Search results for "tensile stress"

showing 3 items of 3 documents

Insights Into the Inside - A Quantitative Histological Study of the Explosively Moving Style in Marantaceae.

2018

This study aims to identify the histological basis for the extraordinary, fast movement of the style in Marantaceae. Although this explosive pollination mechanism was subject of many studies, quantitative measurements to document volumetric changes have never been conducted. Based on physical parameters and limitations (poroelastic time), the movement itself is by far too fast to be explained by turgor changes solely. Therefore, we address the hypothesis that the style contains elastic structures to store energy allowing the fast movement. We provide an experimental approach in Goeppertia bachemiana to identify histological differences of styles in various states, i.e., steady, unreleased, …

Marantaceaeanatomytensile stressPlant Sciencemovementcell volume reconstructionturgorelastic energyOriginal ResearchFrontiers in plant science
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Insights Into the Inside – A Quantitative Histological Study of the Explosively Moving Style in Marantaceae

2018

This study aims to identify the histological basis for the extraordinary, fast movement of the style in Marantaceae. Although this explosive pollination mechanism was subject of many studies, quantitative measurements to document volumetric changes have never been conducted. Based on physical parameters and limitations (poroelastic time), the movement itself is by far too fast to be explained by turgor changes solely. Therefore, we address the hypothesis that the style contains elastic structures to store energy allowing the fast movement. We provide an experimental approach in Goeppertia bachemiana to identify histological differences of styles in various states, i.e., steady, unreleased, …

Marantaceaeanatomytensile stresslcsh:SB1-1110movementlcsh:Plant cultureturgorelastic energyFrontiers in Plant Science
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Simple metal under tensile stress: layer-dependent herringbone reconstruction of thin potassium films on graphite

2014

While understanding the properties of materials under stress is fundamentally important, designing experiments to probe the effects of large tensile stress is difficult. Here tensile stress is created in thin films of potassium (up to 4 atomic layers) by epitaxial growth on a rigid support, graphite. We find that this “simple” metal shows a long-range, periodic “herringbone” reconstruction, observed in 2- and 3- (but not 1- and 4-) layer films by low-temperature scanning tunneling microscopy (STM). Such a pattern has never been observed in a simple metal. Density functional theory (DFT) simulations indicate that the reconstruction consists of self-aligned stripes of enhanced atom density fo…

potassium filmstensile stressArticle
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