Neural Network Supported Microscale In Situ Deformation Tracking: A Comparative Study of Testing Geometries

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Neural Network Supported Microscale In Situ Deformation Tracking: A Comparative Study of Testing Geometries. / Keckes, Julius F.; Jelinek, Alexander; Kiener, Daniel et al.
in: JOM, Jahrgang 76.2024, Nr. May, 23.02.2024, S. 2336-2351.

Publikationen: Beitrag in FachzeitschriftArtikelForschung(peer-reviewed)

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@article{f43bddd6658b4845875791d12b52ac4a,
title = "Neural Network Supported Microscale In Situ Deformation Tracking: A Comparative Study of Testing Geometries",
abstract = "Micro- and nanomechanical testing techniques have become an integral part of today{\textquoteright}s materials research portfolio. Contrary to well-studied and majorly standardized nanoindentation testing, in situ testing of various geometries, such as pillar compression, dog bone tension, or cantilever bending, remains rather unique given differences in experimental equipment and sample processing route. The quantification of such experiments is oftentimes limited to load-displacement data, while the gathered in situ images are considered a qualitative information channel only. However, by utilizing modern computer-aided support in the form of the recently developed Segment Anything Model (SAM), quantitative mechanical information from images can be evaluated in a high-throughput manner and adds to the data fidelity and accuracy of every individual experiment. In the present work, we showcase image-assisted mechanical evaluation of compression, tension and bending experiments on micron-scaled resin specimens, produced via two-photon lithography. The present framework allows for a determination of an accurate sample strain, which further enables determination of quantities such as the elastic modulus, Poisson{\textquoteright}s ratio or viscoelastic relaxation after fracture.",
author = "Keckes, {Julius F.} and Alexander Jelinek and Daniel Kiener and Markus Alfreider",
note = "Publisher Copyright: {\textcopyright} The Author(s) 2024.",
year = "2024",
month = feb,
day = "23",
doi = "10.1007/s11837-024-06437-1",
language = "English",
volume = "76.2024",
pages = "2336--2351",
journal = "JOM",
issn = "1047-4838",
publisher = "Minerals, Metals and Materials Society",
number = "May",

}

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TY - JOUR

T1 - Neural Network Supported Microscale In Situ Deformation Tracking: A Comparative Study of Testing Geometries

AU - Keckes, Julius F.

AU - Jelinek, Alexander

AU - Kiener, Daniel

AU - Alfreider, Markus

N1 - Publisher Copyright: © The Author(s) 2024.

PY - 2024/2/23

Y1 - 2024/2/23

N2 - Micro- and nanomechanical testing techniques have become an integral part of today’s materials research portfolio. Contrary to well-studied and majorly standardized nanoindentation testing, in situ testing of various geometries, such as pillar compression, dog bone tension, or cantilever bending, remains rather unique given differences in experimental equipment and sample processing route. The quantification of such experiments is oftentimes limited to load-displacement data, while the gathered in situ images are considered a qualitative information channel only. However, by utilizing modern computer-aided support in the form of the recently developed Segment Anything Model (SAM), quantitative mechanical information from images can be evaluated in a high-throughput manner and adds to the data fidelity and accuracy of every individual experiment. In the present work, we showcase image-assisted mechanical evaluation of compression, tension and bending experiments on micron-scaled resin specimens, produced via two-photon lithography. The present framework allows for a determination of an accurate sample strain, which further enables determination of quantities such as the elastic modulus, Poisson’s ratio or viscoelastic relaxation after fracture.

AB - Micro- and nanomechanical testing techniques have become an integral part of today’s materials research portfolio. Contrary to well-studied and majorly standardized nanoindentation testing, in situ testing of various geometries, such as pillar compression, dog bone tension, or cantilever bending, remains rather unique given differences in experimental equipment and sample processing route. The quantification of such experiments is oftentimes limited to load-displacement data, while the gathered in situ images are considered a qualitative information channel only. However, by utilizing modern computer-aided support in the form of the recently developed Segment Anything Model (SAM), quantitative mechanical information from images can be evaluated in a high-throughput manner and adds to the data fidelity and accuracy of every individual experiment. In the present work, we showcase image-assisted mechanical evaluation of compression, tension and bending experiments on micron-scaled resin specimens, produced via two-photon lithography. The present framework allows for a determination of an accurate sample strain, which further enables determination of quantities such as the elastic modulus, Poisson’s ratio or viscoelastic relaxation after fracture.

UR - http://www.scopus.com/inward/record.url?scp=85185969348&partnerID=8YFLogxK

U2 - 10.1007/s11837-024-06437-1

DO - 10.1007/s11837-024-06437-1

M3 - Article

AN - SCOPUS:85185969348

VL - 76.2024

SP - 2336

EP - 2351

JO - JOM

JF - JOM

SN - 1047-4838

IS - May

ER -