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1. Uncovering the Influence of Ni 2+ Doping in Lead-Halide Perovskite Nanocrystals Using Optically Detected Magnetic Resonance Spectroscopy

   https://doi.org/10.1021/acs.chemmater.1c03822  

   Barak, Yahel ; Meir, Itay ; Dehnel, Joanna ; Horani, Faris ; Gamelin, Daniel R. ; Shapiro, Arthur ; Lifshitz, Efrat ( February 2022 , Chemistry of Materials)
2. Ab initio determination of a simultaneous dual-ion charging mechanism for Ni 0.25 Mn 0.75 O 2 through redox reactions of Ni 2+ /Ni 4+ and O 2- /O -

   https://doi.org/10.1039/D2TA03938A  

   Shepard, Robert ; Brennan, Scott ; Juran, Taylor R ; Young, Joshua ; Smeu, Manuel ( July 2022 , Journal of Materials Chemistry A)

   Over recent years, great efforts have been made to push the limits of layered transition metal oxides for secondary battery cathodes. This is particularly true for overall capacity, which has reached a terminal theoretical value for many materials. One avenue for increasing this capacity during charging is the intercalation of anions post cation deintercalation. This work investigates the charging mechanism of the P3-Na0.5Ni0.25 Mn0.75O2 cathode material through cation (Na) deintercalation and anion (ClO4) intercalation by means of density functional theory. The calculations corroborate experimental findings of increased capacity (135 mAh g-1 to 180 mAh g-1) through the intercalation of anions. However, this work demonstrates that a process of simultaneous cation deintercalation/anion intercalation is the primary charging mechanism, with charge compensation reactions of Ni2+/Ni4+ and O2-/O- occurring within the cathode material. To elucidate this simultaneous process, a novel method for computationally determining anion voltage in which one must consider full electrolyte interactions is proposed. Based on the results, it is believed that a simultaneous cation deintercalation/anion intercalation mechanism provides one potential avenue for the discovery of the next generation of secondary batteries. 

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3. Electronic structure of (MePh 3 P) 2 [Ni II (bdtCl 2 ) 2 ]·2(CH 3 ) 2 SO and (MePh 3 P)[Ni III (bdtCl 2 ) 2 ] (bdtCl 2 = 3,6-dichlorobenzene-1,2-dithiolate)

   https://doi.org/10.1107/S2052520621011495  

   Adamko Koziskova, Julia ; Chen, Yu-Sheng ; Grass, Su-Yin ; Chuang, Yu-Chun ; Hsu, I-Jui ; Wang, Yu ; Lutz, Martin ; Volkov, Anatoliy ; Herich, Peter ; Vénosová, Barbora ; et al ( December 2021 , Acta Crystallographica Section B Structural Science, Crystal Engineering and Materials)

   High-resolution X-ray diffraction experiments, theoretical calculations and atom-specific X-ray absorption experiments were used to investigate two nickel complexes, (MePh 3 P) 2 [Ni II (bdtCl 2 ) 2 ]·2(CH 3 ) 2 SO [complex (1)] and (MePh 3 P)[Ni III (bdtCl 2 ) 2 ] [complex (2)]. Combining the techniques of nickel K - and sulfur K -edge X-ray absorption spectroscopy with high-resolution X-ray charge density modeling, together with theoretical calculations, the actual oxidation states of the central Ni atoms in these two complexes are investigated. Ni ions in two complexes are clearly in different oxidation states: the Ni ion of complex (1) is formally Ni II ; that of complex (2) should be formally Ni III , yet it is best described as a combination of Ni 2+ and Ni 3+ , due to the involvement of the non-innocent ligand in the Ni— L bond. A detailed description of Ni—S bond character (σ,π) is presented. 

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4. The versatility of 1,4,8,11-tetraazacyclotetradecane (cyclam) in the formation of compounds of Co 2+ , Ni 2+ , Cu 2+ , and Zn 2+ with metal ions in and out of the cyclic ligand ring

   https://doi.org/10.1515/zkri-2023-0026  

   Noor, Mah ; Chah, Hamza ; Tresp, David ; Bernal, Ivan ; Lalancette, Roger A. ( June 2023 , Zeitschrift für Kristallographie - Crystalline Materials)

   Herein we report the results of preparing metal compounds (where the metal ions are Co2+, Ni2+, Cu2+, Zn2+) with the cyclic ligand 1,4,8,11-tetraazacyclotetradecane [cyclam] under a variety of conditions of metal-ligand ratios and solvent media. In all cases, we used metal Cl2 . nH2O salts (except for anhydrous CoCl2), as specified. Outcome: we isolated species with a four-coordinate metal in the N4 cavity of the ligand alone, and also with either one or two additional axial ligands. Those axial ligands can be (a) a single chloride, leading to penta-coordinated+ products; (b) two chlorides, leading to octahedral-neutral compounds; (c) two waters, giving rise to hexa-coordinated [(cyclam)metal(H2O)2]2+ species. Finally, in the case of HCl added to the reaction medium, the cyclam can be di-protonated and appears as [(cyclam)H2]2+ in the crystals. With such a variety of products, it is not surprising that since the metal coordination numbers vary, the cyclam ligand stereochemistries are thereby affected. Interestingly, the [(cyclam)metal] species are invariably hydrogen-bonded to one another in infinite strings of two kinds: (1) those for which the crystal’s Z’ = 1 have single strings; (2) when Z’ = 2, there is a pair of homogeneous strings attached to one another by a variety of hydrogen-bonding linkages. Finally, we observed an interesting pair of hydroxonium cations: the first is hydoxonium cations in a pleated 2-D sheet consisting of fused pentagons located between sheets of [(cyclam)metal] moieties; the second one is an infinite string of composition (H3O+)-(H2O)-(H3O+)-(H2O)-(H3O+)-(H2O)-(H3O+). 

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5. Useful Method for the Preparation of Low-Coordinate Nickel(I) Complexes via Transformations of the Ni(I) Bis(amido) Complex K{Ni[N(SiMe 3 )(2,6- i Pr 2 -C 6 H 3 )] 2 }

   https://doi.org/10.1021/om500849u  

   Lipschutz, Michael I. ; Tilley, T. Don ( October 2014 , Organometallics)