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The New Jersey Institute of Technology's
Electronic Theses & Dissertations Project

Title: Emissivity of patterned silicon wafers in rapid thermal processing
Author: Rabus, Markus
View Online: njit-etd2005-115
(xi, 90 pages ~ 6.0 MB pdf)
Department: Federated Physics Department of NJIT and Rutgers-Newark
Degree: Master of Science
Program: Applied Physics
Document Type: Thesis
Advisory Committee: Fiory, Anthony (Committee co-chair)
Ravindra, N. M. (Committee co-chair)
Ivanov, Dentcho V. (Committee member)
Abedrabbo, Sufian (Committee member)
Dieng, Lamine M. (Committee member)
Date: 2005-08
Keywords: Emissivity
Silicon wafers
rapid thermal processing systems
Availability: Unrestricted
Abstract:

The influence of patterns on emissivity in silicon wafers in rapid thermal processing systems has been investigated. In this study, two experiments with layered and patterned silicon wafers were conducted. The main difference in the experiments is the way in which the temperature was controlled. The first experiment was performed under Open Loop Intensity Control (OLIC). For OLIC, no feedback from the wafer is returned. It is assumed that supplying a certain power level will lead to the desired temperature. The other experiment used the Closed Loop Intensity Control. In this case, a feedback, in the form of temperature deviation is used to adjust the temperature.

By using the Stefan-Boltzmann T4-law, a heat balance equation describing the incoming and outgoing heat can be derived. This heat balance equation can be used to calculate the spatial temperature differences due to different emissivities of the various thin film layers of patterned wafers. A mathematical model was developed based on the heat balance equation. The mathematical model was verified with experiments. The model showed good agreement with the experiments.


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