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1. MIDA‐ and TIDA‐Boronates Stabilize α‐Radicals Through B−N Hyperconjugation

   https://doi.org/10.1002/anie.202309566  

   LaPorte, Antonio J. ; Feldner, Jack E. ; Spies, Jan C. ; Maher, Tom J. ; Burke, Martin D. ( August 2023 , Angewandte Chemie International Edition)

   Multifunctional organoboron compounds increasingly enable the simple generation of complex, Csp³‐rich small molecules. The ability of boron‐containing functional groups to modify the reactivity of α‐radicals has also enabled a myriad of chemical reactions. Boronic esters with vacant p‐orbitals have a significant stabilizing effect on α‐radicals due to delocalization of spin density into the empty orbital. The effect of coordinatively saturated derivatives, such as N‐methyliminodiacetic acid (MIDA) boronates and counterparts, remains less clear. Herein, we demonstrate that coordinatively saturated MIDA and TIDA boronates stabilize secondary alkyl α‐radicals via σ_B‐Nhyperconjugation in a manner that allows site‐selective C−H bromination. DFT calculated radical stabilization energies and spin density maps as well as LED NMR kinetic analysis of photochemical bromination rates of different boronic esters further these findings. This work clarifies that the α‐radical stabilizing effect of boronic esters does not only proceed via delocalization of radical character into vacant boron p‐orbitals, but that hyperconjugation of tetrahedral boron‐containing functional groups and their ligand electron delocalizing ability also play a critical role. These findings establish boron ligands as a useful dial for tuning reactivity at the α‐carbon.

    

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2. Isolation of the elusive bisbenzimidazole Bbim 3− ˙ radical anion and its employment in a metal complex

   https://doi.org/10.1039/d1sc07245e  

   Benner, Florian ; Demir, Selvan ( May 2022 , Chemical Science)

   The discovery of singular organic radical ligands is a formidable challenge due to high reactivity arising from the unpaired electron. Matching radical ligands with metal ions to engender magnetic coupling is crucial for eliciting preeminent physical properties such as conductivity and magnetism that are crucial for future technologies. The metal-radical approach is especially important for the lanthanide ions exhibiting deeply buried 4f-orbitals. The radicals must possess a high spin density on the donor atoms to promote strong coupling. Combining diamagnetic 89 Y ( I = 1/2) with organic radicals allows for invaluable insight into the electronic structure and spin-density distribution. This approach is hitherto underutilized, possibly owing to the challenging synthesis and purification of such molecules. Herein, evidence of an unprecedented bisbenzimidazole radical anion (Bbim 3− ˙) along with its metalation in the form of an yttrium complex, [K(crypt-222)][(Cp* 2 Y) 2 (μ-Bbim˙)] is provided. Access of Bbim 3− ˙ was feasible through double-coordination to the Lewis acidic metal ion and subsequent one-electron reduction, which is remarkable as Bbim 2− was explicitly stated to be redox-inactive in closed-shell complexes. Two molecules containing Bbim 2− (1) and Bbim 3− ˙ (2), respectively, were thoroughly investigated by X-ray crystallography, NMR and UV/Vis spectroscopy. Electrochemical studies unfolded a quasi-reversible feature and emphasize the role of the metal centre for the Bbim redox-activity as neither the free ligand nor the Bbim 2− complex led to analogous CV results. Excitingly, a strong delocalization of the electron density through the Bbim 3− ˙ ligand was revealed via temperature-dependent EPR spectroscopy and confirmed through DFT calculations and magnetometry, rendering Bbim 3− ˙ an ideal candidate for single-molecule magnet design. 

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3. Thiophene‐Based Double Helices: Radical Cations with SOMO–HOMO Energy Level Inversion †

   https://doi.org/10.1111/php.13475  

   Rajca, Andrzej ; Shu, Chan ; Zhang, Hui ; Zhang, Sheng ; Wang, Hua ; Rajca, Suchada ( July 2021 , Photochemistry and Photobiology)

   We report relatively persistent, open‐shell thiophene‐based double helices, radical cations 1^•+‐TMS₁₂and 2^•+‐TMS₈. Closed‐shell neutral double helices, 1‐TMS₁₂and 2‐TMS₈, have nearly identical first oxidation potentials,E^+/0 ≈ +1.33 V, corresponding to reversible oxidation to their radical cations. The radical cations are generated, using tungsten hexachloride in dichloromethane (DCM) as an oxidant,E^+/0 ≈ +1.56 V. EPR spectra consist of a relatively sharp singlet peak with an unusually lowg‐value of 2.001–2.002, thus suggesting exclusive delocalization of spin density over π‐conjugated system consisting of carbon atoms only. DFT computations confirm these findings, as only negligible fraction of spin density is found on sulfur and silicon atoms and the spin density is delocalized over a single tetrathiophene moiety. For radical cation, 1^•+‐TMS₁₂, energy level of the singly occupied molecular orbital (SOMO) lies below the four highest occupied molecular orbitals (HOMOs), thus indicating the SOMO–HOMO inversion (SHI) and therefore, violating the Aufbau principle. 1^•+‐TMS₁₂has a half‐life of the order of only 5 min at room temperature. EPR peak intensity of 2^•+‐TMS₈, which does not show SHI, is practically unchanged over at least 2 h.

    

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4. Synthesis of Aldehydes by Organocatalytic Formylation Reactions of Boronic Acids with Glyoxylic Acid

   https://doi.org/10.1002/ange.201703127  

   Huang, He ; Yu, Chenguang ; Li, Xiangmin ; Zhang, Yongqiang ; Zhang, Yueteng ; Chen, Xiaobei ; Mariano, Patrick S. ; Xie, Hexin ; Wang, Wei ( June 2017 , Angewandte Chemie)

   Reported herein is a conceptually novel organocatalytic strategy for the formylation of boronic acids. New reactivity is engineered into the α‐amino‐acid‐forming Petasis reaction occurring between aryl boronic acids, amines, and glyoxylic acids to prepare aldehydes. The operational simplicity of the process and its ability to generate structurally diverse and valued aryl, heteroaryl, and α,β‐unsaturated aldehydes containing a wide array of functional groups, demonstrates the practical utility of the new synthetic strategy.

    

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5. Effects of Intra‐Base Pair Proton Transfer on Dissociation and Singlet Oxygenation of 9‐Methyl‐8‐Oxoguanine−1‐Methyl‐Cytosine Base‐Pair Radical Cations

   https://doi.org/10.1002/cphc.202300511  

   Moe, May Myat ; Tsai, Midas ; Liu, Jianbo ( October 2023 , ChemPhysChem)

   8‐Oxoguanosine is the most common oxidatively generated base damage and pairs with complementary cytidine within duplex DNA. The 8‐oxoguanosine−cytidine lesion, if not recognized and removed, not only leads to G‐to‐T transversion mutations but renders the base pair being more vulnerable to the ionizing radiation and singlet oxygen (¹O₂) damage. Herein, reaction dynamics of a prototype Watson−Crick base pair [9MOG ⋅ 1MC]⋅⁺, consisting of 9‐methyl‐8‐oxoguanine radical cation (9MOG⋅⁺) and 1‐methylcystosine (1MC), was examined using mass spectrometry coupled with electrospray ionization. We first detected base‐pair dissociation in collisions with the Xe gas, which provided insight into intra‐base pair proton transfer of 9MOG⋅⁺ ⋅ 1MC[9MOG − H_N1]⋅ ⋅ [1MC+H_N3′]⁺and subsequent non‐statistical base‐pair separation. We then measured the reaction of [9MOG ⋅ 1MC]⋅⁺with¹O₂, revealing the two most probable pathways, C5‐O₂addition and H_N7‐abstraction at 9MOG. Reactions were entangled with the two forms of 9MOG radicals and base‐pair structures as well as multi‐configurations between open‐shell radicals and¹O₂(that has a mixed singlet/triplet character). These were disentangled by utilizing approximately spin‐projected density functional theory, coupled‐cluster theory and multi‐referential electronic structure modeling. The work delineated base‐pair structural context effects and determined relative reactivity toward¹O₂as [9MOG − H]⋅>9MOG⋅⁺>[9MOG − H_N1]⋅ ⋅ [1MC+H_N3′]⁺≥9MOG⋅⁺ ⋅ 1MC.

    

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