Self-assembly of rigid magnetic rods consisting of single dipolar beads in two dimensions

Domingos, Jorge Luiz Coelho; Peeters, F. M.; Ferreira, W. P.

doi:10.1103/physreve.96.012603

Cited by 12 publications

(13 citation statements)

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“…The interaction is given by the superposition of the dipolar fields of each dipole bead. Differently of our previous work [ 19 ], in this study the direction of the dipole moment is altered with respect to the rod axis, opening the possibility of a plethora of new kinds of assembled clusters. Many experiments involving assemblies of colloids are actually done at surfaces and/or thin films [ 20 – 25 ], which motivates us to explore two dimensional (2 D ) systems.…”

Section: Introductionmentioning

confidence: 88%

“…We present here a numerical study of the self-assembly of a two dimensional system of stiff peapod-like straight filaments, composed of single magnetic dipolar beads that are rigidly linked one by one. A similar system was studied earlier by experiment [ 17 ] and simulations [ 18 , 19 ]. The interaction is given by the superposition of the dipolar fields of each dipole bead.…”

Section: Introductionmentioning

confidence: 99%

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Self-assembly and clustering of magnetic peapod-like rods with tunable directional interaction

2018

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Based on extensive Langevin Dynamics simulations we investigate the structural properties of a two-dimensional ensemble of magnetic rods with a peapod-like morphology, i.e, rods consisting of aligned single dipolar beads. Self-assembled configurations are studied for different directions of the dipole with respect to the rod axis. We found that with increasing misalignment of the dipole from the rod axis, the smaller the packing fraction at which the percolation transition is found. For the same density, the system exhibits different aggregation states for different misalignment. We also study the stability of the percolated structures with respect to temperature, which is found to be affected by the microstructure of the assembly of rods.

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Section: Introductionmentioning

confidence: 88%

Section: Introductionmentioning

confidence: 99%

Self-assembly and clustering of magnetic peapod-like rods with tunable directional interaction

2018

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“…記録材料 (Verdes et al, 2006)の分野への応用に加え，近年では医用工学 (Häfeli et al, 1997)や環境資源工学 (Girginova et al, 2010)の分野への応用展開が活発になされるに至っている．医用工学や環境資源工学の分野では，目的に合わせた高次機能性磁性粒子の創製やその凝集構造や運動の制御法の構築が主な研究課題となっている．医用工学分野での応用に際しては，薬剤を包含した機能性粒子をガン・腫瘍部への誘導のための drug delivery システムの構築 (Shapiro, 2009) ，磁気モーメントの緩和現象に基づいた磁気温熱効果の制御法の構築 (Rosensweig, 2002, Obaidat et al, 2015)などがある．環境資源工学での応用に際しては，物質の吸着現象の解明と磁場勾配による回収技術の構築 (Konicki et al, 2017)などが必要となる．磁性粒子や非磁性粒子の高次機能化を計るには，物質の表面改質技術が必要となる．物質の表面改質に関する研究は非常に数多くなされているが，ここでは物理的な観点から，表面改質技術の磁性粒子への応用に関係する研究について簡単に言及する．磁性球状粒子を対象とした研究として，2 次元平面上での凝集形態や相転移現象の解明と印加磁場の影響を検討した研究 (Duncan and Camp, 2004, Dempster et al, 2015, Pham et al, 2017, Theis-Bröhl et al, 2015などがある．このような物質表面での磁性粒子の凝集構造・相転移・配向特性に関する研究は，球状粒子から，軸対称粒子の代表的な形状である棒状粒子 (Gil-Villegas et al, 1997, Domingos et al, 2017, Aoshima and Satoh, 2005や扁平粒子 (Satoh and Sakuda, 2010)に範囲を広げて，活発に遂行されてきている．さらに最近では，キューブ状磁性粒子を対象に，磁場の強さの変化に対する凝集構造の相転移の研究もされている (Satoh andOkada, 2017, Okada andSatoh, 2018) ．キューブ状ヘマタイト粒子の場合には，対角線に近い方向で磁化されていると考えられる (Rossi et al, 2011, Meijer et al, 2012) ．キューブ状磁性粒子の物質表面上の単層の凝集構造の研究により，ある条件下では面接触による凝集体を形成する傾向が非常に強いことがわかっている (Rossi et al, 2011, Meijer et al, 2012, Linse, 2015, Donaldson and Kantorovich, 2015, Satoh and Okada, 2017 ．上述の研究例でもわかるように，物質表面上での磁性粒子の凝集形態や内部構造を制御するためには，外部磁場を効果的に活用する方法が有効である．さらに一歩進めて，磁性粒子を帯電させ，電場と磁場により，より高度に物質表面上の磁性粒子の内部構造を制御しようとするアプローチも非常に可能性があるものと期待される．帯電した非磁性粒子の電極板表面への付着特性や層構造に関する研究は，これまで多くの研究者により非常に活発に研究がなされている．例えば，電気力により電極板表面に付着させ，所望の層構造を発生させようとする研究 (Oćwieja et al, 2017) ，帯電した棒状粒子の 2 次元系での凝集現象と相転移現象の研究 (Rutkowski et al, 2016) ，帯電した粒子の運動を電場により制御することで電極表面に付着させ，不純物質を取り除こうとする環境工学的な研究 (Choi et al, 2001)などが挙げられる．これらの現象解明もしくは技術構築を達成させるために，平板電極により発生した電場中における帯電粒子の動的な挙動の解明が精力的になされてきている (Watanabe et al, 2005…”

Section: 緒言磁性粒子を母液に懸濁して機能性を持たせた磁性サスペンションは，従来の流体工学(Wereley 2013)や磁気unclassified

3D Monte Carlo simulations on the control of the aggregate structures of cubic magnetic particles in terms of an external electric field

Satoh

Okada

Futamura

2018

Transactions of the JSME (In Japanese)

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We have addressed a suspension composed of magnetic cubic particles, which have a magnetic dipole moment at the particle center magnetized along the diagonal direction of the cube, in order to elucidate the physical phenomenon of the attachment characteristics and the aggregation structure of these particles, by means of Monte Carlo simulations. The cubic particles are negatively charged and confined between the two parallel walls one of which is positively charged (i.e., electrode) and the other is connected to the ground. The main results obtained here are summarized as follows. In the case of no external magnetic field, if the magnetic interaction is sufficiently strong for the formation of stable chain-like clusters, then longer chain-like clusters are formed between the two parallel walls and these clusters are more significantly located along the surface of the electrode as the electric interaction strength is increased. In the case of the electric particle-wall interaction being stronger than the magnetic interaction, almost all constituent cubic particles of chain-like clusters more significantly attach to the surface of the electrode in a face-to-face contact manner between the face of the cube and the wall. To the contrary, if the magnetic interaction is stronger than the electric interaction, the chain-like clusters are formed in the space of the two parallel walls from the end particle attached to the electrode wall. In the case of an external magnetic field applied along the surface of the electrode wall, the chain-like clusters are formed and extended from the surface to the space of the two parallel walls with the end of the particle of the clusters attached to the electrode wall.

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“…An obvious extension in the study of this kind of systems would be the consideration of the two-dimensional counterparts of paramagnetic filaments, that is, membranes consisting of two-dimensional arrays of paramag- * Electronic address: pablo.vazquez@correo.uady.mx † m-olvera@northwestern.edu netic beads linked by elastic polymers. However, such systems have not been synthesized yet and previous work on two-dimensional arrays of magnetic nanoparticles has been devoted to free magnetic colloids confined to a plane [16], or to arrays of magnetic filaments on a plane [17].…”

Section: Introductionmentioning

confidence: 99%

Flexible paramagnetic membranes in fast precessing fields

Vázquez-Montejo

Cruz

2018

Phys. Rev. E

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Elastic membranes composed of paramagnetic beads offer the possibility of assembling versatile actuators operated autonomously by external magnetic fields. Here we develop a theoretical framework to study shapes of such paramagnetic membranes under the influence of a fast precessing magnetic field. Their conformations are determined by the competition of the elastic and magnetic energies, arising as a result of their bending and the induced dipolar interactions between nearest neighbors beads. In the harmonic approximation, the elastic energy is quadratic in the surface curvatures. To account for the magnetic energy we introduce a continuum limit energy, quadratic in the projections of the surface tangents onto the precession axis. We derive the Euler-Lagrange equation governing the equilibria of these membranes, as well as the corresponding stresses. We apply this framework to examine paramagnetic membranes with quasiplanar, cylindrical, and helicoidal geometries. In all cases we found that their shape, energy, and stresses can be modified by means of the parameters of the magnetic field, mainly by the angle of precession.

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Self-assembly of rigid magnetic rods consisting of single dipolar beads in two dimensions

Cited by 12 publications

References 69 publications

Self-assembly and clustering of magnetic peapod-like rods with tunable directional interaction

Self-assembly and clustering of magnetic peapod-like rods with tunable directional interaction

3D Monte Carlo simulations on the control of the aggregate structures of cubic magnetic particles in terms of an external electric field

Flexible paramagnetic membranes in fast precessing fields

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