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1. Asymmetric allylic substitution–isomerization to axially chiral enamides via hydrogen-bonding assisted central-to-axial chirality transfer

   https://doi.org/10.1039/D0SC02828B  

   Sun, Chao; Qi, Xiaotian; Min, Xiao-Long; Bai, Xue-Dan; Liu, Peng; He, Ying (September 2020, Chemical Science)

   null (Ed.)

   Axially chiral enamides bearing a N–C axis have been recently studied and were proposed to be valuable chiral building blocks, but a stereoselective synthesis has not been achieved. Here, we report the first enantioselective synthesis of axially chiral enamides via a highly efficient, catalytic approach. In this approach, C(sp 2 )–N bond formation is achieved through an iridium-catalyzed asymmetric allylation, and then in situ isomerization of the initial products through an organic base promoted 1,3-H transfer, leading to the enamide products with excellent central-to-axial transfer of chirality. Computational and experimental studies revealed that the 1,3-H transfer occurs via a stepwise deprotonation/re-protonation pathway with a chiral ion-pair intermediate. Hydrogen bonding interactions with the enamide carbonyl play a significant role in promoting both the reactivity and stereospecificity of the stepwise 1,3-H transfer. The mild and operationally simple formal N -vinylation reaction delivered a series of configurationally stable axially chiral enamides with good to excellent yields and enantioselectivities. 

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2. Electrocatalytic Nitrate Reduction for Denitrifying Wastewater

   https://doi.org/10.1149/MA2021-02521513mtgabs  

   Li, Wenzhen; Liu, Hengzhou; Park, Jaeryl; Chen, Yifu; Roling, Luke; Gu, Shuang (October 2021, ECS Meeting Abstracts)

   Removing excessive nitrate (NO3−) from wastewater has increasingly become an important research topic in light of the growing concerns over the related environmental problems and health issues. In particular, catalytic/electrocatalytic approaches are attractive for NO3− removal, because NO3− from wastewater can be converted to N2 and released back to the atmosphere using renewable H2 or electricity, closing the loop of the global N cycle. However, achieving high product selectivity towards the desirable N2 has proven challenging in the direct NO3−-to-N2 reaction. In this presentation, we will report our finding on unique and ultra-high electrochemical NO3−-to-NO2−activity on an oxide-derived silver electrode (OD-Ag). Up to 98% selectivity and 95% faradaic efficiency of NO2− were observed and maintained under a wide potential window. Benefiting from overcoming the rate-determining barrier of NO3−-to-NO2−during nitrate reduction, further reduction of accumulated NO2− to NH4+ can be well regulated by the cathodic potential on OD-Ag to achieve a faradaic efficiency of 89%. These indicated the potential controllable pathway to the key nitrate reduction products (NO2−or NH4+) on OD-Ag. DFT computations provided insights into the unique NO2−selectivity on Ag electrodes compared with Cu, showing the critical role of a proton-assisted mechanism. Based on the ultra-high NO3−-to-NO2−activity on OD-Ag, we designed a novel electrocatalytic-catalytic combined process for denitrifying real-world NO3−-containing agricultural wastewater, leading to 95+% of NO3− conversion to N2 with minimal NOX gases. In addition to the wastewater treatment process to N2 and electrochemical synthesis of NH3, NO2− derived from electrocatalytic NO3− conversion can serve as a reactive platform for distributed production of various nitrogen products. Our new research progress along this direction will be briefly presented. 

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3. Electrochemical Liquid‐Liquid‐Solid Growth of Ag‐In Crystals with Liquid Indium Alloy Electrodes

   https://doi.org/10.1002/celc.202400229  

   Wu, Henry; Hazelnis, Joshua_P; Maldonado, Stephen (June 2024, ChemElectroChem)

   Abstract Synthesis of intermetallic crystals by electrodeposition of Ag from alkaline aqueous electrolytes containing AgCN onto liquid metal electrodes via an electrochemical liquid‐liquid‐solid (ec‐LLS) process has been performed. X‐ray diffraction, scanning electron microscopy, and transmission electron microscopy were performed to identify crystalline products. Ec‐LLS experiments performed with pure liquid Hg and Ga electrodes resulted in the formation of polycrystalline Ag₂Ga and Ag₂Hg₃. Experiments performed with In‐containing liquid metals preferentially yielded Ag₉In₄and AgIn₂products with liquid Hg_0.35In_0.65and Ga_0.86In_0.14, respectively. The product distribution with liquid Hg_0.35In_0.65depended on the level of Ag supersaturation during the electrodeposition. A mechanism that accounts for the aforementioned observations is presented and discussed. This work described the formation of Ag−In intermetallic phases by the isothermal electroreduction of Ag into different liquid metal solvents via ec‐LLS. Electrodeposition of Ag into a pure Ga or pure Hg liquid metal pool yielded precisely the compounds predicted from isothermal cross‐sections of the respective binary phase diagrams. These compounds were not found when using liquid Hg or Ga containing appreciable In. The smaller enthalpy of formation for AgIn₂was consistent with its synthesis in Ga_0.86In_0.14. However, the observed product of Ag₉In₄in Hg‐containing liquid metals could not be rationalized solely from thermodynamic factors. Instead, this observation was consistent with a kinetic pathway based on the lability of Hg‐metal bonds and nearly identical crystal structures of Ag₉In₄and Ag₂Hg₃. Site exchange of Hg for In is consistent with our prior observations^[23]of In exchange into Hg−Pd structures during Pd electrodeposition. This mechanism is not based on any direct role of electrochemistry other than aspects that dictate the operative supersaturation of the metal solute. 

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4. Recent Applications of Asymmetric Organocatalytic Methods in Total Synthesis

   https://doi.org/10.1002/slct.202004196  

   Parella, Ramarao; Jakkampudi, Satish; Zhao, John_C‐G (March 2021, ChemistrySelect)

   Abstract Natural products are the great sources of drugs and leading compounds in drug discovery, as it has been estimated that most of the current medicines are derived from natural products. Total synthesis of natural products, especially those of biological activities, has been an important part of organic chemistry, which, besides its potential practical utilities, also provides new inspirations and novel synthetic methodologies. Over the past two decades, organocatalysis has been shown to be very effective in controlling the stereochemistry of the reaction products and has found many applications in the asymmetric synthesis of natural products and related compounds. In this review we will attempt to summarize some applications of asymmetric organocatalysis in the total synthesis of natural products and related compounds in the past seven years. 

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5. Sequential Iron-Catalyzed C(sp2)–C(sp3) Cross-Coupling of Chlorobenzamides/Chemoselective Amide Reduction and Reductive Deuteration to Benzylic Alcohols

   https://doi.org/10.3390/molecules28010223  

   Bisz, Elwira; Podchorodecka, Pamela; Li, Hengzhao; Ochędzan-Siodłak, Wioletta; An, Jie; Szostak, Michal (January 2023, Molecules)

   Benzylic alcohols are among the most important intermediates in organic synthesis. Recently, the use of abundant metals has attracted significant attention due to the issues with the scarcity of platinum group metals. Herein, we report a sequential method for the synthesis of benzylic alcohols by a merger of iron catalyzed cross-coupling and highly chemoselective reduction of benzamides promoted by sodium dispersion in the presence of alcoholic donors. The method has been further extended to the synthesis of deuterated benzylic alcohols. The iron-catalyzed Kumada cross-coupling exploits the high stability of benzamide bonds, enabling challenging C(sp2)–C(sp3) cross-coupling with alkyl Grignard reagents that are prone to dimerization and β-hydride elimination. The subsequent sodium dispersion promoted reduction of carboxamides proceeds with full chemoselectivity for the C–N bond cleavage of the carbinolamine intermediate. The method provides access to valuable benzylic alcohols, including deuterium-labelled benzylic alcohols, which are widely used as synthetic intermediates and pharmacokinetic probes in organic synthesis and medicinal chemistry. The combination of two benign metals by complementary reaction mechanisms enables to exploit underexplored avenues for organic synthesis. 

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