Main Page
About Science
Faculty Deanship
Letter of Dean
Overview of Deanship
Vice Deans
Vice Dean
Letter of Vice-dean
Overview of Vice-deanship
Vice Dean for Graduate Studies
Letter of Vice Dean for Graduate Studies
Overview of Vice Dean of Postgraduate Studies
Research and Innovation Unit
Vice Dean for Girls Campus
Faculty Management
Letter of Managing Director-Boys Campus
Letter of Managing Director-Girls Campus
Overview of Management
Educational Affairs
Males Campus
Staff
Females Campus
Contact Us
Research
عربي
English
About
Admission
Academic
Research and Innovations
University Life
E-Services
Search
Faculty of Sciences
Document Details
Document Type
:
Article In Journal
Document Title
:
Photoelectrocatalytic disinfection of E. coli suspensions by iron doped TiO2
Photoelectrocatalytic disinfection of E. coli suspensions by iron doped TiO2
Subject
:
Photoelectrocatalytic disinfection of E. coli suspensions by iron doped TiO2
Document Language
:
English
Abstract
:
Photoelectrocatalytic disinfection of E. coli by an iron doped TiO2 sol–gel electrode is shown to be more efficient than disinfection by the corresponding undoped electrode. Thus, the improvements in photocatalytic efficiency associated with selective doping have been combined with the electric field enhancement associated with the application of a small positive potential to a UV irradiated titanium dioxide electrode. The optimum disinfection rate corresponds to the replacement of 0.1% of the Ti atoms by Fe. The enhanced disinfection associated with iron doping is surprising because iron doping decreases the photocurrent, and photocurrent is generally taken to be a good indicator of photoelectrocatalytic efficiency. As the level of iron is increased, the character of the current–voltage curve changes and the enhancement of photocurrent associated with methanol addition decreases. This suggests that iron reduces the surface recombination which in the absence of iron is reduced by methanol. Therefore the enhanced photocatalysis is interpreted as due to iron reducing surface recombination, by trapping electrons. It is proposed that at low iron levels the photo-generated electrons are trapped at surface Fe(III) centres and that consequently, because the electron–hole recombination rate is reduced, the number of holes available for hydroxyl radical formation is increased. It is also proposed that at higher iron levels, the disinfection rate falls because electron hole recombination at iron centres in the lattice reduces the number of holes which reach the surface. Our conclusion that the optimum electrode performance is a balance between surface and bulk effects is consistent with the proposal, of earlier authors for photocatalytic reactions that the optimum dopant level depends on the TiO2.
ISSN
:
0
Journal Name
:
Phys. Chem. Chem. Phys
Volume
:
8
Issue Number
:
3
Publishing Year
:
1427 AH
2006 AD
Number Of Pages
:
9
Article Type
:
Article
Added Date
:
Sunday, May 24, 2009
Researchers
Researcher Name (Arabic)
Researcher Name (English)
Researcher Type
Dr Grade
Email
ساميه عبد الحميد محمد
Samia A. M.
Researcher
Doctorate
skousah@kau.edu.sa
Terry A.
Terry A.
Investigator
Doctorate
Paul A.
Paul A.
Researcher
Doctorate
Back To Researches Page