Your search keyword '"Melvin, Ambrose A."' showing total 2 results

1. Spatially Controlled CO 2 Conversion Kinetics in Natural Leaves for Motion Generation.

Author

Melvin AA, Goudeau B, Nogala W, and Kuhn A

Subjects

Light, Photosynthesis, Plant Leaves, Carbon Dioxide, Seeds

Abstract

Living systems that can spontaneously exhibit directional motion belong to diverse classes such as bacteria, sperm and plankton. They have fascinated scientists in recent years to design completely artificial or biohybrid mobile objects. Natural ingredients, like parts of plants, have been used to elaborate miniaturized dynamic objects, which can move when they are combined with other, non-natural, building blocks. Herein, we report that the precise structural tailoring of natural plant leaves allows generating a spatially predefined and confined release of oxygen gas, due to the conversion of carbon dioxide. This constitutes the driving force for generating motion, which is solely due to the respiration of leaves by photosynthesis. The rate of gas evolution can be fine-tuned by changing the light intensity and the leaf size, allowing ultimately to control the motility of objects with dimensions ranging from the millimeter to the micrometer scale., (© 2022 Wiley-VCH GmbH.)

Published

2022

2. Spatially Controlled CO2 Conversion Kinetics in Natural Leaves for Motion Generation.

Author

Melvin, Ambrose A., Goudeau, Bertrand, Nogala, Wojciech, and Kuhn, Alexander

Subjects

*LIGHT intensity, *CARBON dioxide, *LEAF physiology, *PHOTOSYNTHESIS, *SPERMATOZOA

Abstract

Living systems that can spontaneously exhibit directional motion belong to diverse classes such as bacteria, sperm and plankton. They have fascinated scientists in recent years to design completely artificial or biohybrid mobile objects. Natural ingredients, like parts of plants, have been used to elaborate miniaturized dynamic objects, which can move when they are combined with other, non‐natural, building blocks. Herein, we report that the precise structural tailoring of natural plant leaves allows generating a spatially predefined and confined release of oxygen gas, due to the conversion of carbon dioxide. This constitutes the driving force for generating motion, which is solely due to the respiration of leaves by photosynthesis. The rate of gas evolution can be fine‐tuned by changing the light intensity and the leaf size, allowing ultimately to control the motility of objects with dimensions ranging from the millimeter to the micrometer scale. [ABSTRACT FROM AUTHOR]

Published

2022