Microfabrication, Characterization, and Application of Carbon Nanotube Templated Thin Layer Chromatography Plates, and Functionalization of Porous Graphitic Carbon

Jensen, David S.

26 November 2012

This dissertation contains the following sections. Chapter 1 contains a detailed description of the theory of thin layer chromatography (TLC). Chapter 2 describes the benefits and practical considerations of elevated temperatures in liquid chromatography (LC). The porous graphitic carbon (PGC) I modified as part of my work is often used in elevated temperature LC. Chapter 3 shows a thermodynamic analysis of chromatographic retention at elevated temperature, and Chapter 4 contains a closer look at the van 't Hoff equation in LC and how it can be used in retention modeling. In Chapter 5, I describe a new procedure for microfabricating TLC plates that avoids the volume/feature distortions that occurred in our first microfabrication. The primary advance of this work was the priming of the carbon nanotube (CNT) forests with chemical vapor deposition (CVD) carbon and atomic layer deposition (ALD) alumina, which permitted effective ALD-like deposition of SiO2. Chapter 6 describes advancements in the microfabrication process of TLC, which excluded the use of the CVD carbon and Al2O3 coating as described in Chapter 5. The use of ozone, to lightly oxidize the CNT surface, primed the material for direct ALD deposition. Chapter 7 gives a detailed surface analysis of the microfabrication process up to and including the CNT forest. It was noticed that a channeling effect was present during Rutherford backscattering analysis of the CNTs. Additionally, characterization of CNTs using time-of-flight secondary ion mass spectrometry in the negative ion mode showed an odd-even effect for a homologous series of carbon, where the even moieties had a stronger signal. Chapter 8 describes the functionalization of PGC with di-tert-amyl peroxide (DTAP) and its effect on increasing the chromatographic performance as seen by a reduction in the tailing factors of test analytes. Chapter 9 -- 13 are detailed X-ray photoelectron analyses of the thin films and CNTs used in producing microfabricated TLC plates.

Carbon nanotubes

atomic layer deposition

chemical vapor deposition

thin layer chromatography

liquid chromatography

elevated temperature chromatography

van 't Hoff

Biochemistry

Chemistry

Magnetron Sputter Epitaxy of High-quality GaNand Plasma Characterization of the Process : Degree Project–Master’s Thesis

Lo, Yi-Ling

January 2021

Several sputtering depositions were done by direct current (DC) magnetron sputtering epitaxy (MSE) techniquefor the goal of improving the growth rate and crystalline quality of GaN thin film on Al2O3 substrate. Thegrowth rate was higher when substrate-to-target distance D = 7 cm compared with D = 9.3 cm with eitherfloating or positive bias on the substrate side. The crystalline quality was improved by raising up the growthtemperature from 700◦C to 900◦C, but the quality was declined from 900◦C to 1000◦C due to strong desorption.Gas composition in the metal mode gives better quality due to its sufficient Ga condition with less N2. Positivesubstrate bias boosted the plasma potential and therefore created higher actual sputtering power comparedwith the condition at floating substrate potential. In general, applying a higher power can elevate the growthrate and film quality. However, there has not been an evident difference of both growth rate and film qualitywhen the actual sputtering power is close for floating substrate potential and positive substrate bias.

GaN

Semiconductors

Nanomaterials

Thin film

Magnetron Sputtering

Epitaxy

XRD

Physical Vapor Deposition

Bearbetnings-, yt- och fogningsteknik

Other Materials Engineering

Annan materialteknik

Nano Technology

Nanoteknik

An Online Input Estimation Algorithm For A Coupled Inverse Heat Conduction-Microstructure Problem

Ali, Salam K.

09 1900

<p> This study focuses on developing a new online recursive numerical algorithm for a coupled nonlinear inverse heat conduction-microstructure problem. This algorithm is essential in identifying, designing and controlling many industrial applications such as the quenching process for heat treating of materials, chemical vapor deposition and industrial baking. In order to develop the above algorithm, a systematic four stage research plan has been conducted. </P> <p> The first and second stages were devoted to thoroughly reviewing the existing inverse heat conduction techniques. Unlike most inverse heat conduction solution methods that are batch form techniques, the online input estimation algorithm can be used for controlling the process in real time. Therefore, in the first stage, the effect of different parameters of the online input estimation algorithm on the estimate bias has been investigated. These parameters are the stabilizing parameter, the measurement errors standard deviation, the temporal step size, the spatial step size, the location of the thermocouple as well as the initial assumption of the state error covariance and error covariance of the input estimate. Furthermore, three different discretization schemes; namely: explicit, implicit and Crank-Nicholson have been employed in the input estimation algorithm to evaluate their effect on the algorithm performance. </p> <p> The effect of changing the stabilizing parameter has been investigated using three different forms of boundary conditions covering most practical boundary heat flux conditions. These cases are: square, triangular and mixed function heat fluxes. The most important finding of this investigation is that a robust range of the stabilizing parameter has been found which achieves the desired trade-off between the filter tracking ability and its sensitivity to measurement errors. For the three considered cases, it has been found that there is a common optimal value of the stabilizing parameter at which the estimate bias is minimal. This finding is important for practical applications since this parameter is usually unknown. Therefore, this study provides a needed guidance for assuming this parameter. </p> <p> In stage three of this study, a new, more efficient direct numerical algorithm has been developed to predict the thermal and microstructure fields during quenching of steel rods. The present algorithm solves the full nonlinear heat conduction equation using a central finite-difference scheme coupled with a fourth-order Runge-Kutta nonlinear solver. Numerical results obtained using the present algorithm have been validated using experimental data and numerical results available in the literature. In addition to its accurate predictions, the present algorithm does not require iterations; hence, it is computationally more efficient than previous numerical algorithms. </p> <p> The work performed in stage four of this research focused on developing and applying an inverse algorithm to estimate the surface temperatures and surface heat flux of a steel cylinder during the quenching process. The conventional online input estimation algorithm has been modified and used for the first time to handle this coupled nonlinear problem. The nonlinearity of the problem has been treated explicitly which resulted in a non-iterative algorithm suitable for real-time control of the quenching process. The obtained results have been validated using experimental data and numerical results obtained by solving the direct problem using the direct solver developed in stage three of this work. These results showed that the algorithm is efficiently reconstructing the shape of the convective surface heat flux. </p> / Thesis / Doctor of Philosophy (PhD)

recursive numerical algorithm

heat transfer

heat treating

chemical vapor deposition

industrial baking

inverse heat conduction

heat flux

Runge-Kutta

nonlinear solver

algorithm

Foundations of physical vapor deposition with plasma assistance

Gudmundsson, Jon Tomas, Anders, André, von Keudell, Achim

30 November 2023

Physical vapor deposition (PVD) refers to the removal of atoms from a solid or a liquid by physical means, followed by deposition of those atoms on a nearby surface to form a thin film or coating. Various approaches and techniques are applied to release the atoms including thermal evaporation, electron beam evaporation, ion-driven sputtering, laser ablation, and cathodic arc-based emission. Some of the approaches are based on a plasma discharge, while in other cases the atoms composing the vapor are ionized either due to the release of the film-forming species or they are ionized intentionally afterward. Here, a brief overview of the various PVD techniques is given, while the emphasis is on sputtering, which is dominated by magnetron sputtering, the most widely used technique for deposition of both metallic and compound thin films. The advantages and drawbacks of the various techniques are discussed and compared.

info:eu-repo/classification/ddc/530

ddc:530

Synthesis and Functionalization of Coiled Carbon Filaments

Hikita, Muneaki

January 2014

No description available.

Materials Science

coiled carbon filament

carbon microcoil

carbon nanocoil

CMC

CNC

chemical vapor deposition

toxicity study

mouse embryonic stem cell

MES cell

Synthesis and Characterization of Novel pi-Conjugated Small Molecules and Polymers with Hydrogen Bonding & Preparation of 2D Single Crystals for Organic Field-Effect Transistors

Deng, Ruonan

02 October 2017

No description available.

Polymers

OFET

conjugated polymers

thermal liable t-Boc group

hydrogen-bonding

single crystal

solution epitaxial growth

mechanical exfoliation

physical vapor deposition

Electrochemically Induced Urea to Ammonia on Ni Based Catalyst

Lu, Fei

19 September 2017

No description available.

Chemical Engineering

selective catalytic reduction

on-site production of ammonia

urea to ammonia

urea hydrolysis

electrochemically induced process

nickel oxyhydroxide

ammonia corrosion

chemical vapor deposition

graphene-coated Ni

Remote microwave-enhanced chemical vapor deposition of silicon-nitrogen (Si <inf>x</inf>N <inf>y</inf>) thin films

Gladysz, Gary M.

January 1991

No description available.

Engineering, Chemical

Remote Microwave-Enhanced Chemical

Vapor Deposition

Development of MOCVD GaN Homoepitaxy for Vertical Power Electronic Device Applications

Zhang, Yuxuan

02 September 2022

No description available.

Electrical Engineering

Materials Science

gallium nitride

vertical power devices

metalorganic chemical vapor deposition

laser-assisted MOCVD

carbon impurity

iron impurity

fast growth rate

defects

thermodynamic modelling

optical characteristics

Photocathodes for high brightness, high average current photoelectron injectors

Schmeißer, Martin Anton Helmut

11 December 2019

Für viele Anwendungen in der Grundlagenforschung, Medizin und industriellen Entwicklung sind Beschleuniger der entscheidende Antrieb. Vor allem Elektronenbeschleuniger sind als Synchrotronquellen unter den brillantesten Quellen für Strahlung im Infrarot- bis Röntgenbereich und damit unerlässlich für eine Vielzahl von Anwendungen und analytischen Methoden. Photoinjektoren stellen als Elektronenquellen für Beschleuniger eine wichtige Komponente für die Entwicklung von Lichtquellen wie Freie-Elektronen-Laser, sowie für neue Beschleunigerkonzepte wie Linearbeschleuniger mit Energierückgewinnung dar. Die Photokathode und der Anregungslaser definieren dabei mit der Quantenausbeute (QE) und der intrinsischen Emittanz zentrale Kenngrößen des Photoinjektors. Diese Arbeit beschreibt die Entwicklung von Alkali-Antimonid Photokathoden für die Anwendung in einem Photoinjektor mit supraleitendem Hochfrequenz-Resonator. Alkali Antimonide zeigen generell eine hohe QE und Cäsium Kalium Antimonid (Cs-K-Sb) im speziellen verspricht eine geringe intrinsische Emittanz aufgrund der Ionisierungsenergie, die nur knapp unter der Photonenenergie der grünen Anregungslaser liegt. Mit der Inbetriebnahme eines Präparations- und Analysesystems konnte die Abscheidung dünner Schichten von Cs-K-Sb sowie die Messung der QE und chemischen Zusammensetzung erzielt werden. Dabei wurde mit der Ko-evaporation der Alkalimetalle eine neue Wachstumsmethode etabliert und hinsichtlich der Prozessstabilität und Qualität der erzeugten Proben mit der sequenziellen Methode verglichen. Schließlich beschreiben die Inbetriebnahme eines Prototyps des Photoinjektors und erste erfolgreiche Kathodentransfers im Vakuum einen wichtigen Schritt hin zum Betrieb eines Beschleunigers mit einer Cs-K-Sb Photokathode im supraleitenden Hochfrequenz-Injektor. Diese Kombination erlaubt die Erzeugung eines Elektronenstrahls mit niedriger Emittanz und hohem mittleren Strom. / For many disciplines in basic and applied research, medicine and industrial development accelerators are an important driving force. Especially electron accelerators as synchrotron sources are among the brightest sources of radiation from the infrared to the X-ray regime and thus fundamental to a broad range of analytical techniques. Photoinjectors as electron sources for accelerator applications are a key component for the development of light sources such as free electron lasers as well as new accelerator concepts like energy-recovery linacs. The photocathode and drive laser define the quantum efficiency (QE) and intrinsic emittance of the photoemission process and thus central figures of merit of the photoinjector. This work focuses on the development of alkali antimonide photocathodes for the application in a superconducting radio frequency photoinjector. Alkali antimonides generally exhibit a high QE and cesium potassium antimonide (Cs-K-Sb) specifically is expected to release electrons with a low intrinsic emittance as the photoemission threshold is close to the photon energy of common, green, drive laser wavelengths. A preparation and analysis system has been commissioned for the deposition of Cs-K-Sb thin film photocathodes and their analysis regarding QE and chemical composition. A new deposition technique, the alkali metal co-deposition, was established and compared to the sequential deposition in terms of process reliability and quality of the produced samples. The work concludes with a report of the commissioning of a prototype of the photoinjector and successful cathode transfers in ultra-high vacuum, which represents an important technological advancement towards the operation of an accelerator with the combination of Cs-K-Sb photocathodes and an SRF injector. This combination makes the generation of an electron beam with low emittance and high average current possible.

Photoinjektoren

Elektronenquellen

Alkali Antimonide

physikalische Dampfphasenabscheidung

CsK2Sb

Elektronenbeschleuniger

Photokathoden

photoinjectors

electron sources

alkali antimonides

physical vapor deposition

Cs2KSb

CsK2Sb

electron accelerators

photocathodes

530 Physik

UN 6410

ddc:530