NANOFOAM 2017 Results

Main activities and results 2017

WP 2: Functionalization of the 3D metallic nanofoams

Task 2.2 – Functional electrodes for hydrogen production Objective: surface functionalization for H₂production through: (i) deposition of Pd /Pt clusters by electroless or electrochemical routes onto Ni and Ni alloy foams; (ii) formation of porous Ni(OH)₂ surfaces by oxidising the metallic Ni foams structures; (iii) formation of polpyrrole (PPy) clustered films onto the Ni and Ni alloys foams

Pd/Pt surface functionalisation of porous Ni and Ni-Mo alloy structures

**SEM micrographs of Ni-Pd alloy foam (1 wt. % Pd) electrodeposited at 25^oC for 3 min. (c.d. = 1 A/cm²) and EDX maps showing the distribution proﬁles of elements within the deposited alloy**

The addition of PdCl₂ in the electroforming electrolyte facilitates the co-deposition of Pd, while keeping the porous morphology of genuine Ni foam. Pd element is quite uniformly distributed within the alloy deposit. Usually the Pd content was in the range of 0.3-3 wt.% with higher values on the increase of Pd concentration in the electrolyte or of the applied current density.

EDX maps showing the distribution proﬁles of elements for Ni-Mo alloy electrodeposited onto NiPd_f
(0.5 % Pd) at 60^oC for 20 min. (c.d = 4 A/dm²)

EDX maps showing the distribution proﬁles of elements for Pt functionalized 3D Nif substrate (0.2 wt.% Pt) obtained by electrochemical deposition (90^oC, 6.5 A dm^-2, 5 min.)

Formation of porous Ni(OH)₂ surfaces

Formation of polpyrrole (PPy) clustered films onto the Ni and Ni alloys foams

SEM micrographs of PPy layer onto Ni_f (a,b) and NiW/Ni_f obtained through electrochemical polymerization involving 0.1M pyrrole in 0.5M H₂SO₄

WP 5 – Electrochemical performance of metallic nanofoams as electrodes for hydrogen production

Comparative linear polarization curves of HER in seawater for different systems of Pd functionalized Ni foams (a), NiMo/ Ni foams (b) and of Pt functionalized Ni foams (c)

The HER activity of Ni_f may be enhanced through Pd surface modification. The corresponding Tafel slopes for NiPd_f and Pd_chem/Ni_f are of 123 and 120 mV.dec^-1, respectively, suggesting that the HER process obeys Volmer reaction mechanism. The higher value of Ni_f may be related to the presence of oxides films on the surface. The Pd functionalization of Ni-Mo alloy based systems determines only a slight improvement of the catalytic activity. The significant effect is mainly due to the presence of Mo as alloying element. The determined Tafel slope values ranged from 118 to 105 mV.dec^-1, indicating the Volmer step as rate determining step.

Pt surface modification provides moderate performance against HER as compared to Pd in the case of seawater electrolyte. However Pt improved the HER activity when 1M KOH alkaline electrolyte has been involved, materialized by exchange current values of one order of magnitude higher.