Phase transitions of a tethered membrane model with intrinsic curvature on spherical surfaces with point boundaries

Koibuchi, Hiroshi

doi:10.1088/1742-5468/2006/05/p05008

Cited by 2 publications

(5 citation statements)

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“…It is also expected that the smooth phase is separated from a non-smooth phase by the first-order transition, where the surface is almost linear and is very similar to the branched polymer surface [47]. We also confirmed in [43] that the order of the transition changes from first-order to second-order on tethered surfaces as the distance L(N) increases. Therefore, we aimed in this paper to see how the transition changes depending on L(N) on dynamically triangulated fluid surfaces, where the surfaces are expected to be oblong at sufficiently large L(N).…”

Section: Discussionsupporting

confidence: 74%

“…Another intrinsic curvature model undergoes a first-order transition, which is independent of the surface topology [40,41,42]. It was also reported that the order of transition changes from first to second as L increases from L = L 0 to L = 2L 0 , where L 0 is the radius of the original sphere constructed to satisfy the relation S 1 /N = 1.5 [43]. However, the string tension was unable to be extracted from the simulations on the tethered surfaces, because the surfaces do not always become string-like even when L is relatively large compared to L 0 .…”

Section: Introductionmentioning

confidence: 99%

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Phase transitions of an intrinsic curvature model on dynamically triangulated spherical surfaces with point boundaries

et al. 2006

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An intrinsic curvature model is investigated using the canonical Monte Carlo simulations on dynamically triangulated spherical surfaces of size upto N = 4842 with two fixed-vertices separated by the distance 2L. We found a first-order transition at finite curvature coefficient α, and moreover that the order of the transition remains unchanged even when L is enlarged such that the surfaces become sufficiently oblong. This is in sharp contrast to the known results of the same model on tethered surfaces, where the transition weakens to a second-order one as L is increased. The phase transition of the model in this paper separates the smooth phase from the crumpled phase. The surfaces become string-like between two point-boundaries in the crumpled phase. On the contrary, we can see a spherical lump on the oblong surfaces in the smooth phase. The string tension was calculated and was found to have a jump at the transition point. The value of σ is independent of L in the smooth phase, while it increases with increasing L in the crumpled phase. This behavior of σ is consistent with the observed scaling relation σ ∼ (2L/N ) ν , where ν ≃ 0 in the smooth phase, and ν = 0.93 ± 0.14 in the crumpled phase. We should note that a possibility of a continuous transition is not completely eliminated.

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Section: Discussionsupporting

confidence: 74%

Section: Introductionmentioning

confidence: 99%

Phase transitions of an intrinsic curvature model on dynamically triangulated spherical surfaces with point boundaries

et al. 2006

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“…The model is defined by a Hamiltonian that is a linear combination of the Gaussian bond potential S 1 and the intrinsic curvature energy S 2 . The model is known to have first-order transitions on the surfaces without boundaries and on those with point boundaries [18,31]. However, it is non-trivial to establish whether the model undergoes a phase transition with the one-dimensional boundaries.…”

Section: Discussionmentioning

confidence: 99%

“…This model leads us to calculate the macroscopic string tension σ of the surface by equating exp(−σL) ∼ Z at sufficiently large L, where Z is the partition function of the surface model [27,28]. The expected scaling relation of σ with respect to N is observed, where N is the total number of vertices of the triangulated surface [29,30,31,32].…”

Section: Introductionmentioning

confidence: 98%

“…The area πRL of the tube can also be used for the calculation of τ ; however, we use the projected area L 2 for simplicity. We should emphasize that it is non-trivial to establish whether the model undergoes a phase transition because the surface is fixed by one-dimensional boundaries, which include many vertices, and the size of the boundaries increases with the system size, and therefore, the phase structure of the model without boundaries [18] or with point boundaries [31] is expected to be influenced by the one-dimensional boundaries. The purpose of the study is to see whether or not the model undergoes phase transitions, and moreover, to see how the transition is reflected in the surface tension if the transition occurs in the model.…”

Section: Introductionmentioning

confidence: 99%

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Surface tension in an intrinsic curvature model with fixed one-dimensional boundaries

Koibuchi

2008

J. Stat. Mech.

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A triangulated fixed connectivity surface model is investigated by using the Monte Carlo simulation technique. In order to have the macroscopic surface tension τ , the vertices on the one-dimensional boundaries are fixed as the edges (=circles) of the tubular surface in the simulations. The size of the tubular surface is chosen such that the projected area becomes the regular square of area A. An intrinsic curvature energy with a microscopic bending rigidity b is included in the Hamiltonian. We found that the model undergoes a first-order transition of surface fluctuations at finite b, where the surface tension τ discontinuously changes. The gap of τ remains constant at the transition point in a certain range of values A/N ′ at sufficiently large N ′ , which is the total number of vertices excluding the fixed vertices on the boundaries. The value of τ remains almost zero in the wrinkled phase at the transition point while τ remains negative finite in the smooth phase in that range of A/N ′ .

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Phase transitions of a tethered membrane model with intrinsic curvature on spherical surfaces with point boundaries

Cited by 2 publications

References 53 publications

Phase transitions of an intrinsic curvature model on dynamically triangulated spherical surfaces with point boundaries

Phase transitions of an intrinsic curvature model on dynamically triangulated spherical surfaces with point boundaries

Surface tension in an intrinsic curvature model with fixed one-dimensional boundaries

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