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Hauptverfasser: Lukas, Sebastian, Esteki, Ardeshir, Rademacher, Nico, Jangra, Vikas, Gross, Michael, Wang, Zhenxing, Ngo, Ha Duong, Bäuscher, Manuel, Mackowiak, Piotr, Höppner, Katrin, Wehenkel, Dominique, van Rijn, Richard, Lemme, Max C.
Format: Preprint
Veröffentlicht: 2024
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Online-Zugang:https://arxiv.org/abs/2408.16408
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author Lukas, Sebastian
Esteki, Ardeshir
Rademacher, Nico
Jangra, Vikas
Gross, Michael
Wang, Zhenxing
Ngo, Ha Duong
Bäuscher, Manuel
Mackowiak, Piotr
Höppner, Katrin
Wehenkel, Dominique
van Rijn, Richard
Lemme, Max C.
author_facet Lukas, Sebastian
Esteki, Ardeshir
Rademacher, Nico
Jangra, Vikas
Gross, Michael
Wang, Zhenxing
Ngo, Ha Duong
Bäuscher, Manuel
Mackowiak, Piotr
Höppner, Katrin
Wehenkel, Dominique
van Rijn, Richard
Lemme, Max C.
contents Suspended membranes of monoatomic graphene exhibit great potential for applications in electronic and nanoelectromechanical devices. In this work, a "hot and dry" transfer process is demonstrated to address the fabrication and patterning challenges of large-area graphene membranes on top of closed, sealed cavities. Here, "hot" refers to the use of high temperature during transfer, promoting the adhesion. Additionally, "dry" refers to the absence of liquids when graphene and target substrate are brought into contact. The method leads to higher yields of intact suspended monolayer CVD graphene and artificially stacked double-layer CVD graphene membranes than previously reported. The yield evaluation is performed using neural-network-based object detection in SEM images, ascertaining high yields of intact membranes with large statistical accuracy. The suspended membranes are examined by Raman tomography and AFM. The method is verified by applying the suspended graphene devices as piezoresistive pressure sensors. Our technology advances the application of suspended graphene membranes and can be extended to other two-dimensional (2D) materials.
format Preprint
id arxiv_https___arxiv_org_abs_2408_16408
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle High-yield large-scale suspended graphene membranes over closed cavities for sensor applications
Lukas, Sebastian
Esteki, Ardeshir
Rademacher, Nico
Jangra, Vikas
Gross, Michael
Wang, Zhenxing
Ngo, Ha Duong
Bäuscher, Manuel
Mackowiak, Piotr
Höppner, Katrin
Wehenkel, Dominique
van Rijn, Richard
Lemme, Max C.
Applied Physics
Suspended membranes of monoatomic graphene exhibit great potential for applications in electronic and nanoelectromechanical devices. In this work, a "hot and dry" transfer process is demonstrated to address the fabrication and patterning challenges of large-area graphene membranes on top of closed, sealed cavities. Here, "hot" refers to the use of high temperature during transfer, promoting the adhesion. Additionally, "dry" refers to the absence of liquids when graphene and target substrate are brought into contact. The method leads to higher yields of intact suspended monolayer CVD graphene and artificially stacked double-layer CVD graphene membranes than previously reported. The yield evaluation is performed using neural-network-based object detection in SEM images, ascertaining high yields of intact membranes with large statistical accuracy. The suspended membranes are examined by Raman tomography and AFM. The method is verified by applying the suspended graphene devices as piezoresistive pressure sensors. Our technology advances the application of suspended graphene membranes and can be extended to other two-dimensional (2D) materials.
title High-yield large-scale suspended graphene membranes over closed cavities for sensor applications
topic Applied Physics
url https://arxiv.org/abs/2408.16408