His primary areas of study are Analytical chemistry, Cathode, Anode, Oxide and Conductivity. His Analytical chemistry research is multidisciplinary, incorporating elements of Doping, Dopant, Ionic conductivity, Dielectric spectroscopy and Mineralogy. His study focuses on the intersection of Anode and fields such as Electrolyte with connections in the field of Inorganic chemistry and Lanthanum.
His studies in Inorganic chemistry integrate themes in fields like Ceramic and Hydrogen fuel. Pedro Núñez undertakes multidisciplinary investigations into Conductivity and Sintering in his work. His study looks at the relationship between Sintering and topics such as Grain boundary, which overlap with Activation energy.
Pedro Núñez spends much of his time researching Analytical chemistry, Conductivity, Inorganic chemistry, Mineralogy and Dielectric spectroscopy. The study incorporates disciplines such as Ion, Partial pressure, Doping and Ceramic in addition to Analytical chemistry. Pedro Núñez combines subjects such as Electrolyte, Catalysis, Calcination and Copper with his study of Inorganic chemistry.
His Electrolyte study incorporates themes from Oxygen permeability, Oxide, Anode and Thermal expansion. His Mineralogy study integrates concerns from other disciplines, such as Solid oxide fuel cell, Atmospheric temperature range and Phase. His work in Dielectric spectroscopy covers topics such as Differential scanning calorimetry which are related to areas like Phase transition.
His scientific interests lie mostly in Conductivity, Inorganic chemistry, Analytical chemistry, Solid solution and Crystal structure. His Inorganic chemistry study combines topics from a wide range of disciplines, such as Hydrogen, Sintering, Catalysis, Copper and Nanocrystalline material. The study incorporates disciplines such as Ion, Samarium, Doping and Grain boundary in addition to Analytical chemistry.
His Grain boundary study combines topics in areas such as Phase, Ceramic and Crystallite. His research investigates the link between Solid solution and topics such as Oxide that cross with problems in Combustion, Temperature-programmed reduction, Composite material, Electrolyte and Ytterbium. His work on Solid oxide fuel cell as part of general Electrolyte study is frequently connected to Open-circuit voltage, therefore bridging the gap between diverse disciplines of science and establishing a new relationship between them.
His primary areas of investigation include Inorganic chemistry, Catalysis, Selectivity, Calcination and Hydrogen. His Inorganic chemistry research incorporates themes from Photocatalysis, Water splitting, Magnetic susceptibility, Analytical chemistry and Copper. His work carried out in the field of Copper brings together such families of science as Crystallography, Carboxylate, Mesoxalic acid and Hydronium.
He combines subjects such as Reagent, Atmospheric temperature range, Methanol and Activation energy with his study of Hydrogen. While the research belongs to areas of X-ray photoelectron spectroscopy, Pedro Núñez spends his time largely on the problem of Fluorite, intersecting his research to questions surrounding Ceramic. His research in Ceramic intersects with topics in Proton conductor, Grain boundary, Mineralogy, Phase stability and Phase formation.
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On the simultaneous use of La0.75Sr0.25Cr0.5Mn0.5O3−δ as both anode and cathode material with improved microstructure in solid oxide fuel cells
Juan Carlos Ruiz-Morales;Jesús Canales-Vázquez;Juan Peña-Martínez;David Marrero López.
Electrochimica Acta (2006)
Dopant distribution in a Tm3+–Yb3+ codoped silica based glass ceramic: An infrared-laser induced upconversion study
F. Lahoz;I. R. Martı́n;J. Méndez-Ramos;P. Núñez.
Journal of Chemical Physics (2004)
Stability, chemical compatibility and electrochemical performance of GdBaCo2O5 + x layered perovskite as a cathode for intermediate temperature solid oxide fuel cells
A. Tarancón;A. Tarancón;J. Peña-Martínez;D. Marrero-López;A. Morata.
Solid State Ionics (2008)
New crystal structure and characterization of lanthanum tungstate "La6WO12" prepared by freeze-drying synthesis.
Anna Magrasó;Anna Magrasó;Carlos Frontera;David Marrero-López;David Marrero-López;Pedro Núñez.
Dalton Transactions (2009)
The effect of cobalt oxide sintering aid on electronic transport in Ce0.80Gd0.20O2−δ electrolyte
D.P Fagg;J.C.C Abrantes;D Pérez-Coll;P Núñez.
Electrochimica Acta (2003)
Influence of rare-earth doping on the microstructure and conductivity of BaCe0.9Ln0.1O3−δ proton conductors
M. Amsif;D. Marrero-Lopez;J.C. Ruiz-Morales;S.N. Savvin.
Journal of Power Sources (2011)
Effect of phase transition on high-temperature electrical properties of GdBaCo2O5 + x layered perovskite
A. Tarancón;A. Tarancón;D. Marrero-López;J. Peña-Martínez;J.C. Ruiz-Morales.
Solid State Ionics (2008)
Electrical conductivity and redox stability of La2Mo2−xWxO9 materials
D. Marrero-López;J. Canales-Vázquez;J.C. Ruiz-Morales;J.T.S. Irvine.
Electrochimica Acta (2005)
Grain boundary conductivity of Ce0.8Ln0.2O2−δ ceramics (Ln = Y, La, Gd, Sm) with and without Co-doping
D. Pérez-Coll;D. Marrero-López;P. Núñez;S. Piñol.
Electrochimica Acta (2006)
Fe-substituted (La,Sr)TiO3 as potential electrodes for symmetrical fuel cells (SFCs)
Jesús Canales-Vázquez;Jesús Canales-Vázquez;Juan Carlos Ruiz-Morales;David Marrero-López;Juan Peña-Martínez.
Journal of Power Sources (2007)
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