Synthesis and characterization of ZnO-Al<sub>2</sub>O<sub>3</sub> oxides as energetic electro-catalytic material for glucose fuel cell

Sujit Kumar Guchhait; Subir Paul

Volume 43 Issue 08

Aug. 2015

Turn off MathJax

Article Contents

Article Navigation > Journal of Fuel Chemistry and Technology > 2015 > 43(08): 1004-1010

Sujit Kumar Guchhait, Subir Paul. Synthesis and characterization of ZnO-Al2O3 oxides as energetic electro-catalytic material for glucose fuel cell[J]. Journal of Fuel Chemistry and Technology, 2015, 43(08): 1004-1010.

Citation:

Sujit Kumar Guchhait, Subir Paul. Synthesis and characterization of ZnO-Al₂O₃ oxides as energetic electro-catalytic material for glucose fuel cell[J]. Journal of Fuel Chemistry and Technology, 2015, 43(08): 1004-1010.

Citation:

PDF( 4069 KB)

Synthesis and characterization of ZnO-Al₂O₃ oxides as energetic electro-catalytic material for glucose fuel cell

Metallurgical and Material Engineering Department, Jadavpur University, Kolkata 700032, India

Received Date: 2015-03-24
Rev Recd Date: 2015-06-24
Publish Date: 2015-08-30

Abstract

Abstract

One of the thrust areas of research is to find an alternative fuel to meet the increasing demand for energy. Glucose is a good source of alternative fuel for clean energy and is easily available in abundance from both naturally occurring plants and industrial processes. Electrochemical oxidation of glucose in fuel cell requires high electro-catalytic surface of the electrode to produce the clean electrical energy with minimum energy losses in the cell. Pt and Pt based alloys exhibit high electro-catalytic properties but they are expensive. For energy synthesis at economically cheap price, non Pt based inexpensive high electro catalytic material is required. Electro synthesized ZnO-Al₂O₃ composite is found to exhibit high electro-catalytic properties for glucose oxidation. The Cyclic Voltammetry and Chronoamperometry curves reflect that the material is very much comparable to Pt as far as the maximum current and the steady state current delivered from the glucose oxidation are concerned. XRD image confirms the mixed oxide composite. SEM images morphology show increased 3D surface areas at higher magnification. This attributed high current delivered from electrochemical oxidation of glucose on this electrode surface.
- glucose,
- energy materials,
- electro-catalyst,
- cyclic voltammetry,
- chronoamperometry,
- polarization

FullText(HTML)

References(28)

References

PAUL S, JANA A, MITRA P. Study on bioelectrochemical fuel cell with algae[J]. J Inst Eng (India): Environ Eng Div, 2007, 88: 27-30.

PAUL S, MONDAL P. Pyrolysis of forest residue for production of bio fuel[J]. J Int Energy, 2006, 7: 221-225.

PAUL S, MONDAL P. Fabrication and characterization of bioelectrochemical fuel cell with pyrolysed produced bio oil and hydrolysed biomass by fermentation[J]. J Inst Eng (India), Part IDGE, 2009, 90: 40-45.

PAUL S. Characterization of bioelectrochemical fuel cell fabricated with agriculture wastes and surface modified electrode materials[J]. J Fuel Cell Sci Technol, 2012, 9(2): 021013-9.

RAO J R, MILAZZO G M. Blank (Eds.), bioelectrochemistry. I. Biological redox reactions[M]. Plenum Press, New York, 1983: 283-335.

RAO M L B, DRAKE R F. Studies of electrooxidation of dextrose in neutral media[J]. J Electrochem Soc, 1969, 116(3): 334-337.

JIN C, TANIGUCHI I. Electrocatalytic activity of silver modified gold film for glucose oxidation and its potential application to fuel cells[J]. Mater Lett, 2006, 61(11/12): 2365-2367.

BASU D, BASU S. A study on direct glucose and fructose alkaline fuel cell[J]. Electrochima Acta, 2010, 55(20): 5775-5779.

KERZENMACHER S, KRäLING U, METZ T, ZENGERLE R, VON STETTEN F. A potentially implantable glucose fuel cell with Raney-platinum film electrodes for improved hydrolytic and oxidative stability[J]. J Power Sources, 2011, 196(3): 1264-1272.

BASU D, BASU S. Synthesis and characterization of Pt-Au/C catalyst for glucose electro-oxidation for the application in direct glucose fuel cell[J]. Int J Hydrogen Energy, 2011, 36(22): 14923-14929.

KERZENMACHER S, DUCREE J, ZENGERLE R, VON STETTEN F. Energy harvesting by implantable abiotically catalyzed glucose fuel cell[J]. J Power Sources, 2008, 182(1): 1-17.

VASSILYEV Y B, KHAZOVA O A, NIKOLAEVA N N. Kinetics and mechanism of glucose electrooxidation on different electrode-catalysts: Part I. Adsorption and oxidation on platinum[J]. J Electroanal Chem, 1985, 196(1): 105-125.

VASSILYEV Y B, KHAZOVA O A, NIKOLAEV A N N. Kinetics and mechanism of glucose electrooxidation on different electrode-catalysts: Part II. Effect of the nature of the electrode and the electrooxidation mechanism[J]. J Electroanal Chem, 1985, 196(1): 127-144.

PAUL S, NAIMUDDIN SK, GHOSH A. Electrochemical characterization of Ni-Co and Ni-Co-Fe for oxidation of methyl alcohol fuel with high energetic catalytic surface[J]. J Fuel Chem Technol, 2014, 42(1): 87-95.

ABBADI A, BEKKUM H VAN. Effect of pH in the Pt-catalyzed oxidation of D-glucose to D-gluconic acid[J]. J Mol Catal A: Chem, 1995, 97(2): 111-118.

POPOVIC K D, TRIPCOVIC A V, ADZIC R R. Oxidation of D-glucose in single-crystal platinum electrodes: A mechanistic study[J]. J Electroanal Chem, 1992, 339(1/2): 227-245.

MAO S S, CHEN X B. Selected nanotechnologies for renewable energy applications[J]. Int J Energy Res, 2007, 31(6/7): 619-636.

SPETS J P, LAMPINEN M J, KIROS Y, RANTANEN J, ANTTILA T. Direct glucose fuel cell with the anion exchange membrane in the near-neutral-state electrolyte[J]. Int J Electrochem Sci, 2012, 7: 11696-1705.

BASNAYAKE R, LI Z, LAKSHMI S, ZHOU W, SMOTKIN E S, CASADONTE D J, KORZENIEWSKI C. Pt-Ru nanoparticle electrocatalyst with bulk alloy properties prepared through a sonochemical method[J]. J Am Chem Soc, 2006, 22(25): 10446-10450.

LUO J, NJOKI P, LIN Y, WANG L, MOTT D, ZHONG C. Activity-composition correlation of AuPt alloy nanoparticle catalysts in electrocatalytic reduction of oxygen[J]. Electrochem Commun, 2006, 8(4): 581-587.

BOCK C, PAQUET C M, COUILLARD G, BOTTON A, MACDOUGALL B R. Size-selected synthesis of PtRu nano-catalysts: Reaction and size control mechanism[J]. J Am Chem Soc, 2004, 126(25): 8028-8037.

LI L, SCOTT K, YU E H. A direct glucose alkaline fuel cell using MnO2ecarbon nanocomposite supported gold catalyst for anode glucose oxidation[J]. J Power Sources, 2013, 221: 1-5.

PAUL S, GHOSH A. Synthesis and characterization of MnO₂ as electrocatalytic energy material for fuel cell electrode[J]. Chem Mater Res, 2014, 6(10): 60-72.

SLAUGHTER G, JOSHUA S. A membraneless single compartment abiotic glucose fuel cell[J]. J Power Sources, 2014, 261: 332-336.

REEVE R W, CHRISTENSEN P A, DICKINSON A J, HAMNETT A, SCOTT K. Methanol-tolerant oxygen reduction catalysts based on transition metal sulfides and their application to the study of methanol permeation[J]. Electrochim Acta, 2000, 45(25/26): 4237-4250.

BAEZ V B, PLETCHER D. Preparation and characterization of carbon/titanium dioxide surfacesdthe reduction of oxygen[J]. J Electroanal Chem, 1995, 382(1/2): 59-64.

LU H, ZHENG F, GUO M, ZHANG M. One-step electrodeposition of single-crystal ZnO nanotube arrays and their optical properties[J]. J Alloys Compd, 2014, 588: 217-221.

LU H, ZHENG F, ZHANG M, GUO M. Effects of preparing conditions on controllable one-step electrodeposition of ZnO nanotube arrays[J]. Electrochim Acta, 2014, 132: 370-376.

Relative Articles

Supplements(0)

Cited By

Proportional views