Gas Phase Etching of Silicon Dioxide Films

Montano, Gerardo

January 2006

The gas phase etching of thermal silicon dioxide films was investigated with in situ Fourier Transformed Infrared Spectroscopy (FTIR) and ex situ X-ray Photoelectron Spectroscopy (XPS). The initiation process, the bulk etching of the oxide, and the termination mechanism were characterized as a function of reactant concentration, temperature, and pressure. The experiments were carried out in a custom made vessel with a gas panel and a data acquisition and control system (DA&C) capable of lowering flow and pressure disturbances originated by reactant introduction. The FTIR technique used to monitor the reaction in real time allowed distinguishing reactions that initiated in a gas/solid regime from reactions that started in a gas/liquid/solid regime. This study was focused on the gas/solid initiation process in order to expand the general assumption in published works that a condensed layer is previously required to initiate and sustain the reaction. It was found in this investigation that, depending on the experimental parameters, the water layer is not always a requisite for the initiation of the reaction but a consequence of the etching process. The FTIR data also showed the role in the initiation process of gas phase heterogeneous associated species, specifically (HF)H₂O and (HF)₂H₂O. After the initiation period, the experimental conditions determined the amount of water present on the surface of the sample, which in turn determined the local environment of the reaction and by extension the etching species. Reactions developing in a gas/solid regime were found to be slow, with etching rates of less than 1 °A/sec. Contrarily, reactions taking place in a gas/liquid/solid regime reached etching rates of 100 °A/sec, a maximum value determined by transport limitations. The condensed layer was found to be especially sensitive to temperature since a variation of 15 ° C changed the local environment from gas/liquid/solid to gas/solid. Finally, it was corroborated through the XPS analysis that the removal process in the gas phase leaves the silicon surfaces with high fluorine and oxygen concentrations in the form of SiFₓ and SiOH.

Data Acquisition and Control

Silicon dioxide

Etching

HF

H2O

Surface Phenomena

Monitoring & Remote Operation of an Engine Test Cell

Turner, Jamie

22 October 2014

In the automotive industry engines are regularly tested and evaluated by running them for a prolonged time under controlled conditions; environmental conditions, engine load, and drive cycle. These tests are performed in an engine test cell; a computer controlled environment with mechanical fittings and sensors to facilitate the testing of an engine. Our goal was to develop a software suite that provides a distributed graphical interface to the data acquisition and control systems of an engine cell. As we found existing systems to be inadequate in providing a distributed interface, we designed and developed a light weight flexible software suite to remotely, over a network, observe and control the parameters in an engine cell. We used the Fast Light Toolkit (FLTK) GUI library, with networking sockets and process threads to establish the software architecture of the engine test system. Through use of process threads, the client architecture divides tasks into network data sending and receiving, local channel synchronization, and interface operation. Networking sockets used in network data sending and receiving facilitate synchronization of each clients' channel storage and host's channel data. The FLTK GUI library produces visual interactive components of the interface for invoking interactions. Distributed interfacing allows display and modification of the engine cell's operation remotely in locations where relocating an engine cell is not feasible. These locations, such as demonstrations to distant clients and meeting rooms, display the current status of the engine cell through its interfaces without requiring migration of the engine cell to the specified rooms. / Thesis / Master of Applied Science (MASc)

Engine Test Cell

FLTK

Data Acquisition and Control

Automotive Testing

Remote Operation