• My UD
  • UDSIS-Students
  • UDSIS-Staff
  • Sakai
  • E-mail
• People
• Maps
• Find It
• A-Z
  • Z
  • Y
  • X
  • W
  • V
  • U
  • T
  • S
  • R
  • Q
  • P
  • O
  • N
  • M
  • L
  • K
  • J
  • I
  • H
  • G
  • F
  • E
  • D
  • C
  • B
  • A
• UD Home

• Demonstration Projects
  • Fuel Cell Bus Program
• Research Topics
  • Balance of Plant
    • Cell Voltage Monitoring
    • Hydrogen Recirculation Ejector
    • Fuel Cell Manifolds
    • Freeze Protection
  • Battery Studies
    • Battery Cooling
    • Novel Lithium Ion Electrodes
  • Catalysts and Membranes
    • Freeze Tolerant Membranes
    • Novel Poly(arylene ether) Membranes
    • Corrosion Resistant Catalyst Supports
    • Catalyst Degradation Studies
  • Direct Borohydride Fuel Cells
    • Borohydride Electro-Oxidation Studies
  • Direct Methanol Fuel Cells
    • Metal Foam Flowfield and GDLs
    • Mathematical Model
    • Feedback Control
  • Flow Field Design
    • Convective Bypass (Analytic)
    • Flow Field Geometry Optimization
  • Gas Diffusion Layer
    • Metallic GDL
    • Permeability Characterization
    • PIV Measurements
  • Hydrogen Production & Storage
    • Solar Fuels by Thermochemical Cycles
    • Catalysts for Borohydride Hydrolysis
    • Metal Hydride Storage
  • System Level Analysis
    • Vehicle Simulation
    • Real-Time Data Acquisition/User Interface
    • Fuel Cell Bus Operations Analysis
  • Water Management
    • Microvisualization of Catalyst Layer
    • Characteristics of GDL and MPL
    • Simultaneous Optical & Neutron Imaging

RRDE Studies of the Electro-Oxidation of Borohydrides

Rotating ring-disc electrode (RRDE) voltammetry is applied for the in situ determination of hydroxy borohydride (BH₃(OH)^-) formation during borohydride (BH₄^-) electro-oxidation on a gold (Au) electrode in 6.0 M NaOH solution. The BH₃(OH)^- is detected at the ring electrode due to its further oxidation to BH₂(OH)^2- by maintaining its potential in the range of −0.800 to −0.600 V vs. normal hydrogen electrode (NHE) while oxidizing BH₄^- on the disc electrode. The study reveals that the generation of BH₃(OH)^- increases if the anodic polarization of the disc electrode is increased. The RRDE ring-shielding experiments show that the electro-oxidation of BH₄^- occurs over a wide potential range of −0.500 to 0.400 V on the Au electrode under hydrodynamic conditions. Chronoamperometry is also used to study the BH₃(OH)^- oxidation in the potential range of −0.800 to −0.600 V with 0.33 M NaBH₄ in three different buffer solutions of pH 10.2, 11.0 and 11.70, respectively. The chronoamperometric studies indicate that the formation and stability of BH₃(OH)^- depends on the pH value.

Cyclic voltammogram recorded with 0.020 M NaBH₄ on Au electrode, with scan rate of 0.100 V s^-1. A well-defined oxidation peak (a1) and a broad hump (a2) are observed during the forward sweep. A sharp anodic spike (c1) and a broad wave (c2) are observed during the reverse sweep.