Litcius/Paper detail

Raisins in a Hydrogen Pie: Ultrastable Cesium and Rubidium Polyhydrides

Di Zhou, Dmitrii V. Semenok, Michele Galasso, Frederico Alabarse, Denis Sannikov, I. A. Troyan, Yuki Nakamoto, Katsuya Shimizu, Artem R. Oganov

2024Advanced Energy Materials11 citationsDOI

Abstract

Abstract A new method for synthesis of metal polyhydrides via high‐pressure thermal decomposition of corresponding amidoboranes in diamond anvil cells is proposed. Within this approach, molecular semiconducting cesium ( P 4/ nmm ‐CsH 7 , P 1‐CsH 15+x ) and rubidium (RbH 9‐x ) polyhydrides with a very high hydrogen content reaching 93 at.% are synthesized. Preservation of CsH 7 at near ambient conditions, confirmed both experimentally and theoretically, represents a significant advance in the stabilization of hydrogen‐rich compounds. In addition, two crystalline modifications of RbH 9‐x with pseudohexagonal and pseudotetragonal structures identified by synchrotron X‐ray diffraction, and Raman measurements are synthesized. Both phases are stable at 8–10 GPa. This is an unprecedentedly low stabilization pressure for polyhydrides. These discoveries open up possibilities for modifying existing hydrogen storage materials to increase their efficiency.

Topics & Concepts

RubidiumCaesiumMaterials scienceHydrogenRaman spectroscopySynchrotronThermal decompositionDecompositionDiamond anvil cellDiffractionAnalytical Chemistry (journal)Inorganic chemistryChemistryPotassiumPhysicsMetallurgyOpticsChromatographyOrganic chemistryHydrogen Storage and MaterialsNuclear Materials and PropertiesBoron and Carbon Nanomaterials Research