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1. Probing the structures and bonding of size-selected boron and doped-boron clusters

   https://doi.org/10.1039/c9cs00233b  

   Jian, Tian; Chen, Xuenian; Li, Si-Dian; Boldyrev, Alexander I.; Li, Jun; Wang, Lai-Sheng (January 2019, Chemical Society Reviews)

   Because of their interesting structures and bonding and potentials as motifs for new nanomaterials, size-selected boron clusters have received tremendous interest in recent years. In particular, boron cluster anions (B n − ) have allowed systematic joint photoelectron spectroscopy and theoretical studies, revealing predominantly two-dimensional structures. The discovery of the planar B 36 cluster with a central hexagonal vacancy provided the first experimental evidence of the viability of 2D borons, giving rise to the concept of borophene. The finding of the B 40 cage cluster unveiled the existence of fullerene-like boron clusters (borospherenes). Metal-doping can significantly extend the structural and bonding repertoire of boron clusters. Main-group metals interact with boron through s/p orbitals, resulting in either half-sandwich-type structures or substitutional structures. Transition metals are more versatile in bonding with boron, forming a variety of structures including half-sandwich structures, metal-centered boron rings, and metal-centered boron drums. Transition metal atoms have also been found to be able to be doped into the plane of 2D boron clusters, suggesting the possibility of metalloborophenes. Early studies of di-metal-doped boron clusters focused on gold, revealing ladder-like boron structures with terminal gold atoms. Recent observations of highly symmetric Ta 2 B 6 − and Ln 2 B n − ( n = 7–9) clusters have established a family of inverse sandwich structures with monocyclic boron rings stabilized by two metal atoms. The study of size-selected boron and doped-boron clusters is a burgeoning field of research. Further investigations will continue to reveal more interesting structures and novel chemical bonding, paving the foundation for new boron-based chemical compounds and nanomaterials. 

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2. Unraveling the role of boron dimers in the electrical anisotropy and superconductivity in boron-doped diamond

   https://doi.org/10.1016/j.carbon.2024.119337  

   Sobaszek, Michał; Kwon, Soonho; Klimczuk, Tomasz; Michałowski, Paweł P; Ryl, Jacek; Rutkowski, Bogdan; Wang, Dongying; Li, Xinwei; Bockrath, Marc; Bogdanowicz, Robert; et al (September 2024, Carbon)
3. Synthesis and Thermal Oxidation Resistance of Boron-Rich Boron–Carbide Material

   https://doi.org/10.3390/ma16196526  

   Iwan, Seth; Sutton, Wesley; Baker, Paul A.; Sereika, Raimundas; Vohra, Yogesh K. (October 2023, Materials)

   A boron-rich boron–carbide material (B4+δC) was synthesized by spark plasma sintering of a ball-milled mixture of high-purity boron powder and graphitic carbon at a pressure of 7 MPa and a temperature of 1930 °C. This high-pressure, high-temperature synthesized material was recovered and characterized by X-ray diffraction, X-ray photoelectron spectroscopy, Raman spectroscopy, Vickers hardness measurements, and thermal oxidation studies. The X-ray diffraction studies revealed a single-phase rhombohedral structure (space group R-3m) with lattice parameters in hexagonal representation as a = 5.609 ± 0.007 Å and c = 12.082 ± 0.02 Å. The experimental lattice parameters result in a value of δ = 0.55, or the composition of the synthesized compound as B4.55C. The high-resolution scans of boron binding energy reveal the existence of a B-C bond at 188.5 eV. Raman spectroscopy reveals the existence of a 386 cm−1 vibrational mode representative of C-B-B linear chain formation due to excess boron in the lattice. The measured Vickers microhardness at a load of 200 gf shows a high hardness value of 33.8 ± 2.3 GPa. Thermal gravimetric studies on B4.55C were conducted at a temperature of 1300 °C in a compressed dry air environment, and its behavior is compared to other high-temperature ceramic materials such as high-entropy transition metal boride. The high neutron absorption cross section, high melting point, high mechanical strength, and thermal oxidation resistance make this material ideal for applications in extreme environments. 

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4. Asymmetric twins in boron rich boron carbide

   https://doi.org/10.1039/C8CP01429A  

   Yang, Xiaokun; Goddard, William A.; An, Qi (January 2018, Physical Chemistry Chemical Physics)

   Twin boundaries (TBs) play an essential role in enhancing the mechanical, electronic and transport properties of polycrystalline materials. However, the mechanisms are not well understood. In particular, we considered that they may play an important role in boron rich boron carbide (B vr BC), which exhibits promising properties such as low density, super hardness, high abrasion resistance, and excellent neutron absorption. Here, we apply first-principles-based simulations to identify the atomic structures of TBs in B vr BC and their roles for the inelastic response to applied stresses. In addition to symmetric TBs in B vr BC, we identified a new type of asymmetric twin that constitutes the phase boundaries between boron rich boron carbide (B 13 C 2 ) and B vr BC (B 14 C). The predicted mechanical response of these asymmetric twins indicates a significant reduction of the ideal shear strength compared to single crystals B 13 C 2 and B 14 C, suggesting that the asymmetric twins facilitate the disintegration of icosahedral clusters under applied stress, which in turn leads to amorphous band formation and brittle failure. These results provide a mechanistic basis towards understating the roles of TBs in B vr BC and related superhard ceramics. 

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5. Reactivity of Boron Nitride Nanomaterials with Phosphoric Acid and Its Application in the Purification of Boron Nitride Nanotubes

   https://doi.org/10.1021/acs.chemmater.3c01424  

   Shumard, Kevin R; Acapulco, Jesus_A I; Pasquali, Matteo; Martí, Angel A (January 2024, Chemistry of Materials)