Seongho Yun scite author profile

Maximum atom efficiency as well as distinct chemoselectivity is expected for electrocatalysis on atomically dispersed (or single site) metal centres, but its realization remains challenging so far, because carbon, as the most widely used electrocatalyst support, cannot effectively stabilize them. Here we report that a sulfur-doped zeolite-templated carbon, simultaneously exhibiting large sulfur content (17 wt% S), as well as a unique carbon structure (that is, highly curved three-dimensional networks of graphene nanoribbons), can stabilize a relatively high loading of platinum (5 wt%) in the form of highly dispersed species including site isolated atoms. In the oxygen reduction reaction, this catalyst does not follow a conventional four-electron pathway producing H2O, but selectively produces H2O2 even over extended times without significant degradation of the activity. Thus, this approach constitutes a potentially promising route for producing important fine chemical H2O2, and also offers opportunities for tuning the selectivity of other electrochemical reactions on various metal catalysts.

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Cross-Linked “Poisonous” Polymer: Thermochemically Stable Catalyst Support for Tuning Chemoselectivity

Yun

Lee

Yook

et al. 2016

ACS Catal.

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Designed catalyst poisons can be deliberately added in various reactions for tuning chemoselectivity. In general, the poisons are "transient" selectivity modifiers that are readily leached out during reactions and thus should be continuously fed to maintain the selectivity. In this work, we supported Pd catalysts on a thermochemically stable crosslinked polymer containing diphenyl sulfide linkages, which can simultaneously act as a catalyst support and a "permanent" selectivity modifier. The entire surfaces of the Pd clusters were ligated (or poisoned) by sulfide groups of the polymer support. The sulfide groups capping the Pd surface behaved like a "molecular gate" that enabled exceptionally discriminative adsorption of alkynes over alkenes. H 2 /D 2 isotope exchange revealed that the capped Pd surface alone is inactive for H 2 (or D 2 ) dissociation, but in the presence of coflowing acetylene (alkyne), it becomes active for H 2 dissociation as well as acetylene hydrogenation. The results indicated that acetylene adsorbs on the Pd surface and enables cooperative adsorption of H 2 . In contrast, ethylene (alkene) did not facilitate H 2 −D 2 exchange, and hydrogenation of ethylene was not observed. The results indicated that alkynes can induce decapping of the sulfide groups from the Pd surface, while alkenes with weaker adsorption strength cannot. The discriminative adsorption of alkynes over alkenes led to highly chemoselective hydrogenation of various alkynes to alkenes with minimal overhydrogenation and the conversion of side functional groups. The catalytic functions can be retained over a long reaction period due to the high thermochemical stability of the polymer.

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ChemInform Abstract: Gas Phase Thermal Cis‐Trans Isomerization Reaction of 1‐Bromopropene.

Huh

Yun

et al. 1991

ChemInform

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ChemInform Abstract: Collisional Energy Transfer in Thermal Decomposition Reaction of 1,2‐Dichloropropane

Yun¹,

Jung²,

Kang³

1989

ChemInform

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Seongho Yun

Tuning selectivity of electrochemical reactions by atomically dispersed platinum catalyst

Cross-Linked “Poisonous” Polymer: Thermochemically Stable Catalyst Support for Tuning Chemoselectivity

ChemInform Abstract: Gas Phase Thermal Cis‐Trans Isomerization Reaction of 1‐Bromopropene.

ChemInform Abstract: Collisional Energy Transfer in Thermal Decomposition Reaction of 1,2‐Dichloropropane

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