ELECTROCHEMICAL PARAMETERS OF MICROBIAL FUEL CELLS BASED ON THE MICROCOCCUS LUTEUS STRAIN, NEW ION-EXCHANGE MEMBRANES AND VARIOUS SUGARS

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Abstract

We studied the physicochemical and electrochemical characteristics of microbial fuel cells (MFCs) with a new proton-exchange membrane. It was synthesized on the basis of zeolite-doped polyvinyl alcohol cross-linked with sulfosuccinic acid (PVA-SSA-BEA). An MF-4SK industrial membrane (Plastpolymer, Russia) was used as a comparative sample. Various sugars were added as substrates (glucose, arabinose, galactose, xylose). The role of the bioagent was performed by the strain Micrococcus luteus 1-i. MFCs with PVA-SSA-BEA and MF-4SK membranes showed rather close electrochemical characteristics. A higher electricity output was performed with the addition of glucose, galactose, the lowest - with the use of xylose. The data obtained indicate that the proposed PVA-SSA-BEA membrane is promising for use as an alternative to proton-exchange membranes widely used in fuel cell technology.

About the authors

A. N. Chesnokova

Irkutsk National Research Technical University

Email: chesnokova@istu.edu
Irkutsk, Russia

S. A. Zakarchevsky

Irkutsk National Research Technical University

Email: stomd@mail.ru
Irkutsk, Russia

G. O. Zhdanova

Irkutsk State University

Email: stomd@mail.ru
Irkutsk, Russia

D. I. Stom

Irkutsk National Research Technical University; Irkutsk State University; Baikal Museum of the SB RAS

Author for correspondence.
Email: stomd@mail.ru
Irkutsk, Russia; Irkutsk, Russia; Listvyanka Irkutsk region, Russia

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Copyright (c) 2023 А.Н. Чеснокова, С.А. Закарчевский, Г.О. Жданова, Д.И. Стом