Advanced Catalysis in Hydrogen Production from Formic Acid and Methanol
Advanced Catalysis in Hydrogen Production from Formic Acid and Methanol
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Advanced Catalysis in Hydrogen Production from Formic Acid and Methanol
Advanced Catalysis in Hydrogen Production from Formic Acid and Methanol
The nature of the catalyst's support plays an important role for the reaction.
Advanced Catalysis in Hydrogen Production from Formic Acid and Methanol
Numéro d'article: 170196962

Advanced Catalysis in Hydrogen Production from Formic Acid and Methanol

Numéro d'article: 170196962

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XAF 40442

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Ce qui se démarque

Innovative Catalytic Methods
This book explores cutting-edge catalytic techniques for efficient hydrogen generation, addressing sustainable energy needs with advanced approaches using formic acid and methanol.
Expert Author Insights
Authored by leading experts in the field, the text provides in-depth knowledge and unique perspectives that enhance understanding of complex catalytic processes for researchers and professionals.
Comprehensive Research Coverage
Covering a wide array of experiments and findings, this resource serves as a complete guide for both academic study and practical application in hydrogen production technologies.

Détails du produit

Shop Advanced Catalysis in Hydrogen Production from Formic Acid and Methanol online at a best price in Gabon. 3039363808
  • This Special Issue is related to studies of the hydrogen production from formic acid decomposition. It is based on five research papers and two reviews. The reviews discuss the liquid phase formic acid decomposition over bimetallic (PdAg), molecular (Ru, Ir, Fe, Co), and heterogenized molecular catalysts. The gas-phase reaction is studied over highly dispersed Pd, Pt, Au, Cu, and Ni supported catalysts. It is shown that the nature of the catalyst's support plays an important role for the reaction. Thus, N-doping of the carbon support provides a significant promotional effect. One of the reasons for the high activity of the N-doped catalysts is the formation of single-atom active sites stabilized by pyridinic N species present in the support. It is demonstrated that carbon materials can be N-doped in different ways. It can be performed either directly from N-containing compounds during the carbon synthesis or by a post-synthetic deposition of N-containing compounds on the carbon support with known properties. The Issue could be useful for specialists in catalysis and nanomaterials as well as for graduate students studying chemistry and chemical engineering. The reported results can be applied for development of catalysts for the hydrogen production from different liquid organic hydrogen carriers.
Publisher Mdpi AG
Publication date June 18, 2020
Language English
Print length 122 pages
ISBN-10 3039363808
ISBN-13 978-3039363803
Item Weight 1.03 pounds (470 grams)
Dimensions 6.69 x 0.5 x 9.61 inches (17 x 1.3 x 24.4 cm)

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À qui est-ce destiné ?

Suitable For
  • Academic Researchers

    Ideal for researchers seeking detailed insights into advanced catalysis for hydrogen production from formic acid and methanol.

  • Energy Engineers

    Beneficial for engineers working on sustainable energy solutions and hydrogen production technologies.

  • Graduate Students

    Great resource for graduate students studying catalysis, energy conversion, or related fields, providing thorough academic content.

Not Suitable For
  • Casual Readers

    Not suitable for casual readers looking for light reading material, as it covers complex scientific topics.

  • General Public

    Not ideal for those without a background in chemistry or catalysis, as it delves deeply into technical details.

  • Commercial Practitioners

    May not meet needs of practitioners seeking commercial applications, focusing more on academic and theoretical frameworks.

DESCRIPTION DU PRODUIT

Vous avez une question ? Chattez avec nous

Questions et réponses des clients

  • question: What is advanced catalysis in hydrogen production?

    répondre: Advanced catalysis in hydrogen production refers to innovative processes that enhance the efficiency of generating hydrogen from various sources, specifically formic acid and methanol. By utilizing advanced catalysts, these processes lower energy requirements and increase reaction rates. This technology is crucial in developing sustainable hydrogen solutions, which can reduce dependency on fossil fuels. For example, industries aiming to transition towards greener energy will find this method particularly beneficial as a viable means of producing clean hydrogen fuel.
  • question: What role do formic acid and methanol play in hydrogen production?

    répondre: Formic acid and methanol serve as effective hydrogen carriers in the process of hydrogen production. When heated or in the presence of a catalyst, they decompose to release hydrogen gas. Their utilization not only offers a practical method to store and transport hydrogen but also contributes to carbon-neutral fuel production. This is particularly advantageous in sectors such as automotive and energy, where reliable hydrogen fuel sources are essential for sustainability efforts.
  • question: What are the benefits of using advanced catalysis for hydrogen production?

    répondre: The benefits of using advanced catalysis for hydrogen production from formic acid and methanol include improved efficiency, reduced energy consumption, and enhanced reaction rates. Catalysts facilitate chemical reactions without being consumed, making the process more cost-effective over time. This technology is particularly advantageous for industries looking to integrate cleaner hydrogen sources into their energy mix, leading to reduced emissions and contributing to a lower carbon footprint.
  • question: How does advanced catalysis compare to traditional hydrogen production methods?

    répondre: Advanced catalysis offers significant advantages over traditional hydrogen production methods, such as steam methane reforming, which relies on fossil fuels. While traditional methods can be energy-intensive and may emit greenhouse gases, advanced catalysis can utilize renewable resources and operate more efficiently. This leads to a cleaner and more sustainable hydrogen production process, making it more attractive for industries aiming to comply with environmental regulations and enhance their green credentials.
  • question: What are some applications of hydrogen produced from formic acid and methanol?

    répondre: Hydrogen produced from formic acid and methanol has a wide range of applications. It can be used as a clean fuel for fuel cells, powering vehicles with zero emissions. Additionally, it serves as an energy carrier in renewable energy systems, where it stores energy generated from sources like solar and wind. Industries involved in chemical synthesis can also use this hydrogen for various reactions, illustrating its versatility in both energy and industrial applications.
  • question: Can advanced catalysis contribute to energy storage solutions?

    répondre: Yes, advanced catalysis plays a vital role in developing energy storage solutions. By efficiently producing hydrogen from formic acid and methanol, it allows for the conversion of renewable energy into storable fuel. This capability is crucial for addressing the intermittent nature of renewable energy sources, providing a means to store excess energy that can be utilized later. Consequently, industries can better manage energy supplies and enhance grid reliability, contributing to a more sustainable energy future.
  • question: What innovations are driving research in this catalysis field?

    répondre: Research in advanced catalysis for hydrogen production is driven by innovations in materials science and nanotechnology. New catalyst formulations, including metal-organic frameworks (MOFs) and nanostructured materials, are being explored to enhance catalytic performance. These advancements enable more efficient reactions, making the process more viable for commercial applications. As research progresses, these innovations could lead to breakthroughs that further reduce costs and improve the sustainability of hydrogen production.
  • question: How can industries benefit from adopting advanced catalysis technologies?

    répondre: Industries can benefit significantly from adopting advanced catalysis technologies for hydrogen production by enhancing operational efficiency and reducing carbon emissions. By integrating these technologies, companies can position themselves as leaders in sustainability, complying with stringent environmental standards while also cutting costs associated with energy consumption. For example, automakers could utilize hydrogen made from formic acid and methanol to power their vehicles, promoting a cleaner alternative and capturing market share in the growing green technology sector.
  • question: What challenges exist in the implementation of advanced catalysis?

    répondre: Implementing advanced catalysis for hydrogen production faces challenges such as catalyst stability, scalability of production, and cost-effectiveness of raw materials. Research is ongoing to develop catalysts that maintain high performance over prolonged use and under varying operational conditions. Additionally, ensuring the availability of formic acid and methanol at a competitive price is critical for widespread adoption. However, overcoming these challenges can lead to transformative advancements in hydrogen production technology, ultimately assisting in the transition to a sustainable energy landscape.
  • question: Where can I buy Advanced Catalysis in Hydrogen Production from Formic Acid and Methanol?

    répondre: You can buy Advanced Catalysis in Hydrogen Production from Formic Acid and Methanol on Ubuy. They offer a range of products related to this cutting-edge technology, providing customers in Gabon access to essential resources for enhancing hydrogen production capabilities. Ubuy is noted for its reliable platform and customer service, ensuring a seamless shopping experience for those interested in this innovative field.

Dmitri A Bulushev (Editor) Format: Hardcover General & Reference Editorial Review

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XAF 33790

XAF 40442

Commandez maintenant et recevez votre commande aux alentours du Mercredi, Juillet 01

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Caractéristiques et avantages

  • Explores advanced catalysis in hydrogen production from formic acid.
  • Includes five research papers and two reviews on effective catalysts.
  • Covers both liquid phase and gas-phase reactions.
  • Highlights the promotional effect of N-doping on carbon supports.
  • Demonstrates the formation of single-atom active sites in catalysts.
  • Suitable for specialists in catalysis and chemistry students alike.