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PhD Defense of Pierre JANIOUD

Published on July 7, 2020
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PhD Defense July 10, 2020
Defense of doctoral thesis of  Pierre JANIOUD, for the University Grenoble Alpes , speciality " NANO ELECTRONIC & NANO TECHNOLOGIES ", entitled:
Due to the Covid-19 health crisis, this defense will held through VISIO - CONFERENCE.

«Thermal piezoresistive back action in suspended silicon nanowires based MEMS »

JANIOUD Pierre

JANIOUD Pierre

Friday, 10 July, 2020 at 2pm

Keywords:
MEMS,silicon nanowire, resonator, thermal piezoresistive back action, thermoelasticity, piezoresistivity, damping, self-sustained oscillation


Abstract:
The development of new technologies, either in consumer electronic domain (smartphones, internet of things...) or in automotive domain (autonomous vehicles), largely boosted the increasing demand of miniaturized and highly performant sensors. Piezoresitive transduction by means of silicon nanowire is particularly interesting to improve detection capability of current sensors. Various benefits of this transduction have been identified for NEMS and MEMS applications, and in particular, high sensitivity and excellent compactness. Moreover, power consumption remains a major issue for miniaturized sensors. Optimized use of nanowires could eventually lead to significant improvement of this transduction mechanism for low power and high performances sensors.

Thermal Piezoresistive Back Action (TPBA), highlighted in DC-biased nanowires, allows to finely control electromechanical response and optimize the transduction mechanism of MEMS. Based on a thermal, electrical and mechanical coupling, this phenomenon particularly allows to reach a self-sustained oscillation regime that could be used to monitor the resonance frequency of a resonator.

The objective of this thesis is to study this back action mechanism in nanowires used for M&NEMS components developed at CEA-Leti. A complete study of silicon nanowires properties, whose typical dimensions are 250 nm x 250 nm x 5 μm, allows to evaluate their interest to implement this mechanism. Based on analytical models and finite element modeling, a model of this phenomenon is proposed. Then, it is confronted with experimental results achieved on existing components and others fabricated during this thesis. Finally, a discussion on the perspectives of this study evaluates the gain brought by this mechanism and its potential applications.
 
Jury members :
  • Bernard LEGRAND,Research Director CNRS, LAAS, Toulouse : Reviewer
  • Guillermo VILLANUEVA, Professor EPFL, Lausanne / Suisse : Reviewer
  • Isabelle DUFOUR, University Professor , IMS, Bordeaux : Examiner
  • Lionel BUCHAILLOT, Research Director CNRS, IEMN, Lille : Examiner
  • Panagiota MORFOULI, Professor Grenoble INP, Grenoble : Supervisor
Guest members :
  • Guillaume JOURDAN, Doctor Engineer, CEA LETI, Grenoble : Co-supervisor
  • Alexandra KOUMELA, Doctor Engineer, CEA LETI, Grenoble : Co-supervisor
  • Christophe POULAIN, Doctor Engineer, CEA LETI, Grenoble : Co-supervisor

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Partenaires

Thesis prepared at CEA-Leti supervised by  Panagiota MORFOULI (professor  Grenoble INP) and  co-supervised by  Christophe POULAIN, Alexandra KOUMELA and Guillaume JOURDAN (Doctor Engineer  at CEA) .

Date of update July 28, 2020

French
IMEP-LAHC
Grenoble site
Grenoble INP - Minatec : 3, Parvis Louis Néel - CS 50257 - 38016 Grenoble Cedex 1

Chambery site
Université Savoie Mont Blanc - F73376 Le Bourget du Lac Cedex
 
 
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Université Grenoble Alpes