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1. Clarifying the structures of imidines: using crystallographic characterization to identify tautomers and localized systems of π-bonding

   https://doi.org/10.1107/S2053229623002036  

   Aristov, Michael M.; Geng, Han; Harris, James W.; Berry, John F. (April 2023, Acta Crystallographica Section C Structural Chemistry)

   Nitrogen heterocycles are a class of organic compounds with extremely versatile functionality. Imidines, HN[C(NH) R ] 2 , are a rare class of heterocycles related to imides, HN[C(O) R ] 2 , in which the O atoms of the carbonyl groups are replaced by N—H groups. The useful synthesis of the imidine compounds succinimidine and glutarimidine, as well as their partially hydrolyzed imino–imide congeners, was first described in the mid-1950s, though structural characterization is presented for the first time in this article. In the solid state, these structures are different from the proposed imidine form: succinimidine crystallizes as an imino–amine, 2-imino-3,4-dihydro-2 H -pyrrol-5-amine, C 4 H 7 N 2 ( 1 ), glutarimidine as 6-imino-3,4,5,6-tetrahydropyridin-2-amine methanol monosolvate, C 5 H 9 N 3 ·CH 3 OH ( 2 ), and the corresponding hydrolyzed imino–imide compounds as amino–amides 5-amino-3,4-dihydro-2 H -pyrrol-2-one, C 4 H 6 N 2 O ( 3 ), and 6-amino-4,5-dihydropyridin-2(3 H )-one, C 5 H 8 N 2 O ( 4 ). Imidine 1 was also determined as the hydrochloride salt solvate 5-amino-3,4-dihydro-2 H -pyrrol-2-iminium chloride–2-imino-3,4-dihydro-2 H -pyrrol-5-amine–water (1/1/1), C 4 H 8 N 3 + ·Cl − ·C 4 H 7 N 3 ·H 2 O ( 1 ·HCl). As such, 1 and 2 show alternating short and long C—N bonds across the molecule, revealing distinct imino (C=NH) and amine (C—NH 2 ) groups throughout the C—N backbone. These structures provide definitive evidence for the predominant imino–amine tautomer in the solid state, which serves to enrich the previously proposed imidine-focused structures that have appeared in organic chemistry textbooks since the discovery of this class of compounds in 1883. 

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2. Dynamical stabilization in delafossite nitrides for solar energy conversion

   https://doi.org/10.1039/c8ta07536k  

   Szymanski, N. J.; Walters, L. N.; Hellman, O.; Gall, D.; Khare, S. V. (October 2018, Journal of Materials Chemistry A)

   Delafossite structured ternary nitrides, ABN 2 , have been of recent experimental investigation for applications such as tandem solar and photoelectrochemical cells. We present a thorough first principles computational investigation of their stability, electronic structure, and optical properties. Nine compounds, where A = Cu, Ag, Au and B = V, Nb, Ta, were studied. For three of these compounds, CuTaN 2 , CuNbN 2 , and AgTaN 2 , our computations agree well with experimental results. Optimized lattice parameters, formation energies, and mechanical properties have been computed using the generalized gradient approximation (GGA). Phonon density of states computed at zero-temperature shows that all compounds are dynamically unstable at low temperatures. Including finite-temperature anharmonic effects stabilizes all compounds at 300 K, with the exception of AgVN 2 . Analysis of Crystal Orbital Hamiltonian Populations (COHP) provides insight into the bonding and antibonding characters of A–N and B–N pairs. Instability at low temperatures can be attributed to strong A–N antibonding character near the Fermi energy. B–N bonding is found to be crucial in maintaining stability of the structure. AgVN 2 is the only compound to display significant B–N antibonding below the Fermi energy, as well as the strongest degree of A–N antibonding, both of which provide explanation for the sustained instability of this compound up to 900 K. Hybrid functional calculations of electronic and optical properties show that real static dielectric constants in the semiconductors are related to corresponding band gaps through the Moss relation. CuTaN 2 , CuNbN 2 , AgTaN 2 , AgNbN 2 , AgVN 2 , AuTaN 2 , and AuNbN 2 exhibit indirect electronic band gaps while CuVN 2 and AuVN 2 are metallic. Imaginary parts of the dielectric function are characterized by d–d interband transitions in the semiconductors and d–d intraband transitions in the metals. Four compounds, CuTaN 2 , CuNbN 2 , AgTaN 2 , and AgNbN 2 , are predicted to exhibit large light absorption in the range of 1.0 to 1.7 eV, therefore making these materials good candidates for solar-energy conversion applications. Two compounds, AuTaN 2 and AuNbN 2 , have band gaps and absorption onsets near the ideal range for obtaining high solar-cell conversion efficiency, suggesting that these compounds could become potential candidates as absorber materials in tandem solar cells or for band-gap engineering by alloying. 

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3. Photocatalytic Hydrophosphination Using Calcium Precatalysts

   https://doi.org/10.1002/chem.202500223  

   Moniruzzaman, Moniruzzaman; Jheng, Nai‐Yuan; Waterman, Rory (April 2025, Chemistry – A European Journal)

   Abstract Hydrophosphination using calcium compounds as catalysts under irradiation is described as a foray into s‐block photocatalysis. Transition‐metal compounds have been highly successful hydrophosphination catalysts under photochemical conditions, utilizing substrates previously considered inaccessible. A calcium hydrophosphination precatalyst, Ca(nacnac) (THF) (N(SiMe₃)₂) (1, nacnac = HC[(C(Me)N‐2,6‐ⁱPr₂C₆H₃)]₂), reported by Barrett and Hill, as well as the presumed intermediate, Ca(nacnac) (THF) (PPh₂) (2), and the Schlenk equilibrium product, Ca[N(SiMe₃)₂]₂(THF)₂(3) were screened under photochemical conditions with a range of unsaturated substrates including styrenic alkenes, Michael acceptors, and dienes with modest to excellent conversions, though unactivated alkenes were inaccessible. All compounds exhibit enhanced catalysis under irradiation by light emitting diode (LED)‐generated blue light. Nacnac‐supported compounds generate radicals as evidenced by Electron Paramagnetic Resonance (EPR) spectroscopy and radical trapping reactions, whereas unsupported calcium compounds are EPR silent and appear to undergo hydrophosphination akin to thermal reactions with these compounds. These results buttress the notion that photoactivation of π‐basic ligands is a broad phenomenon, extending beyond the d‐block, but like d‐block metals, consideration of ancillary ligands is essential to avoid radical reactivity. 

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4. Concept of Utilizing Ionic Liquids for the Co‐electroreduction of Carbon Dioxide and Nitrogen‐containing Compounds

   https://doi.org/10.1002/cctc.202400966  

   Gurkan, Burcu; Dongare, Saudagar; Kagan_Coskun, Oguz (July 2024, ChemCatChem)

   Formation of C‐N bonds through the electrochemical utilization of CO2 and nitrogen containing compounds (N‐compounds) is appealing for the purpose of converting waste and readily available sources or pollutants into value added chemicals at ambient conditions. Existing research predominantly explores these electrochemical reactions independently, often in aqueous electrolytes, leading to challenges associated with competitive hydrogen evolution reaction (HER), low product selectivity, and yield. Functional electrolytes such as those containing ionic liquids (ILs) present selective solubility to the solute reactants and present unique interactions with the electrode surface that can suppress the undesired side reaction HER while simultaneously co‐catalyzing the conversion of CO2 and N‐compounds such as N2, NO, NO2, andNO3. In this concept paper, we discuss how the microenvironment enabled by ILs can be  leveraged to stabilize reaction intermediates at the electrode‐electrolyte interface, thereby promoting C‐N bond formation on an active electrode surface at reduced overpotential, with the case study of CO2 and N‐compounds co‐catalysis to generate urea. 

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5. The role of alanine synthesis and nitrate‐induced nitric oxide production during hypoxia stress in Cucurbita pepo nectaries

   https://doi.org/10.1111/tpj.15055  

   Solhaug, Erik M.; Roy, Rahul; Venterea, Rodney T.; Carter, Clay J. (November 2020, The Plant Journal)

   SUMMARY Floral nectar is a sugary solution produced by nectaries to attract and reward pollinators. Nectar metabolites, such as sugars, are synthesized within the nectary during secretion from both pre‐stored and direct phloem‐derived precursors. In addition to sugars, nectars contain nitrogenous compounds such as amino acids; however, little is known about the role(s) of nitrogen (N) compounds in nectary function. In this study, we investigated N metabolism inCucurbita pepo(squash) floral nectaries in order to understand how various N‐containing compounds are produced and determine the role of N metabolism in nectar secretion. The expression and activity of key enzymes involved in primary N assimilation, including nitrate reductase (NR) and alanine aminotransferase (AlaAT), were induced during secretion inC. peponectaries. Alanine (Ala) accumulated to about 35% of total amino acids in nectaries and nectar during peak secretion; however, alteration of vascular nitrate supply had no impact on Ala accumulation during secretion, suggesting that nectar(y) amino acids are produced by precursors other than nitrate. In addition, nitric oxide (NO) is produced from nitrate and nitrite, at least partially by NR, in nectaries and nectar. Hypoxia‐related processes are induced in nectaries during secretion, including lactic acid and ethanolic fermentation. Finally, treatments that alter nitrate supply affect levels of hypoxic metabolites, nectar volume and nectar sugar composition. The induction of N metabolism inC. peponectaries thus plays an important role in the synthesis and secretion of nectar sugar. 

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