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Compositional flexibility in Li–N–H materials: implications for ammonia catalysis and hydrogen storage

Joshua W. Makepeace, Jake M. Brittain, Alisha Sukhwani Manghnani, Claire A. Murray, Thomas J. Wood, William I. F. David

2021Physical Chemistry Chemical Physics32 citationsDOIOpen Access PDF

Abstract

Li-N-H materials, particularly lithium amide and lithium imide, have been explored for use in a variety of energy storage applications in recent years. Compositional variation within the parent lithium imide, anti-fluorite crystal structure has been related to both its facile storage of hydrogen and impressive catalytic performance for the decomposition of ammonia. Here, we explore the controlled solid-state synthesis of Li-N-H solid-solution anti-fluorite structures ranging from amide-dominated (Li4/3(NH2)2/3(NH)1/3 or Li1.333NH1.667) through lithium imide to majority incorporation of lithium nitride-hydride (Li3.167(NH)0.416N0.584H0.584 or Li3.167NH). Formation of these solid solutions is demonstrated to cause significant changes to the thermal stability and ammonia reactivity of the samples, highlighting the potential use of compositional variation to control the properties of the material in gas storage and catalytic applications.

Topics & Concepts

Hydrogen storageAmmoniaCatalysisLithium amideEnergy storageFlexibility (engineering)HydrogenImideLithium (medication)Inorganic chemistryFluoriteMaterials scienceChemistryChemical engineeringOrganic chemistryThermodynamicsPhysicsEngineeringMathematicsEnantioselective synthesisStatisticsMedicinePower (physics)EndocrinologyHydrogen Storage and MaterialsAmmonia Synthesis and Nitrogen ReductionInorganic Chemistry and Materials