CO-Reductive and O2-Oxidative Annealing Assisted Surface Restructure and Corresponding Formic Acid Oxidation Performance of PdPt and PdRuPt Nanocatalysts

Abstract: Formic acid oxidation reaction (FAOR) at anode counterpart incurs at substantial high overpotential, limiting the power output efficiency of direct formic acid fuel cells (DFAFCs). Despite intense research, the lack of high-performance nanocatalysts (NCs) for FAOR remains a challenge in realizing DFAFC technologies. To surmount the overpotential losses, it is desirable to have NCs to trigger the FAOR as close to the reversible conditions (i.e. with over-potential loss as close to zero as possible). Herein, Pd-… Show more

“…The desired voltage to drive the maximum CO ads oxidation kinetics was represented by the positions of the CO ads oxidation peaks in a CO stripping curve. 61 In 0.5 mol L −1 FA, CO was permitted to adsorb on the surfaces of the bare-Pt, NiO x /Pt, FeO x /NiO x /Pt and a-FeO x /NiO x /Pt electrodes for 10 min at open circuit potential. The adsorbed CO layer was next stripped electrochemically (oxidatively) in 0.5 mol L −1 H 2 SO 4 at a potential scan rate of 50 mV s −1 , yielding the oxidation peaks displayed in Fig.…”

Tailor-designed nanowire-structured iron and nickel oxides on platinum catalyst for formic acid electro-oxidation

“…The desired voltage to drive the maximum CO ads oxidation kinetics was represented by the positions of the CO ads oxidation peaks in a CO stripping curve. 61 In 0.5 mol L −1 FA, CO was permitted to adsorb on the surfaces of the bare-Pt, NiO x /Pt, FeO x /NiO x /Pt and a-FeO x /NiO x /Pt electrodes for 10 min at open circuit potential. The adsorbed CO layer was next stripped electrochemically (oxidatively) in 0.5 mol L −1 H 2 SO 4 at a potential scan rate of 50 mV s −1 , yielding the oxidation peaks displayed in Fig.…”

Tailor-designed nanowire-structured iron and nickel oxides on platinum catalyst for formic acid electro-oxidation

“…In recent years, heterogeneous catalysts have attracted large interest for formic acid decomposition because of enhanced separability, reusability, and relatively low reaction temperatures (less than 80 • C). The heterogeneous catalysts Pd, Au, or Ag and their alloys have been commonly studied [4][5][6][7][8][9][10][11][12][13][14][15][16][17][18][19][20][21]. A variety of materials have additionally been investigated as catalyst supports for the dehydrogenation of formic acid, such as activated carbon [22][23][24], zeolites [16,25], amines [26][27][28][29], metal organic frameworks (MOFs) [11,13,30,31], and macroreticular resins [32][33][34].…”

Experimental and Process Modelling Investigation of the Hydrogen Generation from Formic Acid Decomposition Using a Pd/Zn Catalyst

Tunable synthesis of highly branched Pd nanodendrites for enhanced electrocatalysis