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Â鶹ÒùÔºicists uncover how geometric frustration shapes the rose's iconic blossom

Four physicists at the Hebrew University of Jerusalem, in Israel, have unraveled the mechanical process behind the growth of roses as they blossom into their unique shape. In their study in the journal Science, Yafei Zhang, Omri Cohen, Michael Moshe and Eran Sharon adopted a multipronged approach to learn the secrets behind rose blossom growth. Qinghao Cui and Lishuai Jin, with the University of Hong Kong have published a piece in the same journal issue outlining the work.

Roses have been prized for their beauty and sweet aromas for thousands of years, but until now, the mechanics behind rose growth have not been explored. To gain a better understanding of the process, the research team undertook a three-pronged approach. First, they conducted a theoretical analysis of the process. Then they created computer models to simulate the ways the flowers might grow and bloom; finally, they created real-world bendable plastic disks to simulate petals and the possible ways they could grow given the constraints of real roses.

They found that the shape of the petals is strongly influenced by the frustration known as the Mainardi-Codazzi-Peterson incompatibility, in which geometric compatibility conditions inherent on a surface made of a particular material are violated, leading to forces that generate rolling and sharp edges.

The researchers describe it as the petals "wanting" to have a given shape in which they would simply curve slightly as they grew, forming a dish-like shape. However, due to the Mainardi-Codazzi-Peterson incompatibility, they are unable to form their natural curl, so in response, they form multiple curls separated by sharp cusps. As the flower continues to grow and more petals emerge, the stresses increase, resulting in more striking features.

The research team notes that roses are unique among flowers, which are typically influenced by the Gauss incompatibility, where stresses lead to wavy patterns, less defined edges, and a lack of sharp cusps. They suggest their work could aid in developing shape-morphing materials.