Abstract
Hydrogen Evolution Reaction: Log j0 Versus Work Function Φ As Viewed from Transition State Theory As an Eyring Plot
Meeting abstracts (Electrochemical Society), Vol.MA2024-01(45), pp.2552-2552
08/09/2024
DOI: 10.1149/MA2024-01452552mtgabs
Abstract
In 1972, Trasatti correlated the log of the exchange current density (j0) for the hydrogen evolution reaction (HER) with the work functions of 31 metal electrodes to yield two parallel regression lines. [1] The lines are separated by Δ log j0 = 3. Thermodynamically, work function Φ is the energy to remove an electron from a metal to infinity. Perhaps counterintuitively, platinum group metals (PGMs) with the highest Φ sustain the highest j0 values.
The elementary, interfacial electron transfer occurs between the electrode and adsorbed hydrogen cation and adsorbed hydrogen atom.
H+ads + e ⇌ H●ads
A materials dependent rate expression is developed as follows. [2]
The properties of the metal are introduced explicitly into reaction mechanism, characterized by M(e) and M(0), the metal electrode with and without the electron.
M(e) + H+ads ⇄ M(0) + H●ads
Classical transition state theory (TST) characterizes the free energy of activation ΔG‡ as the energy difference between the transition state (TS) and the minimum energy of the reactants. The TS forms at equilibrium, where adsorbed hydrogen and metal electrode share the electron.
M(e) + H+ads ⇌ [M ●●● e ●●● Hads]‡ ⇌ M(0) + H●ads
Electrochemical potentials set the energy difference in the products and reactant, which sets ΔG‡. Chemical potential (𝞵) difference for the metal without and with the electron define Φ.
FΦ = 𝞵M(0) - 𝞵M(e)
FΦ is further defined as a chemical free energy that that lowers ΔG‡. FΦ is a material specific property that is atypically specified in the rate equation. Because log j0 ∝ - ΔG‡, and chemical free energy FΦ lowers ΔG‡, log j0 ∝ FΦ. Thus, j0 increases exponentially with FΦ, so PGMs with highest Φ sustain highest j0. Further, the rate expression embeds material specific property Φ.
The classical Eyring perspective for generic rate constant k' is k' = A' exp[-ΔG‡/RT]. Rate constant is typically determined by varying temperature in a plot of ln k' versus T-1, where ln k' = ln A' - ΔG‡/RT. For isothermal measurements, log j0 is linear with Φ because FΦ is a term ΔG‡chem that is a component in the total ΔG‡. For metals, where Φ > 0, FΦ always lowers ΔG‡ for HER; the total activation energy is lowered in proportion to FΦ. The slopes of log j0 versus Φ is proportional to 𝝰ΦFΦ/2.303, where partition coefficient 𝝰Φ characterizes ∂ΔG‡/∂Φ. For the parallel lines in Trasatti's plot, 𝝰Φ = 0.38. The intercepts are independent of Φ.
The material specific rate expressions derived from classical TST and electrochemical potentials may provide guidance on design of electrocatalysts and provide a path to integration of classical and contemporary modeling of important reaction processes such as HER.
Details
- Title: Subtitle
- Hydrogen Evolution Reaction: Log j0 Versus Work Function Φ As Viewed from Transition State Theory As an Eyring Plot
- Creators
- Kasun Saweendra Rathnatunga Dadallagei - University of IowaDaniel Parr - University of IowaNoel Buckley - University of LimerickJohna Leddy - University of Iowa
- Resource Type
- Abstract
- Publication Details
- Meeting abstracts (Electrochemical Society), Vol.MA2024-01(45), pp.2552-2552
- Publisher
- The Electrochemical Society, Inc
- DOI
- 10.1149/MA2024-01452552mtgabs
- ISSN
- 2151-2043
- eISSN
- 2151-2035
- Language
- English
- Date published
- 08/09/2024
- Academic Unit
- Chemistry
- Record Identifier
- 9984699516802771
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