Layer-by-layer Assembly of Nanobrick Wall Ultrathin Transparent Gas Barrier Films

Priolo, Morgan Alexander

2012 May 1900

Thin layers with high barrier to oxygen and other gases are a key component to many packaging applications, such as flexible electronics, food, and pharmaceuticals. Vapor deposited thin films provide significant gas barrier, but are prone to cracking when flexed, require special, non-ambient processing environments, and can involve complex fabrication when layered with polymers. The addition of clay into polymers can enhance barrier properties relative to the neat polymer; however, these composites are subject to clay aggregation at high loadings, which leads to increased opacity and random platelet alignment that ultimately reduce barrier improvement. Layer-by-layer (LbL) assembly is capable of producing thin films that exhibit super gas barrier properties, while remaining flexible and completely transparent. Montmorillonite (MMT) clay and branched polyethylenimine (PEI) were deposited via LbL assembly to create gas barrier films that can be tailored by altering the pH of the PEI deposition solution or the concentration of the MMT suspension. Films grow linearly as a function of layers deposited, where increasing PEI pH increases spacing between clay layers and increasing MMT concentration increases thin film clay content. An oxygen transmission rate (OTR) below the detection limit of commercial instrumentation (< 0.005 cm3/m2•day•atm) is observed after 70 layers of 0.2 wt % MMT or 24 layers of 2 wt % MMT are deposited with pH 10 PEI onto 179 µm thick poly(ethylene terephthalate) (PET) film. Three-component films of PEI, poly(acrylic acid) (PAA), and MMT grow exponentially as a function of PEI/PAA/PEI/MMT quadlayers deposited. A transparent, ultrathin film of only four quadlayers deposited onto PET exhibits the lowest oxygen permeability ever reported for any thin film material, at only 51 nm thick. Finally, the first example of LbL assembly using large aspect ratio vermiculite (VMT) clay was performed. PEI/VMT films grow linearly as a function of layers deposited and exhibit 95 % light transmission with 97 wt % VMT. The barrier of these films is due to the highly aligned nanobrick wall structure that creates a tortuous path for permeating molecules. Coupling high flexibility, transparency, and barrier, these coatings are good candidates for a variety of packaging applications.

layer-by-layer assembly

thin films

oxygen barrier

packaging

clays

nanocomposites

Near surface atmospheric flow over high latitude glaciers

Parmhed, Oskar

January 2004

In this thesis various descriptions of the near surface atmospheric flow over a high latitude glacier is used in an effort to increase our understanding of the basic flow dynamics there. Through their contribution to sea-level change, mountain glaciers play a significant role in Earth’s climate system. Properties of the near surface atmospheric flow are important for understanding glacier response to climate change. Here, the near surface atmospheric flow is studied from several perspectives including the effects of both rotation and slope. Rotation is an important aspect of most atmospheric flows and its significance for mesoscale flows have gained recognition over the last years. Similarly, the very stable boundary layer (VSBL) has lately gained interest. Within a VSBL over sloping terrain katabatic flow is known to be usual and persistent. For the present thesis a combination of numerical and simple analytical models as well as observations from the Vatnajökull glacier on Iceland have been used. The models have continuously been compared to available observations. Three different approaches have been used: linear wave modeling, analytic modeling of katabatic flow and of the Ekman layer, and numerical simulations of the katabatic flow using a state of the art mesoscale model. The analytic models for the katabatic flow and the Ekman layer used in this thesis both utilizes the WKB method to allow the eddy diffusivity to vary with height. This considerably improves the results of the models. Among other findings it is concluded that: a large part of the flow can be explained by linear theory, that good results can be obtained for surface energy flux using simple models, and that the very simple analytic models for the katabatic flow and the Ekman layer can perform adequately if the restraint of constant eddy diffusivity is relieved.

Stable boundary layer

Ekman layer

Katabatic flow

gravity wave

low-level jets

Meteorology

Meteorologi

Stimuli Responsive Multilayer Thin Films And Microcapsules Of Polymers Via Layer-By-Layer Self-Assembly

Manna, Uttam

05 1900

The present thesis focuses on the selection of polymers and methods to fabricate stable and stimuli responsive multilayer self-assembly via layer-by-layer (LbL) approach. The polymers utilized in this study are biodegradable and biocompatible such as hyaluronic acid, chitosan and poly(vinyl alcohol) (PVA). The thesis is comprised of six chapters and a brief discussion on the contents of the individual chapters is given below. Chapter I reviews the LbL self-assembly approach in the context of drug delivery. The various interactions such as electrostatic, hydrogen bonding and covalent bonding involved in preparation of stable multilayer assemblies via LbL approach are discussed. Stimuli responsive behaviour of these multilayer assemblies can be tuned by choosing suitable depositing materials and method. Preparation of hollow microcapsules using LbL approach and its application in drug delivery has also been described in this chapter. Chapter II deals with the LbL assembly of a neutral polymer, poly(vinyl alcholol) (PVA). The negative charge on PVA backbone was induced by physical cross-linking with borax. The PVA-borate can undergo electrostatic interaction with positively charged chitosan in LbL process to form multilayer thin film. The thin film of PVA-borate complex/chitosan was found be responsive towards glucose concentration; disintegration of the multilayer assembly was observed at a high glucose concentration. This finding was rationalized on the basis of strong interaction of glucose with borate ions leading to dissociation of PVA-borate complex and subsequent collapse of the assembly. Thus, this multilayer self-assembly is potent for glucose triggered drug delivery. Chapter III reports the construction of a stable hydrogen bonded multilayer self-assembly based on complementary DNA base pairs (adenine and thymine) interaction. The natural polymer such as chitosan was modified with adenine whereas hyaluronic acid was modified with thymine. These two modified polymers were sequentially deposited on flat substrate and melamine formaldehyde (MF) particles; wherein strong interaction among the DNA base pairs led to the formation of stable assembly without utilizing any external cross-linking agent. The modified polymers are non-cytotoxic as proved from MTT assay. Further the multilayer assembly was used for pH responsive anticancer drug doxorubicin hydrochloride (DOX) release. In Chapter IV, glutaraldehyde mediated LbL self-assembly of single polymer multilayer thin films on flat and colloidal substrate by covalent bonding is described. A comparitive study between the native polymer (chitosan) and adenine modified polymer in the growth of thin film is performed. It is established from the study that the conformation of polymer and the availability of cross-linking points on the polymer play a crucial role in controlling the growth of these multilayer assemblies. Chapter V is divided into two parts (A and B). Part A describes a simple and unique protocol for fabrication of water dispersed chitosan nanoparticles (CH NPs). The method utilized in this work is based on the fast desolvation technique without using any additional stabilizer or any sophisticated instrumental setup. Furthermore, the CH NPs prepared from the mentioned protocol were proved to be cell-viable and are found to be responsive towards pH of the solution. In part B of this chapter, the LbL self-assembly of the responsive CH NPs is fabricated via electrostatic interaction with hyaluronic acid (HA). The growth of the multilayer thin film was found to be linear as function of number of bilayers. The morphology of thin film was characterized by atomic force microscopy (AFM) and scanning electron microscopy (SEM). The microscopic images reveal the uniform film morphology devoid of any phase separation of nanoparticles and polymers. Subsequently, the film was loaded with an anticancer therapeutic, doxorubicin hydrochloride (DOX). The release dynamics of encapsulated drug from the self-assembly are tunable and pH responsive. Chapter VI deals with the general and versatile method for the encapsulation of hydrophobic model drugs into polymeric multilayer assembly by using LbL approach. Electrical charge was induced on the surface of pyrene (uncharged organic substance) using an amphiphilic surfactant, sodium dodecyl sulfate (SDS) by micellar solubilization. The SDS micellar solution of pyrene was utilized to grow LbL multilayer thin film on a planar substrate and colloidal particles along with chitosan as a polycation. The LbL self-assembly of pyrene loaded SDS micelles/chitosan is additionally able to encapsulate hydrophobic or hydrophilic model therapeutics, thus providing an opportunity for dual-drug delivery. The desorption kinetics of the two model drugs from the thin film is found to follow a second order rate model.

Multilayer Thin Films

Layer-by-Layer Self-Assembly

Polymer - Structure

Microcapsules

Drug Delivery

Polymer Multilayer Thin Films

Polymers - Multilayer Self-Assembly

Polymer Microcapsules

Chitosan - Layer-by-Layer Self-assembly

Chitosan Nanoparticles

Theoretical Chemistry

Surface Modifications of Nanocarbon Materials for Electrochemical Capacitors

Akter, Tahmina

14 December 2010

Multi-walled carbon nanotubes (MWCNTs) were successfully coated with two different pseudocapacitive polyoxometalates (POMs) (SiMo12O40-4 (SiMo12) and PMo12O40-3 (PMo12)) via “Layer-by-Layer” deposition. Even with merely a “single-layer” of POM, the modified nanotubes exhibited more than 2X increase in capacitance compared with that of bare nanotubes. To further improve their electrochemical performances, the deposition sequence of the POM layers was adjusted to form “alternate layer” coating to modify MWCNT. A synergistic effect on the capacitance and kinetics was observed with the alternate layer coatings. X-ray Photoelectron Spectroscopy (XPS) and Scanning Electron Microscopy (SEM) also proved the successful coating of POMs on MWCNTs. The potential-pH relationship provided important insights in terms of the deposition mechanism and suggested that the bottom layer close to the electrode substrate was the dominating layer in alternate layer coated MWCNT electrodes.

Nanocarbon

Electrochemical Capacitor

Polyoxometaltes

Layer by Layer Deposition

Pseudocapacitance

MWCNT

0794

Surface Modifications of Nanocarbon Materials for Electrochemical Capacitors

Akter, Tahmina

14 December 2010

Multi-walled carbon nanotubes (MWCNTs) were successfully coated with two different pseudocapacitive polyoxometalates (POMs) (SiMo12O40-4 (SiMo12) and PMo12O40-3 (PMo12)) via “Layer-by-Layer” deposition. Even with merely a “single-layer” of POM, the modified nanotubes exhibited more than 2X increase in capacitance compared with that of bare nanotubes. To further improve their electrochemical performances, the deposition sequence of the POM layers was adjusted to form “alternate layer” coating to modify MWCNT. A synergistic effect on the capacitance and kinetics was observed with the alternate layer coatings. X-ray Photoelectron Spectroscopy (XPS) and Scanning Electron Microscopy (SEM) also proved the successful coating of POMs on MWCNTs. The potential-pH relationship provided important insights in terms of the deposition mechanism and suggested that the bottom layer close to the electrode substrate was the dominating layer in alternate layer coated MWCNT electrodes.

Nanocarbon

Electrochemical Capacitor

Polyoxometaltes

Layer by Layer Deposition

Pseudocapacitance

MWCNT

0794

Design of an Instrumentation System for a Boundary Layer Transition Wing Glove Experiment

Williams, Thomas 1987-

14 March 2013

Laminar flow control holds major promise for increasing aircraft efficiency and increasing laminar flow over aerodynamic surfaces could decrease drag by up to 30 percent. The Flight Research Lab at Texas A&M University has studied laminar flow over a wing with 30 degrees of leading edge sweep with Discrete Roughness Elements (DREs) installed and has indicated that DREs can be used to increase laminar flow at Reynolds numbers up to 7.5 million at Mach 0.3. A new project, termed SARGE, has been commissioned in conjunction with NASA for studying DREs on a swept wing glove at conditions relevant to jet transports. The SARGE project must have an instrumentation system capable of accurately measuring flow conditions and transition location on the suction side of the glove. Infrared (IR) thermography has been selected as the primary transition detection tool. A heat transfer analysis has shown that solar radiation will warm the surface of the glove above the adiabatic wall temperature and therefore the laminar region will appear to be warmer. The FLIR SC8000 IR camera has been selected for this application due to its ability to produce high-resolution images in the appropriate IR band. High quality air data is also required for the experiment. A five-hole probe will be used to measure flow angle and velocity near the glove. This instrument will provide meanflow conditions due to its limited frequency response. High quality pressure transducers coupled with careful probe calibration will allow for differential measurements to be made with an uncertainty of +/- 0.03 degrees. Static pressure ports and high frequency response Kulite transducers will also be employed. Hotfilm sensors will be used to verify the state of the boundary layer on the glove through spectral analysis. A unique hotfilm array has been proposed that will enable the measurement of traveling wave vectors through a spectral technique. An experiment on the Flight Research Lab's Cessna O-2 to investigate the veracity of this technique has also been suggested. Thermocouples will also be installed on the glove's surface to monitor temperatures and verify transition location. The layout of the hotfilms and thermocouples is also detailed.

traveling wave

heat transfer

boundary layer transition

boundary layer

transition

hotfilms

wing glove

laminar flow

Red EL Properties of OLED Having Hole Blocking Layer

LEE, Duck-Chool, MIZUTANI, Teruyoshi, MORI, Tatsuo, KIM, Hyeong-Gweon

20 July 2000

No description available.

electroluminescent (EL)

hole transport layer

emission layer

red organic light-emitting-diode(OLED)

New techniques for the fabrication of biosensors based on nad (P) + dependent dehydrogenases

Paulov, Valeri

28 January 2005

DE LA TESIS EN CASTELLANOAntecedentesUn avance importante en el campo de química analítica se hizo por Clark y Lyons en los años setenta. Ellos propusieron acoplar la especificidad de la enzima glucosa oxidasa con la transducción electroquímica de la señal en "biosensores". En general, los biosensores son artefactos integrados autocontenidos, capazes de proporcionar información analítica, cuantitativa utilizando un elemento biológico de reconocimiento (receptor bioquímico) que se retiene en contacto espacial directo con un elemento de transducción. Posteriormente, los primeros biosensores de glucosa, basados en la detección amperométrica de peróxido de hidrógeno generado por glucosa oxidasa en la presencia de oxígeno fueron introducidos en el mercado por la empresa estadounidense Yellow Spring Instrument Co. (Ohio, EE. UU.) en 1975. La respuesta de biosensores electroquímicos basados en el uso de oxígeno como cosustrato para oxidasas se ve desviada por la presencia de interferencias que pueden contribuir a la corriente. Por lo tanto la superficie de electrodo debe estar protegida por una membrana no permeable por sustancias que pueden interferir con la señal. Para evitar corrientes que perjudican la selectividad de los biosensores, el potencial aplicado puede ser aminorado usando electrocatalizadores difusionales ("mediadores") en lugar de oxígeno, con un potencial redox controlable. Pero la respuesta de estos sensores también depende de la concentración de oxígeno porque este compite con los mediadores, para la reoxidación de las oxidasas. Un inconveniente adicional del uso de mediadores diffusionales artificiales en biosensores es la baja estabilidad de los mismos debida al escape de mediadores desde la superficie del electrodo cuando esto se usa en linea. Se puede aliviar este problema creando enlaces covalentes entre los mediadores y la superficie del electrodo o usando polímeros redox que se adsorben fu&#263;rtemente en la superficie del electrodo. Una de las posibles maneras para disminuir la influencia del oxígeno a la corriente de la respuesta de biosensores es el uso de las deshidrogenasas dependientes de la pareja redox NAD+/NADH. El potencial estándar redox de esta pareja es -0.56 V vs. SCE pero para conseguir la oxidación de NADH en la superficie de electrodos de carbono un sobrepotencial de +0.5 V vs. SCE debe aplicarse. Bajo estas condiciones los electrodos tienen tiempo de vida corto debido a la adsorción de los productos de oxidación en su superficie ya que la oxidación de NADH no es reversible químicamente. Por otro lado estos electrodos sufren por la oxidación no especifica de interferencias a estos potenciales de operación. Los electrodos modificados químicamente por mediadores pueden oxidar NADH a potenciales más bajos. Sin embargo, muchos de los mediadores mencionados en la bibliografía no son estables o/y no forman NAD+ enzimaticamente activo. Un problema adicional de los sistemas analíticos basados en deshidrogenasas dependientes de NAD+ es la necesidad de añadir este cofactór, que tiene alto coste y es inestable, en las muestras. Se puede inmovilizar NAD+ en la superficie de electrodos para producir biosensores capaces de funcionar en muestras que no contienen NAD+, biosensores reagentless (sin necesidad de adición de reactivos). Los métodos descritos en la bibliografía para la fabricación de biosensores reagentless se basan en cinco estrategias: (1) la inmovilización en hidrogeles formados in situ; (2) la inmovilización por una membrana; (3) la inmovilización en películas preparadas por electropolimerización; (4) la inmovilización en una pasta de carbono; (5) la inmovilización en monocapas auto ensambladas. Sólo los electrodos preparados con la estrategia (4) son biosensores reagentless con estabilidad operacional relativamente alta. Las demás estrategias no resultan en biosensores con suficiente estabilidad operacional por culpa de la perdida del mediador, de NAD+ o de la deshidrogenasa. Sin embargo la estrategia basada en electrodos de pasta de carbono no permite su aplicación a la producción de microsensores (electrodos con diámetro de menos de 10 &#61549;m) para su uso in vivo. MetodologíaEl objetivo principal de esta tesis es el desarrollo de nuevas estrategias para la fabricación de biosensores reagentless basados en deshidrogenasas dependientes de NAD+ con características mejoradas respecto a la densidad de la corriente, de la estabilidad operacional y de almacenamiento. Para cumplir el objetivo se han sintetizado dos nuevos mediadores para la oxidación de NADH: un polímero insoluble en agua [Os(1,10-fenantrolina-5,6-diona)2(PVP)4Cl]Cl, (Os-fendiona-PVP) y un complejo amfifílico [Os(1,10-fenantrolina-5,6-diona)24,4'-(n-C18H37NHCO)2bpi)](PF6)2 (Os-fendiona-surfactante). El polímero Os-fendiona-PVP fue producido vía la derivatización de poli(vinilpiridina) (peso molecular 50000) con [Os(1,10-fenantrolina-5,6-diona)2Cl2]. El estudio electroquímico de este polímero redox adsorbido en electrodos de grafito se realizó por voltametría cíclica a distintas velocidades de barrido para evaluar el número de protones y electrones que participan en la reacción redox, la influencia del pH a su potencial estándar formal, y la constante de la transferencia heterogénea del electrónes kS. Bajo bien definidas condiciones hidrodinámicas se realizaron estudios para encontrar la constante de la interacción con NADH k[NADH]=0. Os-fendiona-surfactante fue producido por la complejacion de [Os(1,10-fenantrolina-5,6-diona)2]Cl2 con el ligando hidrófobo octadodecilamida del acido 2,2'-Bipiridina-4,4'-dicarboxilico. Las monocapas de Langmuir-Blorgett de Os-fendiona-surfactante y las de su análogo [Os(bpi)24,4'-(n-C18H37NHCO)2bpi)](PF6)2 fueron estudiados en un equipo de Langmuir-Blodgett. Os-fendiona-surfactante fue aplicado a la construcción de biosensores reagentless del glutamato vía la inmovilización de glucosa deshidrogenasa y de NAD+ entre las bicapas en la fase lamelar formada por Os-fendiona-surfactante y el lípido 1,2-dioleoilo-sn-glicero-3-fosfatidilcolina. Dos métodos adicionales para la fabricación de los biosensores reagentless de glutamato y glucosa basados en deshidrogenasas fueron desarrollados. Los electrodos del grafito fueron modificados con Os-fendiona-PVP y utilizados para (a) la inmovilización de deshidrogenasa y de NAD+ en un hidrogel formado por entercruzamiento de poli(vinilpiridina) modificado por grupos amino con el éter diglicidil de poli(etilenglicol); (b) la inmovilización por adsorción de la deshidrogenasa y del ácido algínico modificado por NAD+. Se ha hecho un estudio de los biosensores reagentless para calcular sus constantes de Michaelis, el efecto del pH y de la temperatura en su respuesta y su estabilidad operacional. Además se ha comparado la estabilidad operacional a temperaturas elevadas de biosensores de la configuración (a) usando glutamato, glucosa y glucosa-6-fosfato deshidrogenasas termófilas y mesófilas. Por otro lado se han estudiado métodos nuevos para mejorar le estabilidad durante el almacenamiento de sensores de glutamato. Con este fin, se han preparado electrodos utilizando glutamato deshidrogenasa mesófila y termófila con varios estabilizadores. Conclusiones1. El polímero [Os(1,10-fenantrolina-5,6-diona)2(PVP)4Cl]Cl, (Os-fendiona-PVP) para la oxidación de NADH se puede sintetizar por la complejación de [Os(1,10-fenantrolina-5,6-diona)2Cl2] con poli(vinilpiridina). La adsorción física de este polímero sobre los electrodos de grafito desde su solución en etilenglicol resulta en la formación de una monocapa de este polimero redox en la superficie del electrodo. 2. El proceso redox de este mediador es casi-reversible e implica 4 electrones y 4 protones dentro del rango del pH de 3-6.5. El mediador pierde su estabilidad química en valores de pH más altos que 6.5. Tres ramas lineales en el diagrama de E0' frente a pH con diversas pendientes se observan. 3. La constante heterogénea de la velocidad de transferencia de electrones (kS) de Os-fendiona-PVP es del mismo orden de magnitud que la de otros mediadores capaces de oxidar NADH mencionados en la bibliografía (kS= 18±2 s-1) . 4. Os-fendiona-PVP es un electrocatalizador eficiente para la oxidación del NADH. La modificación de los electrodos del grafito con Os-fendiona-PVP conduce a la disminución del sobrepotential para la oxidación electroquímica del NADH desde +0.33 V vs. Ag/AgCl/KClsat para los electrodos no modificados hasta +0.11 V vs. Ag/AgCl/KClsat. La constante cinética para la interacción del polímero redox con el NADH (k1,[NADH]=0 = (1.9±0.2)x103 s-1 M-1) coincide prácticamente con la de Os-fendiona que sugiere que el número de los ligandos de fendiona en los complejos del osmio es proporcional a la corriente de la respuesta al NADH pero no afecta a las constantes cinéticas electroquímicas. / The objective of this work was the development of new configurations of reagentless biosensors based on NAD+ dependent dehydrogenases. These configurations are based on the immobilisation of enzyme, cofactor and the electrochemical catalyst used for its regeneration. In addition to being reagentless these configurations yielded biosensors with improved current density and operational stability compared to the state of the art. To achieve the objective two new NADH oxidising mediators were synthesised: a water insoluble polymer [Os(1,10-phenanthroline-5,6-dione)2(PVP)4Cl]Cl (Os-phendione-PVP) and an amphiphilic complex [Os(1,10-phenanthroline-5,6-dione)24,4'-(n-C18H37NHCO)2bpy)](PF6)2 (Os-phendione-surfactant). The electrochemical study of Os-phendione-PVP has revealed a rate constant for the heterogeneous electron transfer of the phendione redox couple ks = 25&#61617;2 s-1, and a second order rate constant for NADH oxidation k[NADH]=0=(1.1&#61617;0.1)x103 M-1 s-1. These constants are higher or of the same order of magnitude as those of previously described NADH oxidising mediators. The tensoactive mediators Os-phendione-surfactant and its analogue [Os(bpy)24,4'-(n-C18H37NHCO)2bpy)](PF6)2 (Os-bpy-surfactant) form very stable monolayers at the air-water interface collapsing at the surface pressure 60-65 mN m-1. The Os-phendione-surfactant was used for the construction of reagentless glutamate biosensors via the immobilisation of dehydrogenase and NAD+ between bilayers in lamellar phase formed by Os-phendione-surfactant and the lipid 1,2-dioleoyl-sn-glycero-3-phosphatidylcholine. The resulting glutamate biosensors demonstrated maximum current density of 3.5 &#61549;A cm-2 (RSD=25%), apparent Michaelis constant of 47 mM, and operational half life of 0.5 h. In addition graphite electrodes were modified by Os-phendione-PVP and utilised for (a) immobilisation of dehydrogenase and NAD+ in a hydrogel formed by crosslinking of poly(vinylpyridine) carrying amino groups with polyethylene glycol diglycidyl ether and (b) immobilisation of dehydrogenase and an NAD+-alginic acid derivative by adsorption. The configuration (a) yielded glutamate sensors with maximum current density of 8.7 &#61549;A cm-2 (RSD=5%), apparent Michaelis constant of 9.1 mM, operational half life of 12 h and glucose sensors with maximum current density of 37 &#61549;A cm-2 (RSD=14%), apparent Michaelis constant of 4.2 mM, the operational half life of 1 h. The glutamate sensors based on the configuration (b) showed maximum current density of 15.8 &#61549;A/cm2 (RSD=21%), apparent Michaelis constant of 17.6 mM and operational half life of 1.5 h. Glucose, glucose-6-phosphate, and glutamate biosensors were prepared and characterised. The employment of the thermophilic enzymes helps to dramatically increase the operational stability of biosensors at elevated temperatures higher than 60oC. The shelf life of glutamate electrodes built with the use of thermophilic dehydrogenase was eleven times longer than this of electrodes modified with the mesophilic enzyme. The addition of the copolymer of vinyl-pyrrolidone and dimethylamino ethyl methacrylate termed as Gafquat HS100 to the enzyme also significantly improved shelf life

langmuir Blodgett

NADH

layer by layer

polimeros redox

biosensores

54

577

A User-level, Reliable and Reconfigurable Transport Layer Protocol

Wang, Tan

January 2009

Over the past 15 years, the Internet has proven itself to be one of the most influential inventions that humankind has ever conceived. The success of the Internet can be largely attributed to its stability and ease of access. Among the various pieces of technologies that constitute the Internet, TCP/IP can be regarded as the cornerstone to the Internet’s impressive scalability and stability. Many researchers have been and are currently actively engaged in the studies on the optimization of TCP’s performance in various network environments. This thesis presents an alternative transport layer protocol called RRTP, which is designed to provide reliable transport layer services to software applications. The motivation for this work comes from the fact that the most commonly used versions of TCP perform unsatisfactorily when they are deployed over non-conventional network platforms such as cellular/wireless, satellite, and long fat pipe networks. These non-conventional networks usually have higher network latency and link failure rate as compared with the conventional wired networks and the classic versions of TCP are unable to adapt to these characteristics. This thesis attempts to address this problem by introducing a user-level, reliable, and reconfigurable transport layer protocol that runs on top of UDP and appropriately tends to the characteristics of non-conventional networks that TCP by default ignores. A novel aspect of RRTP lies in identifying three key characteristic parameters of a network to optimize its performance. The single most important contribution of this work is its empirical demonstration of the fact that parameter-based, user-configurable, flow-control and congestion-control algorithms are highly effective at adapting to and fully utilizing various networks. This fact is demonstrated through experiments designed to benchmark the performance of RRTP against that of TCP on simulated as well as real-life networks. The experimental results indicate that the performance of RRTP consistently match and exceed TCP’s performance on all major network platforms. This leads to the conclusion that a user-level, reliable, and reconfigurable transport-layer protocol, which possesses the essential characteristics of RRTP, would serve as a viable replacement for TCP over today’s heterogeneous network platforms.

reliable trnasport layer protocol

reconfigurable transport layer protocol

Electrical and Computer Engineering

A User-level, Reliable and Reconfigurable Transport Layer Protocol

Wang, Tan

January 2009

Over the past 15 years, the Internet has proven itself to be one of the most influential inventions that humankind has ever conceived. The success of the Internet can be largely attributed to its stability and ease of access. Among the various pieces of technologies that constitute the Internet, TCP/IP can be regarded as the cornerstone to the Internet’s impressive scalability and stability. Many researchers have been and are currently actively engaged in the studies on the optimization of TCP’s performance in various network environments. This thesis presents an alternative transport layer protocol called RRTP, which is designed to provide reliable transport layer services to software applications. The motivation for this work comes from the fact that the most commonly used versions of TCP perform unsatisfactorily when they are deployed over non-conventional network platforms such as cellular/wireless, satellite, and long fat pipe networks. These non-conventional networks usually have higher network latency and link failure rate as compared with the conventional wired networks and the classic versions of TCP are unable to adapt to these characteristics. This thesis attempts to address this problem by introducing a user-level, reliable, and reconfigurable transport layer protocol that runs on top of UDP and appropriately tends to the characteristics of non-conventional networks that TCP by default ignores. A novel aspect of RRTP lies in identifying three key characteristic parameters of a network to optimize its performance. The single most important contribution of this work is its empirical demonstration of the fact that parameter-based, user-configurable, flow-control and congestion-control algorithms are highly effective at adapting to and fully utilizing various networks. This fact is demonstrated through experiments designed to benchmark the performance of RRTP against that of TCP on simulated as well as real-life networks. The experimental results indicate that the performance of RRTP consistently match and exceed TCP’s performance on all major network platforms. This leads to the conclusion that a user-level, reliable, and reconfigurable transport-layer protocol, which possesses the essential characteristics of RRTP, would serve as a viable replacement for TCP over today’s heterogeneous network platforms.

reliable trnasport layer protocol

reconfigurable transport layer protocol

Electrical and Computer Engineering