Intertwined Multiple Spiral Fracture in Perforated Sheets

Juan Francisco Fuentealba; Eugenio Hamm; Benoît Roman

doi:10.1103/PhysRevLett.116.165501

Intertwined Multiple Spiral Fracture in Perforated Sheets

Juan Francisco Fuentealba
, Eugenio Hamm
, Benoît Roman

Universidad de Santiago de Chile
Université Paris 6

Research output: Contribution to journal › Article › peer-review

12 Scopus citations

Abstract

We study multiple tearing of a thin, elastic, brittle sheet indented with a rigid cone. The n cracks initially prepared symmetrically propagate radially for n≥4. However, if n<4 the radial symmetry is broken and fractures spontaneously intertwine along logarithmic spiral paths, respecting order n rotational symmetry. In the limit of very thin sheets, we find that fracture mechanics is reduced to a geometrical model that correctly predicts the maximum number of spirals to be strictly 4, together with their growth rate and the perforation force. Similar spirals are also observed in a different tearing experiment (this time up to n=4, in agreement with the model), in which bending energy of the sheet is dominant.

Original language	English
Article number	165501
Journal	Physical Review Letters
Volume	116
Issue number	16
DOIs	https://doi.org/10.1103/PhysRevLett.116.165501
State	Published - 20 Apr 2016
Externally published	Yes

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10.1103/PhysRevLett.116.165501

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title = "Intertwined Multiple Spiral Fracture in Perforated Sheets",

abstract = "We study multiple tearing of a thin, elastic, brittle sheet indented with a rigid cone. The n cracks initially prepared symmetrically propagate radially for n≥4. However, if n<4 the radial symmetry is broken and fractures spontaneously intertwine along logarithmic spiral paths, respecting order n rotational symmetry. In the limit of very thin sheets, we find that fracture mechanics is reduced to a geometrical model that correctly predicts the maximum number of spirals to be strictly 4, together with their growth rate and the perforation force. Similar spirals are also observed in a different tearing experiment (this time up to n=4, in agreement with the model), in which bending energy of the sheet is dominant.",

author = "Fuentealba, \{Juan Francisco\} and Eugenio Hamm and Beno{\^i}t Roman",

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AU - Fuentealba, Juan Francisco

AU - Hamm, Eugenio

AU - Roman, Benoît

PY - 2016/4/20

Y1 - 2016/4/20

N2 - We study multiple tearing of a thin, elastic, brittle sheet indented with a rigid cone. The n cracks initially prepared symmetrically propagate radially for n≥4. However, if n<4 the radial symmetry is broken and fractures spontaneously intertwine along logarithmic spiral paths, respecting order n rotational symmetry. In the limit of very thin sheets, we find that fracture mechanics is reduced to a geometrical model that correctly predicts the maximum number of spirals to be strictly 4, together with their growth rate and the perforation force. Similar spirals are also observed in a different tearing experiment (this time up to n=4, in agreement with the model), in which bending energy of the sheet is dominant.

AB - We study multiple tearing of a thin, elastic, brittle sheet indented with a rigid cone. The n cracks initially prepared symmetrically propagate radially for n≥4. However, if n<4 the radial symmetry is broken and fractures spontaneously intertwine along logarithmic spiral paths, respecting order n rotational symmetry. In the limit of very thin sheets, we find that fracture mechanics is reduced to a geometrical model that correctly predicts the maximum number of spirals to be strictly 4, together with their growth rate and the perforation force. Similar spirals are also observed in a different tearing experiment (this time up to n=4, in agreement with the model), in which bending energy of the sheet is dominant.

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DO - 10.1103/PhysRevLett.116.165501

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JO - Physical Review Letters

JF - Physical Review Letters

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Intertwined Multiple Spiral Fracture in Perforated Sheets

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