Materials for hydrogen storage: current research trends and perspectives

TL;DR: This critical review of the current status of hydrogen storage within microporous metal-organic frameworks provides an overview of the relationships between structural features and the enthalpy of hydrogen adsorption, spectroscopic methods for probing framework-H(2) interactions, and strategies for improving storage capacity.

TL;DR: In this paper, a brief review of hydrogen as an ideal sustainable energy carrier for the future economy, its storage as the stumbling block as well as the current position of solid-state hydrogen storage in metal hydrides and makes a recommendation based on the most promising novel discoveries made in the field in recent times which suggests a prospective breakthrough towards a hydrogen economy.

TL;DR: In this article, the potential applications of metal-organic frameworks are examined and an outlook is proposed for these potential applications, including materials for gas storage, gas/vapor separation, catalysis, luminescence, and drug delivery.

TL;DR: In this paper, a useful interpretation of the hydrogen adsorption data according to the porosity of the materials and to the adaption conditions, using the fundamentals of adsorptions, is provided.

TL;DR: Three structurally diverse polymers of intrinsic microporosity reversibly adsorb significant quantities of hydrogen and represent the first examples of a new type of purely organic hydrogen storage material, which can be tailored to meet the specific requirements of hydrogen physisorption.

TL;DR: The concept of free volume is useful for explaining aspects of the chain mobility and permeability of polymers, even though its precise definition is subject to debate as mentioned in this paper, and polymers that trap a large amount of interconnected free volume in the glassy state behave in many respects like microporous materials and potentially find application in membrane separations and heterogeneous catalysis.

TL;DR: In this paper, a hydrogen clathrate hydrate, H2(H2O)2, was synthesized at 200-300 MPa and 240-249 K, which can be preserved to ambient P at 77 K.