Preparation of new ferroelectric Li0.95Ta0.57Nb0.38Cu0.15O3 materials as photocatalysts in microbial fuel cells

Preparation of new ferroelectric Li0.95Ta0.57Nb0.38Cu0.15O3 materials as photocatalysts in microbial fuel cells

A microbial fuel cell (MFC) is a device for both the generation of bioelectricity and the treatment of wastewater. However, its performance is affected by several parameters, and more particularly the materials used as the active phase at the cathode. In order to develop new, more efficient cathodes...

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Bibliographic Details
Published in:Canadian journal of chemical engineering Vol. 96; no. 8; pp. 1656 - 1662
Main Authors: Louki, Sami, Touach, Nour‐eddine, Benzaouak, Abdellah, Salar‐García, María José, Ortiz‐Martínez, Víctor Manuel, Hernández‐Fernández, Francisco José, de los Ríos, Antonia Pérez, El Mahi, Mohammed, Lotfi, El Mostapha
Format: Journal Article
Language:English
Published: Hoboken Wiley Subscription Services, Inc 01-08-2018
Subjects:
Biochemical fuel cells
Bioelectricity
Catalytic activity
Cathodes
Cooling
Electric power generation
Electrode materials
Ferroelectric materials
Ferroelectricity
Heat treatment
Maximum power density
microbial fuel cell
Microorganisms
Particle size distribution
Phases
Photocatalysis
photocatalyst
Photocathodes
rapid cooling
slow cooling
Synthesis
tantalo‐niobate phase
Wastewater treatment
Water treatment
X-ray diffraction
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Summary:A microbial fuel cell (MFC) is a device for both the generation of bioelectricity and the treatment of wastewater. However, its performance is affected by several parameters, and more particularly the materials used as the active phase at the cathode. In order to develop new, more efficient cathodes, two new non‐stoichiometric ferroelectric cathode materials are studied in this work. These electrodes have been synthesized according to two heat treatment modes (slow cooling and rapid cooling) from non‐stoichiometric ferroelectric materials with the formula Li0.95Ta0.57Nb0.38Cu0.15O3. The synthesized phases were characterized by X‐ray diffraction (XRD), transmission electronic microscopy (TEM), particle size distribution (PSD), and differential scanning calorimetry (DSC). The main characteristics of these phases are the Curie temperatures, 1217 and 1197 °C, and the specific surfaces of 0.572 and 0.801 m2/g for the slow and rapid cooling phases, respectively. These materials were subsequently tested as photocathodes in a single chamber MFC in terms of the bioenergy production and wastewater treatment, by measuring the output power density and the rate of removal of COD in the presence of a light source. For the samples prepared by slow and rapid cooling, the values of maximum power density were 20.10 and 205.35 mW/m3, respectively. The COD removal rates were 74 and 80 %, respectively. Accordingly, the phase prepared by rapid cooling was shown to be more efficient in terms of power generation and wastewater treatment with a significant improvement in photocatalytic activity.
ISSN:0008-4034
1939-019X
DOI:10.1002/cjce.23117