Dublin, June 27, 2022 / PRNewswire /-“Catalyst Growth Opportunities to Enable Global Low Carbon Transition” report added to ResearchAndMarkets.com Recruitment.
This survey aims to answer the following questions:
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How important are catalysts for low carbon transitions?
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What are the different types of current and emerging catalytic technologies and their intended uses?
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What are the advantages and limitations of catalysts that affect adoption in low carbon transitions?
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What are the various R & D efforts by industry participants aimed at accelerating the adoption of catalysts in the low carbon transition?
The role of catalysts in the production of renewable energies such as solar energy, green hydrogen, power to X, waste to fuel, etc. is primarily focused on increasing efficiency while reducing heat loss. With solar energy produced through solar panels, catalysts help enhance the energy absorbed and transported across the solar panels. In applications such as carbon / methane conversion and gray and blue hydrogen production, the catalyst optimizes the conversion rate while reducing the production of harmful by-products such as methane and carbon monoxide.
Catalytic technology helps meet the growing demand for clean energy by increasing the efficiency of solar and wind energy. In addition, technological developments focused on making catalysts from recyclable or natural materials and / or making them biodegradable can support sustainability practices in a variety of industries. I can do it.
The use of catalysts in a variety of processes can lower the operating temperature and ultimately reduce energy consumption and provide stability. This reduces the risk of heat loss and harmful by-product emissions in low carbon applications. Over the years, technology developers have focused on providing low-cost, sustainable alternatives within the catalytic processes of technologies such as carbon conversion, hydrogen production, and solar energy to ensure a smooth low carbon transition. I guessed.
There are four types of catalysts: homologous, heterogeneous, mixed, and biocatalyst. The first two catalysts are widely commercialized and are already used in low carbon applications, while the other two catalysts are in the early stages of development and adoption.
Emerging technologies such as nanocatalysts and photocatalysts offer high stability and durability, increase reaction rates, and show the potential to reduce maintenance costs. However, understanding the safety of adopting these catalysts in low carbon applications remains limited.
Studies have shown that doping of metal oxides and rare earth metals can not only increase the durability of certain catalysts, but also increase the active sites of the catalysts due to their porous structure. These doped catalysts have been tested for hydrogen production and utilization. These catalysts also show high stability with the minimum maintenance required to generate hydrogen energy from seawater.
In the carbon / methane conversion process, transition metal-based catalysts have been shown to increase the conversion rate while lowering the operating temperature. For waste-to-fuel applications, photocatalysts are also effective in alkaline solutions.
Main topics to cover:
1 Strategic command
1.1 Why is growth becoming more difficult?Strategic Essentials: Factors that Create Pressure on Growth
1.2 Strategic orders
1.3 Impact of the top three strategic obligations on catalysts that enable low carbon transitions
1.4 Growth Opportunities Fuel Growth Pipeline Engines
1.5 Survey method
2 Growth environment
2.1 Conspicuous low-carbon transition across the region
2.2 The role of catalysts in the smooth transition to low carbon energy
2.3 Financing and investment activities to enable low carbon transition between regions
2.4 Research background
2.5 Important questions answered as survey scope
2.6 Possibility of adopting catalyst technology to promote various low carbon technologies
3 Technology Assessment
3.1 Overview of various catalysts
3.2 Uniform and heterogeneous catalysts widely used in energy and power applications
3.3 Catalysts play an important role in low carbon energy production
3.4 Standards and protocols in catalyst manufacturing and handling
3.5 Factors that influence and limit Catalyst adoption across applications
3.6 Catalyst technology has the potential to optimize hydrogen production
3.7 Metal / Metal Composite Catalysts Provide Sustainable Alternatives to Carbon / Methane Conversion
3.8 Comparative analysis of commercialized catalyst technologies
3.9 Comparative analysis of nanocatalyst technology
3.10 Comparative analysis of biocatalyst technology
3.11 Comparative analysis of photocatalytic technology
3.12 Comparative analysis of heterogeneous homogeneous catalysts
4 Innovation index
4.1 Increased research efforts by academia to develop homogeneous catalysts using nanotechnology
4.2 Academia focused on catalyst development for hydrogen production
4.3 Development of cost-effective high-performance hydrogen production process using various catalysts
4.4 Catalyzed improvement of carbon conversion rate, which is the focus of various research efforts
4.5 Testing on the use of heterogeneous homogeneous catalysts for hydrogen production is underway
4.6 Development of sustainable and environmentally friendly catalysts in line with the principles of the circular economy is being considered.
4.7 North America And Europe lead patent activities
4.8 Possibility of developing high-performance catalyst technology by nanotechnology
4.9 Overall Government Financing Opportunities Europe And APAC
4.10 Financing Opportunities Focused on Catalyst Development
4.11 Collaboration and partnership in Catalyst development
5 companies to act
5.1 Sustainable technologies to reduce carbon emissions
5.2 Creating circular economy materials for various industries using biocatalysts
5.3 Manufacture of green industrial raw materials using catalytic technology
5.4 Strengthening the adoption of catalyst-based low-carbon technology
5.5 Promoting the adoption of cost-effective hydrogen utilization with homogeneous catalysts
5.6 Expanding adoption of homogeneous catalysts for brown hydrogen production
5.7 Increased efficiency of carbon conversion with cost-effective homogeneous catalysts
5.8 Cost-effective and adjustable in the development of green industrial raw materials
5.9 Production of gray hydrogen by efficient catalytic technology
5.10 Improved carbon conversion process with low cost homogeneous catalyst
5.11 Eco-friendly alternatives for clean energy generation
5.12 Improving the efficiency of homogeneous catalysts in the development of high-value chemical syntheses
5.13 Generation of green energy by composite catalyst
5.14 Improvement of carbon conversion technology using heterogeneous catalyst
5.15 Low cost yet highly functional catalyst in hydrogen production process
6 Growth Opportunity Universe
6.1 Growth Opportunities 1: Optimizing Renewable Resources Recruitment with Catalyst Technology
6.2 Growth Opportunities 2: Development of Circular Economy Pathways Using Catalytic Technology for Waste to Fuel Applications
6.3 Growth Opportunities 3: Increasing Adoption of Nanotechnology for Catalyst Development
7 Appendix
For more information on this report, please visit https://www.researchandmarkets.com/r/6mnwgh.
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