Phd Degree / Doktora

Permanent URI for this collectionhttps://hdl.handle.net/11147/2869

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Author: search.filters.author.Çelebi, CemSubject: search.filters.subject.Gas sensor

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  • Doctoral Thesis
    Two Dimensional Material Based Field Effect Transistor for Biosensing Applications
    (01. Izmir Institute of Technology, 2023) İnanç, Dilce; Yıldız, Ümit Hakan; Çelebi, Cem
    This thesis presents research on the use of two-dimensional material graphene as an area-effective transistor and its application in biological fields. The formation of wrinkled and flat structures on the surface of a single-layer graphene area-effective transistor, epitaxially grown for determining the bio-membrane dynamics of graphene, was examined using two different methods of deposition (thermal evaporation and pulsed electron accumulation) of a silicon dioxide (SiO2) layer. The investigation aimed to evaluate the pH and lipid bilayer formation performance of both wrinkled and flat GFETs. Increased sensitivity was determined through electrical measurements, as the oxide layer becomes thinner due to the existence of wrinkles, thus providing electrostatic coating on graphene. A sensor platform of chemiresistor type was developed for the differential determination of volatile organic compounds (VOCs) by synthesizing single-layer, bilayer, and multilayer graphene, enabling the analysis of ethanol (EtOH) and methanol (MetOH). Sensors produced using three different graphene morphologies demonstrated differential MeOH-EtOH responses attributed to the differential intercalation phenomenon in multilayer graphene morphologies when compared to ethanol. For the detection of VOCs such as acetone, ethanol, and hexane in human breath, a polymer nanofiber/multi-walled carbon nanotube or poly (3,4-ethylenedioxythiophene)/gold (Au) and iron oxide (Fe) hybrid bioelectronic interface was developed. Sensitivity studies were conducted by applying pure VOCs at different concentrations to the sensor platforms, and the behavior of the sensor platforms against interfering elements was evaluated by recharacterizing them under CO2 and humidity conditions. Considering the responses of MWCNT-PLLCL-Fe-based sensors to acetone, ethanol, and hexane, the tendency of water molecules to adhere to the Fe surface was shown to decrease water condensation on the conductive layer compared to other sensor configurations, indicating that the humidity effect was minimized in MWCNT-PLLCL-Fe-based sensors.
  • Doctoral Thesis
    Functionalized Cvd Grown Graphene for Gas Sensing Applications
    (Izmir Institute of Technology, 2017) Yağmurcukardeş, Nesli; Çelebi, Cem; Çelebi, Cem; Ünverdi, Özhan
    Graphene is a two dimensional one-atom thick sheet of sp2 bonded carbon atoms arranged in a honeycomb lattice structure. It has high electron mobility and it is the material with the lowest resistivity at room temperature. By changing the edge properties with chemical modification, few-layer graphene may gain new magnetic properties. Besides having unusual electronic properties, single-layer graphene has important gas sensing capability. With the adsorption of the gas molecules, the local carrier concentration of graphene is modified and its resistance is altered. The high mobility, large area ohmic contact and metallic conductivity of graphene help to reduce the background noise and thus make it highly sensitive device even small molecular changes at atomic ranges. In this dissertation, Chemical Vapor Deposition (CVD) grown graphene layers were functionalized by self-assembled monolayers (SAMs) and etched anisotropically by H2 for the first time to improve sensor characteristics for toxic gas sensing. CO, CO2, NH3 gases were used as target molecules. Characterization techniques such as Optical Microscopy, Scanning Electron Microscopy (SEM), Atomic Force Microscopy (AFM), Kelvin Probe Force Microscopy (KPFM), Raman Spectroscopy, Quartz Crystal Microbalance (QCM) and amperometric measurements were used for the investigation of the metal thin film, graphene layers and gas adsorbed film structures. Results indicate that the SAM modification enhanced CO and NH3 absorbing capability of graphene films and also improved their periodic reversible response characteristics. The resistivity results are consistent with frequency change results. Humidity sensitivity of sensors are also decreased significantly due to the applied etching process.