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1. Comparison of the Ability of N‐Bases to Engage in Noncovalent Bonds

   https://doi.org/10.1002/cphc.202300326  

   Amonov, Akhtam; Scheiner, Steve (June 2023, ChemPhysChem)

   Abstract The lone pair of the N atom is a common electron donor in noncovalent bonds. Quantum calculations examine how various aspects of the base on which the N is located affect the strength and other properties of complexes formed with Lewis acids FH, FBr, F₂Se, and F₃As that respectively encompass hydrogen, halogen, chalcogen, and pnicogen bonds. In most cases the halogen bond is the strongest, followed in order by chalcogen, hydrogen, and pnicogen. The noncovalent bond strength increases in the sp²³order of hybridization of N. Replacement of H substituents on the base by a methyl group or substituting N by C atom to which the base N is attached, strengthens the bond. The strongest bonds occur for trimethylamine and the weakest for N₂. 

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2. Relation between Halogen Bond Strength and IR and NMR Spectroscopic Markers

   https://doi.org/10.3390/molecules28227520  

   Amonov, Akhtam; Scheiner, Steve (November 2023, Molecules)

   The relationship between the strength of a halogen bond (XB) and various IR and NMR spectroscopic quantities is assessed through DFT calculations. Three different Lewis acids place a Br or I atom on a phenyl ring; each is paired with a collection of N and O bases of varying electron donor power. The weakest of the XBs display a C–X bond contraction coupled with a blue shift in the associated frequency, whereas the reverse trends occur for the stronger bonds. The best correlations with the XB interaction energy are observed with the NMR shielding of the C atom directly bonded to X and the coupling constants involving the C–X bond and the C–H/F bond that lies ortho to the X substituent, but these correlations are not accurate enough for the quantitative assessment of energy. These correlations tend to improve as the Lewis acid becomes more potent, which makes for a wider range of XB strengths. 

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3. Influence of Substituents in the Benzene Ring on the Halogen Bond of Iodobenzene with Ammonia

   https://doi.org/10.1002/cphc.202200011  

   Scheiner, Steve; Hunter, Sarah (February 2022, ChemPhysChem)

   Abstract The effects on the C−I⋅⋅N halogen bond between iodobenzene and NH₃of placing various substituents on the phenyl ring are monitored by quantum calculations. Substituents R=N(CH₃)₂, NH₂, CH₃, OCH₃, COCH₃, Cl, F, COH, CN, and NO₂were each placed ortho, meta, and para to the I. The depth of the σ‐hole on I is deepened as R becomes more electron‐withdrawing which is reflected in a strengthening of the halogen bond, which varied between 3.3 and 5.5 kcal mol⁻¹. In most cases, the ortho placement yields the largest perturbation, followed by meta and then para, but this trend is not universal. Parallel to these substituent effects is a progressive lengthening of the covalent C−I bond. Formation of the halogen bond reduces the NMR chemical shielding of all three nuclei directly involved in the C−I⋅⋅N interaction. The deshielding of the electron donor N is most closely correlated with the strength of the bond, as is the coupling constant between I and N, so both have potential use as spectroscopic measures of halogen bond strength. 

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4. Tris( ortho ‐carboranyl)borane: An Isolable, Halogen‐Free, Lewis Superacid

   https://doi.org/10.1002/anie.202212073  

   Akram, Manjur O.; Tidwell, John R.; Dutton, Jason L.; Martin, Caleb D. (October 2022, Angewandte Chemie International Edition)

   Abstract The synthesis of tris(ortho‐carboranyl)borane (BoCb₃), a single site neutral Lewis superacid, in one pot from commercially available materials is achieved. The high fluoride ion affinity (FIA) confirms its classification as a Lewis superacid and the Gutmann‐Beckett method as well as adducts with Lewis bases indicate stronger Lewis acidity over the widely used fluorinated aryl boranes. The electron withdrawing effect ofortho‐carborane and lack of pi‐delocalization of the LUMO rationalize the unusually high Lewis acidity. Catalytic studies indicate that BoCb₃is a superior catalyst for promoting C−F bond functionalization reactions than tris(pentafluorophenyl)borane [B(C₆F₅)₃]. 

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5. The Close Interaction of a C−F Bond with an Amide Carbonyl: Crystallographic and Spectroscopic Characterization

   https://doi.org/10.1002/anie.202207966  

   Harry, Stefan Andrew; Kazim, Muhammad; Nguyen, Phuong Minh; Zhu, Andrea; Xiang, Michael Richard; Catazaro, Jonathan; Siegler, Maxime; Lectka, Thomas (July 2022, Angewandte Chemie International Edition)

   Abstract The putative interaction of a C−F bond with an amide carbonyl has been an intriguing topic of interest in this century for reasons spanning basic physical organic chemistry to biochemistry. However, to date, there exist no examples of a close, well‐defined interaction in which its unique aspects can be identified and exploited. Herein, we finally present an engineered system possessing an exceptionally tight C−F‐amide interaction, allowing us to obtain spectroscopic, crystallographic, and kinetic details of a distinctive, biochemically relevant chemical system for the first time. In turn, we also explore Lewis acid coordination, C−F bond promotion of amide isomerization, enantiomerization, and ion protonation processes. 

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