Constant temperature embossing of supercooled polymer films

Kuduva Raman Thanumoorthy, Ramasubramani

21 January 2011

In this dissertation work, a constant temperature embossing process was developed and investigated. By softening and crystallizing a supercooled polymer at the same temperature, the embossing and solidification stages can be carried out isothermally without thermal cycling. The new process was demonstrated for replicating rectangular trenches with different aspect ratio for two different polymers PET and PEEK. The raw materials were characterized for their thermal and rheological properties to determine the processing parameters. The polymers were also characterized by a modified tensile testing apparatus to determine the tensile properties of the film during embossing. The processing parameters including embossing temperature, embossing pressure and embossing time were varied based on the material properties and optimized. A semi-empirical model was established to correlate the crystallizing kinetics of the materials to the change in rheological properties during embossing. The model was used as a tool to predict the rheological properties of the polymer at conditions where experimental determination is difficult. Finally, embossing simulations with the semi-empirical rheological model were conducted to study the unique process dynamics of constant-temperature embossing and verify some experimental findings. Different cases of constant-temperature embossing involving low to high rates of crystallization were simulated and compared with the conventional embossing process. Based on the experimental and simulation results, processing strategies for constant-temperature embossing were devised.

Microreplication

Hot embossing

Microfabrication

Crystalline polymers

Polymers

Micro-fabrication of a Mach-Zehnder interferometer combining laser direct writing and fountain pen micropatterning for chemical/biological sensing applications

Kallur, Ajay. Wang, Shuping,

January 2009

Thesis (M.S.)--University of North Texas, May, 2009. / Title from title page display. Includes bibliographical references.

Defining cellular microenvironments using multiphoton lithography

Kaehr, Bryan James, 1975-

28 August 2008

To understand the chemistry of life processes in detail is largely a challenge of resolving them in their native, cellular environment. Cell culture, first developed a century ago, has proven to be an essential tool for reductionist studies of cellular biochemistry and development. However, for the technology of cell culture to move forward and address increasingly complex problems, in vitro environments must be refined to better reflect the cellular environment in vivo. This dissertation work has focused on the development of methods to define cellular microenvironments using the high resolution, 3D capabilities of multiphoton lithography. Here, site-specific photochemistry using multiphoton excitation is applied to the photocrosslinking of proteins, providing the means to organize bioactive species into well-defined 3D microenvironments. Further, conditions have been identified that enable microfabrication to be performed in the presence of cells -- allowing cell outgrowth and motility to be directed in real time. In addition to the intrinsic chemical functionality of microfabricated protein structures, 3D protein matrices are shown to respond mechanically to changes in the chemical environment, enabling new avenues for micro-scale actuation to be explored. Complex 2D and 3D protein photocrosslinking is further facilitated by integrating transparency and automated reflectance photomasks into the fabrication system. These advances could be transformative in efforts to fabricate precise cellular scaffolding that replicates the morphological (and potentially biochemical) features of in vivo tissue microenvironments. Finally, these methods are applied to the study of microorganism behavior with single-cell resolution. Microarchitectures are designed that allow the position and motion of motile bacterial to generate directional microfluidic flow -- providing a foundation to develop micro-scale devices powered by cells. / text

Multiphoton processes

Microlithography

Proteins--Crosslinking

Microfabrication

Micro- and nano-periodic-structure-based devices for laser beam control

Gu, Lanlan, 1975-

28 August 2008

With the progress of microfabrication and nanofabrication technologies, there has been a reawakened interest in the possibility of controlling the propagation of light in various materials periodically structured at a scale comparable to, or slightly smaller than the wavelength. We can now engineer materials with periodic structures to implement a great variety of optical phenomena. These include well known effects, such as dispersing a variety of wavelength to form a spectrum and diffracting light and controlling its propagation directions, to new ones such as prohibiting the propagation of light in certain directions at certain wavelengths and localizing light with defects in some artificially synthesized dielectric materials. Advances in this field have had tremendous impact on modern optical and photonic technologies. This doctoral research was aimed at investigating some of the physics and applications of periodic structures for building blocks of the optical communication and interconnection system. Particular research emphasis was placed on the exploitation of innovative periodic structure-based optical and photonic devices featuring better functionality, higher performance, more compact size, and easier fabrication. Research topics extended from one-dimensional periodic-structure-based wavelength-division-multiplexing (WDM) optical interconnects (beam wavelength selection devices), and liquid crystal beam steerers (beam steering devices), to two-dimensional periodic-structure-based silicon photonic-crystal thermo-optic and electro-optic modulators (beam switching devices). This research was specifically targeted to seek novel and effective solutions to some long-standing technical problems, such as the limited wavelength coverage of coarse WDM devices, small bandwidth of highly dispersed dense WDM devices, low deflection efficiency of high-resolution liquid crystal beam steerers, slow switching speed, large device size, and high power consumption of silicon optical modulators, among others. For each subtopic, research challenges were presented and followed by the proposed solutions with extensive theoretical analysis. The proposals were then verified by experimental implementations. Experimental results were carefully interpreted and the future improvements were also discussed.

Lasers--Industrial applications

Microfabrication

Nanostructured materials

The development and characterisation of microfabricated polymer electrolyte membrane fuel cells

Sombatmankhong, Korakot

January 2012

No description available.

660

Control and measurement of oxygen in microfluidic bioreactors.

Nock, Volker Michael

January 2009

Bioartificial Liver (BAL) is a term for medical devices designed to replace natural liver functions. The idea behind the use of artificial livers is to either externally support an injured liver to recovery or bridge a patient with a failing liver to transplantation. Central to all BAL systems is a bioreactor for culturing liver cells. The main function of this reactor is to provide a cell adhesion matrix and supply the necessary nutrient solution. A high cellular oxygen uptake rate combined with low solubility in aqueous media makes oxygen supply to the liver cells the most constraining factor in current reactor designs. Devices with parallel-plate channel geometry promise high efficiency for blood detoxification and liver metabolism. However, due to their specific flow regime oxygen depletion in the medium is a major problem in these devices. This thesis explores a unique method of controlling and measuring dissolved oxygen in BAL cell-culture bioreactors and lab-on-a-chip devices. Testing is performed using simulations, prototype bioreactor devices and in-vitro measurement of dissolved oxygen. Several strategies developed to fabricate the bioreactors and integrate oxygen sensing are presented. Emphasis is placed on techniques that provide compatibility with commonly used microfabrication processes, while allowing for laterally-resolved measurement of oxygen in a re-usable, low-cost setup. The most significant contribution presented is the development and assessment of the tapered cell-culture bioreactor with integrated PtOEPK/PS oxygen sensor. The combination adopts a unique approach to oxygen control. Bioreactor shape is used to modulate the oxygen supplied to cells via the resulting shear-stress function. By linearly increasing the shear-stress oxygen concentration can be maintained constant over the length of the reactor. Using the integrated oxygen sensor, the resulting concentration profile can be monitored in real-time with high lateral resolution. The advantage of the device over existing techniques is that no additional oxygenation inside the reactor chamber is required to maintain a certain concentration profile and that oxygen concentration can be mapped in-situ without having to introduce further chemicals into the perfusion medium. This thesis presents a number of other contributions: a grayscale mask process, development of the PtOEPK/PS sensor patterning method and signal optimization regime, demonstration of the multi-stream flow application, an experimental setup for sensor calibration and a process to pattern cell-adhesion proteins simultaneously with the oxygen sensor, a multi-layer BAL prototype and the results of a brief experiment to test an approach using vertically aligned carbon nanotube bundles as fluidic conduits for bile drainage.

microfluidics

bioreactor

oxygen sensor

cell culture

microfabrication

A Versatile fabrication platform for the exploration of new electronic materials and device structures

Collins, Daniel

31 August 2012

Ubiquitous concerns in device fabrication are nanoscale positioning and the integration of complex combinations of diverse materials, many of which are extremely fragile. Frequently the completed device requires one or more of the constituent materials to be synthesized under suboptimal conditions, thus compromising the performance of the final structure. We have developed a platform to fabricate multi-component electrode cross-bar structures, where each material can be synthesized under its own ideal conditions. Furthermore, surface treatments and procedures that may otherwise be incompatible can be performed without concern of damage to the other constituent materials. We demonstrate our approach by fabricating an all carbon cross-bar electrode structure comprised of a graphene-graphite heterojunction. Initially, a graphene field effect transistor is fabricated using electron beam and optical lithography. The top graphite electrode is sculpted from a bulk piece of highly oriented pyrolytic graphite with the aid of a focused ion beam (FIB) and integrated micromanipulator system. This requires real-time shaping, cutting, accurate positioning (circa 100 nm precision) and wiring of the graphite top electrode. Electron transport characteristics of each electrode component and the final heterostructure have been measured. We show that this process is effective for the production of micron and submicron-scale multi-layer device structures including other materials such as gold. This fabrication scheme could be extended to produce novel structures such as mechanical resonators, and provide a foundation for combining fragile materials that have otherwise been incompatible with traditional fabrication techniques. / Graduate

Graphene

Nanofabrication

Microfabrication

Graphite

FIB

Lithography

Development of high-density optical fiber arrays : new designs and applications in microscopy, microfabrication and chemical sensing /

Michael, Karri L.

January 1999

Thesis (Ph.D.)--Tufts University, 1999. / Adviser: David R. Walt. Submitted to the Dept. of Chemistry. Includes bibliographical references (leaves 233-253). Access restricted to members of the Tufts University community. Also available via the World Wide Web;

Fabrication of hollow optical waveguides on planar substrates /

Barber, John P.,

January 2006

Thesis (Ph. D.)--Brigham Young University. Dept. of Electrical and Computer Engineering, 2006. / Includes bibliographical references (p. 139-148).

Characterisation and optimisation of the variable frequency microwave technique and its application to microfabrication

Antonio, Christian.

January 2006

Thesis (PhD) - Swinburne University of Technology, Industrial Research Institute Swinburne - 2006. / A thesis submitted to the Industrial Research Institute Swinburne, Swinburne University of Technology in fulfillment of the requirements for the degree of Doctor of Philosophy - 2006. Typescript. Includes bibliographical references (p. 183-193).