Catalytic splitting NH3 to H2 is one of the foundations for building a carbon‐free H2 energy
system but requires NH3 splitting catalysts that are highly active and durable at low …

In this study, a CeO2 and BN hybrid-supported Ni catalyst (Ni/CeO2–BN) was developed for
efficient NH3-to-H2 conversion. By adding BN to Ni/CeO2 as an additional support material …

Ammonia (NH 3) has been regarded as an attractive energy source for hydrogen production
via catalytic decomposition, especially over non-noble metal catalysts. Owing to the decent …

The development of efficient catalysts for hydrogen generation via ammonia decomposition
is crucial for the use of ammonia as an energy carrier. Here, we report the effect of pore …

On-site ammonia decomposition has been considered as a potential candidate to alleviate
the challenges of hydrogen storage and transportation by utilizing NH 3 (with a high …

The emerging H2 economy faces storage and transport challenges, and the use of ammonia
(NH3) as a CO x-free source of H2 via NH3 decomposition has recently attracted attention …

Nickel based materials are the most potential catalysts for CO x-free hydrogen production
from ammonia decomposition. However, the facile synthesis of supported Ni-based catalysts …

Catalytic ammonia decomposition is an attractive method to generate hydrogen at mid-
temperatures (< 700° C) but must incorporate precious metals (Pd, Ru, etc.) to ensure high …

Ammonia (NH3) splitting to hydrogen (H2) is a promising route for on-site production of
green hydrogen energy; however, the application is limited due to high-cost noble-metal …

Ammonia is a prospective fuel for hydrogen storage and production, but its application is
limited by the high cost of the catalysts (Ru, etc.) to decompose NH 3. Decomposing …