SINTESIS TiO2/Ti DENGAN TEKNIK ANODISASI DAN UJI AKTIVITAS FOTOKATALIS SEBAGAI ANTIBAKTERI Escherichia coli

Authors

  • Resti Fartiwi Jurusan kimia, Fakultas MIPA, Universitas Tanjungpura
  • Warsidah Warsidah Jurusan Ilmu Kelautan, Fakultas MIPA, Universitas Tanjungpura
  • Anthoni Batahan Aritonang Jurusan Kimia, Fakultas MIPA, Universitas Tanjungpura

DOI:

https://doi.org/10.26418/indonesian.v2i3.36899

Abstract

Titanium dioxide (TiO2) thin layer on the surface of metal Ti has been successfully synthesized using anodization method by varying the anodization times 30, 45 and 60 minutes. Characterization of TiO2/Ti with FTIR method gives absorption peaks at wave number 457,490 cm-1 and 796,635 cm-1, which is a Ti-O vibration. Visualization TiO2/Ti under SEM showed pores with diameter of 10-45 nm as an indication of the morphology of nanotubes, although the length of tubes have not been obtained. The results of XRD measurement give diffractogram at 2q: 25,337 °; 37,891 ° and 48,074 ° and characterization DR-UV visible value 3,276 eV band gap which characterize crystalline anatase TiO2 phase. Photocatalytic TiO2/Ti exhibit antibacterial activity Escherichia coli were tested using the method of turbidimetry with a spectrophotometer at wavelength of 600 nm. Photocatalyst TiO2/Ti which are synthesized by anodizing process for 60 minutes have inhibitory bacterial growth better than synthesized for 30 minutes and 45 minutes.

References

Aritonang AB, Krisnandi YK, Gunlazuardi, J. (2018). Modification of TiO2 Nanotube Arrays with N Doping and Ag Decorating for Enhenced Visible Light Photoelectrocatalytic Degradation of Methylene Blue. International J. on Advanced science Engineering Information Technology, 8 (1), 234-241.

Bauer S, Pittrof A, Tsuchiya H, Schmuki P. (2011). Size-effects in TiO2 Nanotubes: Diameter Dipendent Anatase/Rutile Stabilization. Electrochem. Commun., 13 (6), 538-541.

Bensaha R, Bensouyad H. (2012). Synthesis, Characterization and Properties of Zirconium Oxide (ZrO2)-Doped Titanium Oxide (TiO2) Thin Films Obtained via Sol-Gel Process. INTECH., 10, 207-234.

Dumitru C, Popescu M, Ungureanu C, Pirvu C. (2015). Antibacterial Efficiencies of TiO2 Nanostructured Layers Prepared in Organic Viscous Electrolytes, J. Applied Surface science, 341, 157-165.

Khalaf MM, Abdallah NY, El-Lateef HM. (2018). Fine Tamplate Synthetic Process of Mesoporous TiO2 Using Ionic/Nonionic Surfactants as Potential Remediation of Pb(II) from Contaminated Soil. International J. of Environmental Science and Technology, 16, 1933-1944.

Linsebigler AL, Guangguan, Yates Jr JT. (1995). Photocatalysis on TiO2 Surface: Priciples, Mechanisms, and Selected Results. Chem. Rev, 95 (3), 735-758.

Listanti A, Taufiq A, Hidayat A, Sunaryono S. (2018). Investigasi Struktur dan Energi Band Gap Partikel Nano TiO2 Hasil Sintesis Menggunakan Metode Sol-Gel. J. of Physical Science and Engineering, 3 (1), 8-15.

Misriyani, Wahab AW, Taba P, Gunlazuardi J. (2017). Effect of Anodizing Time and Annealing Temperature on Photoelectrochemical Propeties of Anodized TiO2 Nanotube for Corrosion Prenetion Application. Indones. J. Chem., 17 (2), 219-277.

Mohamed AEL, Rohani S. (2011). Modified TiO2 Nanotube Arrays (TNTAs):Progressive Strategies towards Visible Light Responsive Photoanode: a review. Energy Environ. Sci., 4, 1065-1086.

Ohtsu N, Yokoi K, Saito, A. (2015). Fabrication of Visible-Light-Responsive Photocatalytic Antibacterial Coating on Titanium Throught Anodic Oxidation in a Nitrate/Ethylene Glycol Electrolyte, J. Surface and Coating Technology, 261, 97-102.

Pratibha V, Bakre, Tilve SG. (2018). Direct Access to Highly Crystlline Mesoporous Nano TiO2 Using Sterically Bulky Organic Acid Templates. J. of physics and Chemistry of Solids, 116, 234-240.

Rilda Y, Dharma A, Arief S, Alief A, Shaleh B. (2010). Efek Dpoing Aktivitas Fotokatalitik dari TiO2 Untuk Inhibisi Bakteri Patogenik. Makara Sains, 14 (1), 7-14.

Rosariawari F, Masduki A, Hadi W. (2012). Proses Fotokatalisis Untuk Penyisihan E. coli dengan Kombinasi TiO2, Karbon Aktif dan Sinar UV. J. Ilmiah Teknik Lingkungan, 4 (1), 27-35.

Roy P, Berger S, Schuki P. (2011). TiO2 Nanotube: Synthesis and Aplications, Angew, Chem. Int. Ed, 50 (13), 2904-2939.

Thahir R, Rosalin, Kherunnisa, Laurenz S, Puspitasari. (2018). Preparasi dan Karakterisasi Titanium Dioksida (TiO2) Mesopori Sebagai Adsorben Logam Cu(II) dan Methylene Blue. Prosiding Seminar Hasil Penelitian, pp, 53-57.

Touc J, Grigorovici R, Vancu. (1966). Optical Properties and Electronic Structure of Amorphous Germanium. Phys. Status Solid, 15, 627-637.

Tussa’adah R, Astuti. (2015). Sintesis Material Fotokatalisis TiO2 Untuk Penjernihan Limbah Tekstil. J. Fisika Unand, 4 (1), 91-96.

Wibowo D, Nurdin M, Maulidiyah. (2013). Fabrikasi Elektroda TiO2/Ti Nanotube dengan Metode Anodizing Terdoping Nitrogen dan Logam Ag: Uji Kinerja Degradasi Senyawa Organik Rhidamin B. J. Prog. Kim., 3 (1), 41-55.

Widodo RT, Hermawan H, Arief Z, Ningrum ES, Hendriawan A. (2013). Penumbuhan Nanokristal TiO2 Sebagai Bahan Fotokatalis dengan Teknik Sintesis Elektro-kimia Anodisasi. Prosiding Conference on Smart-Green Technology in Electrical and Information Systems, Bali.

Downloads

Published

2019-10-10

Issue

Section

Articles