1. Electro-catalytic supports for noble metals for exploitation as electrodes for fuel cells
Ph.D., Seminar - II
Sep. 20, 2006
T. Maiyalagan
CYD01006

2. Outline Introduction Principle of DMFC1
Introduction
Principle of DMFC
Role of supports in electrocatalyst
Nitrogen containing carbon nanotubes
Metal oxide nanomaterials (TiO2 nanotubes & WO3 nanorods)
Conducting polymer nanotubules and polymer -metal oxide nanocomposite (PEDOT–V2O5 )
Conclusion

3. What are fuel cells ? Direct Energy Conversion Vs Indirect Technology
C. K. Dyer, J. Power. Sources, 106 (2002) 245

4. Various types of fuel cells
Research area
Methanol Fuel Cells
Direct methanol fuel cell
Indirect methanol fuel cell
Fuel : Hydrogen
(Reformed from methanol)
Fuel reformer makes the system bulky
Fuel : Methanol

5. Direct Methanol Fuel Cell (DMFC)
DMFC advantages
More environmentally friendly
High efficiency
Low temperature ( C)
Long membrane lifetime
Methanol is safe to store and
distribute than hydrogen
Low emission future power sources
Catalyst poisoning
Pt-CO
Anode: CH3OH + H2O  CO2 + 6H+ + 6e E = V (RHE)Cathode: 3/2O2 + 6H+ + 6e-  3 H2O E = V (RHE)
Overall : CH3OH + 3/2O2  CO2 + 2H2O E = V (RHE)
Heinzel et al, J. Power Sources 105 (2002) 250

6. REDUCTION OF PLATINUM LOADINGS
Objective
 To reduce the amount of noble metal loading in the electrodes
 Increase metal dispersion on suitable electronically conducting supports
REDUCTION OF PLATINUM LOADINGS
Dispersion Utilization 
Stability

7. Why supported catalyst?
High Temperature
Unsupported catalyst
High Temperature
Supported catalyst
Role of support ?

8. Role of electro-catalyst supports
High surface-to-volume ratios
High dispersion of noble metal particles to reduce noble metal loadings
Avoid the agglomeration of the metal particles in operation,
Good stability of electrocatalysts
Improved the activity of electro-catalysts through the interaction between metal and support
Lower the resistance of mass transportation
Always superior to respective unsupported and conventional supported systems
Shorten the time of DMFC commercialization

9. Increase in metal dispersion,
Strategy
Metal catalysts
Electrocatalyst supports
Unsupported
Conducting polymers
Metal oxides
Carbon nanotubes
Conducting polymer nanotubes, Polymer- metal oxide nanocomposite
TiO2, WO3
nanomaterials
Nitrogen containing
carbon nanotubes
Poor performance,
not economical
Stability
Increase in metal dispersion,
Economical
 Interactions between the noble metal and the support may lead to
increase catalyst performance

10. Role of nitrogen on the carbon nanotube supported anodes for methanol oxidation
Why carbon materials are used as an electrocatalyst support ?
Electrochemical properties
- wide electrochemical potential window
Chemical properties
- Good corrosion resistance
Electrical properties
- Good conductivity
Mechanical properties
- Dimensional & mechanical stability
- Light weight & adequate strength
Carbon nanotube as an electrode support in fuel cells
Mesoporosity (2-50nm)
Improved mass transfer
Better dispersion
Surface bound groups
High accessible surface area
High purity → avoids self-poisoning
Good electronic conductivity

11. Nitrogen functionalization in carbon support
Pt bound strongly to nitrogen sites so higher dispersion, avoids sintering
Addition of nitrogen increases the conductivity of the material by raising the Fermi level towards the conduction band
The presence of nitrogen generates catalytic site and this catalytic site is responsible for increased activity of methanol oxidation
Electrode
Methanol oxidation potential at +50 mA/cm2 (V)
Untreated (U)
604
Nitrogen functionalized (N)
554
Sulfur functionalized (S)
633
Current – potential curve for sulfur functionalized (S), nitrogen functionalized (N) and un-functionalized (U) carbon supports
S.C. Roy et al., J. Electrochem. Soc., 144 (1997) 2323

12. Nitrogen induces catalytic activity+ ê + ê + ê + ê + ê + ê
carbon
oxygen
hydrogen Pt Pt e- e- e- e-

13. Synthesis of Nitrogen containing carbon nanotubes
Present work
NITROGEN CONTAINING POLYMERS
PPP
N= 0%
PVP
N=12.9%
PPY
N=21.2%
PVI
N=33.0%

14. Synthesis of CNT from poly(paraphenylene)
AlCl3(0.5M),CuCl2
Benzene (1M)
Alumina
membrane
Polymerization, RT , 3h
PPP/alumina
Carbonization,
Ar atm
CNT/alumina
48% HF, 24 h
CNTPPP

15. Electrochemical studies
Cyclic Voltammograms in 1 M H2SO4 aqueous solution at (a) Glassy carbon coated carbon nanotube electrode (b) Glassy carbon coated Vulcan electrode (c) Glassy carbon.

16. Loading of catalyst inside nanotubes
73mM H2PtCl6
12 h
H2 atm,
823 K, 3 h
48% HF,24 h

17. Electrocatalytic activity of the catalyst
Cyclic Voltammograms of (c) GC/CNTppp-Pt--Nafion Nafion in 1 M H2SO4/1 M CH3OH run at 50 mV/s

18. Synthesis of N-CNTs from Poly(vinylpyrolidone)
in dichloromethane
AFM
Alumina membrane
Carbonization, Ar atm
PVP/alumina
TEM
48% HF, 24 h
CNTPVP
SEM

19. XPS
T. Maiyalagan, B.Viswanathan, Mater.Chem.Phys , 93 (2005) 291

20. Cyclic Voltammograms of (a) GC/CNTppp-Pt-Nafion Nafion in 1 M H2SO4/1 MCH3OH run at 50 mV/s
T. Maiyalagan, B. Viswanathan, U.V. Varadaraju, Electrochem. Commun. 7 (2005) 905

21. Synthesis of N-CNTs from Poly(pyrrole)
FeCl36H2O(0.2M)
Pyrrole (0.1M)
PTSA (0.2 M)
Alumina
membrane
SEM: N-CNT
Polymerization, RT , 3h
PPY/alumina
Carbonization, Ar atm
TEM: Pt/N-CNT
48% HF, 24 h
CNTPPY

22. Synthesis of N-CNTs from Poly(vinylimidazole)
Benzene
Vinyl imidazole (0.1m)
AIBN
Alumina
membrane
Polymerization , 68o C, 10 h
PVI/alumina
Carbonization, Ar atm
CNT/alumina
48% HF, 24 h
CNTPVI

23. Elemental analysis (CHN)
Calculated from polymer
Calculated from carbon nanotubes
SAMPLE
% C
% N
% H
PPP-CNT
93.0
0.0
4.9
92.3
1.8
PVP-CNT
64.8
12.6
8.2
87.0
6.6
0.8
PPY-CNT
66.7
21.2
6.1
78.2
10.3
0.6
PVI-CNT
63.8
29.8
6.4
75.5
18.9

24. Electrocatalytic activity
Electrode
Nitrogen content
Activity Ip (mA/cm2) Pt -
0.076
GC/ETek 20% Pt/C Naf
1.3
GC/CNT-Pt PPP-Naf
0.0
12.4
GC/CNT-Pt PVP -Naf
6.63
16.2
GC/CNT-Pt PPY -Naf
10.5
21.4
GC/CNT-Pt PVI-Naf
16.7 
18.6
Electrocatalytic activity of the N-CNTs electrodes in comparison with commercial catalysts for methanol oxidation
Specific activity for methanol oxidation versus nitrogen content of the catalysts

25. Stability of the electrodes

26. Salient Features
Higher surface area of the CNT - better utilization of the catalytic particles
Tubular morphology & nitrogen presence - better dispersion of Pt
E-TEK < Pt PPP-CNT < Pt PVP-CNT < Pt PVI-CNT < Pt PPY-CNT
Nitrogen presence – dispersion & also in increasing the hydrophilic nature of the catalyst
Correlation between the catalytic activity and the nitrogen concentration (at%)

27. Methanol oxidation catalysts
Electro-oxidation of methanol on Pt/TiO2 nanotube catalysts
Methanol oxidation catalysts
Pt alloys
Intrinsic mechanism
(bifunctional mechanism)
Pt-Ru
Pt with metal oxides
Promoted mechanism
(hydrogen spill over and
oxygen spill over)
TiO2, WO3 O H C O P t Ru

28. Synthesis of Pt /TiO2 nanotube catalyst
Alumina
Membrane
Titanium isopropoxide
in isopropanol
Impregnation
Calcined at
873 K, 2 h
TiO2 Anatase /Alumina
Immersion in 73mM H2PtCl6, 12 h
823 K, H2 atm, 3h
3 M NaOH
Pt-TiO2 Nanotube

29. UV and Raman spectra
Raman spectrum
UV Spectrum

30. SEM & TEM images of TiO2 nanotubes
Pt/TiO2 nanotube

31. X- Ray diffraction pattern
A - Anatase
R - Rutile
Pt- Platinum
(111)

32. Electrode fabrication
10 mg Pt/TiO2 nanotubes/ 100 l water
Ultrasonicated for 30 min
Dispersion (10 l) / Glassy Carbon (0.07 cm2)
Dried in air
5 l Nafion (binder)
Solvent evaporated
ELECTRODE
Counter electrode-platinum foil
Reference electrode-Ag/AgCl/KCl(saturated)

33. Electrocatalytic activity of the catalyst
Electrocatalyst
Anodic scan peak potential (V) vs Ag/AgCl
Anodic peak current density (mA cm-2)
Bulk Pt
0.16
20 % Pt/C
0.762
1.3
Pt/TiO2 nanotube
0.680
13.2
Cyclic voltammograms in 0.5 M H2SO4 and 1 M CH3OH Scan rate : 50mV/s

34. Promoting effect of TiO2 nanotube support
Strong metal support interaction (SMSI)
OH adsorption on TiO2 facilitates CO oxidation
Pt-CO + OH(ads) → Pt∙∙∙CO2 + H+ + e-
OH(ads) forms on TiO2 surface and oxidizes Pt-CO
Model presentation of M-OH transfer and spillover upon metallic part of electrocatalyst.
T. Maiyalagan, B. Viswanathan and U. V. Varadaruju J. Nanosci. Nanotech 6 (2006) 2067

35. Salient Features
 TiO2 nanotubes have been explored as support for Pt
 High platinum dispersion was obtained on these TiO2 nanotube supports by
the reduction of the Pt ions with H2 at 873 K
 The resulting electrodes were tested for methanol oxidation reaction and
shows higher catalytic activity than the commercial catalyst
 Strong metal support interaction (SMSI)
 COads on the Pt sites reacts with surface hydroxyl species (OHads), at the
adjacent TiO2 sites facilitates CO oxidation
 TiO2 nanotube morphology was also assumed to be responsible for the
higher specific activity of methanol oxidation

36. Electro-oxidation of methanol on Pt/WO3 nanorods catalysts
Metal oxides - promising CO tolerance
Metal oxides supports to Pt must fulfill the requirement of forming O-containing surface species at
low potentials
Pt + H2O PtO + 2 H+ + 2 e Eo = 0.99V
Mo + 3H2O MoO3 +6 H+ + 6 e Eo = 0.25V
W + 2H2O WO2 + 4H e Eo = -0.05V
W + 3H2O WO3 + 6H e Eo = 0.09V
Lower values of Eo for the Mo/MoOx, and W/WOx than that for Pt /PtO enhance the ability of OH adsorption
Metal oxides forms hydrogen bronzes provides H2 spill over and oxygen spill over mechanism
Ability to act as redox centers
Ionic and Electronic conductivity
M.S. Antelman, Encyclopedia of chemical electrode potentials, Plenum, New York, 1982

37. Electro-oxidation of methanol on Pt/WO3 catalysts
P. K. Shen et al., Catalysis Today 38 (1997) 439

38. Template Synthesis of WO3 nanorods
10 gm Phosphotungstic acid + 30 ml methanol
Impregnation
H3PW12O40/Alumina membrane
Calcined at 873 K 3h
WO3/Alumina membrane HF
73 mM H2PtCl6 Evaporated to dryness
H2 atm, 623 K, 4h
Pt/WO3 nanorods
(dark powder)
WO3 nanorods
(light blue powder)

39. FTIR spectra
990 cm-1 is for as(W-Od)
1080 cm-1 is for  as (X-Oa)
894 cm-1 is for as(W-Ob-W)
817 cm-1 is for as(W-Oc-W)
The strong absorption between 500 and 1000 cm-1 can be associated with the W-O-W stretching modes ( characteristic peak of tungsten oxide )

40. UV and Raman spectrum UV spectrum Raman spectrum
717.6 and 808 cm-1 : O-W-O stretching modes

41. X- Ray diffraction pattern
XRD pattern of tungsten oxide nanorods

42. SEM/EDX images
Mag:3000K

43. TEM/EDX images
200 nm
100 nm

44. Electrochemical studies
Bulk WO3
WO3 nanorods
xH+ + xe WO > HxWO3
(formation of hydrogen tungsten bronze)

45. Hydrogen spill-over effect on Pt/WO3 nanorods
Pt H+ + e > xPt
WO xPt-H >HxWO xPt-H
HxWO >xH+ + xe WO3
overlap between reoxidation of hydrogen tungsten
bronze and desorption of hydrogen on Pt, difficult to
estimate the active surface area of Pt

46. Electrocatalytic activity of the catalyst Specific activity mA/cm2
Pt loading g/cm2
Specific activity mA/cm2
Pt/Vulcan 20 23
Pt/WO3 nanorods 60

47. Salient Features
Metal oxide nanorods as supports for Pt electrodes in the
electrooxidation of methanol in acid electrolyte has been investigated
WO3 was demonstrated to promote electrocatalytic oxidation of
methanol by interacting with Pt via hydrogen spillover or
through the formation of highly conductive tungsten bronzes
Improvement of performance may be due to the presence of OHads
groups on the oxide surface, that should facilitate oxidation of
poisoning CO intermediates
The promotional activity of WO3 nanorod is related to the
W(VI)/W(IV) redox couple acting as a surface mediator for
the oxidation of surface methanolic residues
The nanorods morphology of the base-metal oxide is promoting the
activity for platinum

48. Why Conducting polymers ?
Electro-oxidation of methanol on electrodeposited platinum in Poly(o-phenylenediamine) nanotubule electrodes
Why Conducting polymers ?
 Easy Fabrication
 Better stability
 Good electronic /ionic conductivity
 Three-dimensional structures and high porosity of the polymeric matrices leads to high dispersion
Minimum transport limitations
 High dispersion of metallic particles inside these polymers gives electrodes with higher surface areas and enhanced electrocatalytic activity

49. Polymers matrices used
Polyaniline,
Polypyrrole
Polythiophene
Poly (3,4, ethylenedioxythiophene)
Poly (2 hydroxy 3-amino phenazine)
Poly (o-aminophenol)
Poly (o-phenylenediamine)
- high aromaticity and high thermal stability
- catalyst for electrochemical reduction of dioxygen
- sensor for many chemical species, ladder polymer

50. Template assisted electrochemical synthesis of conducting polymer nanotubes
Matrix = Alumina membrane
Graphite electrode
(Nafion coating)
Polymer
nanostructure
Electrochemical
Dissolution
polymerization
Alumina membrane
Conducting
composite
Nanotubes
0.6 µm-thickness
200 nm pore diameter

51. Experimental setup AE WE RE
Schematic view of an electrochemical cell for the formation of nanostructured materials. RE, reference electrode; AE, auxiliary electrode; WE, working electrode (template membrane with a deposited Nafion contact layer).

52. Template assisted electrochemical synthesis of Pt/PoPD nanotubules
Graphite 1 cm2
Coating of 5 wt% Nafion,
Al2O3 Membrane hot pressed on Graphite at 393 K, 3 min.
Graphite /Naf/Al2O3
0.5 M OPD / 0.5 M H2SO4
Scanned between -0.2 V to 1.2 V vs Ag/AgCl at 50 mV/s
GR/Naf/Al2O3/PoPD
Electro reduction in 0.01 M H2PtCl6
0.8 V to -0.2 V
GR/Naf/Al2O3-PoPD-Pt
Cyclic voltammograms during the electropolymerization of o-phenylenediamine in
0.5M oPD + 0.5M H2SO4 solution (v = 50mVs−1)
Dissolution of Al2O3 in 0.2M NaOH, Followed
by immersion in 1% HBF4 (10 min)
GR/Naf/PoPDtemp-Pt

53. FT-IR and Raman spectrum
N-H stretching
C=Stretching
812 cm−1 1,4-disubstitude ring
These bands are assigned to stretching of
Aminobenzene units of azo groups

54. UV spectrum

55. Electron microscopic images of Pt/PoPD nanotubules
AFM
Graphite/PoPD nanotube
TEM image of Pt/PoPD
Graphite/Pt-PoPD nanotube

56. Electrocatalytic activity of the catalyst
Cyclic Voltammograms of GR/Naf/PoPD Temp in 0.5 M H2SO4 ( after the dissolution of the template)

57. Plot of anodic peak current density as a function of Platinum loading
on Nanotubule and conventional electrodes. (Current densities were
evaluated from CV run in 0.5 M H2SO4 / 1M CH3OH at 50 mV/s )

58. Electrocatalytic activity of the catalyst
S.No
Electrode
Onset
Potential
(V)
Activity*
Forward sweep
Reverse sweep I
( mA cm-2) E 1 2
GR/Naf/PoPD Temp –Pt
GR/Naf/PoPD Conv –Pt
+0.1
+0.2 84
13.3a
0.82
0.70 --
6. a
---
0.45
* Activity evaluated from cyclic voltammogram run in 0.5 M H2SO4 / 1M CH3OH scanned between -0.2 and 1 V vs Ag/AgCl a peak current density (mA cm-2)

59. Stability of the electrodes
GR/Naf/PoPD Temp –Pt
GC/ 20 % Pt/C (E-TEK)
GR/Naf/PoPD Conv –Pt

60. Salient Features
Template synthesis of conducting poly (o-phenylenediamine) yielded cylindrical nanotubules with outer diameter matches with pore diameter of the template used
Polymer nanotubules have adequate conductivity and allows both the incorporation of metal particles and an easy accessibility of the methanol to the catalytic sites.
 Polymer nanotubules electrode have higher electrocatalytic activity than the conventional polymer film electrode.

61. Nanocomposites with catalytic activity
Electro-oxidation of methanol on Pt supported PEDOT/ V2O5 nanocomposites electrodes
Nanocomposites
Organic-inorganic hybrid materials:
“Compounds which contain both inorganic and organic
moieties within the same micro structure”
Organic moiety - flexibility
Inorganic moiety - thermal stability and structural rigidity
Active moiety- catalysis
Nanocomposites with catalytic activity
PPY-SiO2 and PANI-SiO2 hybrid nanocomposites offer large surface area - Exploited as host for entrapping large amount of metal particles with desirable catalytic activity

62. Poly (3,4, ethylenedioxythiophene) (PEDOT)
Has wide potential range
Low band gap
Electroactive
Enhanced stability compared to polyaniline & polypyrrole
Excellent environmental stability
High electrical conductivity
Transparency in thin oxidized film
and is always in the p-doped state, i.e. conductive
Applications
solid electrolytic capacitors,
antielectrostatic agents,
transparent electrodes in light emitting diodes,
and underlayers for the metallization of printed circuit boards
Vanadium(V) oxide xerogel (VXG)
Exhibiting high proton conductivity, as well as electronic conductivity arising from the presence of V(IV) ions

63. V2O5 catalysts for methanol oxidation
E0/V
+0.5
VO2+/V3+
CH3OH/HCHO
HCHO/HCOOH
CH3OH/CO2
Vanadium potentials and steps of methanol oxidation
HCOOH/CO2
V3+/V2+
-0.5
Comparison of the potentials at which methanol is usually oxidized electrochemically and the normal redox couples. The normal potentials of the probable intermediates in the methanol oxidation are also included
B. FolKesson et al., J. Electroanal. Chem., 267 (1989) 149

64. PEDOT is meant to substitute the carbon usually mixed with the inorganic oxide-based electrodes to improve their electronic conductivity; the PEDOT thus functions as electronic conductor
13.4 A0 +
This PEDOT-V2O5 based organic inorganic nanocomposites could be a good
Catalyst support for methanol oxidation

65. Synthesis of poly(3,4-ethylenedioxythiophene)/ V2O5 nanocomposites
V2O5 Powder
(1 g, or mol)
100 ml aqueous solution
of hydrogen peroxide (10%)
V2O5.nH2O gels
0.75ml EDOT
Ammonium persulphate
Dried at 60 0 C
PEDOT/V2O5 nanocomposite

66. Preparation of Pt /PEDOT/ V2O5 nanocomposite
5 %H2Pt Cl6 (35ml)
Stirring at 800C for 30 min
to allow dispersion
0.1 N NaOH added to bring the pH 10-11
20% Formaldehyde
Stirred at 70C for 1 hour
Cooled
Filtered and washed with distilled water
Dried in air oven at 125  C for 4h
20% Pt-PEDOT/V2O5nanocomposite

67. FTIR spectra After intercalation Extra peaks --C-O-COH
After intercalation
Extra peaks
--C-O-C
stretching vibrations
FT-IR spectra of (a) V2O5 (b) V2O5 Xerogel and (C) PEDOT/V2 O5 nanocomposites

68. X- Ray diffraction pattern
After intercalation
Incorporation of PEDOT
in V2O5 increases the
interlayer spacing to
13.4 A0
X-Ray diffraction patterns of (a) V2O5 and (b) PEDOT-V2O5 nanocomposite

69. Thermal studies
first one step 8 % weight loss below 120 C----- due to water
second one step16.2 % weight loss up to 420 C ----combustion of organic polymer
mass gain 2.6 % up to 650 C ---- formation of orthorhombic V2O5
Thermogravimetric curves of (a) V2O5 (b) V2O5 xerogel and (c) PEDOT-V2O5
nanocomposite

70. SEM images of PEDOT/ V2O5 nanocomposite

71. SEM images of PEDOT/ V2O5 nanocomposite
Layered structure

72. SEM/EDX images of Pt-PEDOT/ V2O5 nanocomposite
EDX mapping of Pt on nanocomposite

73. XRD and TEM images of Pt-PEDOT/ V2O5 nanocomposite
Average particle size of 4.52 nm

74. Electrochemical studies
V5+/VO2+
V5+
Cyclic voltammograms in 0.5 M H2SO4 Scan rate : 50mV/s

75. Electrocatalytic activity of the catalyst
Cyclic voltammograms in 0.5 M H2SO4 and 1 M CH3OH Scan rate : 50mV/s

76. Electrocatalytic activity of the catalyst Stability of the electrodes
Methanol oxidation activity of Pt/ PEDOT-V2O5 catalyst
prepared by formaldehyde reduction method
Catalyst
Pt loading g/cm2
Methanol oxidation activity mA/cm2
Pt/(C6H4O2 S)0.4V2O5.0.5H2O 10
28.4
Pt/Vulcan 15
Nearly two times higher activity for the same Pt loading

77. Salient Features
The Pt loaded on PEDOT-V2O5 nanocomposite has been evaluated as the electrode for methanol oxidation in acid medium
EDX mapping and TEM images shows fine dispersion of Pt particles in the nanocomposite leading to a better utilisation of the noble metal catalyst
Electrocatalytic activity of methanol oxidation reaction for Pt/PEDOT-V2O5 was higher than Pt/C

78. Conclusions The salient points of the present investigation are:
The supports for noble metal electro-catalyst have a definite role in the development of electrodes for fuel cells
The functionalization of the support carbon materials is a mean to increase dispersion and also intrinsic activity of the noble metal sites
Oxide supports, though may lead to net loss of energy, can favour the removal of otherwise poisons for the noble metal electro-catalytic sites
Conducting polymers and their composites can be conceived as alternate supports for noble metal electrodes for effective dispersion and intrinsic activity