Origami in seed capsules

The lids on the seed cases of an ice plant unfold when a honeycomb structure swells on the inside of them

June 15, 2011

A number of plants disperse their seeds in a rather artistic way: the seed capsules of the ice plant Delosperma nakurense, for instance, unfold lids over the seed compartments in the manner of a movable origami when they are moistened by rain. This is the finding of researchers at the Max Planck Institute of Colloids and Interfaces in Potsdam and the Technische Universität Dresden in a precise investigation of the opening mechanism. The lids open up because cells on the inside of them absorb water and change their structure. The plant, which grows in very arid regions, thereby ensures that its seeds have a good chance of opening. The researchers are keen to use this model to develop materials that move when they become wet or when their temperature changes.

Swelling cellulose opens the seed capsule

When the lid opens, it deforms particularly where it is attached to the capsule. "This section acts like a hinge", explains Matthew Harrington. How the seal opens, however, only became apparent to the researchers when they looked very closely at the structure of the swellable tissue. This consists namely of upward-opening, more or less hexagonal cells that form a honeycomb structure.

The honeycomb structure that has become saturated with water and preferably expands in one direction. The researchers have stained the swellable cellulose blue. The lignin in the cell walls is stained red.

The opening mechanism only functions, however, because the cells are constructed of two different materials, as the researchers discovered in spectroscopic investigations. The cell walls consist essentially of cellulose and lignin, a major component of wood. Lignin absorbs little water, but inside the cell there is cellulose without lignin; this soaks up a lot of water and thus swells considerably. The machine is then complete, folding an origami virtually by water power. "When the cellulose expands, the hexagonal cells extend predominantly in the longitudinal direction of the lid", explains Matthew Harrington. The honeycomb structure expands in this direction and thus presses on the lid. Conversely, the valve closes again when the cellulose dries and the honeycomb structure contracts.

"The mechanism is interesting for technical applications because the energy for the directed movement is already stored in the material", says Peter Fratzl. As part of the focus program "Biomimetic Materials Research: Functionality by Hierarchical Structuring of Materials" funded by the DFG 1420, the scientists are now keen to transfer this concept to a technology that could be used for example in biomedicine or architecture. The principle can also be transferred to materials that expand or contract in very different ways when the temperature changes: for example, an awning unfolding by itself over the patio when the sun becomes uncomfortably hot.


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