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INTEGRATION OF CERAMIC-METAL VERTICALLY ALIGNED NANOCOMPOSITE THIN FILMS ON FLEXIBLE MICA SUBSTRATESJuncheng Liu (13113660) 18 July 2022 (has links)
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<p>Integration of functional thin films on flexible substrates has piqued interests owing to the needs of flexible devices. Selecting a suitable flexible substrate is crucial for such integration. Recently, muscovite mica has been developed as a flexible platform for functional thin film epitaxy growth. Mica can be easily peeled off due to the weak van der Waals interaction between different layers of mica, along with other advantages including cheap, high elasticity and thermal stability, biocompatible, <em>etc</em>. On the other hand, vertically aligned nanocomposites (VANs) have been attractive because of their unique anisotropic structures, which can achieve physical property anisotropy, easy tunability, out-of-plane strain engineering as well as combined multifunctionality. However, limited work on the integration of nanocomposite thin films on mica with tunable physical properties has been reported due to growth challenges. </p>
<p>In this dissertation, different ceramic-metal VAN systems integrated on mica substrates towards different functionalities using pulsed laser deposition (PLD) have been demonstrated. The first chapter is on the integration of BaTiO3-Au nanocomposite system on mica. Tunable optical properties have been achieved by controlling the geometries of the Au nanostructures between nanoparticles and nanopillars by varying the growth temperature. The laser energy was also found to play a role in terms of the Au pillar dimension. The second chapter is on the integration of BaZrO3-Co VAN system on mica towards flexible spintronics. Tunable, anisotropic ferromagnetic property has been realized by controlling the aspect ratio of the Co pillars. The third chapter is on integration of BaTiO3-Fe VAN system on mica towards multiferroics. Different buffer layers have been tried out to facilitate the growth of VAN structure. Room temperature ferroelectric and anisotropic ferromagnetic properties of the films have been confirmed. The last chapter is focused on multiphase nitride-metal nanocomposite design and integration, with films showing unique optical and magnetic properties. The reliability and stability of the physical properties of the films have been verified though bending tests. The growth mechanism and criteria of ceramic-metal nanocomposite on mica have also been discussed. These demonstrations all pave a new way towards the integration and design of multifunctional nanocomposites towards flexible nanodevices.</p>
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TUNABLE MULTIFUNCTIONALITIES ACHIEVED IN OXIDE-BASED NANOCOMPOSITE THIN FILMSXingyao Gao (8088647) 06 December 2019 (has links)
<p>Functional oxide-based thin films
have attracted much attention owing to their broad applications in modern
society. The multifunction tuning in oxide thin films is critical for obtaining
enhanced properties. In this dissertation, four new nanocomposite thin film
systems with highly textured growth have been fabricated by pulsed laser
deposition technique. The functionalities including ferromagnetism,
ferroelectricity, multiferroism, magnetoelectric coupling, low-field
magnetoresistance, transmittance, optical bandgap and dielectric constants have
been demonstrated. Besides, the tunability of the functionalities have been
studied via different approaches.</p>
<p>First, varies deposition
frequencies have been used in vertically aligned nanocomposite BaTiO<sub>3</sub>:YMnO<sub>3</sub>
(BTO:YMO) and BaTiO<sub>3</sub>:La<sub>0.7</sub>Sr<sub>0.3</sub>Mn<sub>3
</sub>(BTO:LSMO) thin films. In both systems, the strain coupling effect
between the phases are affected by the density of grain boundaries. Increasing
deposition frequency generates thinner columns in BTO:YMO thin films, which
enhances the anisotropic ferromagnetic response in the thin films. In contrast,
the columns in BTO:LSMO thin films become discontinuous as the deposition
frequency increases, leading to the diminished anisotropic ferromagnetic
response. Coupling with the ferroelectricity in BTO, the room temperature
multiferroic properties have been obtained in these two systems.</p>
<p> Second, the
impact of the film composition has been demonstrated in La<sub>0.7</sub>Ca<sub>0.3</sub>MnO<sub>3</sub>
(LCMO):CeO<sub>2 </sub>thin film system, which has an insulating CeO<sub>2 </sub>in
ferromagnetic conducting LCMO matrix structure. As the atomic percentage of the
CeO<sub>2 </sub>increases, enhanced low-field magnetoresistance and increased
metal-to-insulator transition temperature are observed. The thin films also
show enhanced anisotropic ferromagnetic response comparing with the pure LCMO
film.</p>
<p> Third, the
transition metal element in Bi<sub>3</sub>MoM<sub>T</sub>O<sub>9 </sub>(M<sub>T</sub>,
transition metals of Mn, Fe, Co and Ni) thin films have been varied. The thin
films have a multilayered structure with M<sub>T</sub>-rich pillar-like domains
embedded in Mo-rich matrix structure. The anisotropic magnetic easy axis and
optical properties have been demonstrated. By the element variation, the
optical bandgaps, dielectric constants as well as anisotropic ferromagnetic
properties have been achieved. </p>
<p> The studies
in this dissertation demonstrate several examples of tuning the
multifunctionalities in oxide-based nanocomposite thin films. These enhanced
properties can broaden the applications of functional oxides for advanced
nanoscale devices.</p><br>
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Integration of oxide-metal and nitride-metal vertically aligned nanocomposites on silicon toward device applicationsMatias Kalaswad (9371222) 26 July 2021 (has links)
<p>Devices that can
process more information in reduced dimensions are essential for an
increasingly information- and efficiency-driven future. To this end,
nanocomposites are promising due
to their inherent multifunctional properties and special behavior at the nanoscale.
Vertically aligned nanocomposites (VANs) are particularly interesting because
of their ability to self-assemble into anisotropic nanostructures and high density
of heterointerfaces – characteristics which introduce unique functionalities
and offer exciting new avenues for device applications. However, a vast
majority of VAN systems are currently fabricated on single-crystal oxide substrates,
which may be cost-prohibitive at large scales and are generally incompatible
with the prevalent device fabrication techniques. Thus, integration of VAN thin
films on silicon becomes a critical step toward implementing VANs in a
well-established semiconductor manufacturing industry. </p>
<p>In this dissertation, the
viability of oxide-metal and nitride-metal VAN thin films integrated on silicon
substrates has been demonstrated through a set of unique buffer layer designs. For
the first three systems presented in this dissertation, namely, LaSrFeO<sub>4</sub>-Fe,
BaTiO<sub>3</sub>-Au, and BaTiO<sub>3</sub>-Fe, microstructural and physical property
(i.e. electrical, magnetic, and optical) analyses confirm their successful epitaxial
growth on silicon, with only minor differences compared to their counterparts
grown on single-crystal oxide substrates. For the fourth system, a new and
robust TiN-Fe VAN has been proposed and demonstrated. The new TiN-Fe VAN system
on Si exhibits superior magnetic properties and unusual optical properties. With
further growth optimization and/or patterning techniques, VAN thin film integration
on silicon presents itself as a feasible and cost-effective approach to
designing electronic, spintronic, photonic, and sensing devices.</p>
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MORPHOLOGY TUNING OF OXIDE-METAL VERTICALLY ALIGNED NANOCOMPOSITES FOR HYBRID METAMATERIALSJuanjuan Lu (17658789) 19 December 2023 (has links)
<p dir="ltr">Metamaterials are artificially engineered nanoscale systems with a three-dimensional repetitive arrangement of certain components, and present exceptional optical properties for applications in nanophotonics, solar cells, plasmonic devices, and more. Self-assembled oxide-metal vertically aligned nanocomposites (VANs), with metallic phase as nanopillars embedded in the matrix oxide, have been recently proposed as a promising candidate for metamaterial applications. However, precise microstructural control and the structure-property relationships in VANs are still in high demand. Thus, by employing multiple approaches for structural design, this dissertation attempts to investigate the mechanisms of nanostructure evolutions and the corresponding optical responses.</p><p dir="ltr">In this dissertation, the precise control over the nanostructures has been demonstrated through morphology tuning, nanopillar orderings, and strain engineering. Firstly, Au, a well-known plasmonic mediator, has been selected as the metallic phase that forms nanopillars. Based on the previously proposed strain compensation model which describes the basic formation mechanism of VAN morphology, two oxides were then considered: La<sub>0.7</sub>Sr<sub>0.3</sub>MnO<sub>3 </sub>(LSMO) and CeO<sub>2</sub>. In the first two chapters of this dissertation, LSMO was considered due to its similar lattice (a<sub>LSMO </sub>= 3.87 Å, a<sub>Au </sub>= 4.08 Å) and its enormous potential in nanoelectronics and spintronics. Deposited on SrTiO<sub>3</sub> (001) substrate through pulsed laser deposition (PLD), LSMO-Au nanocomposites exhibit ideal VAN morphology as well as promising hyperbolic dispersions in response to the incident illuminations. By substrate surface treatment of annealing at 1000°C, and variation of STO substate orientations from (001), to (111) and (110), the improved and tunable in-plan orderings of Au nanopillars have been successfully achieved. In the third chapter, a new oxide-metal VAN system of <a href="" target="_blank">CeO<sub>2</sub></a>-Au (a<sub>CeO2 </sub>= 5.411 Å, and a<sub> CeO2</sub>/= 3.83 Å) has been deposited. The intriguing 45° rotated in-plan epitaxy presents an unexpected update to the strain compensation model, and tuning of Au morphology from nanopillars, nanoantennas, to nanoparticles also shows an effective modulation of the LSPR responses. COMSOL simulations have been exploited to reveal the relationships between Au morphologies and optical responses. In the last chapter, the two VAN systems of LSMO-Au and CeO<sub>2</sub>-Au have been combined to form a complex layered VAN thin film. Investigations into the strain states, the nature of complex interfaces, and the according hybrid properties, show dramatic possibilities for further strain engineering. In summary, this dissertation has provided multiple routes for highly tailorable oxide-metal nanocomposite designs. And the two proposed material systems present great potential in optical metamaterial applications including biosensors, photovoltaics, super lenses, and more.</p>
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