Titanium Dioxide Sensitized with Porphyrin Dye as a Photocatalyst for the Degradation of Water Pollutants Kevin Reyes, A.S. & Ivana Jovanovic, Ph.D. Department.

Slides:



Advertisements
Similar presentations
TOWARDS GREEN PRODUCTION OF CHEMICALS: INCREASE SOLAR ABSORPTION WITH BLUE TITANIA NANO-PARTICLES MOHAMED S. HAMDY.
Advertisements

Colors of M & Ms and Skittles Dr. Frank Walmsley Trinity University San Antonio, TX
Photocatalytic reduction of CO 2 with TiO 2 -based semiconductor catalyst Reporter: Xiang Tianyu Supervisor: Xin Feng.
Chapter 14 Applications of Ultraviolet-Visible Molecular Absorption Spectrometry.
Introduction to Spectrophotometry
Solubility Product Constant Factors Affecting Solubility Selective Precipitation.
Determination of Iron in Water
Determination of Iron in Water
Copper sulfate solution and potassium iodide solution
Rokospol a.s. Czech republic. The worst removable side products of human activities: -car exhaust fumes -cigarette smoke -organic solvents released from.
Samuel Shisso Project SEED Summer 2010 Abstract Background Procedures and Results With this research, I was assigned to work specifically with the TiO.
Li Yanping 讨论制备方法对光催化剂 CuO/TiO 2 活性的影响. Recent experimental summary Other researchers’ reports.
2. Experimental 4. Conclusions Nano crystalline zinc oxide can be prepared by a simple and cost-effective sol–gel process using aromatic acid ( salicylic.
QUANTUM DOTS , 9,7 0":, 39: ,/ :8, 3 / 6:, 39: ":, 39:2498 &36: "498 ',7 4:8,-7., 943! !
Electricity from Light: The Grätzel Cell. Electromagnetic Spectrum  -rays X-raysUVIRFMAM Radio Waves Long Radio Waves Wavelength ( )
1 Date: Speaker: G. Magesh Visible light photocatalytic activity of PbSe nanocrystal/TiOx films Reference: C. Wang, K. Kwon, M. L. Odlyzko, B.
Zinc Porphyrin Chromophores A qualitative introduction…
Xiukai Li et al., Applied Catalysis A: General 429 (2012) 31
Nafion layer-enhanced photosynthetic conversion of CO 2 into Hydrocarbons on TiO 2 nanoparticles Wooyul Kim et al., Energy Environ. Sci., 5, 2012, 6066.
Department of Chemistry, Clemson University, Clemson, SC 29634
SPECTROPHOTOMETRY PRACTICAL 213 PHC INSTUMENTAL ANALYSIS.
Nature Inspired Nanomaterials Easy to clean and self cleaning materials Florian Doll Ruta Ruperte Nina Muratovska Sigrid Aamot Jan Dobeš 1.
Project #3: Optical Method for Detection and Analysis of Biological Molecules Participants: Heather K. Cooper, Chemistry, University of Cincinnati, Senior.
By: Monal Patel. Did you know that blackberry juice can be used to convert light energy into electrical energy? Dye-sensitized solar cells are photovoltaic.
National I-lan University, Taiwan 1 Photocatalyst Titanium Nanotubes Study Treatment of Volatile Organic Compounds.
Synthesis of Carbon Quantum Dots and Their Use as Photosensitizers Anthony J. Lemieux, Christine A. Caputo Department of Chemistry, University of New Hampshire,
“Self-cleaning coatings of doped TiO 2 nanostructured powders for applications in construction industry” I. Deligkiozi *, P. Karlsson, T. Kosanovic, M.
Dinuclear Ruthenium Complexes as Photosensitizers Emily Woodard Department of Chemistry.
Results: Figure 3. a) Fluorescence spectra of SNP-NH 2 at different irradiation times for the excitation wavelength λ exc = 330 nm. b) Fluorescence enhancement.
Effect of spectral characteristics of different retail lightings and residual oxygen on cured meat products Nadine Böhner, Wolfgang Danzl, Klaus Rieblinger.
Application of AOPs for the removal of nonylphenol and short-chain nonylphenol ethoxylates from water and wastewater effluent Klontza E.E.1,*, Xekoukoulotakis.
Preparation and Characterization of Beta-glucan/silica Nanocomposites
SYNTHESIS OF π-EXTENDED TETRAPHENYLPORPHYRINS
BIOSYNTHESIS OF SILVER NANOPARTICLES USING MELIA DUBIA LEAF AQUEOUS EXTRACT AND ITS ANTIBACTERIAL ACTIVITY   Submitted by:
Zr AND Cu MODIFIED TiO2 PHOTOCATALYSTS FOR WATER TREATMENT
Experimental results II Experimental results I
Sol–gel preparation of efficient red phosphor Mg2TiO4:Mn4+ and XAFS investigation on the substitution of Mn4+ for Ti4+ Tiannan Ye, Shan Li, Xueyan Wu,
Fabrication of Hybrid Solar Cells using ZnS Nanoparticles
Temporal Thin Film Stability Studies Using Silver Nanoparticles
Reduction Potential of Red Light-Emitting Si NPs
M. Dhanasekar, Dr. S. Venkataprasad Bhat*
Lab.8
Adsorption capacity study of activated bone carbon to remove yellow dye tartrazine from aqueous solution I. M. Reck, R. M. Paixão, R. Bergamasco, M. F.
Rama Gaur and P. Jeevanandam*
Prof. Sergiy Lavrynenko National Technical University “Kh. P. I
Ganesan Raja, Siwon Kim, Dahye Yoon, Heonho Lee and Suhkmann Kim*
Synthesis and Characterization of ZnO-CdS Core-Shell Nanohybrids by Thermal Decomposition Method and Studies on Their Charge Transfer Characteristics Rama.
Colors of M & Ms and Skittles
Volume 21, Issue 1, Pages (January 2014)
The 7th International Color and Coating Congress December 2017
Volume 21, Issue 1, Pages (January 2014)
Nanotechnology.
ICAME-2017 Yildiz University
Light-Triggered Differentiation of Human Neural Stem Cells to Neurons
Analytical methods Prepared By Dr. Biswajit Saha.
BiVO4 and WO3 nanophotocatalysts:
Research and Development Department of United Global Pavings
Energy Conversion in Natural and Artificial Photosynthesis
Shiue-Chang Lee#, Wen-Ta Chiu and Yuh-Shan Ho*
Data and Interpretation 4NaHSO4+5NaClO24ClO2+2H2O+4Na2SO4 (2)
Project #3: Optical Method for Detection and Analysis of Biological Molecules Participants: Heather K. Cooper, Chemistry, University of Cincinnati, Senior.
Lab Activity 7 IUG, Fall 2017 TMZ.
Volume 5, Issue 3, Pages (March 2019)
Lab Activity 7 IUG, Fall 2017 TMZ.
Lab Session 7 IUG, 2012 TMZ.
Energy Conversion in Natural and Artificial Photosynthesis
Fiber-Dependent and -Independent Toxicity of Islet Amyloid Polypeptide
By Osifeko, Olawale Lawrence and Prof. T. Nyokong
Volume 2, Issue 6, Pages (June 2017)
Spectroscopic Studies of Brooker’s Merocyanine in Zeolite L
Presentation transcript:

Titanium Dioxide Sensitized with Porphyrin Dye as a Photocatalyst for the Degradation of Water Pollutants Kevin Reyes, A.S. & Ivana Jovanovic, Ph.D. Department of Chemistry, New York City College of Technology, CUNY Abstract Methods Results TiO2 was sensitized with a porphyrin, Tetra(4-carboxyphenyl) porphyrin(TCPP) and used as photocatalyst under visible light for degradation of aqueous solutions of methylene blue (MB) dye. The quantification of the degradation of MB was assessed by UV-Vis spectroscopy. The results of this procedure showed the decrease in concentration of MB over time when reaction is exposed to visible light. The TiO2-TCPP complex was tested as well for the recovery of metals from the AgNO3 aqueous solution. The reduction of silver cations to silver metal was observed through formation of black precipitate. Preparation of  TiO2 -TCPP complex: 16mg of TCPP was dissolved in 30 mL of ethanol and mixed with 400mg of TiO2. The mixture was stirred overnight away from the light to produce TiO2 coated with TCPP. The mixture was centrifuged to separate solid TiO2-TCPP complex, and washed with ethanol and water three times. The brownish/pinkish solid of TiO2-TCPP complex was let to dry for 24h (fig 2).[2] The photocatalytic activity of TiO2 under UV and visible light: TiO2 - TCPP complex as photocatalyst under visible light: 30mg of TiO2 -TCPP and 3.0mM MB solution was let to equilibrate for 1h in the dark, then irradiated with the visible light lamp for 2 h. A control test was preformed - same sample left in the dark for 2h. The UV-Vis spectrum of MB was observed over the course of 2h. The irradiated solution was left in the sunlight for 3 days, and the dark solution was kept in the dark (resulting solutions fig 6). TiO2 -TCPP as photocatalyst for precipitation of metals: 30mg of TiO2-TCPP was suspended in water. And mixed with 5 ml 1mM AgNO3 and 1 ml of 2-propanol[3] and irradiated under visible light for 2h, then left in the sunlight for 3 days (fig 7). The black precipitate was formed indication of the reduction of Ag+ to Ag 0. A C A B B D Fig. 2. A. The TiO2-TCPP complex powder seen to have a brown color as opposed to B. the white color of solid TiO2. Introduction Fig. 4. Absorption spectra of 1.5mM MB monitored over 2h of irradiation with A. UV lamp (660nm band decreased) and C. UV-Vis lamp (660nm decreased very little) when TiO2 as photocatalyst was used. B. and D. The linearized percentage of initial concentration over time. A B Two 1.5mM aq. solutions of MB were mixed with 30mg of TiO2 and left for 30 min in the dark to equilibrate. One was irradiated with a UV lamp and 2nd with visible spectrum LED lamp for 2h (fig 3). Every 30 min during the irradiation period, an aliquot was taken from each, solution, filtered and examined by UV-Vis spectrophotometer. A C A B C Fig. 1. A. The tetragonal crystalline structure of TiO2, the red molecules being oxygen and the gray molecules being titanium. B. The molecular structure of Tetra(4-carboxyphenyl) porphyrin (TCPP) C. Rendition of TCPP attaching to the surface of a TiO2 crystal.[2] B D Fig. 3. A. The UV light set-up with the TiO2-MB solution (right), and MB only solution (left). B. The visible light set-up with the MB only solution(front), the TiO2-MB solution (back left), and TiO2-TCPP-MB solution(back right). Fig. 5. Absorption spectra of  3.0mM MB monitored over 2h of irradiation with A. UV-Vis lamp and C. in dark (no light) using TiO2-TCPP as photocatalyst. 660nm band decreased over time in both samples, significant difference was not observed.   B. and D. The linearized percentage of initial concentration over time. Titanium dioxide is a non-toxic, white, crystalline, semiconductor that has applications across many industries, from its use as a food additive, to solar cell panels. It is useful as a photocatalyst under UV wavelengths due to its electronic properties. More importantly, when treated with porphyrins, it is observed that the photocatalytic properties of TiO2 shift to be more sensitive under the visible light spectrum. This molecular complex (fig 1) becomes a cost-effective candidate for the degradation of water pollutants. When excited, the TiO2 valence electrons have enough energy to produce highly reactive oxidizing species(ROS) such as hydroxyl(•OH) and superoxide(O2•-) radical anions that can promote the degeneration of water pollutants.[1] After 3 days in sunlight and dark A B Fig. 6. A. TiO2-TCPP in 3.0mM MB solution left in sunlight. Solution colorless, no band at 660 nm was observed.  B. TiO2-TCPP in 3.0mM MB solution left in the dark; purple color is indication of TCPP in solution, confirmed with the absorption spectra showing bands of porphyrin. Conclusion TiO2 sensitized with TCPP was observed to be a viable photocatalyst for the degradation of methylene blue in an aqueous solution, as well as a viable reducing agent for cationic metals from an aqueous solution. Further research is required to examine the adsorption effect of MB to TiO2 to explain similar result obtained in the light and dark samples. This research can be expanded to the degradation of different “pollutants”. Further applications can be for the reduction of metal cations to form metal nanoparticles which have applications across many scientific fields. References [1] Pelaez, M. et al. Applied Catalysis B: Environmental 2012, 125, 331–349. [2] Wang, H. et al. Materials Research Bulletin 2014, 57, 311–319. [3]Pearson, Andrew, et al.  Langmuir, vol. 27, no. 15, 2011, pp. 9245–9252. Fig .7. Precipitation of Ag metal Acknowledgements Special thanks to Professor Hamid Norouzi, Director of Undergraduate Research, and the Emerging Scholars Program at the New York City College of Technology.