Instability and reorientation of block copolymer microstructure by imposed electric fields

Orizaga, Saulo; Glasner, Karl

doi:10.1103/physreve.93.052504

Cited by 15 publications

(11 citation statements)

References 42 publications

(74 reference statements)

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“…In addition to the basic OK formulation, we allow phase properties also to differ, e.g., their permittivities and/or free energies. Letting Ω be a bounded domain, the extended Ohta-Kawasaki (EOK) functional [22] reads as…”

Section: Extended Ohtakawasaki Frameworkmentioning

confidence: 99%

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Spatially Localized Self-Assembly Driven by Electrically Charged Phase Separation

Gavish¹,

Versano²,

Yochelis³

2017

SIAM J. Appl. Dyn. Syst.

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Self-assembly driven by phase separation coupled to Coulombic interactions is fundamental to a wide range of applications, examples of which include soft matter lithography via di-block copolymers, membrane design using polyelectrolytes, and renewable energy applications based on complex nano-materials, such as ionic liquids. The most common mean field framework for these problems is the non-local Cahn-Hilliard (a.k.a. Ohta-Kawasaki) framework. In this work, we study the emergence of spatially localized states in both the classical and the extended Ohta-Kawasaki model. The latter also accounts for: (i) asymmetries in long-range Coulomb interactions that are manifested by differences in the dielectric response, and (ii) asymmetric short-range interactions that correspond to differences in the chemical potential between two materials phases. It is shown that in one space dimension (1D) there is a multiplicity of coexisting localized solutions, which organize in the homoclinic snaking structure, bearing similarity to dissipative systems. In addition, an analysis of 2D extension is performed and distinct instability mechanisms (related to extended and localized modes) of localized stripes are discussed with respect to model parameters and domain size. Finally, implications to localized hexagonal patterns are also made. The insights provide an efficient mechanistic framework to design and control localized self-assembly that might be a plausible strategy for low cost of nano electronic applications, i.e., a rather simple nano scale fabrication of isolated morphologies.

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Section: Extended Ohtakawasaki Frameworkmentioning

confidence: 99%

“…For simplicity, we assume a relatively weak difference in permittivity, i.e., linear order in u [22],…”

Section: Extended Ohtakawasaki Frameworkmentioning

confidence: 99%

Spatially Localized Self-Assembly Driven by Electrically Charged Phase Separation

Gavish¹,

Versano²,

Yochelis³

2017

SIAM J. Appl. Dyn. Syst.

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“…In the case of the Cahn‐Hilliard (or Van der Waals) approximation,

g = g_{h} (c) + \frac{1}{2} κ | \nabla c {false|}^{2}

, where g h ( c ) is the homogeneous free energy density and κ is the gradient penalty. This model has recently been used to describe phase separation in binary fluids, solids, and polymers driven by applied electric fields. In the case of LTO, an expression for the chemical part of the free energy has already been developed and parameterized in a recent phase‐field model for Li‐ion battery simulations, also including electrochemical intercalation reactions and polaron diffusion, but neglecting large electric fields within the active material, which become important in the new application to neuromorphic computing.…”

mentioning

confidence: 99%

“…In the case of the Cahn-Hilliard (or Van der Waals) approximation, g g c c h ( ) 1 2 | | 2 κ = + ∇ , where g h (c) is the homogeneous free energy density and κ is the gradient penalty. This model has recently been used to describe phase separation in binary fluids, [66] solids, [67,68] and polymers [69][70][71] driven by applied electric fields. In the case of LTO, Adv.…”

mentioning

confidence: 99%

Lithium‐Battery Anode Gains Additional Functionality for Neuromorphic Computing through Metal–Insulator Phase Separation

et al. 2020

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Specialized hardware for neural networks requires materials with tunable symmetry, retention, and speed at low power consumption. The study proposes lithium titanates, originally developed as Li‐ion battery anode materials, as promising candidates for memristive‐based neuromorphic computing hardware. By using ex‐ and in operando spectroscopy to monitor the lithium filling and emptying of structural positions during electrochemical measurements, the study also investigates the controlled formation of a metallic phase (Li7Ti5O12) percolating through an insulating medium (Li4Ti5O12) with no volume changes under voltage bias, thereby controlling the spatially averaged conductivity of the film device. A theoretical model to explain the observed hysteretic switching behavior based on electrochemical nonequilibrium thermodynamics is presented, in which the metal‐insulator transition results from electrically driven phase separation of Li4Ti5O12 and Li7Ti5O12. Ability of highly lithiated phase of Li7Ti5O12 for Deep Neural Network applications is reported, given the large retentions and symmetry, and opportunity for the low lithiated phase of Li4Ti5O12 toward Spiking Neural Network applications, due to the shorter retention and large resistance changes. The findings pave the way for lithium oxides to enable thin‐film memristive devices with adjustable symmetry and retention.

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“…In this Letter, we consider a computational model which originates from DFT for block copolymers [17] and has been extensively used to study morphological phases of diblock copolymers both analytically [15,16,[18][19][20][21][22][23][24] and numerically [13,[25][26][27]. Considerably less theoretical work exists for triblock copolymers.…”

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confidence: 99%

Bubble assemblies in ternary systems with long range interaction

Wang

Ren

Zhao

2019

Communications in Mathematical Sciences

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A nonlocal diffuse interface model is used to study bubble assemblies in ternary systems. As model parameters vary, a large number of morphological phases appear as stable stationary states. One open question related to the polarity direction of double bubble assemblies is answered numerically. Moreover, the average size of bubbles in a single bubble assembly depends on the sum of the minority constituent areas and the long range interaction coefficients. One identifies the ranges for area fractions and the long range interaction coefficients for double bubble assemblies. arXiv:1712.00724v1 [cond-mat.soft]

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Instability and reorientation of block copolymer microstructure by imposed electric fields

Cited by 15 publications

References 42 publications

Spatially Localized Self-Assembly Driven by Electrically Charged Phase Separation

Spatially Localized Self-Assembly Driven by Electrically Charged Phase Separation

Lithium‐Battery Anode Gains Additional Functionality for Neuromorphic Computing through Metal–Insulator Phase Separation

Bubble assemblies in ternary systems with long range interaction

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