Novel Class of Rhenium Borides Based on Hexagonal Boron Networks Interconnected by Short B 2 Dumbbells.
Elena BykovaErik JohanssonMaxim BykovStella CharitonHongzhan FeiSergey V OvsyannikovAlena AslandukovaStefan GabelHendrik HolzBenoit MerleBjörn AllingIgor A AbrikosovJesse S SmithVitali B PrakapenkaTomoo KatsuraNatalia DubrovinskaiaAlexander F GoncharovLeonid DubrovinskyPublished in: Chemistry of materials : a publication of the American Chemical Society (2022)
Transition metal borides are known due to their attractive mechanical, electronic, refractive, and other properties. A new class of rhenium borides was identified by synchrotron single-crystal X-ray diffraction experiments in laser-heated diamond anvil cells between 26 and 75 GPa. Recoverable to ambient conditions, compounds rhenium triboride (ReB 3 ) and rhenium tetraboride (ReB 4 ) consist of close-packed single layers of rhenium atoms alternating with boron networks built from puckered hexagonal layers, which link short bonded (∼1.7 Å) axially oriented B 2 dumbbells. The short and incompressible Re-B and B-B bonds oriented along the hexagonal c -axis contribute to low axial compressibility comparable with the linear compressibility of diamond. Sub-millimeter samples of ReB 3 and ReB 4 were synthesized in a large-volume press at pressures as low as 33 GPa and used for material characterization. Crystals of both compounds are metallic and hard (Vickers hardness, H V = 34(3) GPa). Geometrical, crystal-chemical, and theoretical analysis considerations suggest that potential ReB x compounds with x > 4 can be based on the same principle of structural organization as in ReB 3 and ReB 4 and possess similar mechanical and electronic properties.
Keyphrases
- transition metal
- induced apoptosis
- air pollution
- cell cycle arrest
- particulate matter
- high resolution
- magnetic resonance imaging
- cell death
- risk assessment
- magnetic resonance
- computed tomography
- solar cells
- endoplasmic reticulum stress
- cell proliferation
- electron microscopy
- signaling pathway
- climate change
- mass spectrometry