Modeling undeposited CNTs for high performance design and the evaluation of reliable CNTFET circuits

Modeling undeposited CNTs for high performance design and the evaluation of reliable CNTFET circuits

The Carbon NanoTube Field Effect Transistor (CNTFET) is one of the most promising emerging technologies to extend and complement silicon MOSFET; this is due to its excellent performance characteristics and similarity in operational principles and device structure. During manufacturing, CNTs are usua...

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Online Access:http://hdl.handle.net/2047/d20002840
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spelling ndltd-NEU--neu-13972021-05-25T05:09:45ZModeling undeposited CNTs for high performance design and the evaluation of reliable CNTFET circuitsThe Carbon NanoTube Field Effect Transistor (CNTFET) is one of the most promising emerging technologies to extend and complement silicon MOSFET; this is due to its excellent performance characteristics and similarity in operational principles and device structure. During manufacturing, CNTs are usually grown or transferred to a substrate with a fixed pitch prior to defining the gates and the contacts. One of the likely defects occurs during the deposition of the CNTs, i.e. only some of the required CNTs are deposited. These defects significantly affect the performance of the CNTFET, because the number of CNTs present in the channel is reduced and the distances between CNTs become uneven, thus causing changes of current and capacitance.http://hdl.handle.net/2047/d20002840
collection NDLTD
sources NDLTD
description The Carbon NanoTube Field Effect Transistor (CNTFET) is one of the most promising emerging technologies to extend and complement silicon MOSFET; this is due to its excellent performance characteristics and similarity in operational principles and device structure. During manufacturing, CNTs are usually grown or transferred to a substrate with a fixed pitch prior to defining the gates and the contacts. One of the likely defects occurs during the deposition of the CNTs, i.e. only some of the required CNTs are deposited. These defects significantly affect the performance of the CNTFET, because the number of CNTs present in the channel is reduced and the distances between CNTs become uneven, thus causing changes of current and capacitance.
title Modeling undeposited CNTs for high performance design and the evaluation of reliable CNTFET circuits
spellingShingle Modeling undeposited CNTs for high performance design and the evaluation of reliable CNTFET circuits
title_short Modeling undeposited CNTs for high performance design and the evaluation of reliable CNTFET circuits
title_full Modeling undeposited CNTs for high performance design and the evaluation of reliable CNTFET circuits
title_fullStr Modeling undeposited CNTs for high performance design and the evaluation of reliable CNTFET circuits
title_full_unstemmed Modeling undeposited CNTs for high performance design and the evaluation of reliable CNTFET circuits
title_sort modeling undeposited cnts for high performance design and the evaluation of reliable cntfet circuits
publishDate
url http://hdl.handle.net/2047/d20002840
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