However, there was a major difference between how vertical and horizontal eggs were distorted in pressure experiments – that is, the previous deformed less than the latter. The hardness of the largest crust along its long axis was an advantage because heavy load was distributed on the surface. (For this reason, the technique of egg adherence is targeted with one with the egg center horizontally.)
But the authors found that this feature, when it was under fixed pressure, was a defect when dropping eggs from the height, with the appearance of the horizontal position as the perfect direction. It comes to the difference between hardness – how much is a lot of strength to distort the egg – and hardness, that is, the amount of energy that eggs can absorb before its cracks.
Cohen and others have shown that the eggs are more stringent when loaded horizontally along their equator, and more solid when pressed vertically, indicating that “the eggs falling on the equator can maintain more drops without breaking.” “Even if the eggs may maintain a higher strength when loading it in the vertical direction, it does not necessarily mean that they are less likely to separate when dropping in this direction. Unlike fixed loading, to stay properly after a dynamic effect, the body should be able to absorb all its kinetic energy by transferring it to a reverse deformation.”
“The eggs should be difficult, not harsh, in order to survive,” Cohen et al. I concluded, pointing to our intuitive understanding that we must bend our knees instead of closing it in a stable position when landing after the jump, for example. “Our results and analyzes are a warning story about how the language affects our understanding of the system, and a problem of a problem of a problem can lead to misunderstanding and education.”
Doe: Communications Physics, 2025. 10.1038/S42005-025-02087-0 (About Dois).
