Journal article 265 views 21 downloads
Structural performance of a climbing cactus: making the most of softness
Anil Bastola 
,
Patricia Soffiatti ,
Marc Behl ,
Andreas Lendlein ,
Nick P. Rowe
,
Patricia Soffiatti ,
Marc Behl ,
Andreas Lendlein ,
Nick P. Rowe
Journal of The Royal Society Interface, Volume: 18, Issue: 178
Swansea University Author:
Anil Bastola
-
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DOI (Published version): 10.1098/rsif.2021.0040
Abstract
Climbing plants must reach supports and navigate gaps to colonize trees. This requires a structural organization ensuring the rigidity of so-called ‘searcher’ stems. Cacti have succulent stems adapted for water storage in dry habitats. We investigate how a climbing cactus Selenicereus setaceus devel...
| Published in: | Journal of The Royal Society Interface |
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| ISSN: | 1742-5662 |
| Published: |
The Royal Society
2021
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| URI: | https://cronfa.swan.ac.uk/Record/cronfa65766 |
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2024-04-27T08:50:20Z |
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2024-11-25T14:16:48Z |
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2024-04-27T09:52:03.7558803 v2 65766 2024-03-05 Structural performance of a climbing cactus: making the most of softness 6775d40c935b36b92058eb10d6454f1a 0000-0002-5598-0849 Anil Bastola Anil Bastola true false 2024-03-05 ACEM Climbing plants must reach supports and navigate gaps to colonize trees. This requires a structural organization ensuring the rigidity of so-called ‘searcher’ stems. Cacti have succulent stems adapted for water storage in dry habitats. We investigate how a climbing cactus Selenicereus setaceus develops its stem structure and succulent tissues for climbing. We applied a ‘wide scale’ approach combining field-based bending, tensile and swellability tests with fine-scale rheological, compression and anatomical analyses in laboratory conditions. Gap-spanning ‘searcher’ stems rely significantly on the soft cortex and outer skin of the stem for rigidity in bending (60–94%). A woody core contributes significantly to axial and radial compressive strength (80%). Rheological tests indicated that storage moduli were consistently higher than loss moduli indicating that the mucilaginous cortical tissue behaved like a viscoelastic solid with properties similar to physical or chemical hydrogels. Rheological and compression properties of the soft tissue changed from young to old stages. The hydrogel–skin composite is a multi-functional structure contributing to rigidity in searcher stems but also imparting compliance and benign failure in environmental situations when stems must fail. Soft tissue composites changing in function via changes in development and turgescence have a great potential for exploring candidate materials for technical applications. Journal Article Journal of The Royal Society Interface 18 178 The Royal Society 1742-5662 climbing cactus, succulence, biomechanics, rheology, skin–hydrogel–core structure 12 5 2021 2021-05-12 10.1098/rsif.2021.0040 COLLEGE NANME Aerospace, Civil, Electrical, and Mechanical Engineering COLLEGE CODE ACEM Swansea University Another institution paid the OA fee This project has received funding from the European Union’s Horizon 2020 research and innovation programme under grant agreement no. 824074 (GrowBot). M.B. and A.L. were financially supported by the Helmholtz Association through programme-oriented funding. 2024-04-27T09:52:03.7558803 2024-03-05T22:10:16.7642125 Faculty of Science and Engineering School of Aerospace, Civil, Electrical, General and Mechanical Engineering - Mechanical Engineering Anil Bastola 0000-0002-5598-0849 1 Patricia Soffiatti 0000-0001-5634-7650 2 Marc Behl 0000-0002-1507-0277 3 Andreas Lendlein 0000-0003-4126-4670 4 Nick P. Rowe 0000-0002-7849-7227 5 65766__30166__55a354a778054ffab53bf78ad69e0321.pdf 65766.VoR.pdf 2024-04-27T09:50:57.3243788 Output 2580209 application/pdf Version of Record true © 2021 The Authors. Published by the Royal Society under the terms of the Creative Commons Attribution License. true eng http://creativecommons.org/licenses/by/4.0/ |
| title |
Structural performance of a climbing cactus: making the most of softness |
| spellingShingle |
Structural performance of a climbing cactus: making the most of softness Anil Bastola |
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Structural performance of a climbing cactus: making the most of softness |
| title_full |
Structural performance of a climbing cactus: making the most of softness |
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Structural performance of a climbing cactus: making the most of softness |
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Structural performance of a climbing cactus: making the most of softness |
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Structural performance of a climbing cactus: making the most of softness |
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6775d40c935b36b92058eb10d6454f1a_***_Anil Bastola |
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Anil Bastola |
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Anil Bastola Patricia Soffiatti Marc Behl Andreas Lendlein Nick P. Rowe |
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Journal of The Royal Society Interface |
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| description |
Climbing plants must reach supports and navigate gaps to colonize trees. This requires a structural organization ensuring the rigidity of so-called ‘searcher’ stems. Cacti have succulent stems adapted for water storage in dry habitats. We investigate how a climbing cactus Selenicereus setaceus develops its stem structure and succulent tissues for climbing. We applied a ‘wide scale’ approach combining field-based bending, tensile and swellability tests with fine-scale rheological, compression and anatomical analyses in laboratory conditions. Gap-spanning ‘searcher’ stems rely significantly on the soft cortex and outer skin of the stem for rigidity in bending (60–94%). A woody core contributes significantly to axial and radial compressive strength (80%). Rheological tests indicated that storage moduli were consistently higher than loss moduli indicating that the mucilaginous cortical tissue behaved like a viscoelastic solid with properties similar to physical or chemical hydrogels. Rheological and compression properties of the soft tissue changed from young to old stages. The hydrogel–skin composite is a multi-functional structure contributing to rigidity in searcher stems but also imparting compliance and benign failure in environmental situations when stems must fail. Soft tissue composites changing in function via changes in development and turgescence have a great potential for exploring candidate materials for technical applications. |
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2021-05-12T14:37:54Z |
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11.048237 |