Palladium Hydride as a Reference Electrode in Aprotic Solutions

Abstract: The results of a variety of electrochemical tests indicate palladium hydride (β-PdH) functions as a thermodynamic reference electrode in three aprotic solutions containing H 2(g) and solvents of dichloromethane, dimethylsulfoxide, and acetonitrile. For enhanced electrical conductivity all solutions contained 0.2 M of an ionic liquid, 1-methyl-3-butyl imidazolium tetrafluoroborate. As is required of all thermodynamic reference electrodes (i) the potential of β-PdH was stable, (ii) its small amplitude anodic and… Show more

“…However, this conflicts with the Nernst equation (see eqn. S7), which essentially demands the opposite [39]. Interestingly, we are not the first to discover "anti-Nernst" behavior, as similar observations have recently been reported by Patrick et al for a PdH RE in aprotic solventbased electrolytes upon increasing the hydrogen pressure, i. e., from ~0.04 to ~1.01 bar.…”

“…As described above, the Mini Hydro-Flex ® RE is also comprised of Pd [35], which exhibits a strong solubility towards H 2 , that is up to ~1000 times its volume of dissolved hydrogen within the crystal structure [39][40][41][42]. Such formed palladium hydride (PdH) is capable of providing hydrogen cations and thus establishing a reversible hydrogen electrode even in aprotic solution [39,43]. Meanwhile, the applicability of PdH and the Mini HydroFlex ® as reference electrode in aprotic organic solvents has been demonstrated by Patrick et al [39].…”

“…The GDE consists of a (platinized) Pt mesh incorporated with palladium (Pd) and PTFE, which is immersed in the electrolyte solution [35]. While this satisfies the principles of a (reversible) hydrogen reference electrode (RHE) in aqueous electrolyte solutions, that is the hydrogen redox reaction (H + (aq) + 1e À * * 0.5H 2(g) ) on Pt eventually establishing the equilibrium potential (i. e., 0.000 V vs. RHE) for measurements at given pH [36][37][38], this is not valid in aprotic organic solvents [39]. As described above, the Mini Hydro-Flex ® RE is also comprised of Pd [35], which exhibits a strong solubility towards H 2 , that is up to ~1000 times its volume of dissolved hydrogen within the crystal structure [39][40][41][42].…”

“…Such formed palladium hydride (PdH) is capable of providing hydrogen cations and thus establishing a reversible hydrogen electrode even in aprotic solution [39,43]. Meanwhile, the applicability of PdH and the Mini HydroFlex ® as reference electrode in aprotic organic solvents has been demonstrated by Patrick et al [39]. and Gaskatel [44], respectively.…”

“…RHE) for measurements at given pH [36–38], this is not valid in aprotic organic solvents [39]. As described above, the Mini HydroFlex® RE is also comprised of Pd [35], which exhibits a strong solubility towards H 2 , that is up to ~1000 times its volume of dissolved hydrogen within the crystal structure [39–42]. Such formed palladium hydride (PdH) is capable of providing hydrogen cations and thus establishing a reversible hydrogen electrode even in aprotic solution [39, 43].…”

Design of a flexible but robust setup for temperature‐dependent electrochemistry down to cryogenic temperatures

“…However, this conflicts with the Nernst equation (see eqn. S7), which essentially demands the opposite [39]. Interestingly, we are not the first to discover "anti-Nernst" behavior, as similar observations have recently been reported by Patrick et al for a PdH RE in aprotic solventbased electrolytes upon increasing the hydrogen pressure, i. e., from ~0.04 to ~1.01 bar.…”

“…As described above, the Mini Hydro-Flex ® RE is also comprised of Pd [35], which exhibits a strong solubility towards H 2 , that is up to ~1000 times its volume of dissolved hydrogen within the crystal structure [39][40][41][42]. Such formed palladium hydride (PdH) is capable of providing hydrogen cations and thus establishing a reversible hydrogen electrode even in aprotic solution [39,43]. Meanwhile, the applicability of PdH and the Mini HydroFlex ® as reference electrode in aprotic organic solvents has been demonstrated by Patrick et al [39].…”

“…The GDE consists of a (platinized) Pt mesh incorporated with palladium (Pd) and PTFE, which is immersed in the electrolyte solution [35]. While this satisfies the principles of a (reversible) hydrogen reference electrode (RHE) in aqueous electrolyte solutions, that is the hydrogen redox reaction (H + (aq) + 1e À * * 0.5H 2(g) ) on Pt eventually establishing the equilibrium potential (i. e., 0.000 V vs. RHE) for measurements at given pH [36][37][38], this is not valid in aprotic organic solvents [39]. As described above, the Mini Hydro-Flex ® RE is also comprised of Pd [35], which exhibits a strong solubility towards H 2 , that is up to ~1000 times its volume of dissolved hydrogen within the crystal structure [39][40][41][42].…”

“…Such formed palladium hydride (PdH) is capable of providing hydrogen cations and thus establishing a reversible hydrogen electrode even in aprotic solution [39,43]. Meanwhile, the applicability of PdH and the Mini HydroFlex ® as reference electrode in aprotic organic solvents has been demonstrated by Patrick et al [39]. and Gaskatel [44], respectively.…”

“…RHE) for measurements at given pH [36–38], this is not valid in aprotic organic solvents [39]. As described above, the Mini HydroFlex® RE is also comprised of Pd [35], which exhibits a strong solubility towards H 2 , that is up to ~1000 times its volume of dissolved hydrogen within the crystal structure [39–42]. Such formed palladium hydride (PdH) is capable of providing hydrogen cations and thus establishing a reversible hydrogen electrode even in aprotic solution [39, 43].…”

Design of a flexible but robust setup for temperature‐dependent electrochemistry down to cryogenic temperatures

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