Graduation Semester and Year
2016
Language
English
Document Type
Dissertation
Degree Name
Doctor of Philosophy in Civil Engineering
Department
Civil Engineering
First Advisor
Hyeok Choi
Second Advisor
Andrew P Kruzic
Third Advisor
Melanie L Sattler
Fourth Advisor
Qinhong Hu
Abstract
Occurrence of Harmful Algal Blooms (HABs) worldwide has caused concern to environmental and health authorities because of their potential to generate and release biological toxins. In particular, microcystins (MCs) produced from cyanobacteria are of great concern. MCs are among the most powerful natural poisons. The presence of MCs in drinking water sources has raised major concern. The overall goal of this research is to predict formation of biological toxins in water bodies and to develop a new sustainable approach to decompose them, if feasible, on-site and in real-time with minimal efforts, less chemicals, and low energy inputs. In order to achieve the goal, the first objective was to predict MC-LR formation during harmful algal blooms utilizing easy-to-detect indirect parameters. There have been efforts to monitor HAB activities and toxin releases, including i) manual field sampling followed by in lab analysis to directly measure MCs (i.e., biological toxins), ii) remote sensing based on satellite image analysis to estimate cyanobacterial index (i.e., algal blooms), and iii) in situ sensing of easily measurable proxy parameters to algal blooms such as phycocyanin (an accessory pigment to chlorophyll associated with HABs). The current observation systems for monitoring HABs discussed while pointing out their advantageous and disadvantages. Second objective was to pioneer a high efficiency visible light-activated TiO2 photocatalytic process to decompose biological toxins. For on-site applications, the TiO2 firmly immobilized onto a glass substrate in form of nanoporous thin film. Effect of operation parameters such as type of surfactants, calcination temperature, number of coatings and pH was investigated. In order to evaluate potential field application of our system, we use lake water spiked with MC-LR under solar radiation and the result showed our film has high potential to decompose biological toxins under solar radiation within a reasonable time
Keywords
Harmful algal blooms, Microcystins, Cyanobacterial index, Monitoring and observation, Biological toxins, TiO2 photocatalysis, On-site treatment
Disciplines
Civil and Environmental Engineering | Civil Engineering | Engineering
License
This work is licensed under a Creative Commons Attribution-NonCommercial-Share Alike 4.0 International License.
Recommended Citation
Zaman Khan Malayeri, Hesam, "HARMFUL ALGAL BLOOMS AND BIOLOGICAL TOXINS PRODUCTIONS; FROM INTEGRATED MONITORING APPROACH TO ON-SITE SOLAR PHOTOCATALYTIC DECOMPOSITION" (2016). Civil Engineering Dissertations. 458.
https://mavmatrix.uta.edu/civilengineering_dissertations/458
Comments
Degree granted by The University of Texas at Arlington