Mathematical modeling and optimization of a secondary lithium battery utilizing a fibrillar polypyrrole cathode /

A mathematical model for a secondary lithium battery with a

Bibliographic Details
Main Author: Prieto-Irizarry, Ricardo J., 1954-
Format: Thesis Book
Language:English
Published: [Place of publication not identified] : [publisher not identified] ; 1996.
Subjects:
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Description
Summary:A mathematical model for a secondary lithium battery with a
fibrillar polypyrrole cathode is developed to investigate the
dynamic performance of the cell charge and discharge
processes. Dilute solution theory and porous electrode
theory are used to characterize the transport phenomena of
the electrolyte species in the porous polypyrrole electrode
and separator. The model is designed to predict the time
dependent distributions of the electrolyte concentration,
inserted species solid concentration, active material
utilization, solid and liquid potentials and current density
for a given electrode and separator porosity and thickness.
The model evaluates the influence of physical, design, and
operation parameters, such as active surface area, diffusion
coefficients, exchange current density, electrode and
separator porosity and thickness, active material loading or
saturation level of the polypyffole electrode, discharge or
charge rate, and operating temperature, on the dynamic
behavior of a lithium battery with a fibrillar polypyrrole
cathode. A sensitivity analysis of the cell performance
with respect to the model parameters is performed. Results
reveal that the most influential physical parameter on the
cell performance is the maximal faradaic charge and the most
critical cell design parameter is the ratio of the electrode
to separator thickness or the ratio of electroactive and
counterion material. Battery optimization should revolve
around electrode and separator thickness and porosity, while
fibril diameter and electrode porosity are not critical.
Sensitivity analysis shows that the model electrokinetic
parameters have less influence on the cell performance than
those parameters describing the double layer charging and
that the effects of the intercalation phenomena during
discharge are significant. Model predictions indicate that
thin electrodes at low current densities yield the optimal
discharge performance and because of the higher active
material utilization, batteries with a fibrillar morphology
deliver charge at higher rates, cell voltage, power and
energy density than equivalent batteries with conventional
flat film electrodes.
Item Description:Vita.
"Major Subject: Chemical Engineering".
Physical Description:xix, 324 leaves : illustrations ; 28 cm.
Issued also on microfiche from University Microfilms Inc.
Bibliography:Includes bibliographical references.