ORR

Presented By
Shanta Majumder
ID: 21714002; Reg No: 21714002
Session: 2016-17
Department of Chemistry
Comilla University
9/16/2019 Department of Chemistry, Comilla University 1

Presentation On
Working Principle & Application of Fuel Cell,
Oxygen Reduction Reaction of Fuel Cell,
Electrocatalysts for Oxygen Reduction Reaction
and Mechanism of Oxygen Reduction Reaction

Working Principle of Fuel Cell
Applications of Fuel Cell
Oxygen Reduction Reaction (ORR)
Mechanism of ORR
Electrocatalysts for ORR
My Today’s Presentation Outline

Construction
• Anode & Cathode: Materials which have
high electric conductivity and zero proton
conductivity in the form of porous catalyst
• Catalyst: Platinum
• Electrolyte: High proton conductivity and
zero electron conductivity
Figure

• Hydrogen or hydrogen –rich fuel, is fed to the anode where a catalyst separates
hydrogen’s negatively charged electrons from positively charged ions.
• At a cathode, oxygen combines with electrons and in some cases, with species
such as protons or water, resulting in water or hydroxide ions, respectively.
• The electrons from the anode side of the cell cannot pass through the membrane to
the positively charged cathode; they must travel around it via an electrical circuit
to reach the other side of the cell.
• This movement of electrons is an electrical current.

Reactions
At cathode: 2𝐻2 → 4 𝐻+ + 4𝑒−
At anode: O2 + 4H+ + 4e−→ 2H2O
Overall reaction: O2 + 2H2→ 2𝐻2 𝑂

Applications of Fuel Cell

• Occurs at cathode
• Produces hydrogen peroxide, super oxide, water or hydroxyl ion based
on electrode materials and the nature of electrolytes
• Kinetics is generally slow
• SEP depends on pathway of reaction
Oxygen Reduction Reaction (ORR)
Standard electrode potentials of the selected ORR
in aqueous electrolytes at 25 °
C
Electrochemical reactions Eo
/ Vvs. SHE
O2 + 4H+
+ 4e−
→ 2H2O 1.229
O2 + 2H+
+ 2e−
→H2O2 0.695
O2 + 2H2O + 4e−
→ 4OH−
0.401
O2 + H+
+ e−
→ HO2 −0.053
O2 + H2O + 2e−
→ + OH− −0.065
O2 + 2H2O + 2e−
→ H2O2 + 2OH−
−0.133
O2 + e−
→ 𝑂2
−
−0.284

Mechanism Oxygen Reduction Reaction
Electrolyte ORR Reaction
Acidic Aqueous Solution O2 + 4H+ +4e- →H2O
O2 + 2H+ +2e- → H2O2
H2O2 + 2H+ +2e- → 2H2O
Alkaline Aqueous
Solution
O2 + H2O +4e- → 4OH-
O2+ H2O + 2e- →HO2
- + OH-
HO2
- + H2O +2e- → 3OH-
Non-aqueous Aprotic
Solvents
O2 + e- → O2
-
O2
- + e- → O2
2-
Mechanism
• 4-electron reduction pathway(O2 to 𝐻2 𝑂)
• 2-electron reduction pathway (O2 to 𝐻2 𝑂2)
• 1-electron reduction pathway (O2 to 𝑂2
−
)

Electrocatalyst
for ORR
Graphite & Carbon
Graphite & Glassy
Carbon
Carbon Nanotubes
Heteroatom Doped
Carbon
Pre-Treated
Carbon Surface
Quinone &
Derivatives
AO Process
Quinone
Metal Catalysts
Platinum
Mixed Pt Surface
Pt AlloysMacrocyclic
Transition Metal
Complexes
Other Catalysts
Transition Metal
Chalcogenides
Transition Metal
Carbide
Electrocatalysts for Oxygen Reduction Reaction

Glassy Carbon Graphite
O2(ads) +e-
→O2
-
(ads) (1)
2O2
-
(ads) +H2O→O2 +HO2
-
+OH-
(2)
ORR on Graphite and Glassy Carbon
Oxygen Reduction Reaction on Graphite & Carbon
𝑂2 → 𝑂2(𝑎𝑑𝑠 ) (1)
O2(ads) + e-
→ [O2(ads)]-
(2)
[O2(ads)]-
→ O2(ads)
-
(3)
O2(ads)
-
+ H2O → HO2(ads) + OH-
(4)
HO2(ads) + e-
→ HO2
-
(ads) (5)
HO2
-
(ads) → HO2
-
(6)

ORR on Carbon Nanotubes ORR on Heteroatom Doped Carbons
• Various heteroatoms, such as N, S, P,
B, and I, have been introduced into
pure carbon materials
• Enhance conductivity and tune the
electron distribution

ORR on Pre-treated Carbon Surface
• More surface functional groups
• Fresh carbon edges, micro particles
• Increase the surface area of carbon

AO Process ORR Catalysed by Quinone
Q+e-
→Qx-
(1)
Qx-
+O2 → O2
x-
+Q (2)
O2
x-
+H2O+e-
→HO2
-
(3)
or
2O2
x-
+H2O→HO2 +O2 +OH-
(4)
Oxygen Reduction Reaction Catalysed by Quinone &Derivatives

Oxygen Reduction Reaction on Metal Catalysts
ORR on Platinum
Dissociative Mechanism:
Associative Mechanism:

Mixed Pt Surface & Rest Potential on Pt
• On Pt and at high potential:
Pt + ½ O2 → PtO Eo = 0.88V
• Here two reactions occur:
Platinum Oxidation
Oxygen Reduction
ORR on Pt Alloys
Due to alloying of Platinum:
• Increase the Pt d- band vacancy
• Change in Pt- Pt interatomic
distance
• Lattice contraction
Oxygen Reduction Reaction on Metal Catalysts

• Reduction proceeds through 2- electron or 4- electron transfer pathway
Mechanism
Oxygen Reduction Reaction on Macrocyclic Transition Metal Complexes

ORR Catalysed by Transition Metal Chalcogenides
• 2 or 4 electron pathway
• Due to semiconducting properties of chalcogenides & occurs
through the interaction of oxygen with transition metal d-
state
• O2 interacts with a transition metal atom of a cluster through a
bridge type bonding to two adjacent metal atoms in the same
cluster.
• The electron transfers between the cluster and the O2 could
result in a metal distance increase, which possibly facilitates
the breaking of the O-O bond and an upward shift of the
electronic level due to the loss of electrons.
• Tungsten Carbide
• The main catalytic activity of carbide is not in the oxygen reduction
reaction, but rather in other reactions such as H2 oxidation.
• WC, TaC, TiC, and TiN showed catalytic activity towards ORR in
acid solutions but these materials are not stable in alkaline solution.
• Even in acid solutions, WC does not show long-term stability in the
presence of O2. Addition of Ta to WC significantly improves its
catalytic activity and stability.
• The best activity can be observed with a W2C-Pt/C catalyst.
Oxygen Reduction Catalysed by Other Catalysts
ORR Catalysed by Transition Metal Carbides

Thank You…….

ORR

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