Pavlo Kurioz scite author profile

The impact of intrinsic and extrinsic curvature on the distribution of topological defects (TDs) in neck‐like regions of biological membranes is studied quantitatively. Biological membranes are modeled effectively at the mesoscopic level as two‐dimensional films described in terms of the tensor nematic order parameter field and curvature fields. It is demonstrated that antidefects robustly form at the neck area and can promote a membrane fission. The assembling of antidefects near the catenoid's equatorial ring, where catenoids roughly mimic neck shapes are analyzed in more detail. It is demonstrated that for sufficiently strong curvatures, the effective topological charge Δmeff within a strongly curved region equals zero, and the resulting structures are topologically neutral. Consequently, the total charge of antidefects within the region equals Δm = −ΔmV − ΔmK. In most cases, the positions of antidefects are strongly influenced by the extrinsic curvature.

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Curvature-Controlled Topological Defects

Mesarec

Kurioz

Iglič

et al. 2017

Crystals

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Effectively, two-dimensional (2D) closed films exhibiting in-plane orientational ordering (ordered shells) might be instrumental for the realization of scaled crystals. In them, ordered shells are expected to play the role of atoms. Furthermore, topological defects (TDs) within them would determine their valence. Namely, bonding among shells within an isotropic liquid matrix could be established via appropriate nano-binders (i.e., linkers) which tend to be attached to the cores of TDs exploiting the defect core replacement mechanism. Consequently, by varying configurations of TDs one could nucleate growth of scaled crystals displaying different symmetries. For this purpose, it is of interest to develop a simple and robust mechanism via which one could control the position and number of TDs in such atoms. In this paper, we use a minimal mesoscopic model, where variational parameters are the 2D curvature tensor and the 2D orientational tensor order parameter. We demonstrate numerically the efficiency of the effective topological defect cancellation mechanism to predict positional assembling of TDs in ordered films characterized by spatially nonhomogeneous Gaussian curvature. Furthermore, we show how one could efficiently switch among qualitatively different structures by using a relative volume v of ordered shells, which represents a relatively simple naturally accessible control parameter.

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Nematic topological defects positionally controlled by geometry and external fields

Kurioz¹,

Kralj²,

Murray³

et al. 2018

Beilstein J. Nanotechnol.

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Using a Landau-de Gennes approach, we study the impact of confinement topology, geometry and external fields on the spatial positioning of nematic topological defects (TDs). In quasi two-dimensional systems we demonstrate that a confinement-enforced total topological charge of m > 1/2 decays into elementary TDs bearing a charge of m = 1/2. These assemble close to the bounding substrate to enable essentially bulk-like uniform nematic ordering in the central part of a system. This effect is reminiscent of the Faraday cavity phenomenon in electrostatics. We observe that in certain confinement geometries, varying the correlation length size of the order parameter could trigger a global rotation of an assembly of TDs. Finally, we show that an external electric field could be used to drag the boojum fingertip towards the interior of the confinement cell. Assemblies of TDs could be exploited as traps for appropriate nanoparticles, opening several opportunities for the development of functional nanodevices.109

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Topological defect enabled formation of nematic domains

et al. 2019

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Annihilation of Highly-Charged Topological Defects

et al. 2020

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We studied numerically external stimuli enforced annihilation of a pair of daughter nematic topological defect (TD) assemblies bearing a relatively strong topological charge |m|=3/2. A Landau- de Gennes phenomenological approach in terms of tensor nematic order parameter was used in an effectively two-dimensional Cartesian coordinate system, where spatial variations along the z-axis were neglected. A pair of {m=3/2,m=−3/2} was enforced by an appropriate surface anchoring field, mimicking an experimental sample realization using the atomic force microscope (AFM) scribing method. Furthermore, defects were confined within a rectangular boundary that imposes strong tangential anchoring. This setup enabled complex and counter-intuitive annihilation processes on varying relevant parameters. We present two qualitatively different annihilation paths, where we either gradually reduced the relative surface anchoring field importance or increased an external in-plane spatially homogeneous electric field E. The creation and depinning of additional defect pairs {12,−12} mediated the annihilation in such a geometry. Furthermore, we illustrate the absorption of TDs by sharp edges of the confining boundary, accompanied by m=±1/4↔∓1/4 winding reversal of edge singularities, and also E-driven zero-dimensional to one-dimensional defect core transformation.

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Pavlo Kurioz

Assembling of Topological Defects at Neck‐Shaped Membrane Parts

Curvature-Controlled Topological Defects

Nematic topological defects positionally controlled by geometry and external fields

Topological defect enabled formation of nematic domains

Annihilation of Highly-Charged Topological Defects

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