Selective Carbon Material Engineering for Improved MEMS and NEMS
The development of micro and nano electromechanical systems and achievement of higher performances with increased quality and life time is confronted to searching and mastering of material with superior properties and quality. Those can affect many aspects of the MEMS, NEMS and MOMS design including...
Main Author: | |
---|---|
Format: | Article |
Language: | English |
Published: |
MDPI AG
2019-08-01
|
Series: | Micromachines |
Subjects: | |
Online Access: | https://www.mdpi.com/2072-666X/10/8/539 |
id |
doaj-cddfbd0641bf45f1b6e49e423d855eed |
---|---|
record_format |
Article |
spelling |
doaj-cddfbd0641bf45f1b6e49e423d855eed2020-11-25T02:20:26ZengMDPI AGMicromachines2072-666X2019-08-0110853910.3390/mi10080539mi10080539Selective Carbon Material Engineering for Improved MEMS and NEMSStephane Neuville0Independent Consultant, F-77165 Cuisy, FranceThe development of micro and nano electromechanical systems and achievement of higher performances with increased quality and life time is confronted to searching and mastering of material with superior properties and quality. Those can affect many aspects of the MEMS, NEMS and MOMS design including geometric tolerances and reproducibility of many specific solid-state structures and properties. Among those: Mechanical, adhesion, thermal and chemical stability, electrical and heat conductance, optical, optoelectronic and semiconducting properties, porosity, bulk and surface properties. They can be affected by different kinds of phase transformations and degrading, which greatly depends on the conditions of use and the way the materials have been selected, elaborated, modified and assembled. Distribution of these properties cover several orders of magnitude and depend on the design, actually achieved structure, type and number of defects. It is then essential to be well aware about all these, and to distinguish and characterize all features that are able to affect the results. For this achievement, we point out and discuss the necessity to take into account several recently revisited fundamentals on carbon atomic rearrangement and revised carbon Raman spectroscopy characterizing in addition to several other aspects we will briefly describe. Correctly selected and implemented, these carbon materials can then open new routes for many new and more performing microsystems including improved energy generation, storage and conversion, 2D superconductivity, light switches, light pipes and quantum devices and with new improved sensor and mechanical functions and biomedical applications.https://www.mdpi.com/2072-666X/10/8/539carbon-based materialcarbon structure differentiationNEMS qualityhigher performancesrevised Raman characterizationquantum electronic activationcarbon phase transition |
collection |
DOAJ |
language |
English |
format |
Article |
sources |
DOAJ |
author |
Stephane Neuville |
spellingShingle |
Stephane Neuville Selective Carbon Material Engineering for Improved MEMS and NEMS Micromachines carbon-based material carbon structure differentiation NEMS quality higher performances revised Raman characterization quantum electronic activation carbon phase transition |
author_facet |
Stephane Neuville |
author_sort |
Stephane Neuville |
title |
Selective Carbon Material Engineering for Improved MEMS and NEMS |
title_short |
Selective Carbon Material Engineering for Improved MEMS and NEMS |
title_full |
Selective Carbon Material Engineering for Improved MEMS and NEMS |
title_fullStr |
Selective Carbon Material Engineering for Improved MEMS and NEMS |
title_full_unstemmed |
Selective Carbon Material Engineering for Improved MEMS and NEMS |
title_sort |
selective carbon material engineering for improved mems and nems |
publisher |
MDPI AG |
series |
Micromachines |
issn |
2072-666X |
publishDate |
2019-08-01 |
description |
The development of micro and nano electromechanical systems and achievement of higher performances with increased quality and life time is confronted to searching and mastering of material with superior properties and quality. Those can affect many aspects of the MEMS, NEMS and MOMS design including geometric tolerances and reproducibility of many specific solid-state structures and properties. Among those: Mechanical, adhesion, thermal and chemical stability, electrical and heat conductance, optical, optoelectronic and semiconducting properties, porosity, bulk and surface properties. They can be affected by different kinds of phase transformations and degrading, which greatly depends on the conditions of use and the way the materials have been selected, elaborated, modified and assembled. Distribution of these properties cover several orders of magnitude and depend on the design, actually achieved structure, type and number of defects. It is then essential to be well aware about all these, and to distinguish and characterize all features that are able to affect the results. For this achievement, we point out and discuss the necessity to take into account several recently revisited fundamentals on carbon atomic rearrangement and revised carbon Raman spectroscopy characterizing in addition to several other aspects we will briefly describe. Correctly selected and implemented, these carbon materials can then open new routes for many new and more performing microsystems including improved energy generation, storage and conversion, 2D superconductivity, light switches, light pipes and quantum devices and with new improved sensor and mechanical functions and biomedical applications. |
topic |
carbon-based material carbon structure differentiation NEMS quality higher performances revised Raman characterization quantum electronic activation carbon phase transition |
url |
https://www.mdpi.com/2072-666X/10/8/539 |
work_keys_str_mv |
AT stephaneneuville selectivecarbonmaterialengineeringforimprovedmemsandnems |
_version_ |
1724871295814860800 |