A combined experimental and theoretical approach towards the understanding of transport in one-dimensional molecular nanostructures

Grimm, Daniel

09 July 2008

This thesis comprises detailed experimental and theoretical investigations of the transport properties of one-dimensional nanostructures. Most of the work is dedicated to the exploration of the fascinating effects occurring in single wall carbon nanotubes (SWCNT). These particular nanostructures gained an overwhelming interest in the past two decades due to its outstanding electronic and mechanical features. We have investigated the properties of a novel family of carbon nanostructures, named here as Y-shaped rings. The studies show that they present very interesting quantum interference effects. A high structural stability under tensile strain and elevated temperatures is observed. Within the semi-classical potential adopted, the critical strain values of structure rupture lie in the same range of their pristine SWCNT counterparts. This is directly verified by the first observations of these ring-like structures in a transmission electron microscopy. A merging process of asymmetric into symmetric rings is investigated in-situ under electron beam irradiation at high temperatures. The electronic properties of these systems are theoretically studied using Monte Carlo simulations and environment dependent tight-binding calculations. From our results, we address the possibility of double-slit like interference processes of counter-propagating electron waves in the ring-like structures. The nature of well defined, sharp peaks in the density of states are determined as the discrete eigenenergies of the central loop part. Furthermore, the formation and dispersion of standing waves inside the ring is shown to originate from the quantum-dot like confinement of each branch between the leads. The obtained dispersion relation is shown to be the same occurring in purely one-dimensional quantum dots of similar geometries. Furthermore, Fabry-Perot-like interferences are observed. We established at the IFW a bottom-up processing route to fabricate nanotube based electronic devices. The SWCNTs are grown by chemical vapor deposition and we present a detailed study of the different approaches to obtain individual nanotubes suitable for a successful integration into electronic devices. Wet-chemistry and ultra-thin films as well as ferritin were employed as catalyst particles in the growth of SWCNT samples. By adjusting the optimized process parameters, we can control the obtained yield from thick nanotube forests down to just a couple of free-standing individual SWCNTs. The nanotubes are localized, contacted by standard e-beam lithography and characterized at ambient- as well as liquid helium temperatures. We usually obtain quite transparent contacts and the devices exhibit metallic or a mixed metallic/semiconducting behavior. The well-known memory effect upon gate voltage sweeping as well as single electron tunneling in the Coulomb blockade regime are addressed.

info:eu-repo/classification/ddc/530

ddc:530

Epitaxy and characterization of SiGeC layers grown by reduced pressure chemical vapor deposition

Hållstedt, Julius

January 2004

Heteroepitaxial SiGeC layers have attracted immenseattention as a material for high frequency devices duringrecent years. The unique properties of integrating carbon inSiGe are the additional freedom for strain and bandgapengineering as well as allowing more aggressive device designdue to the potential for increased thermal budget duringprocessing. This work presents different issues on epitaxialgrowth, defect density, dopant incorporation and electricalproperties of SiGeC epitaxial layers, intended for variousdevice applications. Non-selective and selective epitaxial growth of Si1-x-yGexCy(0≤x≤30, ≤y≤0.02) layershave been optimized by using high-resolution x-ray reciprocallattice mapping. The incorporation of carbon into the SiGematrix was shown to be strongly sensitive to the growthparameters. As a consequence, a much smaller epitaxial processwindow compared to SiGe epitaxy was obtained. Differentsolutions to decrease the substrate pattern dependency (loadingeffect) of SiGeC growth have also been proposed. The key pointin these methods is based on reduction of surface migration ofthe adsorbed species on the oxide. In non-selective epitaxy,this was achieved by introducing a thin silicon polycrystallineseed layer on the oxide. The thickness of this seed layer had acrucial role on both the global and local loading effect, andon the epitaxial quality. Meanwhile, in selective epitaxy,polycrystalline stripes introduced around the oxide openingsact as migration barriers and reduce the loading effecteffectively. Chemical mechanical polishing (CMP) was performedto remove the polycrystalline stripes on the oxide. Incorporation and electrical properties of boron-doped Si1-x-yGexCylayers (x=0.23 and 0.28 with y=0 and 0.005) with aboron concentration in the range of 3x1018-1x1021atoms/cm3 have also been investigated. In SiGeClayers, the active boron concentration was obtained from thestrain compensation. It was also found that the boron atomshave a tendency to locate at substitutional sites morepreferentially compared to carbon. These findings led to anestimation of the Hall scattering factor of the SiGeC layers,which showed good agreement with theoretical calculations. Keywords:Silicon germanium carbon (SiGeC), Epitaxy,Chemical vapor deposition (CVD), Loading effect, Highresolution x-ray diffraction (HRXRD), Hall measurements, Atomicforce microscopy (AFM).

Silicon germanium carbon (SiGeC)

Epitaxy

Chemical vapor deposition (CVD)

Loading effect

Hall measurements

Atomic force microscopy (AFM).

Diagnosis and Treatment of Peripheral Arterial Disease Compared With Other Atherosclerotic Vascular Diseases in a University Primary Care Clinic

Ismail, Hassan, Jackson, Kyoo, Smith, Daniel

01 January 2006

Background: Despite the fact that peripheral arterial disease (PAD) significantly increases the risk of cardiovascular mortality, it is significantly underdiagnosed and underrated. The purpose of this study was to evaluate the practice at a northeast Tennessee university primary care clinic regarding the diagnosis and treatment of PAD. Methods: A retrospective medical record survey was conducted to evaluate practice patterns in diagnosing and treating PAD in a university primary care clinic. A clinic population of 711 patients was selected using International Classification of Diseases-9 codes for coronary artery disease (CAD), cerebovascular disease (CVD), and/ or PAD. A sample of 180 patients (25.3%) was randomly selected using a systematic statistical method. Of these, 125 patients met the diagnostic criteria for CAD, CVD, and/or PAD. The study covered a 3-year period, from July 2001 until June 2004. Demographic and other data, including the use of antiplatelet therapy, were collected. Results: One hundred ten patients met all of the inclusion and exclusion criteria. Thirty-nine percent were males, and 61% were females. Overall, 79% had CAD, 53% had CVD, and 25% had PAD. Almost half of the patients had some combination of these. Only about 2% had PAD only compared with 36% with CAD only and 17% with CVD only. Although the prevalence of CAD and CVD (among other atherosclerotic vascular diseases) in our clinic was comparable to national figures, the prevalence of PAD was significantly lower (p = .004). The overall use of any antiplatelet agent was 84.2% for patients with only CAD and 80% for only CVD. There was not an adequate number of patients with only PAD to evaluate the use of antiplatelet therapy in this group. Conclusion: The low prevalence of PAD only (most PAD patients had coexisting CAD and CVD) indicates that PAD is underdiagnosed at our clinic. There was suboptimal use of aspirin and other antiplatelet drugs among patients with atherosclerotic vascular disease.

atherosclerotic vascular disease

cerebrovascular disease (CVD)

coronary artery disease (CAD)

peripheral arterial disease (PAD)

The San Diego Artery study

ADVANCED CMOS AND QUANTUM TUNNELING DIODES: MATERIALS, EXPERIMENT AND MODELING

Fakhimi, Parastou

28 August 2019

No description available.

Electrical Engineering

Quantum tunneling

resonant tunneling diode

Ge epitaxy

photoluminescence spectroscopy

CVD growth

unipolar doped light emitting diode

InGaAs

AlAs

SiGe

Ge

Diet Quality and Dyslipidemia in the US Population

Costantini, Lianna Hope

04 September 2018

No description available.

Nutrition

Public Health

Medicine

Health

Health Care

cholesterol

heart disease

nutrition

diet

diet quality

NHANES

Healthy Eating Index-2015

AHA Healthy Diet Score

CVD

Functionalization of In-plane Photonic Microcantilever Arrays for Biosensing Applications

Ness, Stanley J.

29 October 2012

Microcantilevers have been investigated as high sensitivity, label free biosensors for approximately 15 years. In nearly all cases, a thin gold film deposited on the microcantilevers is used as an intermediate attachment layer because of the convenience of thiol-gold chemistry. Unfortunately, this attachment chemistry can be unstable when used with complex sample media such as blood plasma. The Nordin group at BYU has recently developed an all-silicon in-plane photonic microcantilever (PMCL) technology to serve as a platform for label-free biosensing. It has the advantage of being readily scalable to simultaneous readout of many PMCLs in array format, and allows integration with polymer microfluidics to facilitate the introduction of biological samples and reagents. An essential processing step for the transformation of the PMCL into a practical biosensor is the ability to effectively immobilize active biological receptors directly on silicon PMCL surfaces such that ligand binding generates sufficient surface stress to cause measureable PMCL deflection. This dissertation presents the development of a method to functionalize the sensor surface of all-silicon in-plane photonic microcantilever (PMCL) arrays. This method employs a materials inkjet printer for non-contact jetting and a fluid that is custom designed for ink-jetting and biological applications with approximately 1 pL droplet size. The method facilitates the application of different receptors on select PMCLs with drop placement accuracy in the +/- 7.5 μm range. The functionalization fluid facilitates further processing using humidity control to achieve full coverage of only the PMCL's top surface and removal of dissolved salts to improve uniformity of receptor coverage and to prevent fouling of the sensor surface. Once a functionalization method was successfully developed, a series of experiments were performed to investigate the amount of surface stress that can be generated when receptors are immobilized directly to the silicon surface. In one series of experiments, a 4.8 μM streptavidin solution was used with biotin immobilized on multiple PMCLs to demonstrate adsorption-induced surface stress and concomitant deflection of the PMCL. The group observed ~ 15 nm PMCL deflection on average, with a corresponding surface stress of approximately 4 mN/m. These experiments yield the sensor response in real-time and employ a combination of multiple PMCLs functionalized as either sensors or unfunctionalized to serve as references. Investigation of various attachment chemistries is included, as well as a comparison with and without passivation of non-sensor surfaces. Investigated passivation strategies prevented ligand binding from generating a differential surface stress. Failure modes and physical mechanisms for adsorption-induced surface stress are discussed. Immobilization and passivation strategies for antibody-based biosensing are demonstrated with fluorescence microscopy and a corresponding PMCL sensing experiment using rabbit anti-goat F(ab') fragments as the receptors and Alex Fluor 488 labeled goat anti-rabbit IgGs as the ligand. While the results of these experiments remain inconclusive, suggestions for future research involving the PMCL sensor array are recommended.

microcantilever

inkjet functionalization

in-plane photonic transduction

photonic microcantilever

biosensor

PDMS microfluidics

streptavidin

biotin

organosilane

CVD

antibody fragment immobilization

F(ab') fragment

adsorption-induced surface stress

Electrical and Computer Engineering

Advanced Techniques for Carbon Nanotube Templated Microfabrication

Lund, Jason Matthew

01 December 2019

Carbon nanotube templated microfabrication (CNT-M) is a term describing a grouping of processes where carbon nanotubes (CNTs) serve a structural role in the fabrication of a material or device. In its basic form, CNT-M is comprised of two steps: produce a template made from carbon nanotubes and infiltrate the porous template with an additional material. Vertically aligned carbon nanotube (VACNT) templates can be grown to heights ranging from microns to millimeters and lithographically patterned to a desired form. Deposition of an existing thin film material onto a CNT template will coat all template surfaces and can produce a near solid material with dimensions on the millimeter scale with resulting material properties coming primarily from the thin film. Progress within CNT-M falls broadly within one of two categories: control of the CNT template's properties and form, or control of infiltration and new materials.Three-dimensional CNT templates were developed to allow patterned multilayer VACNT structures. In one embodiment, VACNTs were grown below an existing, patterned and capillary-formed VACNT structure by reusing the original catalyst in combination with newly deposited catalyst to create a CNT-based microneedle array on a VACNT support. In another embodiment, VACNTs were mechanically coupled from the initial stages of growth to create a smooth, low porosity surface on which a secondary, patterned CNT forest was grown using standard film deposition and lithographic techniques.A microfabrication compatible thermal barrier was produced using CNTs as a sacrificial template for silicon oxide. The resulting thermal barrier exhibited a thermal conductivity that could be tuned across 2 orders of magnitude based on the degree to which the sacrificial template was removed. Carbon infiltrated carbon nanotubes (CI-CNTs) were produced that exhibited a Young's modulus ranging from 5GPa to 26GPa based on controlled process parameters. Porosity, centroid position, and the second moment of area was calculated from SEM images of CI-CNT structures using an automatic pore identification technique. The porosity results suprisingly show little to no porosity gradient across the width of the structure and a nearly linear increase in porosity from the top to bottom. This work advances the understanding of existing CNT-M processes and demonstrates novel techniques for producing future CNT templates.

carbon nanotubes

CNT

CVD

MEMS

3D MEMS

ICCNT

VACNT

Porosity

CI-CNT

Carbon Infiltration

CNT Template

CNT-M

Nanoinjection

Initially Coupled CNT

microfabrication

Engineering

Mechanical Engineering

Analyses and Declarations of Omega-3 Fatty Acids in Canned Seafood May Help to Quantify Their Dietary Intake

Singer, Peter, Richter, Volker, Singer, Konrad, Löhlein, Iris

05 May 2023

The American Heart Association (AHA) recently confirmed common recommendations of one to two fish dishes per week in order to prevent cardiovascular disease (CVD). Nevertheless, the natural fluctuations of lipids and fatty acids (FA) in processed seafood caught little public attention. Moreover, consumers of unprocessed seafood in general do not know how much omega-3 fatty acids (omega-3 FA) within servings they actually ingest. The few studies published until today considering this aspect have been re-evaluated in today’s context. They included four observational studies with canned fatty coldwater fish (mackerel and herring from the same region, season, producer and research group). Their outcomes were similar to those conducted in the following years using supplements. Cans containing seafood (especially fatty coldwater fish) with declared content of omega-3 FA are ready-to-use products. Human studies have shown a higher bioavailability of omega-3 FA by joint uptake of fat. Canned fatty coldwater fish contain omega-3 FA plus plenty of fat in one and the same foodstuff. That suggests a new dietary paradigm with mixed concepts including several sources with declared content of omega-3 FA for reducing the cardiovascular risk and other acknowledged indications.

info:eu-repo/classification/ddc/610

ddc:610

Mono-to-few Layers Transition Metal Dichalcogenides, Exciton Dynamics, and Versatile Growth of Naturally Formed Contacted Devices

ALEITHAN, SHROUQ H.

06 June 2018

No description available.

Physics

Materials Science

Two dimensional materials

Transition Metal Dichalcogenides

Monolayer

Few layers

CVD growth

Exciton dynamics

Synthesis of Thin Films in Boron-Carbon-Nitrogen Ternary System by Microwave Plasma Enhanced Chemical Vapor Deposition

Kukreja, Ratandeep

January 2010

No description available.

Materials Science

Microwave Plasma CVD

Carbon Nitride Thin Films

Boron Nitride Thin Films

Low Temperature Diamond Thin Films

Nano-Seeding

Residual Stress