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1. Anions Formed by Perchlorofluorobenzenes C ₆ Cl _n F _6–n ( n = 0–6)

   https://doi.org/10.1021/acs.jpca.4c04359  

   Sommerfeld, Thomas (September 2024, The Journal of Physical Chemistry A)

   Anions formed by the perhalobenzene series C$$_6$$Cl$$_{n}$$F$$_{6-n}$$ ($n=0-6$) are studied computationally. All members of the series form both stable valence and stable non-valence anions. At the geometry of the neutral parents, only non-valence anions are bound, and the respective vertical electron affinities show values in the $20$ to $60$meV range. Valence anions show distorted non-planar structures, and one can distinguish two types of conformers. A-type conformers show puckered-ring structures and excess electrons delocalized over several C-Cl bonds [in case of C$$_6$$F$$_6^-$$, C-F bonds], while B-type conformers possess excess electrons essentially localized in a single C-Cl bond, which is accordingly strongly stretched and bent out-of-plane. For a specific anion, all conformers are close in energy (relative energies of less than $10$kJ/mol) and are connected by low-lying transition states. Accordingly, A-type and B-type conformers possess similar adiabatic electron affinities, however, their vertical detachment energies exhibit drastically different values, which should ease conformer distinction in photoelectron spectroscopy. 

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2. Spectroscopic Measurement of a Halogen Bond Energy

   https://doi.org/10.1002/anie.201906279  

   Zhang, Xinxing; Liu, Gaoxiang; Ciborowski, Sandra; Wang, Wei; Gong, Chu; Yao, Yifan; Bowen, Kit (July 2019, Angewandte Chemie International Edition)

   Abstract Halogen bonding (XB) has emerged as an important bonding motif in supramolecules and biological systems. Although regarded as a strong noncovalent interaction, benchmark measurements of the halogen bond energy are scarce. Here, a combined anion photoelectron spectroscopy and density functional theory (DFT) study of XB in solvated Br⁻anions is reported. The XB strength between the positively‐charged σ‐hole on the Br atom of the bromotrichloromethane (CCl₃Br) molecule and the Br⁻anion was found to be 0.63 eV (14.5 kcal mol⁻¹). In the neutral complexes, Br(CCl₃Br)_1,2, the attraction between the free Br atom and the negatively charged equatorial belt on the Br atom of CCl₃Br, which is a second type of halogen bonding, was estimated to have interaction strengths of 0.15 eV (3.5 kcal mol⁻¹) and 0.12 eV (2.8 kcal mol⁻¹). 

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3. Why are the Elemental Nonmetals (F ₂ , Cl ₂ , Br ₂ , I ₂ , S ₈ , P ₄ ) of so Many Hues or of Any Hues and Where is the Chromophore? Insight into Intera ‐X–X Bonds

   https://doi.org/10.1111/php.13270  

   Jabeen, Shakeela; Greer, Alexander; Edwards, Kathleen F.; Liebman, Joel F. (May 2020, Photochemistry and Photobiology)

   Abstract A unique approach is used to relate the HOMO‐LUMO energy difference to the difference between the ionization potential (IP) and electron affinity (EA) to assist in deducing not only the colors, but also chromophores in elemental nonmetals. Our analysis focuses on compounds with lone pair electrons and σ electrons, namely X₂(X = F, Cl, Br, I), S₈and P₄. For the dihalogens, the [IP – EA] energies are found to be: F₂(12.58 eV), Cl₂(8.98 eV), Br₂(7.90 eV), I₂(6.78 eV). We suggest that theinterahalogen X–X bond itself is the chromophore for these dihalogens, in which the light absorbed by the F₂, Cl₂, Br₂, I₂leads to longer wavelengths in the visible by a π → σ* transition. Trace impurities are a likely case of cyclic S₈which contains amounts of selenium leading to a yellow color, where the [IP – EA] energy of S₈is found to be 7.02 eV. Elemental P₄with an [IP – EA] energy of 9.09 eV contains a tetrahedral and σ aromatic structure. In future work, refinement of the analysis will be required for compounds with π electrons and σ electrons, such as polycyclic aromatic hydrocarbons (PAHs). 

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4. The dicarbon bonding puzzle viewed with photoelectron imaging

   https://doi.org/10.1038/s41467-019-13039-y  

   Laws, B. A.; Gibson, S. T.; Lewis, B. R.; Field, R. W. (December 2019, Nature Communications)

   null (Ed.)

   Abstract Bonding in the ground state of C $${}_{2}$$ 2 is still a matter of controversy, as reasonable arguments may be made for a dicarbon bond order of $$2$$ 2 , $$3$$ 3 , or $$4$$ 4 . Here we report on photoelectron spectra of the C $${}_{2}^{-}$$ 2 − anion, measured at a range of wavelengths using a high-resolution photoelectron imaging spectrometer, which reveal both the ground $${X}^{1}{\Sigma}_{\mathrm{g}}^{+}$$ X 1 Σ g + and first-excited $${a}^{3}{\Pi}_{{\mathrm{u}}}$$ a 3 Π u electronic states. These measurements yield electron angular anisotropies that identify the character of two orbitals: the diffuse detachment orbital of the anion and the highest occupied molecular orbital of the neutral. This work indicates that electron detachment occurs from predominantly $$s$$ s -like ( $$3{\sigma}_{\mathrm{g}}$$ 3 σ g ) and $$p$$ p -like ( $$1{\pi }_{{\mathrm{u}}}$$ 1 π u ) orbitals, respectively, which is inconsistent with the predictions required for the high bond-order models of strongly $$sp$$ s p -mixed orbitals. This result suggests that the dominant contribution to the dicarbon bonding involves a double-bonded configuration, with 2 $$\pi$$ π bonds and no accompanying $$\sigma$$ σ bond. 

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5. Vibrationally- and rotationally-resolved photoelectron imaging of cryogenically-cooled SbO ₂ ^–

   https://doi.org/10.1080/00268976.2023.2182610  

   Kocheril, G. Stephen; Gao, Han-Wen; Wang, Lai-Sheng (February 2023, Molecular Physics)

   We report a temperature-controlled photoelectron imaging study of SbO2–, produced from a laser vaporization source and cooled in a cryogenic 3D Paul trap. Vibrationally resolved photoelectron spectra are obtained for the ground state detachment transition, yielding the bending frequencies for both SbO2 and SbO2–. Franck-Condon simulations also allow the estimate of the vibrational temperature of the trapped SbO2– anion. A near-threshold spectrum of SbO2– at a photon energy of 3.4958 eV reveals partially resolved rotational structure for the 0-0 transition, which yields an accurate electron affinity of 3.4945 ± 0.0004 eV for SbO2. The rotational simulation also yields an estimated rotational temperature of the trapped ions. 

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