Curvature-Induced Instabilities of Shells

Pezzulla, Matteo; Stoop, Norbert; Steranka, Mark; Bade, Abdikhalaq J.; Holmes, Douglas P.

doi:10.1103/physrevlett.120.048002

Cited by 62 publications

(106 citation statements)

References 35 publications

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“…2D). This field exerts active mechanical stress on the sheet by direct modification of the reference tensors described above, consistent with prior work on the active deformation of thin shells: 33,34,38 % aexp(2ac)% a, % b -Àbc% a,…”

Section: Modelsupporting

confidence: 82%

Gait-optimized locomotion of wave-driven soft sheets

Miller

Dunkel

2020

Soft Matter

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Section: Modelsupporting

confidence: 82%

Gait-optimized locomotion of wave-driven soft sheets

Miller

Dunkel

2020

Soft Matter

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“…This parameter may now be interpreted as the lateral size of the shell, L, compared to the width of the typical boundary layer that is induced by the competition between bending and stretching, (hR) 1/2 . If the shell is large compared to this boundary layer, we expect it should remain bistable, but if the boundary layer becomes too large then it will instead be monostable, similar to the threshold for bistability in spherical caps subjected to an evolving natural curvature [24].…”

Section: Shallow Shellsmentioning

confidence: 90%

“…More recently, structures that are able to switch between two different configurations have attracted interest for applications in which morphing between states is desirable, for example in mechanical metamaterials and origami structures [1,7,14] or in actuators [3]. Various mechanisms have been proposed by which the system may be forced between two stable states including loading via magnetic forces [18,29], fluid flow [2,12,31], changes in lateral confinement [13,11] or, more generally, variations in the natural curvature of a structure [23,24].…”

Section: Introductionmentioning

confidence: 99%

Static bistability of spherical caps

et al. 2018

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Depending on its geometry, a spherical shell may exist in one of two stable states without the application of any external force: there are two 'self-equilibrated' states, one natural and the other inside out (or 'everted'). Though this is familiar from everyday life-an umbrella is remarkably stable, yet a contact lens can be easily turned inside out-the precise shell geometries for which bistability is possible are not known. Here, we use experiments and finite-element simulations to determine the threshold between bistability and monostability for shells of different solid angle. We compare these results with the prediction from shallow shell theory, showing that, when appropriately modified, this offers a very good account of bistability even for relatively deep shells. We then investigate the robustness of this bistability against pointwise indentation. We find that indentation provides a continuous route for transition between the two states for shells whose geometry makes them close to the threshold. However, for thinner shells, indentation leads to asymmetrical buckling before snap-through, while also making these shells more 'robust' to snap-through. Our work sheds new light on the robustness of the 'mirror buckling' symmetry of spherical shell caps.

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“…Another crucial difference is the role of spontaneous curvature (or the conjugate integrated mean curvature or area difference) as control parameter. For red blood cells, area difference is an important control parameters of shape sequences [28][29][30] whereas spherical shells are treated with a fixed spontaneous curvature given by the spherical rest shape (only recently, Pezulla et al started to address the role of spontaneous curvature in buckling of spherical shells [64]). Viruses range in size from 15 to 500nm and have elastic moduli Y = Eh ∼ 0.1 − 1 N/m and bending moduli κ ∼ Eh 3 ∼ 5 × 10 −19 to 5 × 10 −15 Nm [65], similar to artificial microcapsules.…”

Section: Discussionmentioning

confidence: 99%

Shallow shell theory of the buckling energy barrier: From the Pogorelov state to softening and imperfection sensitivity close to the buckling pressure

Baumgarten

Kierfeld

2019

Phys. Rev. E

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We study the axisymmetric response of a complete spherical shell under homogeneous compressive pressure p to an additional point force. For a pressure p below the classical critical buckling pressure pc, indentation by a point force does not lead to spontaneous buckling but an energy barrier has to be overcome. The states at the maximum of the energy barrier represent a subcritical branch of unstable stationary points, which are the transition states to a snap-through buckled state. Starting from nonlinear shallow shell theory we obtain a closed analytical expression for the energy barrier height, which facilitates its effective numerical evaluation as a function of pressure by continuation techniques. We find a clear crossover between two regimes: For p/pc 1 the post-buckling barrier state is a mirror-inverted Pogorelov dimple, and for (1 − p/pc) 1 the barrier state is a shallow dimple with indentations smaller than shell thickness and exhibits extended oscillations, which are well described by linear response. We find systematic expansions of the nonlinear shallow shell equations about the Pogorelov mirror-inverted dimple for p/pc 1 and the linear response state for (1 − p/pc) 1, which enable us to derive asymptotic analytical results for the energy barrier landscape in both regimes. Upon approaching the buckling bifurcation at pc from below, we find a softening of an ideal spherical shell. The stiffness for the linear response to point forces vanishes ∝ (1 − p/pc) 1/2 ; the buckling energy barrier vanishes ∝ (1 − p/pc) 3/2 ; and the shell indentation in the barrier state vanishes ∝ (1 − p/pc) 1/2 . This makes shells sensitive to imperfections which can strongly reduce pc in an avoided buckling bifurcation. We find the same softening scaling in the vicinity of the reduced critical buckling pressure also in the presence of imperfections. We can also show that the effect of axisymmetric imperfections on the buckling instability is identical to the effect of a point force that is preindenting the shell. In the Pogorelov limit, the energy barrier maximum diverges ∝ (p/pc) −3 and the corresponding indentation diverges ∝ (p/pc) −2 . Numerical prefactors for proportionalities both in the softening and the Pogorelov regime are calculated analytically. This also enables us to obtain results for the critical unbuckling pressure and the Maxwell pressure.

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Curvature-Induced Instabilities of Shells

Cited by 62 publications

References 35 publications

Gait-optimized locomotion of wave-driven soft sheets

Gait-optimized locomotion of wave-driven soft sheets

Static bistability of spherical caps

Shallow shell theory of the buckling energy barrier: From the Pogorelov state to softening and imperfection sensitivity close to the buckling pressure

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