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Electronic And Optoelectronic Transport Properties Of Carbon Nanotube/organic Semiconductor DevicesSarker, Biddut 01 January 2012 (has links)
Organic field effect transistors (OFETs) are of significant research interest due to their promising applications in large area, low-cost electronic devices such as flexible displays, sensor arrays, and radio-frequency identification tags. A major bottleneck in fabricating highperformance OFET is the large interfacial barrier between the metal electrodes and organic semiconductors (OSC) which results in an inefficient charge injection. Carbon nanotubes (CNTs) are considered to be a promising electrode material which can address this challenge. In this dissertation, we demonstrate fabrication of high-performance OFETs using aligned array CNT electrodes and investigate the detailed electronic transport properties of the fabricated devices. The OFETs with CNT electrodes show a remarkable enhancement in the device performance such as high mobility, high current on-off ratio, higher cutoff frequency, absence of short channel effect and better charge carrier injection than those OFETs with metal electrodes. From the low temperature transport measurements, we show that the charge injection barrier at CNT/OSC interface is smaller than that of the metal/OSC interface. A transition from direct tunneling to Fowler-Nordheim tunneling observed in CNT/OSC system shows further evidence of low injection barrier. A lower activation energy measured for the OFETs with CNT electrodes gives evidence of lower interfacial trap states. Finally, OFETs are demonstrated by directly growing crystalline organic nanowires on aligned array CNT electrodes. In addition to investigating the interfacial barrier at CNT/OSC interface, we also studied photoconduction mechanism of the CNT and CNT/OSC nanocomposite thin film devices. We found that the photoconduction is due to the exciton dissociations and charge carrier separation caused by a Schottky barrier at the metallic electrode/CNT interface and diffusion of the charge iv carrier through percolating CNT networks. In addition, it is found that photoresponse of the CNT/organic semiconductor can be tuned by changing the weight percentage of CNT into the organic semiconductors.
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Molecular Designs for Organic Semiconductors: Design, Synthesis and Charge Transport PropertiesKale, Tejaswini Sharad 13 May 2011 (has links)
Understanding structure-property relationship of molecules is imperative for designing efficient materials for organic semiconductors. Organic semiconductors are based on π-conjugated molecules, either small molecules or macromolecules such as dendrimers or polymers. Charge transport through organic materials is one of the most important processes that drive organic electronic devices. We have investigated the charge transport properties in various molecular designs based on dendrons, dendron-rod-coil molecular triads, and conjugated oligomers. The charge transport properties were studied using bottom contact field effect transistors, in which the material was deposited by spin coating.
In case of dendrons, their generation and density of charge transporting functionalities were found to play a significant role in influencing the charge transport properties. In case of macromolecules such as dendron-rod-coil molecules, the solid state morphology plays a significant role in influencing the charge transport properties. While these molecules exhibit only electron transporting behavior in field-effect transistor measurements, ambipolar charge transport is observed in the diode configuration.
Short conjugated oligomers, based on donor-acceptor-donor design, provide model systems for conjugated polymers. Effect of varying the donor functionality on optoelectronic and charge transport properties was studied in short donor-acceptor-donor molecules. While donor-acceptor-donor molecules are well known in the literature, the effect of molecular composition on the charge transport properties is not well understood. We designed molecules with 2,1,3-benzothiadiazole as the acceptor and thiophene based donor functionalities. These molecules exhibit a reduced bandgap, good solution processability and charge mobility making them interesting systems for application in organic photovoltaics.
Cyclopentadithiophene (CPD) based materials have been widely utilized as organic semiconductors due to their planar nature which favors intermolecular charge transport. While most CPD based materials are hole transporting, incorporation of electron withdrawing fluorinated substituents imparts n-type behavior to these molecules. This change in charge transport properties has often been attributed to the lowering of the LUMO energy level due to the increased electron affinity in the molecule. We designed CPD based semiconductors in which the bridgehead position was functionalized with electron withdrawing ketone or dicyanomethylene group and the -positions were substituted with phenyl or pentafluorophenyl groups. Both the phenyl substituted molecules are p-type materials, even though the dicyanomethylene group lowers the LUMO by 500 meV as compared to the carbonyl compound. The pentafluorophenyl substituted molecules are n-type materials even as their LUMO energy levels are about 300 meV higher than the corresponding phenyl substituted molecules. This indicates that charge transport behavior is not an exclusive function of the frontier orbital energy levels.
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Charge Transport Studies of Proton and Ion Conducting MaterialsVersek, Craig William 01 May 2013 (has links)
The development of a high-throughput impedance spectroscopy instrumentation platform for conductivity characterization of ion transport materials is outlined. Collaborative studies using this system are summarized. Charge conduction mechanisms and conductivity data for small molecule proton conducting liquids, pyrazole, imidazole, 1,2,3-triazole, 1,2,4-triazole, and select mixtures of these compounds are documented. Furthermore, proton diffusivity measurements using a Pulse Field Gradient Nuclear Magnetic Resonance (PFG NMR) technique for imidazole and 1,2,3-triazole binary mixtures are compared. Studies of azole functionalized discotic and linear mesogens with conductivity, structural, and thermal characterizations are detailed.
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Thermoelectric Properties of Carbon Nanotubes (CNT) - Fibroin CompositesEnyinnaya, Chukwuka January 2022 (has links)
No description available.
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A Theoretical Study of Charge Transport in Molecular CrystalsMozafari, Elham January 2013 (has links)
The main objective of this thesis is to provide a deeper understanding of the charge transport phenomena occuring in molecular crystals. The focus is on the stability and the dynamics of the polaron as the charge carrier. To achieve this goal, a series of numerical calculations are performed using the semi-emprical "Holstien-Peierls" model. The model considers both intra- (Holstein) and inter- (Peierls) molecular interactions, in particular the electron-phonon interactions. First, the stability of the polaron in an ordered two dimensional molecular lattice with an excess charge is studied using Resilient backPropagation, RPROP, algorithm. The stability is defined by the "polaron formation energy". This formation energy is obtained for a wide range of parameter sets including both intra- and inter-molecular electron-phonon coupling strengths and their vibrational frequencies, transfer intergral and electric field. We found that the polaron formation energies lying in the range of 50-100 meV are more interesting for our studies. The second step to cover is the dynamical behaviour of the polaron. Using the stable polaron solutions acheived in the first step, an electric field is applied as an external force, pushing the charge to move. We observed that the polaron remains stable and moves with a constant velocity for only a limited range of parameter sets. Finally, the impact of disorder and temperature on the charge dynamics is considered. Adding disorder to the system will result in a more restricted parameter set space for which the polaron is dynamically stable and mobile. Temperature is included in the Newtonian equations of motion via a random force. We observed that the polaron remains localized and moves with a diffusive behaviour up to a certain temperature. If the temperature increases to values above this critical temperature, the localized polaron becomes delocalized. All this research work is coded in MATLAB software , allowing us to run the calculations, test and validate our results.
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Monte Carlo Simulations of charge Transport in Organic SemiconductorsAung, Pyie Phyo January 2014 (has links)
No description available.
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Studying Spin and Charge Coupling in Operational Spintronic Devices Using Multi-Mode Magnetotransport Scanning Probe Microscopy and Ferromagnetic ResonanceBerger, Andrew Joseph 28 May 2015 (has links)
No description available.
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DNA Manipulation and Characterization for Nanoscale ElectronicsHartzell, Brittany January 2004 (has links)
No description available.
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The nature of electronic states in conducting polymer nano-networksAdetunji, Oludurotimi Oluwaseun 15 April 2008 (has links)
No description available.
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Elucidating the Mid-Infrared Spectral Signatures of Bipolarons in Doped Organic Conjugated Polymers: A Holstein-style Multiparticle ApproachBalooch Qarai, Mohammad, 0000-0002-0947-0557 05 1900 (has links)
Organic conducting polymers are essential for the development of various electronic devices, including field-effect transistors, light-emitting diodes, solar cells, and thermoelectric devices. Understanding the charge transport mechanisms within these materials, particularly the roles of polarons and bipolarons as charge carriers, is crucial. Despite the recognized importance of these carriers, there are ongoing debates regarding the interpretation of their mid-IR absorption spectral signatures in the 0.3-0.7 eV range. This is mainly due to challenges in applying the conventional mid-gap state model, especially in the context of doped P3HT (poly(3-hexylthiophene)) films. The conventional model predicts a blueshift for the mid-IR P1 band of bipolarons compared to polarons, yet recent experiments reveal both blueshifted and redshifted bands, at elevated oxidation levels, leading to confusion about the true mid-IR spectral hallmark of spinless singlet bipolarons. This thesis aims to resolve these inconsistencies by proposing a Holstein-style model for singlet bipolarons in π-conjugated polymers with nondegenerate ground states. The model incorporates hole hopping, electron−vibration coupling involving the prominent aromatic-quinoidal mode, and Coulombic interactions between (hole) polarons and between polarons and dopant anions. In contrast to the conventional interpretation where bipolaron formation results from self-trapping, our findings indicate that it is primarily driven by attractive electrostatic interactions with dopant anions. Without these anions, two holes would not pair to form singlet bipolarons. More importantly, our results indicate that the observed blueshift at lower oxidation levels signifies the increased localization of Coulombically interacting polarons, whereas at higher oxidation levels, the simultaneous emergence of both redshifted and blueshifted bands is indeed the spectral signature of spinless singlet bipolarons formation. Furthermore, we find that the binding energy of bipolarons in π-stacks of P3HT chains is significantly higher, nearly threefold, than in a single chain, highlighting the profound influence of long-range order and chain stacking on bipolarons formation. This work contributes to resolving the theoretical ambiguities surrounding charge carrier dynamics in organic conjugated polymers and enhances our understanding of their optoelectronic properties. / Chemistry
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