & Africa
UAE
Saudi Arabia
Qatar
South Africa
Rest of Middle East & Africa
Latin America
Brazil
Argentina
Rest of Latin America
Request for Country Level Research Report: Country Level Customization Request
Available Customization
With the given market data, SNS Insider offers customization as per the company’s specific needs. The following customization options are available for the report:
Detailed Volume Analysis
Criss-Cross segment analysis (e.g. Product X Application)
Competitive Product Benchmarking
Geographic Analysis
Additional countries in any of the regions
Customized Data Representation
Detailed analysis and profiling of additional market players
