Electrochemical deposition of Bi2Te3 for infiltrating into patterned templates

Bi2Te3-based materials are the most promising thermoelectric (TE) materials for near room temperature applications and currently being used for fabricating commercial TE devices. However, the higher ZT achieved so far for Bi2Te3-based materials still remains around 1.0. ZT is expected to improve by...

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Main Author: Zhao, Junnan.
Other Authors: Hng Huey Hoon
Format: Final Year Project
Language:English
Published: 2010
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Online Access:http://hdl.handle.net/10356/39949
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Institution: Nanyang Technological University
Language: English
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spelling sg-ntu-dr.10356-399492023-03-04T15:41:30Z Electrochemical deposition of Bi2Te3 for infiltrating into patterned templates Zhao, Junnan. Hng Huey Hoon School of Materials Science and Engineering DRNTU::Engineering::Materials Bi2Te3-based materials are the most promising thermoelectric (TE) materials for near room temperature applications and currently being used for fabricating commercial TE devices. However, the higher ZT achieved so far for Bi2Te3-based materials still remains around 1.0. ZT is expected to improve by designing phononic structure which can reduce thermal conductivity but not affect the electrical conductivity. Cost-effectiveness and relative ease in controlling the experimental parameters make electrochemical deposition (ECD) on templated substrates an attractive process for the synthesis of novel structures. This work was divided into two parts. The first part established the optimum deposition conditions which were then used for depositions on templated substrates. Two series of Bi2Te3 films were deposited with varying potential (-0.1V, -0.2V, -0.3V, -0.4V)and varying film thickness (1μm and 2μm) respectively via pulsed ECD on sputtered Bi2Te3 conductive layer to study the effect of various potentials and film thickness on TE properties. The optimized conditions were then used to infiltrate Bi2Te3 into commercial templates, so as to determine the suitability of ECD for future infiltration into phononic templates. The deposited films exhibited higher electrical conductivity and lower Seebeck coefficient as compared to sputtered Bi2Te3 conductive layer. A peak power factor of 1.05×10-3 W/m.K2 was achieved in the film deposited at potential of -0.1V with 2μm thick, which was contributed to the large increase in electrical conductivity. Infiltration of Bi2Te3 into AAO and PC templates was conducted at potential of -0.1V, determined by results obtained in the first part of the project. High yielding rates were achieved in both AAO and PC templates. It is predicted that Bi2Te3 can be infiltrated successfully into phononic templates to create phononic structure when phononic templates can be finally created in the future work. Bachelor of Engineering (Materials Engineering) 2010-06-08T04:45:50Z 2010-06-08T04:45:50Z 2010 2010 Final Year Project (FYP) http://hdl.handle.net/10356/39949 en Nanyang Technological University 48 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
spellingShingle DRNTU::Engineering::Materials
Zhao, Junnan.
Electrochemical deposition of Bi2Te3 for infiltrating into patterned templates
description Bi2Te3-based materials are the most promising thermoelectric (TE) materials for near room temperature applications and currently being used for fabricating commercial TE devices. However, the higher ZT achieved so far for Bi2Te3-based materials still remains around 1.0. ZT is expected to improve by designing phononic structure which can reduce thermal conductivity but not affect the electrical conductivity. Cost-effectiveness and relative ease in controlling the experimental parameters make electrochemical deposition (ECD) on templated substrates an attractive process for the synthesis of novel structures. This work was divided into two parts. The first part established the optimum deposition conditions which were then used for depositions on templated substrates. Two series of Bi2Te3 films were deposited with varying potential (-0.1V, -0.2V, -0.3V, -0.4V)and varying film thickness (1μm and 2μm) respectively via pulsed ECD on sputtered Bi2Te3 conductive layer to study the effect of various potentials and film thickness on TE properties. The optimized conditions were then used to infiltrate Bi2Te3 into commercial templates, so as to determine the suitability of ECD for future infiltration into phononic templates. The deposited films exhibited higher electrical conductivity and lower Seebeck coefficient as compared to sputtered Bi2Te3 conductive layer. A peak power factor of 1.05×10-3 W/m.K2 was achieved in the film deposited at potential of -0.1V with 2μm thick, which was contributed to the large increase in electrical conductivity. Infiltration of Bi2Te3 into AAO and PC templates was conducted at potential of -0.1V, determined by results obtained in the first part of the project. High yielding rates were achieved in both AAO and PC templates. It is predicted that Bi2Te3 can be infiltrated successfully into phononic templates to create phononic structure when phononic templates can be finally created in the future work.
author2 Hng Huey Hoon
author_facet Hng Huey Hoon
Zhao, Junnan.
format Final Year Project
author Zhao, Junnan.
author_sort Zhao, Junnan.
title Electrochemical deposition of Bi2Te3 for infiltrating into patterned templates
title_short Electrochemical deposition of Bi2Te3 for infiltrating into patterned templates
title_full Electrochemical deposition of Bi2Te3 for infiltrating into patterned templates
title_fullStr Electrochemical deposition of Bi2Te3 for infiltrating into patterned templates
title_full_unstemmed Electrochemical deposition of Bi2Te3 for infiltrating into patterned templates
title_sort electrochemical deposition of bi2te3 for infiltrating into patterned templates
publishDate 2010
url http://hdl.handle.net/10356/39949
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