Electrochemical characterization of Ni-Co and Ni-Co-Fe for oxidation of methyl alcohol fuel with high energetic catalytic surface

Subir Paul; Sk Naimuddin; Asmita Ghosh

Volume 42 Issue 01

Jan. 2014

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Subir Paul, Sk Naimuddin, Asmita Ghosh. Electrochemical characterization of Ni-Co and Ni-Co-Fe for oxidation of methyl alcohol fuel with high energetic catalytic surface[J]. Journal of Fuel Chemistry and Technology, 2014, 42(01): 87-95.

Citation:

Subir Paul, Sk Naimuddin, Asmita Ghosh. Electrochemical characterization of Ni-Co and Ni-Co-Fe for oxidation of methyl alcohol fuel with high energetic catalytic surface[J]. Journal of Fuel Chemistry and Technology, 2014, 42(01): 87-95.

Citation:

Subir Paul, Sk Naimuddin, Asmita Ghosh. Electrochemical characterization of Ni-Co and Ni-Co-Fe for oxidation of methyl alcohol fuel with high energetic catalytic surface[J]. Journal of Fuel Chemistry and Technology, 2014, 42(01): 87-95.

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Electrochemical characterization of Ni-Co and Ni-Co-Fe for oxidation of methyl alcohol fuel with high energetic catalytic surface

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

Received Date: 2013-08-08
Rev Recd Date: 2013-11-04
Publish Date: 2014-01-30

Abstract

Abstract

Non Pt based metals and alloys as electrode materials for methyl alcohol fuel cells have been investigated with an aim of finding high electrocatalytic surface property for the faster electrode reactions. Electrodes were fabricated by electrodeposition on pure Al foil, from an electrolyte of Ni, Co, Fe salts. The optimum condition of electrodeposition were found out by a series of experiments, varying the chemistry of the electrolyte, pH valve, temperature, current and cell potential. Polarization study of the coated Ni-Co or Ni-Co-Fe alloy on pure Al was found to exhibit high exchange current density, indicating an improved electro catalytic surface with faster charge-discharge reactions at anode and cathode and low overvoltage. Electrochemical impedance studies on coated and uncoated surface clearly showed that the polarization resistance and impedance were decreased by Ni-Co or Ni-Co-Fe coating. X-ray diffraction (XRD), energy dispersive X-ray spectroscopy (EDX) and atomic absorption spectroscopy (AAS) studies confirmed the presence of alloying elements and constituents of the alloy. The morphology of the deposits from scanning electron microscope (SEM) images indicated that the electrode surface was a three dimensional space which increased the effective surface area for the electrode reactions to take place.
- electrodeposition,
- Ni-Co alloy,
- electrocatalytic,
- exchange current density,
- impedance,
- X-ray diffraction (XRD),
- scanning electron microscope (SEM)

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References(21)

References

PAUL S, JANA A. Study on bioelectrochemical fuel cell with algae[J]. J Inst Eng Int Div, 2007, 88: 27-30.

PAUL S, MONDAL P. Pyrolysis of forest residue for production of bio fuel[J]. Int Energy J, 2006, 7(3): 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 Int Div, 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 ASME, 2012, 9(2): 021013(9 pages).

LEE J. Biological conversion of lignocelluloses biomass to ethanol[J]. J Biotechnol, 1997, 56(1): 1-24.

IRANMAHBOOBA J, NADIMA F, MONEMIB S. Optimizing acid-hydrolysis: A critical step for production of ethanol from mixed wood chips[J]. Biomass Bioenergy, 2002, 22(5): 401-404.

SCHELL D J, SCHELL D J, RILEY C J, DOWE N, FARMER J, IBSEN K N, RUTH M F, TOON S T, LUMPKIN R E. A bioethanol process development unit: Initial operating experiences and results with a corn fiber feedstock[J]. Bioresour Technol, 2004, 91(2): 179-188.

CHAUDHURI S K, LOVLEY D R. Electricity generation by direct oxidation of glucose in mediatorless microbial fuel cells[J]. Nat Biotechnol, 2003, 21(10): 1229-1232.

KIM J R, S H JUNG, REGAN J M, LOGAN B E. Electricity generation and microbial community analysis of alcohol powered microbial fuel cells[J]. Bioresour Technol, 2007, 98(13): 2568-2577.

WANG X, FENG Y J, LEE H. Electricity production from beer brewery wastewater using single chamber microbial fuel cell[J]. Water Sci Technol, 2008, 57(7): 1117-1121.

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

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.

SHAN C, TSAI D S, HUANG Y S, JIAN S H, CHENG C L. Pt-Ir- IrO₂NT THIN-WALL ELECTROCATALYSTS Derived from IrO2 Nanotubes and their CATALYTIC ACTIVITIES IN METHANOL OXIDATION[J]. Chem Mater, 2007, 19(3): 424-431.

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]. J Electrochem Commun, 2006, 8(4): 581-587.

CASADO-RIVERA E, VOLPE D J, ALDEN L, DOWNIE C, VAZQUEZ-ALVAREZ T, ANGELO A C D, DISALVO F J,ABRUNA H D. Electrocatalytic activity of ordered intermetallic phases for fuel cell applications[J]. J Am Chem Soc, 2004, 126(12): 4043-4049.

MOHAMEDI M, HISAMITSU Y, KIHARA K, KUDO T, ITOH T, UCHIDA I. Ni-Al alloy as alternative cathode for molten carbonate fuel cells[J]. J Alloys Compd, 2001, 315(1/2): 224-233.

KUMAR S K, HARIDOSS P, SESHADRI S K. Synthesis and characterization of electrodeposited Ni-Pd alloy electrodes for methanol oxidation[J]. Surface Coat Technol, 2008, 202(9): 1764-1770.

CHENG S A, LIU H, LOGAN B E. Increased power generation in a continuous flow MFC with advective flow through the porous anode and reduced electrode spacing[J]. Environ Sci Technol, 2006, 40(7): 364-369.

MORRIS J M, JIN S, WANG J Q, ZHU C Z, URYNOWICZ M A. Lead dioxide as an alternative catalyst to platinum in microbial fuel cells[J]. Electrochem Commun, 2007, 9(7): 1730-1734.

LI Y, LU A H, DING H R, JIN S, YAN Y H, WANG C Q, ZEN C P, WANG X. Cr(VI) reduction at rutile-catalyzed cathode in microbial fuel cells[J]. Electrochem Commun, 2009, 11(7): 1496-1499.

DAS D, SEN P K, DAS K. Electrodeposited MnO₂ as electrocatalyst for carbohydrate oxidation[J]. J Appl Electrochem, 2006, 36(6): 685-690.

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