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1. Ruthenium Catalyst for Ammonia Decomposition

   Ammonia is of interest as a hydrogen transport carrier because of the high hydrogen storage capacity and easy liquefaction, and its decomposition to...

   Tadahiro Fujitani, Isao Nakamura in CO2 Free Ammonia as an Energy Carrier

   Chapter 2023
   

2. Ammonia Decomposition Catalysts for Fuel Cell Application

   Ammonia has attracted interest as a hydrogen source for fuel cells. Hydrogen production from ammonia is mainly carried out using decomposition...

   Hiroki Muroyama in CO2 Free Ammonia as an Energy Carrier

   Chapter 2023
   

3. Ammonia Synthesis and Decomposition in the Presence of Supported Ruthenium Catalysts

   Abstract

   Based on analysis of the catalytic properties of 4%Ru–13.6%Cs/Sibunit and 4%Ru–5.4%Ba–7.9%Cs/Sibunit in the ammonia decomposition (10 ⁵ Pa,...

   D. A. Shlyapin, V. A. Borisov, ... P. V. Snytnikov in Kinetics and Catalysis

   Article 12 December 2023
   

4. Estimating the Efficiency of Commercial Domestic Catalysts in the Reaction of Ammonia Decomposition

   Abstract

   Adapting domestic commercial catalysts for use in such important technological processes as the environmentally friendly production of...

   R. E. Yakovenko, T. V. Krasnyakova, ... S. A. Mitchenko in Catalysis in Industry

   Article 01 March 2024
   

5. Ammonia Decomposition over Cobalt-Based Silica-Supported Fischer-Tropsch Synthesis Catalysts

   Abstract

   Decomposition of ammonia over silica-supported cobalt catalysts for Fischer–Tropsch synthesis has been studied at a pressure of 0.1 MPa, a...

   R. E. Yakovenko, T. V. Krasnyakova, ... S. A. Mitchenko in Kinetics and Catalysis

   Article 01 April 2023
   

6. Reactant-induced dynamics of lithium imide surfaces during the ammonia decomposition process

   Ammonia decomposition on lithium imide surfaces has been intensively investigated owing to its potential role in a sustainable hydrogen-based...

   Manyi Yang, Umberto Raucci, Michele Parrinello in Nature Catalysis

   Article 28 August 2023
   

7. Production of High-Purity Hydrogen Through Ammonia Decomposition and Gas Removal

   Ammonia gas has potential as an energy carrier because it is easy to liquefy and transport and has a very high hydrogen density. Therefore, it could...

   Takayoshi Adachi in CO2 Free Ammonia as an Energy Carrier

   Chapter 2023
   

8. Preparation of Lanthanum Hexaaluminate Supported Nickel Catalysts for Hydrogen Production by Ammonia Decomposition

   Lanthanum hexaaluminate (LHA) supported NiO catalysts (xNi/LHA) with varied mass loading of Ni (x = 15, 20, 25, 30 wt%) were prepared by impregnating...

   Guoru Li, **aoting Yu, ... **aobo He in Catalysis Letters

   Article 21 November 2022
   

9. Ammonia-Fueled SOFC Stack

   Solid oxide fuel cell (SOFC) is a type of fuel cell that can convert the chemical energy of fuels into electrical energy in a highly efficient...

   Masashi Kishimoto in CO2 Free Ammonia as an Energy Carrier

   Chapter 2023
   

10. Plasma-Catalytic Ammonia Decomposition for Carbon-Free Hydrogen Production Using Low Pressure-Synthesized Mo₂N Catalyst

    Ammonia decomposition to produce hydrogen can be promoted by the combination of plasma and catalyst. In this study, molybdenum nitride (Mo ₂ N)...

    **uxia Yu, Ke Hu, ... Zhijun Wang in Plasma Chemistry and Plasma Processing

    Article 08 October 2022
    

11. Investigating Periodic Table Interpolation for the Rational Design of Nanoalloy Catalysts for Green Hydrogen Production from Ammonia Decomposition

    Develo** highly active catalysts for the decomposition of ammonia to produce hydrogen is an important goal in the context of renewable energy....

    Luke A. Parker, Nia Richards, ... Graham J. Hutchings in Catalysis Letters

    Article Open access 07 September 2023
    

12. Tuning the Interaction Between Ru Nanoparticles and Nd₂O₃ to Enhance Hydrogen Formation from Ammonia Decomposition

    Development of highly active and stable catalysts for production of CO _x -free hydrogen from ammonia is crucial for the use of ammonia as hydrogen...

    **aohua Ju, Lin Liu, ... ** Chen in Topics in Catalysis

    Article 28 March 2024
    

13. Ammonia Combustion Chemistry

    This chapter summarized studies on chemical kinetic modeling for ammonia combustion in two “Energy Carriers” projects: PREST (Precursory Research for...

    Hisashi Nakamura in CO2 Free Ammonia as an Energy Carrier

    Chapter 2023
    

14. CO2 Free Ammonia as an Energy Carrier Japan's Insights

    This book describes important findings in intensive studies conducted in Japan on ammonia as an energy carrier. It illustrates an advanced solar-heat...

    Ken-ichi Aika, Hideaki Kobayashi

    Book 2023
    

15. Environmental Concerns About Fuel Ammonia

    The Haber–Bosch process saved the world from starvation by creating an artificial fertilizer supply. However, plants accept only about 50% of...

    Ken-ichi Aika in CO2 Free Ammonia as an Energy Carrier

    Chapter 2023
    

16. Low-Temperature Ammonia Fuel Cells

    Low-temperature fuel cells are one of the promising energy conversion devices that use ammonia as a fuel. In this chapter, we focus on fuel cells...

    Toshiaki Matsui in CO2 Free Ammonia as an Energy Carrier

    Chapter 2023
    

17. Numerical Modeling of Ammonia-Fed SOFCs

    For the safe and efficient operation of SOFCs, it is important to understand and properly control the internal phenomena during operation. It is,...

    Hiroshi Iwai in CO2 Free Ammonia as an Energy Carrier

    Chapter 2023
    

18. Ru Nanoparticles on K Doped γ-Alumina with Abundant Surface Superbasic Sites for Ammonia Decomposition

    Catalytic performances of Ru nanoparticles (NPs) on the oxides can be remarkably regulated by the surface properties of oxide supports. Herein, we...

    **aohua Ju, Lin Liu, ... ** Chen in Catalysis Letters

    Article 18 April 2023
    

19. Decomposition of zinc (1-hydroxyethylidene)diphosphonate induced by aliphatic amines and ammonia. Molecular structures of ammonium (1-hydroxyethylidene)diphosphonates

    A suspension of sparingly soluble zinc (1-hydroxyethylidene)diphosphonate ZnH ₂ L•2H ₂ O (H ₄ L = MeC(OH)[P(O)(OH) ₂ ] ₂ ) is rapidly transformed into an...

    V. V. Semenov, N. V. Zolotareva, ... E. N. Razov in Russian Chemical Bulletin

    Article 21 May 2022

20. Lithium-mediated nitrogen reduction to ammonia via the catalytic solid–electrolyte interphase

    The lithium-mediated nitrogen reduction reaction (LiNRR) produces ammonia in ambient conditions. This electrochemical pathway is dependent on a...

    Wesley Chang, Anukta Jain, ... Karthish Manthiram in Nature Catalysis

    Article 11 March 2024