Ambarneil Saha scite author profile

Vicinal diamines are a common structural motif in bioactive natural products, therapeutic agents, and molecular catalysts, motivating the continuing development of efficient, selective, and sustainable technologies for their preparation. We report an operationally simple and environmentally friendly protocol that converts alkenes and sodium azide-both readily available feedstocks-to 1,2-diazides. Powered by electricity and catalyzed by Earth-abundant manganese, this transformation proceeds under mild conditions and exhibits exceptional substrate generality and functional group compatibility. Using standard protocols, the resultant 1,2-diazides can be smoothly reduced to vicinal diamines in a single step, with high chemoselectivity. Mechanistic studies are consistent with metal-mediated azidyl radical transfer as the predominant pathway, enabling dual carbon-nitrogen bond formation.

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Electrochemical Azidooxygenation of Alkenes Mediated by a TEMPO–N₃ Charge-Transfer Complex

Siu

et al. 2018

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We report a mild and efficient electrochemical protocol to access a variety of vicinally C–O and C–N difunctionalized compounds from simple alkenes. Detailed mechanistic studies revealed a distinct reaction pathway from those previously reported for TEMPO-mediated reactions. In this mechanism, electrochemically generated oxoammonium ion facilitates the formation of azidyl radical via a charge-transfer complex with azide, TEMPO–N3. DFT calculations together with spectroscopic characterization provided a tentative structural assignment of this charge-transfer complex. Kinetic and kinetic isotopic effect studies revealed that reversible dissociation of TEMPO–N3 into TEMPO• and azidyl precedes the addition of these radicals across the alkene in the rate-determining step. The resulting azidooxygenated product could then be easily manipulated for further synthetic elaborations. The discovery of this new reaction pathway mediated by the TEMPO+/TEMPO• redox couple may expand the scope of aminoxyl radical chemistry in synthetic contexts.

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Characterization of Reactive Organometallic Species via MicroED

et al. 2019

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Here we apply microcrystal electron diffraction (MicroED) to the structural determination of transition-metal complexes. We find that the simultaneous use of 300 keV electrons, very low electron doses, and an ultrasensitive camera allows for the collection of data without cryogenic cooling of the stage. This technique reveals the first crystal structures of the classic zirconocene hydride, colloquially known as “Schwartz’s reagent”, a novel Pd(II) complex not amenable to solution-state NMR or X-ray crystallography, and five other paramagnetic and diamagnetic transition-metal complexes.

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Electron Diffraction of 3D Molecular Crystals

2022

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Electron crystallography has a storied history which rivals that of its more established X-ray-enabled counterpart. Recent advances in data collection and analysis have sparked a renaissance in the field, opening a new chapter for this venerable technique. Burgeoning interest in electron crystallography has spawned innovative methods described by various interchangeable labels (3D ED, MicroED, cRED, etc.). This Review covers concepts and findings relevant to the practicing crystallographer, with an emphasis on experiments aimed at using electron diffraction to elucidate the atomic structure of threedimensional molecular crystals. CONTENTS 1. Introduction and Historical Background 13883 2. Theoretical Foundations 13884 2.1. Differences Between X-ray and Electron Scattering 13884 2.2. Differences Between X-ray and Electron Wavelengths 13886 2.3.

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Isolation and X-ray Crystal Structure of an Electrogenerated TEMPO–N₃ Charge-Transfer Complex

et al. 2021

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Recent advances in radical-based catalytic reactions have created an increasing demand for the understanding of their mechanistic underpinnings. Structural elucidation of transient reactive intermediates via diffraction techniques, though rarely possible, is one of the most decisive ways to support such mechanistic hypotheses. Here we present the isolation, structural elucidation, and theoretical analysis of an electrochemically generated and catalytically relevant charge-transfer species formed between the azidyl radical and (2,2,6,6-tetramethylpiperidin-1-yl)oxyl (TEMPO). The unusual bent N-N-N angle and the pancake bonding between these two fragments highlight the weak bonding interactions present in this complex. This X-ray structure validates computational predictions as well as mechanistic proposals of TEMPO-mediated radical azidation reactions. File list (3) download file view on ChemRxiv 02_SI_updated.pdf (4.34 MiB) download file view on ChemRxiv 01_MS.pdf (1.81 MiB)

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Ambarneil Saha

Metal-catalyzed electrochemical diazidation of alkenes

Electrochemical Azidooxygenation of Alkenes Mediated by a TEMPO–N₃ Charge-Transfer Complex

Characterization of Reactive Organometallic Species via MicroED

Electron Diffraction of 3D Molecular Crystals

Isolation and X-ray Crystal Structure of an Electrogenerated TEMPO–N₃ Charge-Transfer Complex

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About

Ambarneil Saha

Metal-catalyzed electrochemical diazidation of alkenes

Electrochemical Azidooxygenation of Alkenes Mediated by a TEMPO–N3 Charge-Transfer Complex

Characterization of Reactive Organometallic Species via MicroED

Electron Diffraction of 3D Molecular Crystals

Isolation and X-ray Crystal Structure of an Electrogenerated TEMPO–N3 Charge-Transfer Complex

Contact Info

Product

Resources

About

Electrochemical Azidooxygenation of Alkenes Mediated by a TEMPO–N₃ Charge-Transfer Complex

Isolation and X-ray Crystal Structure of an Electrogenerated TEMPO–N₃ Charge-Transfer Complex