Rational design of metal nitride redox materials for solar-driven ammonia synthesis

Rational design of metal nitride redox materials for solar-driven ammonia synthesis

Fixed nitrogen is an essential chemical building block for plant and animal protein, which makes ammonia (NH3) a central component of synthetic fertilizer for the global production of food and biofuels. A global project on artificial photosynthesis may foster the development of production technologi...

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Bibliographic Details
Published in:Interface focus Vol. 5; no. 3; p. 20140084
Main Authors: Michalsky, Ronald, Pfromm, Peter H., Steinfeld, Aldo
Format: Journal Article
Language:English
Published: England The Royal Society 06-06-2015
Subjects:
Concentrated Solar Energy
Density Functional Theory
Haber–bosch
Hydrogen Storage
Metal Nitride
Thermochemical Redox Cycle
concentrated solar energy
metal nitride
Haber–Bosch
thermochemical redox cycle
density functional theory
hydrogen storage
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Summary:Fixed nitrogen is an essential chemical building block for plant and animal protein, which makes ammonia (NH3) a central component of synthetic fertilizer for the global production of food and biofuels. A global project on artificial photosynthesis may foster the development of production technologies for renewable NH3 fertilizer, hydrogen carrier and combustion fuel. This article presents an alternative path for the production of NH3 from nitrogen, water and solar energy. The process is based on a thermochemical redox cycle driven by concentrated solar process heat at 700–1200°C that yields NH3 via the oxidation of a metal nitride with water. The metal nitride is recycled via solar-driven reduction of the oxidized redox material with nitrogen at atmospheric pressure. We employ electronic structure theory for the rational high-throughput design of novel metal nitride redox materials and to show how transition-metal doping controls the formation and consumption of nitrogen vacancies in metal nitrides. We confirm experimentally that iron doping of manganese nitride increases the concentration of nitrogen vacancies compared with no doping. The experiments are rationalized through the average energy of the dopant d-states, a descriptor for the theory-based design of advanced metal nitride redox materials to produce sustainable solar thermochemical ammonia.
Bibliography:Theme issue ‘Do we need a global project on artificial photosynthesis (solar fuels and chemicals)?’ organized by Thomas Faunce
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One contribution of 11 to a theme issue ‘Do we need a global project on artificial photosynthesis (solar fuels and chemicals)?’.
Present address: ETH Zürich, Institute of Energy Technology, Sonneggstrasse 3, ML K 23, 8092 Zürich, Switzerland.
ISSN:2042-8898
2042-8901
DOI:10.1098/rsfs.2014.0084