6^th Global Summit and Expo on Pollution Control May 06-07, 2019 | Holiday Inn Amsterdam – Arena Towers | Amsterdam, Netherlands

Shiao-Wei Kuo is a Professor in the Department of Materials and Optoelectronic Science at National Sun Yat-Sen University, Taiwan. He has received his PhD in Applied Chemistry from National Chiao-Tung University, Taiwan. After some years of Post-doctoral research work there and in the University of Akron, USA, he joined National Sun Yat-Sen University as a Faculty Member. Now, he is also the Coordinator of Polymer Science and Engineering Program, Ministry of Science and Technology in Taiwan, RSC Fellow, Associate Editor in Journal of Polymer Research, and several Editorial Board Members in journals. His research interests include polymers, supramolecules, self-assembly nanostructures, mesoporous materials, POSS nanocomposites, low surface free energy materials, and polypeptides. He has published over 300 SCI papers and several book and book chapters. His total ciatition is >10000 and H-index is 53.

We have utilized several unique amphiphilic block copolymers as templates to successfully fabricate a series of mesoporous materials, for example, mesoporous silicas, mesoporous phenolic resins and mesoporous carbons by a convenient EISA method. In addition, we expended the research method to the many block copolymer systems, especially for the unusual ABC type triblock copolymers, we obtained the hierarchical mesostructure by single template. These specific mesostructures could be observed easily by small angle X-ray scattering (SAXS), transmission electron microscopy (TEM) and isotherm N2 experiment. Moreover, blending technique could also be used in the templating process during EISA; the clear method could easily control the morphology and pore size of the mesoporous materials.

Yehya Elsayed is an Associate Professor of Chemistry at the American University of Sharjah (AUS). In 2006, he received his PhD in Chemistry from the Graduate Center at the City University of New York. Immediately after graduation, he joined Donaldson Company as a Senior Scientist where he was responsible for the development of new filtration technologies for environmental, industrial and medical applications. He joined AUS in 2009. His recent work is focused on the development of new adsorbents using local raw and waste materials. Moreover, he is involved in the chemical identification and health assessment of harmful compounds in the smoke generated from hookah, midwakh, and Arabian incense. In 2015, he received a joint grant from General. Electric directed toward dust profiling and analysis near GCC airports. He has co-authorship of several patent applications, peer-reviewed journal articles, and conference proceedings.

Due to rapid urbanization, climate change, industrial activities, and improper managements, access to clean water is threatened with time. Phenols are classified to be one of the most hazardous pollutants found in industrial wastewater that contributes significantly to water pollution. Activated carbon fibers (ACFs) of high surface area are developed from Polyacrylonitrile (PAN) and compared with other granular activated carbon materials. The PAN fibers were stabilized initially followed by carbonization either by physical (carbon dioxide) or chemical (potassium hydroxide) activation. The stabilization, carbonization and activation conditions such as flow rate, temperature, time and dosages were optimized. The synthesized ACFs as well as the intermediate materials were characterized using Scanning Electron Microscopy(SEM), Energy-DispersiveX-raySpectroscopy(EDS),Thermogravimetric Analysis (TGA) and Carbon, Hydrogen, Nitrogen and Sulphur content (CHNS) methods. The synthesized ACFs with highest surface area as well as commercial ACFs (C-ACFs) were evaluated for p-cresol removal from water and later applied for produced water treatment. The results showed that ACF, produced by chemical activation (Syn-ACF) using 3:1 by weight KOH: carbonized fiber produced, have very high surface area (2885 m2/g) compared to the ones produced by physical activation (774 m2 /g) and exceed by far those reported in the literature using KOH. The adsorption study on Syn-ACF gave a higher removal efficiency of 90.0% of p-cresol in comparison with 71.6% using commercial C-ACFs at challenge concentration of 350 ppm. In addition, the adsorption isotherms of p-cresol on C-ACFs and Syn-ACFs were measured and found to fit well using Langmuir isotherm; however, Syn-AFCs revealed higher Qmax=500 mg/g compared to C-ACFs Qmax=294 mg/g at 25°C. Regeneration of the contaminated Syn-ACFs with p-cresol was done using two methods: thermally at 600°C and chemically with n-Hexane achieving removal efficiency of 84% and 78%, respectively. The adsorption study using the Syn-ACFs was completed using produced water to ensure a removal of 71.2%.