Journal
GREEN CHEMISTRY
Volume 22, Issue 19, Pages 6497-6509Publisher
ROYAL SOC CHEMISTRY
DOI: 10.1039/d0gc01636e
Keywords
-
Funding
- CTI Swiss Competence Center for Energy Research (SCCER Heat and Electricity Storage)
- Swiss Govt. Excellence Scholarship (ESKAS)
- Swiss National Science Foundation (SNSF) [200020_172507]
- Swiss National Science Foundation (SNF) [200020_172507] Funding Source: Swiss National Science Foundation (SNF)
Ask authors/readers for more resources
We present a novel, foam-type, high surface area electrocatalyst for the CO(2)reduction reaction (CO2RR) that is not only highly selective towardn-propanol (PrOH) formation (FEPrOH= 13.7%,j(PrOH)= -1.15 mA cm(-2)) at relatively low overpotentials (-0.65 Vvs.RHE) but also demonstrates an excellent long-term stability during CO(2)electrolysis experiments of 102 h in duration. A dynamic hydrogen bubble template approach is applied to electrodeposit a binary PdCu alloy foam yielding a nominal bulk composition of 9 at% Pd and 91 at% Cu (denoted as Pd9Cu91). The material is further modified by means of thermal annealing (12 h at 200 degrees C in air), which completely transforms the as-prepared metallic Pd(9)Cu(91)alloy foam into its oxidic state. The ultimate catalyst activation is achieved by subsequent reduction (at -0.65 Vvs.RHE for 45 min) of the oxidic precursors (composite of Cu2O, CuO, and CuPdO3) into metallic state, as indicated byoperandoRaman spectroscopy. Identical location scanning electron microscopy (IL-SEM) analysis, carried out prior to and after the activation treatments, demonstrates significant morphological alterations of the Pd(9)Cu(91)foam on the nm length scale, which go along with a phase segregation into nm-range Pd-rich and Cu-rich domains that helps to increase the PrOH selectivity. Time-dependent ICP-MS analyses of the electrolyte solution, carried out during the catalyst activation, demonstrate preferential (rapid) Cu dissolution followed by (slow) Cu redeposition on the catalyst surface. These processes are found to be superimposed on the actual oxide reduction. A two-fold selectivity of PrOH was observed over ethanol (EtOH). The excellent long-term stability of the activated Pd(9)Cu(91)foam catalyst is rationalized by the full suppression of the C1 hydrocarbon (methane) pathway. The improved product selectivity towards the highly valuable C3 alcohol is rationalized by an efficient and concerted spillover of chemisorbed carbon monoxide (*CO) and atomic hydrogen (*H) species from the Pd-rich domains to the activated Cu-rich domains of the oxide-derived Pd(9)Cu(91)foam catalyst where the C-C coupling and subsequent hydrogenation processes take place to form the targeted oxygenate product.
Authors
I am an author on this paper
Click your name to claim this paper and add it to your profile.
Reviews
Recommended
No Data Available