Development and Proof of Concept of a Miniaturized MEMS Quantum Tunneling Accelerometer Based on PtC Tips by Focused Ion Beam 3D Nano-Patterning

Development and Proof of Concept of a Miniaturized MEMS Quantum Tunneling Accelerometer Based on PtC Tips by Focused Ion Beam 3D Nano-Patterning

Most accelerometers today are based on the capacitive principle. However, further miniaturization for micro integration of those sensors leads to a poorer signal-to-noise ratio due to a small total area of the capacitor plates. Thus, other transducer principles should be taken into account to develo...

Full description

Bibliographic Details
Main Authors: Michael Haub, Martin Bogner, Thomas Guenther, André Zimmermann, Hermann Sandmaier
Format: Article
Language:English
Published: MDPI AG 2021-05-01
Series:Sensors
Subjects:
tunneling effect
accelerometer
focused ion beam
fib
quantum sensor
tunneling tip
Online Access:https://www.mdpi.com/1424-8220/21/11/3795
id doaj-271c050d61814e809831c653692b461b
record_format Article
spelling doaj-271c050d61814e809831c653692b461b2021-06-01T01:41:12ZengMDPI AGSensors1424-82202021-05-01213795379510.3390/s21113795Development and Proof of Concept of a Miniaturized MEMS Quantum Tunneling Accelerometer Based on PtC Tips by Focused Ion Beam 3D Nano-PatterningMichael Haub0Martin Bogner1Thomas Guenther2André Zimmermann3Hermann Sandmaier4Institute for Micro Integration (IFM), University of Stuttgart, Allmandring 9b, 70569 Stuttgart, GermanyInstitute for Micro Integration (IFM), University of Stuttgart, Allmandring 9b, 70569 Stuttgart, GermanyInstitute for Micro Integration (IFM), University of Stuttgart, Allmandring 9b, 70569 Stuttgart, GermanyInstitute for Micro Integration (IFM), University of Stuttgart, Allmandring 9b, 70569 Stuttgart, GermanyChair of Microsystems (MST), University of Stuttgart, Pfaffenwaldring 4F, 70569 Stuttgart, GermanyMost accelerometers today are based on the capacitive principle. However, further miniaturization for micro integration of those sensors leads to a poorer signal-to-noise ratio due to a small total area of the capacitor plates. Thus, other transducer principles should be taken into account to develop smaller sensors. This paper presents the development and realization of a miniaturized accelerometer based on the tunneling effect, whereas its highly sensitive effect regarding the tunneling distance is used to detect small deflections in the range of sub-nm. The spring-mass-system is manufactured by a surface micro-machining foundry process. The area of the shown polysilicon (PolySi) sensor structures has a size smaller than 100 µm × 50 µm (L × W). The tunneling electrodes are placed and patterned by a focused ion beam (FIB) and gas injection system (GIS) with MeCpPtMe<sub>3</sub> as a precursor. A dual-beam system enables maximum flexibility for post-processing of the spring-mass-system and patterning of sharp tips with radii in the range of a few nm and initial distances between the electrodes of about 30–300 nm. The use of metal–organic precursor material platinum carbon (PtC) limits the tunneling currents to about 150 pA due to the high inherent resistance. The measuring range is set to 20 g. The sensitivity of the sensor signal, which depends exponentially on the electrode distance due to the tunneling effect, ranges from 0.4 pA/g at 0 g in the sensor operational point up to 20.9 pA/g at 20 g. The acceleration-equivalent thermal noise amplitude is calculated to be 2.4–3.4 mg/. Electrostatic actuators are used to lead the electrodes in distances where direct quantum tunneling occurs.https://www.mdpi.com/1424-8220/21/11/3795tunneling effectaccelerometerfocused ion beamfibquantum sensortunneling tip
collection DOAJ
language English
format Article
sources DOAJ
author Michael Haub
Martin Bogner
Thomas Guenther
André Zimmermann
Hermann Sandmaier
spellingShingle Michael Haub
Martin Bogner
Thomas Guenther
André Zimmermann
Hermann Sandmaier
Development and Proof of Concept of a Miniaturized MEMS Quantum Tunneling Accelerometer Based on PtC Tips by Focused Ion Beam 3D Nano-Patterning
Sensors
tunneling effect
accelerometer
focused ion beam
fib
quantum sensor
tunneling tip
author_facet Michael Haub
Martin Bogner
Thomas Guenther
André Zimmermann
Hermann Sandmaier
author_sort Michael Haub
title Development and Proof of Concept of a Miniaturized MEMS Quantum Tunneling Accelerometer Based on PtC Tips by Focused Ion Beam 3D Nano-Patterning
title_short Development and Proof of Concept of a Miniaturized MEMS Quantum Tunneling Accelerometer Based on PtC Tips by Focused Ion Beam 3D Nano-Patterning
title_full Development and Proof of Concept of a Miniaturized MEMS Quantum Tunneling Accelerometer Based on PtC Tips by Focused Ion Beam 3D Nano-Patterning
title_fullStr Development and Proof of Concept of a Miniaturized MEMS Quantum Tunneling Accelerometer Based on PtC Tips by Focused Ion Beam 3D Nano-Patterning
title_full_unstemmed Development and Proof of Concept of a Miniaturized MEMS Quantum Tunneling Accelerometer Based on PtC Tips by Focused Ion Beam 3D Nano-Patterning
title_sort development and proof of concept of a miniaturized mems quantum tunneling accelerometer based on ptc tips by focused ion beam 3d nano-patterning
publisher MDPI AG
series Sensors
issn 1424-8220
publishDate 2021-05-01
description Most accelerometers today are based on the capacitive principle. However, further miniaturization for micro integration of those sensors leads to a poorer signal-to-noise ratio due to a small total area of the capacitor plates. Thus, other transducer principles should be taken into account to develop smaller sensors. This paper presents the development and realization of a miniaturized accelerometer based on the tunneling effect, whereas its highly sensitive effect regarding the tunneling distance is used to detect small deflections in the range of sub-nm. The spring-mass-system is manufactured by a surface micro-machining foundry process. The area of the shown polysilicon (PolySi) sensor structures has a size smaller than 100 µm × 50 µm (L × W). The tunneling electrodes are placed and patterned by a focused ion beam (FIB) and gas injection system (GIS) with MeCpPtMe<sub>3</sub> as a precursor. A dual-beam system enables maximum flexibility for post-processing of the spring-mass-system and patterning of sharp tips with radii in the range of a few nm and initial distances between the electrodes of about 30–300 nm. The use of metal–organic precursor material platinum carbon (PtC) limits the tunneling currents to about 150 pA due to the high inherent resistance. The measuring range is set to 20 g. The sensitivity of the sensor signal, which depends exponentially on the electrode distance due to the tunneling effect, ranges from 0.4 pA/g at 0 g in the sensor operational point up to 20.9 pA/g at 20 g. The acceleration-equivalent thermal noise amplitude is calculated to be 2.4–3.4 mg/. Electrostatic actuators are used to lead the electrodes in distances where direct quantum tunneling occurs.
topic tunneling effect
accelerometer
focused ion beam
fib
quantum sensor
tunneling tip
url https://www.mdpi.com/1424-8220/21/11/3795
work_keys_str_mv AT michaelhaub developmentandproofofconceptofaminiaturizedmemsquantumtunnelingaccelerometerbasedonptctipsbyfocusedionbeam3dnanopatterning
AT martinbogner developmentandproofofconceptofaminiaturizedmemsquantumtunnelingaccelerometerbasedonptctipsbyfocusedionbeam3dnanopatterning
AT thomasguenther developmentandproofofconceptofaminiaturizedmemsquantumtunnelingaccelerometerbasedonptctipsbyfocusedionbeam3dnanopatterning
AT andrezimmermann developmentandproofofconceptofaminiaturizedmemsquantumtunnelingaccelerometerbasedonptctipsbyfocusedionbeam3dnanopatterning
AT hermannsandmaier developmentandproofofconceptofaminiaturizedmemsquantumtunnelingaccelerometerbasedonptctipsbyfocusedionbeam3dnanopatterning
_version_ 1721411767753506816

Similar Items