Thermal conductivity of AlN-cordierite composite for microelectronic packaging

The ongoing pursuit of improving the performance of microelectronics constantly increases the demands for better heat dissipation capability of the packagings which house these electronic devices. Besides heat dissipation, other factors such as the dielectric constant, processing temperature and...

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Main Author: Chua, Jonathan Loy Pang.
Other Authors: Oh, Joo Tien
Format: Final Year Project
Language:English
Published: 2009
Subjects:
Online Access:http://hdl.handle.net/10356/15429
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Institution: Nanyang Technological University
Language: English
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spelling sg-ntu-dr.10356-154292023-03-04T15:41:16Z Thermal conductivity of AlN-cordierite composite for microelectronic packaging Chua, Jonathan Loy Pang. Oh, Joo Tien School of Materials Science and Engineering DRNTU::Engineering::Materials::Composite materials The ongoing pursuit of improving the performance of microelectronics constantly increases the demands for better heat dissipation capability of the packagings which house these electronic devices. Besides heat dissipation, other factors such as the dielectric constant, processing temperature and coefficient of thermal expansion also need to be considered where selecting an effective packaging material. A composite consisting of Aluminium Nitride and Cordierite could in theory meet all of the above requirements. This project involved the characterization of the microstructure and thermal conductivity of a set of samples consisting of varying amounts of Aluminium Nitride and Cordierite. Increasing amounts of Aluminium Nitride generally increased the thermal conductivity of the composite for Aluminium Nitride content lesser than 60%. At 60% Aluminium Nitride content, there is a drop in thermal conductivity. This is followed by a subsequent increase in thermal conductivity in the last sample containing 70% Aluminium Nitride. It was observed that these changes in thermal conductivity with Aluminium Nitride and Cordierite content were linked to the microstructure and thermal conduction pathways within the composite. A transition in the continuous phase of the composite from Cordierite to Aluminium Nitride was linked to the drop in thermal conductivity at 60% Aluminium Nitride content. The completion of this transition at higher Aluminium Nitride content led to a subsequent increase in thermal conductivity of the composite. Bachelor of Engineering (Materials Engineering) 2009-04-29T08:03:22Z 2009-04-29T08:03:22Z 2009 2009 Final Year Project (FYP) http://hdl.handle.net/10356/15429 en 43 p. application/pdf
institution Nanyang Technological University
building NTU Library
continent Asia
country Singapore
Singapore
content_provider NTU Library
collection DR-NTU
language English
topic DRNTU::Engineering::Materials::Composite materials
spellingShingle DRNTU::Engineering::Materials::Composite materials
Chua, Jonathan Loy Pang.
Thermal conductivity of AlN-cordierite composite for microelectronic packaging
description The ongoing pursuit of improving the performance of microelectronics constantly increases the demands for better heat dissipation capability of the packagings which house these electronic devices. Besides heat dissipation, other factors such as the dielectric constant, processing temperature and coefficient of thermal expansion also need to be considered where selecting an effective packaging material. A composite consisting of Aluminium Nitride and Cordierite could in theory meet all of the above requirements. This project involved the characterization of the microstructure and thermal conductivity of a set of samples consisting of varying amounts of Aluminium Nitride and Cordierite. Increasing amounts of Aluminium Nitride generally increased the thermal conductivity of the composite for Aluminium Nitride content lesser than 60%. At 60% Aluminium Nitride content, there is a drop in thermal conductivity. This is followed by a subsequent increase in thermal conductivity in the last sample containing 70% Aluminium Nitride. It was observed that these changes in thermal conductivity with Aluminium Nitride and Cordierite content were linked to the microstructure and thermal conduction pathways within the composite. A transition in the continuous phase of the composite from Cordierite to Aluminium Nitride was linked to the drop in thermal conductivity at 60% Aluminium Nitride content. The completion of this transition at higher Aluminium Nitride content led to a subsequent increase in thermal conductivity of the composite.
author2 Oh, Joo Tien
author_facet Oh, Joo Tien
Chua, Jonathan Loy Pang.
format Final Year Project
author Chua, Jonathan Loy Pang.
author_sort Chua, Jonathan Loy Pang.
title Thermal conductivity of AlN-cordierite composite for microelectronic packaging
title_short Thermal conductivity of AlN-cordierite composite for microelectronic packaging
title_full Thermal conductivity of AlN-cordierite composite for microelectronic packaging
title_fullStr Thermal conductivity of AlN-cordierite composite for microelectronic packaging
title_full_unstemmed Thermal conductivity of AlN-cordierite composite for microelectronic packaging
title_sort thermal conductivity of aln-cordierite composite for microelectronic packaging
publishDate 2009
url http://hdl.handle.net/10356/15429
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