2026-05-30T02:13:11Zhttps://riuma.uma.es/rest/oai/requestoai:riuma.uma.es:10630/286252026-05-04T10:26:35Zcom_10630_2254col_10630_37957
Microstructural tailoring of nanocomposite electrodes for solid oxide fuel cells
Zamudio-García, Javier
Ramírez-Losilla, Enrique
Pilas de combustible - Tesis doctorales
The results revealed that La0.98Cr0.75Mn0.25O3-δ-CGO and (La0.8Sr0.2)0.95Fe0.8Ti0.2O3-δ-CGO are promising
electrodes for symmetrical SOFCs with good electrochemical properties and durability in both oxidizing and
reducing atmospheres. In particular, La0.98Cr0.75Mn0.25O3-δ-CGO exhibits polarization resistance of 0.09 Ω cm2
at 700 ºC in H2, comparable to the state-of-the-art Ni-YSZ anode.
Nanocomposite active layers were also prepared by spray-pyrolysis deposition to improve the ORR activity of a
LSM cathode. Among the different compositions, LSM-CGO layers showed improved adherence and electrical
properties. The incorporation of this active layer enhances the ion transfer at the cathode/electrode interface and
also extended the ionic/electronic conducting paths for electrochemical reactions. A Ni-YSZ/YSZ/LSM-CGO/LSM
anode-supported cell showed a maximum power density of 1200 mW cm-2 at 800 ºC compared to 790 mW cm-2 for
the same cell without an active layer.
Vertically Aligned Nanostructures (VANs) of (La0.8Sr0.2)0.98Fe0.8Ti0.2O3−δ-CGO and
(Sr0.7Pr0.3)0.95Ti0.9Ni0.1O3−δ-CGO were prepared by PLD for their implementation as redox stable active layers
for SOFCs. The heteroepitaxial films exhibited long-range columnar architecture of 5 nm width. The VAN films
showed higher conductivity than that observed for the polycrystalline samples.
The high demand for electrical energy induced by the rapid population growth has arisen the necessity
to develop sustainable and environmentally friendly energy sources. In this context, fuel cells are one of the most
promising technologies to obtain electrical energy from a wide variety of fuels with good efficiencies and lower
emission of pollutants. In particular, Solid Oxide Fuel Cells (SOFCs) have attracted great attention in recent years
due to their fuel flexibility, good tolerance to impurities in the fuel and higher efficiencies.
However, the high operating temperatures of SOFCs (600-800 ºC) needed to achieve a good electrode performance
and a sufficient ionic conductivity for the electrolyte, negatively affect the long-term stability of these devices. For
this reason, decreasing the operating temperature is one of the main goals for the wide implementation of SOFCs. It
is well known that the crystal structure and composition of the electrodes play a key role in the electrochemical
performance; nevertheless, the microstructural optimization of the electrodes has demonstrated to be crucial to
boost the electrochemical properties at low operating temperatures in both oxidizing and reducing conditions.
In this PhD thesis, different nanostructured and nanocomposite electrode layers based on the combination of
perovskite-type electrodes, i.e. LaCrO3, SrTiO3 or LaFeO3 and the ionic conductor Ce0.9Gd0.1O1.95 (CGO) with
fluorite-type structure have been prepared and tested for their implementation in SSOFCs. The electrode layers
were prepared directly onto Zr0.84Y0.16O1.92 (YSZ) or La0.9Sr0.1Ga0.8Mg0.2O2.85 (LSGM) electrolytes by
spray-pyrolysis. Additionally, pulsed laser deposition (PLD) was employed for the preparation of active layers. For
comparison purposes, the same electrode compositions were prepared as powders from freeze-dried precursors
and then deposited onto the electrolyte by screen-printing method.
2024-01-11T08:57:51Z
2024-01-11T08:57:51Z
2024
2023
2023-05-04
doctoral thesis
https://hdl.handle.net/10630/28625
eng
http://creativecommons.org/licenses/by-nc-nd/4.0/
open access
Attribution-NonCommercial-NoDerivatives 4.0 Internacional
UMA Editorial