Biomechanical Replication of Salt Marsh Vegetation using Resin 3D Printing

Publikation: Beitrag in Buch/Bericht/Sammelwerk/KonferenzbandAufsatz in KonferenzbandForschungPeer-Review

Autoren

  • Kara Keimer
  • Viktoria Kosmalla
  • Oliver Lojek
  • Nils Goseberg

Organisationseinheiten

Externe Organisationen

  • Technische Universität Braunschweig
Forschungs-netzwerk anzeigen

Details

OriginalspracheEnglisch
Titel des SammelwerksProceedings of the 40th IAHR World Congress
PublikationsstatusVeröffentlicht - 2022
Veranstaltung39th IAHR World Congress, 2022 - Granada, Spanien
Dauer: 19 Juni 202224 Juni 2022

Publikationsreihe

NameProceedings of the IAHR World Congress
ISSN (Print)2521-7119

Abstract

Climate change and sea-level rise have increased the scientific and societal interest in ecosystem services. Salt marshes, dunes and oyster reefs are prominent examples of ecosystems, where research groups systematically assess processes and aim to utilize system related characteristics, e.g. hydrodynamic resistance, for coastal protection measures. To investigate wave-current-vegetation interaction processes in salt marsh meadows under controlled conditions, biomechanical behavior of live vegetation needs to be replicated and scaled for laboratory experiments. Surrogate vegetation has been used before in a broad spectrum of investigations, while in regards to modeling biomechanical properties and transferring the results onto vegetated foreshores, shortcomings-like dynamical scaling-have been identified. Therefore, this study investigates the possibility of using resin 3D printing as a highly customizable option for salt marsh vegetation modeling. To compare the Young’s modulus of both, the resin model and live vegetation, three-point bending tests are performed. This approach to model salt marsh vegetation shows high potential to realistically model and represent salt marsh vegetation’s biomechanical characteristics, while further research needs to be conducted to fully comprehend the influencing parameters and optimal materials for each vegetation species, seasonality and scaling.

ASJC Scopus Sachgebiete

Ziele für nachhaltige Entwicklung

Zitieren

Biomechanical Replication of Salt Marsh Vegetation using Resin 3D Printing. / Keimer, Kara; Kosmalla, Viktoria; Lojek, Oliver et al.
Proceedings of the 40th IAHR World Congress. 2022. (Proceedings of the IAHR World Congress).

Publikation: Beitrag in Buch/Bericht/Sammelwerk/KonferenzbandAufsatz in KonferenzbandForschungPeer-Review

Keimer, K, Kosmalla, V, Lojek, O & Goseberg, N 2022, Biomechanical Replication of Salt Marsh Vegetation using Resin 3D Printing. in Proceedings of the 40th IAHR World Congress. Proceedings of the IAHR World Congress, 39th IAHR World Congress, 2022, Granada, Spanien, 19 Juni 2022. https://doi.org/10.3850/IAHR-39WC252171192022SS2087
Keimer, K., Kosmalla, V., Lojek, O., & Goseberg, N. (2022). Biomechanical Replication of Salt Marsh Vegetation using Resin 3D Printing. In Proceedings of the 40th IAHR World Congress (Proceedings of the IAHR World Congress). https://doi.org/10.3850/IAHR-39WC252171192022SS2087
Keimer K, Kosmalla V, Lojek O, Goseberg N. Biomechanical Replication of Salt Marsh Vegetation using Resin 3D Printing. in Proceedings of the 40th IAHR World Congress. 2022. (Proceedings of the IAHR World Congress). doi: 10.3850/IAHR-39WC252171192022SS2087
Keimer, Kara ; Kosmalla, Viktoria ; Lojek, Oliver et al. / Biomechanical Replication of Salt Marsh Vegetation using Resin 3D Printing. Proceedings of the 40th IAHR World Congress. 2022. (Proceedings of the IAHR World Congress).
Download
@inproceedings{f1138cc8535943c2b3722082a46bc80e,
title = "Biomechanical Replication of Salt Marsh Vegetation using Resin 3D Printing",
abstract = "Climate change and sea-level rise have increased the scientific and societal interest in ecosystem services. Salt marshes, dunes and oyster reefs are prominent examples of ecosystems, where research groups systematically assess processes and aim to utilize system related characteristics, e.g. hydrodynamic resistance, for coastal protection measures. To investigate wave-current-vegetation interaction processes in salt marsh meadows under controlled conditions, biomechanical behavior of live vegetation needs to be replicated and scaled for laboratory experiments. Surrogate vegetation has been used before in a broad spectrum of investigations, while in regards to modeling biomechanical properties and transferring the results onto vegetated foreshores, shortcomings-like dynamical scaling-have been identified. Therefore, this study investigates the possibility of using resin 3D printing as a highly customizable option for salt marsh vegetation modeling. To compare the Young{\textquoteright}s modulus of both, the resin model and live vegetation, three-point bending tests are performed. This approach to model salt marsh vegetation shows high potential to realistically model and represent salt marsh vegetation{\textquoteright}s biomechanical characteristics, while further research needs to be conducted to fully comprehend the influencing parameters and optimal materials for each vegetation species, seasonality and scaling.",
keywords = "Bending Behavior, Ecosystem Services, Physical Modeling, Resin 3D Printing, Salt Marsh",
author = "Kara Keimer and Viktoria Kosmalla and Oliver Lojek and Nils Goseberg",
year = "2022",
doi = "10.3850/IAHR-39WC252171192022SS2087",
language = "English",
isbn = "978-90-833476-1-5",
series = "Proceedings of the IAHR World Congress",
booktitle = "Proceedings of the 40th IAHR World Congress",
note = "39th IAHR World Congress, 2022 ; Conference date: 19-06-2022 Through 24-06-2022",

}

Download

TY - GEN

T1 - Biomechanical Replication of Salt Marsh Vegetation using Resin 3D Printing

AU - Keimer, Kara

AU - Kosmalla, Viktoria

AU - Lojek, Oliver

AU - Goseberg, Nils

PY - 2022

Y1 - 2022

N2 - Climate change and sea-level rise have increased the scientific and societal interest in ecosystem services. Salt marshes, dunes and oyster reefs are prominent examples of ecosystems, where research groups systematically assess processes and aim to utilize system related characteristics, e.g. hydrodynamic resistance, for coastal protection measures. To investigate wave-current-vegetation interaction processes in salt marsh meadows under controlled conditions, biomechanical behavior of live vegetation needs to be replicated and scaled for laboratory experiments. Surrogate vegetation has been used before in a broad spectrum of investigations, while in regards to modeling biomechanical properties and transferring the results onto vegetated foreshores, shortcomings-like dynamical scaling-have been identified. Therefore, this study investigates the possibility of using resin 3D printing as a highly customizable option for salt marsh vegetation modeling. To compare the Young’s modulus of both, the resin model and live vegetation, three-point bending tests are performed. This approach to model salt marsh vegetation shows high potential to realistically model and represent salt marsh vegetation’s biomechanical characteristics, while further research needs to be conducted to fully comprehend the influencing parameters and optimal materials for each vegetation species, seasonality and scaling.

AB - Climate change and sea-level rise have increased the scientific and societal interest in ecosystem services. Salt marshes, dunes and oyster reefs are prominent examples of ecosystems, where research groups systematically assess processes and aim to utilize system related characteristics, e.g. hydrodynamic resistance, for coastal protection measures. To investigate wave-current-vegetation interaction processes in salt marsh meadows under controlled conditions, biomechanical behavior of live vegetation needs to be replicated and scaled for laboratory experiments. Surrogate vegetation has been used before in a broad spectrum of investigations, while in regards to modeling biomechanical properties and transferring the results onto vegetated foreshores, shortcomings-like dynamical scaling-have been identified. Therefore, this study investigates the possibility of using resin 3D printing as a highly customizable option for salt marsh vegetation modeling. To compare the Young’s modulus of both, the resin model and live vegetation, three-point bending tests are performed. This approach to model salt marsh vegetation shows high potential to realistically model and represent salt marsh vegetation’s biomechanical characteristics, while further research needs to be conducted to fully comprehend the influencing parameters and optimal materials for each vegetation species, seasonality and scaling.

KW - Bending Behavior

KW - Ecosystem Services

KW - Physical Modeling

KW - Resin 3D Printing

KW - Salt Marsh

UR - http://www.scopus.com/inward/record.url?scp=85149655096&partnerID=8YFLogxK

U2 - 10.3850/IAHR-39WC252171192022SS2087

DO - 10.3850/IAHR-39WC252171192022SS2087

M3 - Conference contribution

AN - SCOPUS:85149655096

SN - 978-90-833476-1-5

T3 - Proceedings of the IAHR World Congress

BT - Proceedings of the 40th IAHR World Congress

T2 - 39th IAHR World Congress, 2022

Y2 - 19 June 2022 through 24 June 2022

ER -