Electrochemical oxidation of ethylenediaminetetraacetic acid in alkaline medium /

Bulk electrolysis of EDTA in alkaline medium suggested that

Bibliographic Details
Main Author: Pakalapati, Surya Narayana Raju, 1968-
Format: Thesis Book
Language:English
Published: [Place of publication not identified] : [publisher not identified] ; 1996.
Subjects:
Online Access:http://proxy.library.tamu.edu/login?url=http://proquest.umi.com/pqdweb?did=739667931&sid=1&Fmt=2&clientId=2945&RQT=309&VName=PQD
Description
Summary:Bulk electrolysis of EDTA in alkaline medium suggested that
stable organic intermediate species are formed. S-EDDA,
glyoxal, formaldehyde and nitrate were identified in the
partially electrolyzed EDTA solution. The oxidation products
suggest that the initial breakdown of EDTA occurs via the
Hofer-Moest type reaction. Complete oxidation reaction
pathways to carbon dioxide are proposed. In alkaline medium,
very little EDTA oxidation was found to occur on bare
platinum. Limiting-current-density behavior due to PtO
formation was observed at potentials immediately positive of
the rest potential. Tafel behavior (Tafel slope: 119
mV/decade) was observed in the potential region positive of
the cessation of oxide film formation and negative of the
onset Of 02 evolution. The reaction orders of EDTA and OH-
were determined to be 0.54 and - 0, respectively. The
reaction mechanism consistent with the observed experimental
data involves Temkin-type adsorption and first-electron-
transfer rate-determining step. Polarization studies of EDTA
and some of the intermediates species (ethylenediamine,
glyoxal, glyoxalate, oxalate, formaldehyde, and formate) were
carried out in alkaline medium using platinized titanium
electrode. Formate and oxalate were found to be oxidized at
rates significantly higher than the oxidation rates of other
intermediate species. EDTA, glyoxalate, and ethylenediamine
were found to oxidize at moderate rates. The aldehydes
(formaldehyde and glyoxal) exhibited the slowest kinetics.
Bench scale parallel plate reactor experiments were carried
out to study the effect of applied current density, flow
rate, and cell configuration on EDTA destruction. The
applied current density was found to have a significant
effect on EDTA destruction rate. The flow rate at an applied
current density of 200 mA/cm,2 had very little effect on EDTA
destruction rate. The divided cell configuration was found
to decrease OH-concentration in the anolyte at a fast rate
which resulted in the decrease in conductivity of the anolyte
solution and an increase in cell potential. A simple
mathematical model of the destruction of EDTA in an undivided
parallel plate reactor is described which takes into account
the reaction chemistry and the observed electrochemical
kinetic behavior of the reactions.
Item Description:Vita.
"Major Subject: Chemical Engineering".
Physical Description:xiii, 124 leaves : illustrations ; 28 cm.
Issued also on microfiche from University Microfilms Inc.
Bibliography:Includes bibliographical references: pages 108-112.