Simulation on Effects of Different Types of Channel/Drain Engineering Structure on MOS Device Performance

This final year project is aimed to analyze the effects of three different types of channel/drain engineering structure on MOS transistor performance. As a project basis, a 0.35μm process recipe from UC Berkeley is used as reference. To proceed it, the other parameters need to be retained and only t...

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Main Author: Norazlina Mohd Amin
Other Authors: Noraini Othman (Advisor)
Format: Learning Object
Language:English
Published: Universiti Malaysia Perlis 2008
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Online Access:http://dspace.unimap.edu.my/xmlui/handle/123456789/1338
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Institution: Universiti Malaysia Perlis
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spelling my.unimap-13382008-06-30T04:25:45Z Simulation on Effects of Different Types of Channel/Drain Engineering Structure on MOS Device Performance Norazlina Mohd Amin Noraini Othman (Advisor) Metal oxide semiconductors MOS transistor Lightly Doped Drain (LDD) Moderately Doped Drain (MDD) Halo-Implantation structure Metal oxide semiconductors -- Mathematical models This final year project is aimed to analyze the effects of three different types of channel/drain engineering structure on MOS transistor performance. As a project basis, a 0.35μm process recipe from UC Berkeley is used as reference. To proceed it, the other parameters need to be retained and only the channel/drain structure is altered. The MOS structure is first designed using TSUPREM4. The channel/drain engineering structures to be designed are Lightly Doped Drain (LDD), Moderately Doped Drain (MDD) and Halo-Implantation structure. This is followed by extraction of the electrical characteristic in MEDICI. Parameters that have been extracted are threshold voltage, linear slope, off-current and the subthreshold slope. From the results, it is found that NMOS transistor with Halo Implant structure gives the best performance. The threshold voltage (Vth) extracted for the halo implant structure is of 0.2613 V with off-current of 9.1553 x 10-3 A/um. The low Vth obtained shows that only a small amount of Vg is needed to turn-on the transistor. Meanwhile, low value of off-current means that only a small amount of leakage current flows when the transistor is in the ‘off’ condition. Other parameters extracted are linear slope with value of 27.16 μA/μm-V and subthreshold slope with value of 85.28 mV/dec. 2008-06-30T04:25:45Z 2008-06-30T04:25:45Z 2007-03 Learning Object http://hdl.handle.net/123456789/1338 en Universiti Malaysia Perlis School of Microelectronic Engineering
institution Universiti Malaysia Perlis
building UniMAP Library
collection Institutional Repository
continent Asia
country Malaysia
content_provider Universiti Malaysia Perlis
content_source UniMAP Library Digital Repository
url_provider http://dspace.unimap.edu.my/
language English
topic Metal oxide semiconductors
MOS transistor
Lightly Doped Drain (LDD)
Moderately Doped Drain (MDD)
Halo-Implantation structure
Metal oxide semiconductors -- Mathematical models
spellingShingle Metal oxide semiconductors
MOS transistor
Lightly Doped Drain (LDD)
Moderately Doped Drain (MDD)
Halo-Implantation structure
Metal oxide semiconductors -- Mathematical models
Norazlina Mohd Amin
Simulation on Effects of Different Types of Channel/Drain Engineering Structure on MOS Device Performance
description This final year project is aimed to analyze the effects of three different types of channel/drain engineering structure on MOS transistor performance. As a project basis, a 0.35μm process recipe from UC Berkeley is used as reference. To proceed it, the other parameters need to be retained and only the channel/drain structure is altered. The MOS structure is first designed using TSUPREM4. The channel/drain engineering structures to be designed are Lightly Doped Drain (LDD), Moderately Doped Drain (MDD) and Halo-Implantation structure. This is followed by extraction of the electrical characteristic in MEDICI. Parameters that have been extracted are threshold voltage, linear slope, off-current and the subthreshold slope. From the results, it is found that NMOS transistor with Halo Implant structure gives the best performance. The threshold voltage (Vth) extracted for the halo implant structure is of 0.2613 V with off-current of 9.1553 x 10-3 A/um. The low Vth obtained shows that only a small amount of Vg is needed to turn-on the transistor. Meanwhile, low value of off-current means that only a small amount of leakage current flows when the transistor is in the ‘off’ condition. Other parameters extracted are linear slope with value of 27.16 μA/μm-V and subthreshold slope with value of 85.28 mV/dec.
author2 Noraini Othman (Advisor)
author_facet Noraini Othman (Advisor)
Norazlina Mohd Amin
format Learning Object
author Norazlina Mohd Amin
author_sort Norazlina Mohd Amin
title Simulation on Effects of Different Types of Channel/Drain Engineering Structure on MOS Device Performance
title_short Simulation on Effects of Different Types of Channel/Drain Engineering Structure on MOS Device Performance
title_full Simulation on Effects of Different Types of Channel/Drain Engineering Structure on MOS Device Performance
title_fullStr Simulation on Effects of Different Types of Channel/Drain Engineering Structure on MOS Device Performance
title_full_unstemmed Simulation on Effects of Different Types of Channel/Drain Engineering Structure on MOS Device Performance
title_sort simulation on effects of different types of channel/drain engineering structure on mos device performance
publisher Universiti Malaysia Perlis
publishDate 2008
url http://dspace.unimap.edu.my/xmlui/handle/123456789/1338
_version_ 1643787259593359360