2026 Fernando M.B. Marques: Materials Science Researcher – H-Index, Publications & Awards

Discipline name	D-Index	World Ranking	Current World Ranking	National Ranking	Current National Ranking	Publications	Citations
Materials Science	54	8869	8567	44	44	245	11054
Chemistry	54	12576	11320	103	99	227	10877

Overview

What is he best known for?

The fields of study he is best known for:

Oxygen
Hydrogen
Ion

Fernando M.B. Marques mainly investigates Ionic conductivity, Inorganic chemistry, Analytical chemistry, Conductivity and Oxygen. His Ionic conductivity research includes themes of Fast ion conductor, Ionic bonding, Oxygen permeability and Ceramic. His Ceramic study deals with Microstructure intersecting with Sintering and Mineralogy.

His studies deal with areas such as Oxide, Electrochemistry, Electrode and Solid oxide fuel cell as well as Inorganic chemistry. He interconnects Seebeck coefficient, Dielectric spectroscopy, Perovskite and Praseodymium in the investigation of issues within Analytical chemistry. His Conductivity research is multidisciplinary, incorporating elements of Thermal conduction and Lanthanum.

His most cited work include:

Transport properties of solid oxide electrolyte ceramics: a brief review (855 citations)
Ceria-based materials for solid oxide fuel cells (358 citations)
Ionic transport in oxygen-hyperstoichiometric phases with K2NiF4-type structure (198 citations)

What are the main themes of his work throughout his whole career to date?

His primary scientific interests are in Analytical chemistry, Inorganic chemistry, Conductivity, Ionic conductivity and Dielectric spectroscopy. The various areas that Fernando M.B. Marques examines in his Analytical chemistry study include Partial pressure, Oxygen, Perovskite and Mineralogy. His Inorganic chemistry research includes elements of Yttria-stabilized zirconia, Doping, Electrolyte, Solid oxide fuel cell and Electrochemistry.

Fernando M.B. Marques focuses mostly in the field of Conductivity, narrowing it down to topics relating to Ceramic and, in certain cases, Microstructure and Phase. His work in Ionic conductivity covers topics such as Ionic bonding which are related to areas like Vacancy defect. His studies in Dielectric spectroscopy integrate themes in fields like Metallurgy, Carbonate, Atmospheric temperature range and Composite material, Scanning electron microscope.

He most often published in these fields:

Analytical chemistry (43.31%)
Inorganic chemistry (37.01%)
Conductivity (38.19%)

What were the highlights of his more recent work (between 2013-2021)?

Dielectric spectroscopy (28.35%)
Conductivity (38.19%)
Electrolyte (25.20%)

In recent papers he was focusing on the following fields of study:

His scientific interests lie mostly in Dielectric spectroscopy, Conductivity, Electrolyte, Ceramic and Oxide. His study on Dielectric spectroscopy also encompasses disciplines like

Permeation and Chemical stability most often made with reference to Composite number,
Atmospheric temperature range together with Activation energy, Inorganic chemistry and Electrochemistry. His Conductivity study combines topics in areas such as Eutectic system, Grain boundary, Ionic conductivity, Gas separation and Composite material.

His Ionic conductivity study frequently draws connections to other fields, such as Ionic bonding. His Electrolyte study integrates concerns from other disciplines, such as Cathode, Mineralogy and Chemical route. His Ceramic research is multidisciplinary, relying on both Lithium fluoride, Phase, Scanning electron microscope and Doping.

Between 2013 and 2021, his most popular works were:

High performance composite CO2 separation membranes (31 citations)
Composite electrolytes for fuel cells: Long-term stability under variable atmosphere (28 citations)
Zn as sintering aid for ceria-based electrolytes (21 citations)

In his most recent research, the most cited papers focused on:

Oxygen
Hydrogen
Ion

The scientist’s investigation covers issues in Dielectric spectroscopy, Conductivity, Ceramic, Composite number and Atmospheric temperature range. Fernando M.B. Marques has included themes like Electrolyte, Ionic conductivity, Mineralogy and Metallurgy, Grain size in his Dielectric spectroscopy study. His research integrates issues of Sintering and Composite material in his study of Conductivity.

The study of Ceramic is intertwined with the study of Oxide in a number of ways. The concepts of his Atmospheric temperature range study are interwoven with issues in Permeation and Activation energy. His biological study spans a wide range of topics, including X-ray crystallography, Inorganic chemistry, Electrochemistry and Mixed oxide.

Best Publications

Transport properties of solid oxide electrolyte ceramics: a brief review

V.V. Kharton;F.M.B. Marques;A. Atkinson

1514
Citations
Ceria-based materials for solid oxide fuel cells

V. V. Kharton;F. M. Figueiredo;F. M. Figueiredo;L. Navarro;E. N. Naumovich

609
Citations
Ionic transport in oxygen-hyperstoichiometric phases with K2NiF4-type structure

V.V. Kharton;V.V. Kharton;A.P. Viskup;A.V. Kovalevsky;E.N. Naumovich

304
Citations
Oxygen ion transport in La2NiO4-based ceramics

Vladislav V. Kharton;Alexandre P. Viskup;Eugene N. Naumovich;Fernando M. B. Marques

303
Citations
Cathode materials for intermediate temperature SOFCs

E Maguire;B Gharbage;F.M.B Marques;J.A Labrincha

261
Citations
Research on the electrochemistry of oxygen ion conductors in the former Soviet Union

Vladislav V. Kharton;Evgeny N. Naumovich;Aleksey A. Yaremchenko;Fernando M.B. Marques

224
Citations
Oxygen transport in Ce0.8Gd0.2O2−δ-based composite membranes

V.V. Kharton;V.V. Kharton;A.V. Kovalevsky;A.P. Viskup;A.L. Shaula

222
Citations
Thermal and chemical induced expansion of La0.3Sr0.7(Fe,Ga)O3−δ ceramics

V.V. Kharton;V.V. Kharton;A.A. Yaremchenko;M.V. Patrakeev;E.N. Naumovich

200
Citations
Oxygen Permeability of Ce0.8Gd0.2 O 2 − δ ‐ La0.7Sr0.3MnO3 − δ Composite Membranes

V. V. Kharton;A. V. Kovalevsky;A. P. Viskup;F. M. Figueiredo

181
Citations
Oxygen Nonstoichiometry, Conductivity, and Seebeck Coefficient of La0.3Sr0.7Fe1−xGaxO2.65+δ Perovskites

M.V. Patrakeev;E.B. Mitberg;A.A. Lakhtin;I.A. Leonidov

152
Citations
La2Zr2O7 formed at ceramic electrode/YSZ contacts

J. A. Labrincha;J. R. Frade;F. M. B. Marques

151
Citations
Oxygen ionic and electronic transport in apatite-type La10−x(Si,Al)6O26±δ

A.L. Shaula;V.V. Kharton;V.V. Kharton;F.M.B. Marques

148
Citations
Influence of microstructure on the electrical properties of NASICON materials

R.O Fuentes;F.M Figueiredo;F.M Figueiredo;F.M.B Marques;J.I Franco

145
Citations
Ionic conductivity of La(Sr)Ga(Mg,M)O3−δ (M=Ti, Cr, Fe, Co, Ni): effects of transition metal dopants

V.V Kharton;A.P Viskup;A.A Yaremchenko;R.T Baker

143
Citations
Transport properties and stability of Ni-containing mixed conductors with perovskite- and K2NiF4-type structure

V.V Kharton;A.A Yaremchenko;A.L Shaula;M.V Patrakeev

141
Citations
Interfacial effects in electrochemical cells for oxygen ionic conduction measurements: I. The e.m.f. method

V.V Kharton;F.M.B Marques

137
Citations
Crystalchemistry and Oxide Ion Conductivity in the Lanthanum Oxygermanate Apatite Series

L. Leon-Reina;M. C. Martin-Sedeno;E. R. Losilla;A. Cabeza

134
Citations
Protonic conduction in La2Zr2O7-based pyrochlore materials

J.A. Labrincha;J.R. Frade;F.M.B. Marques

131
Citations
Perovskite-like system (Sr,La)(Fe,Ga)O3−δ: structure and ionic transport under oxidizing conditions

V.V Kharton;V.V Kharton;A.L Shaulo;A.P Viskup;M Avdeev

129
Citations
Mixed ionic–electronic conductors: effects of ceramic microstructure on transport properties

V.V Kharton;F.M.B Marques

125
Citations