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1. Planar B ₄₁ ⁻ and B ₄₂ ⁻ clusters with double-hexagonal vacancies

   https://doi.org/10.1039/C9NR09522E  

   Bai, Hui; Chen, Teng-Teng; Chen, Qiang; Zhao, Xiao-Yun; Zhang, Yang-Yang; Chen, Wei-Jia; Li, Wan-Lu; Cheung, Ling Fung; Bai, Bing; Cavanagh, Joseph; et al (December 2019, Nanoscale)

   Since the discovery of the B 40 borospherene, research interests have been directed to the structural evolution of even larger boron clusters. An interesting question concerns if the borospherene cages persist in larger boron clusters like the fullerenes. Here we report a photoelectron spectroscopy (PES) and computational study on the structures and bonding of B 41 − and B 42 − , the largest boron clusters characterized experimentally thus far. The PE spectra of both clusters display broad and complicated features, suggesting the existence of multiple low-lying isomers. Global minimum searches for B 41 − reveal three low-lying isomers ( I–III ), which are all related to the planar B 40 − structure. Isomer II ( C s , 1 A′) possessing a double hexagonal vacancy is found to agree well with the experiment, while isomers I ( C s , 3 A′′) and III ( C s , 1 A′) both with a single hexagonal vacancy are also present as minor isomers in the experiment. The potential landscape of B 42 − is found to be much more complicated with numerous low-lying isomers ( VII–XII ). The quasi-planar structure VIII ( C 1 , 2 A) containing a double hexagonal vacancy is found to make major contributions to the observed PE spectrum of B 42 − , while the other low-lying isomers may also be present to give rise to a complicated spectral pattern. Chemical bonding analyses show isomer II of B 41 − ( C s , 1 A′) and isomer VIII of B 42 − ( C 1 , 2 A) are π aromatic, analogous to that in the polycyclic aromatic hydrocarbon C 27 H 13 + ( C 2v , 1 A 1 ). Borospherene cage isomers are also found for both B 41 − and B 42 − in the global minimum searches, but they are much higher energy isomers. 

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2. Probing the Effects of Size and Charge on the Monohydration and Dihydration of SiF ₅ ^– and SiF ₆ ^2– via Comparisons with BF ₄ ^– and PF ₆ ^–

   https://doi.org/10.1021/acs.jpca.4c03430  

   Mosely, Jacquelyn J; Tschumper, Gregory S (July 2024, The Journal of Physical Chemistry A)
3. Lanthanides with Unusually Low Oxidation States in the PrB ₃ ^– and PrB ₄ ^– Boride Clusters

   https://doi.org/10.1021/acs.inorgchem.8b02572  

   Chen, Xin; Chen, Teng-Teng; Li, Wan-Lu; Lu, Jun-Bo; Zhao, Li-Juan; Jian, Tian; Hu, Han-Shi; Wang, Lai-Sheng; Li, Jun (December 2018, Inorganic Chemistry)
4. Redox Studies of the Scandium Metallocene (C ₅ H ₂ ^t Bu ₃ ) ₂ Sc ^II Lead to a Terminal Side-On (N═N) ^2– Complex: [(C ₅ H ₂ ^t Bu ₃ ) ₂ Sc ^III (η ² -N ₂ )] ⁻

   https://doi.org/10.1021/jacs.5c00607  

   Queen, Joshua D; Rajabi, Ahmadreza; Ziller, Joseph W; Furche, Filipp; Evans, William J (April 2025, Journal of the American Chemical Society)
5. Dinitrogen reduction chemistry with scandium provides a complex with two side-on (NN) ²⁻ ligands bound to one metal: (C ₅ Me ₅ )Sc[(µ-η ² :η ² -N ₂ )Sc(C ₅ Me ₅ ) ₂ ] ₂

   https://doi.org/10.1039/d4sc03977g  

   Queen, Joshua D; Rajabi, Ahmadreza; Goudzwaard, Quinn E; Yuan, Qiong; Nguyen, Dang Khoa; Ziller, Joseph W; Furche, Filipp; Xi, Zhenfeng; Evans, William J (January 2024, Chemical Science)

   Although there are few reduced dinitrogen complexes of scandium, this metal has revealed a new structural type in reductive dinitrogen chemistry by reduction of bis(pentamethylcyclopentadienyl) scandium halides under N2. 

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