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1. Non‐Oxidative Dehydroaromatization of Linear Alkanes on Intermetallic Nanoparticles

   https://doi.org/10.1002/cctc.202401263  

   Behera, Ranjan_K; Lamkins, Andrew_R; Chen, Minda; Maligal‐Ganesh, Raghu_V; Yu, Jiaqi; Huang, Wenyu (October 2024, ChemCatChem)

   Abstract There has been significant interest in developing new catalytic systems to convert linear chain alkanes into olefins and aromatics. In the case of higher alkanes (≥C₆), the production of aromatic compounds such as benzene‐toluene‐xylenes is highly desirable. However, as the length of the carbon chain increases, the dehydrogenation process becomes more complex, not only due to the challenges of C−H activation but also the need for selectivity towards the desired products by the possibility of side reactions such as isomerization and cracking. Here, we present a detailed analysis of the dehydroaromatization of n‐hexane, n‐heptane, and n‐octane, using PtSn intermetallic nanoparticles supported on SBA‐15 as the catalyst. Throughin situspectroscopic and kinetic analysis, we have probed the reaction kinetics and catalyst deactivation, and provided a mechanistic understanding of the dehydroaromatization process on the surface of the PtSn intermetallic nanoparticles. Introducing Sn has been shown to be crucial not only for enhancement of catalytic activity, but also for higher aromatics selectivity and stability on stream. Furthermore, the analysis of dehydroaromatization reaction rates of reactant and possible intermediates indicates that the dehydroaromatization of n‐hexane to benzene likely proceeds through initial dehydrogenation steps followed by ring closing. 

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2. Directed gas-phase preparation of the elusive phosphinosilylidyne (SiPH ₂ , X ² A′′) and cis / trans phosphinidenesilyl (HSiPH; X ² A′) radicals under single-collision conditions

   https://doi.org/10.1039/D1CP02812J  

   He, Chao; Goettl, Shane J.; Yang, Zhenghai; Doddipatla, Srinivas; Kaiser, Ralf I.; Silva, Mateus Xavier; Galvão, Breno R. (September 2021, Physical Chemistry Chemical Physics)

   The reaction of the D1-silylidyne radical (SiD; X 2 Π) with phosphine (PH 3 ; X 1 A 1 ) was conducted in a crossed molecular beams machine under single collision conditions. Merging of the experimental results with ab initio electronic structure and statistical Rice–Ramsperger–Kassel–Marcus (RRKM) calculations indicates that the reaction is initiated by the barrierless formation of a van der Waals complex (i0) as well as intermediate (i1) formed via the barrierless addition of the SiD radical with its silicon atom to the non-bonding electron pair of phosphorus of the phosphine. Hydrogen shifts from the phosphorous atom to the adjacent silicon atom yield intermediates i2a, i2b, i3; unimolecular decomposition of these intermediates leads eventually to the formation of trans / cis -phosphinidenesilyl (HSiPH, p2/p4) and phosphinosilylidyne (SiPH 2 , p3) via hydrogen deuteride (HD) loss (experiment: 80 ± 11%, RRKM: 68.7%) and d - trans / cis -phosphinidenesilyl (DSiPH, p2′/p4′) plus molecular hydrogen (H 2 ) (experiment: 20 ± 7%, RRKM: 31.3%) through indirect scattering dynamics via tight exit transition states. Overall, the study reveals branching ratios of p2/p4/p2′/p4′ ( trans / cis HSiPH/DSiPH) to p3 (SiPH 2 ) of close to 4 : 1. The present study sheds light on the complex reaction dynamics of the silicon and phosphorous systems involving multiple atomic hydrogen migrations and tight exit transition states, thus opening up a versatile path to access the previously elusive phosphinidenesilyl and phosphinosilylidyne doublet radicals, which represent potential targets of future astronomical searches toward cold molecular clouds (TMC-1), star forming regions (Sgr(B2)), and circumstellar envelopes of carbon rich stars (IRC + 10216). 

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3. Elucidating the essential role of hydrogen bonding and direct H-transfer in transfer hydrogenation on transition metal catalysts

   https://doi.org/10.1039/D5CY00238A  

   Li, Aojie; Rangarajan, Srinivas (June 2025, Catalysis Science & Technology)

   Catalytic transfer hydrogenation (CTH) employs organic hydrogen donors such as alcohols and formic acid as hydrogen source, enabling a more sustainable process at milder conditions compared to conventional hydrogenation use molecular hydrogen gas. 

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4. Preserving the symmetry of cis -1,2-difluoroethylene in the gas-phase heterodimer with hydrogen chloride: A microwave rotational study revealing a novel structure

   https://doi.org/10.1063/5.0231236  

   Leung, Helen O; Marshall, Mark D (September 2024, The Journal of Chemical Physics)

   The microwave spectra of three isotopologues of the gas-phase heterodimer formed between cis-1,2-difluoroethylene and hydrogen chloride are obtained in the 5–21 GHz region using Fourier transform microwave spectroscopy. The molecular structure, determined from the analysis of the spectra and supported by quantum chemistry calculations, has the hydrogen atom of the hydrogen chloride molecule interacting with both fluorine atoms of the fluoroethylene and no interaction between the chlorine atom and the olefin. Although the equilibrium structure has two inequivalent H⋯F interactions, zero-point motion averages over the two equivalent choices for these interactions, rendering the pairs of like atoms (C, H, and F) of the fluoroethylene equivalent, retaining the C2v symmetry of the olefin. This results in only one unique singly substituted 13C isotopologue and in the observed effects on transition intensities due to nuclear spin statistics. The heterodimer structure allows for a strong, linear hydrogen bond between the HCl donor and the fluoroethylene acceptor that is more important here than in the analogous acetylene containing complex, where the interaction between the π electrons of acetylene and an electrophilic hydrogen atom on the olefin compensates for the loss of linearity required for binding to a geminal F/H pair. 

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5. Design principles for the synthesis of platinum–cobalt intermetallic nanoparticles for electrocatalytic applications

   https://doi.org/10.1039/d3cc00590a  

   Yu, Siying; Yang, Hong (April 2023, Chemical Communications)

   As the development of polymer electrolyte membrane fuel cells (PEMFCs) has sped up in recent years, producing active and durable electrocatalysts has become an increasingly important technical challenge. Platinum–cobalt (Pt–Co) alloy electrocatalyst has been commercially applied to hydrogen-powered fuel cell vehicles, and their intermetallic forms promise better durability, which is crucial to satisfy the 8000 h lifetime target of heavy-duty vehicles and other transportation options. In this feature article, we first present the atomically ordered structures of Pt–Co intermetallic, then discuss the thermodynamic and kinetic driving forces for making the PtCo-based intermetallic nanoparticles with desired structural attributes, followed by recent examples to illustrate how to achieve better control in composition, size, and shape. Discussion on the relationship between the key structural features and catalytic performance is focused on the application of Pt–Co intermetallic nanostructures as oxygen reduction reaction (ORR) electrocatalysts for hydrogen-powered PEMFCs. We emphasize specifically the importance of intermetallic structures for enhancing the durability and summarize the characterizations of their electrocatalytic performance in both three-electrode system and full cell studies. Finally, we provide our perspectives on the design, synthesis, characterization, and property studies of Pt–Co intermetallic nanoparticles as ORR electrocatalysts. This article should provide a new understanding on the design of ORR electrocatalytic applications using this class of intermetallics. 

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