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328 results on '"Hirst, Linda S."'

1. Surfing, sweeping, and assembly of particles by a moving liquid crystal phase boundary

Author

Shneer, Tom, Ochoa, Jocelyn, Wheeler, Alauna C., Reyes, Isabella C., Joshi, Chaitanya, Stokes, Benjamin J., Hirst, Linda S., and Atherton, Timothy J.

Subjects
Condensed Matter - Soft Condensed Matter, Condensed Matter - Statistical Mechanics
Abstract

Non-equilibrium transport of particles embedded in a liquid crystal host can, by cooling through a phase transition, be exploited to create a remarkable variety of structures including shells, foams, and gels. Due to the complexity of the multicomponent system and protocol-dependent experimental results, the physical mechanisms behind structure selection remain only partially understood. Here we formulate a new model coupling LC physics to a Fokker-Planck equation as is commonly used in studies of transport. The resulting model allows us to draw an analogy between the LC-nanocomposite system and chemotaxis, enriching the space of possible target structures that could be produced. We study the model in one dimension both analytically and numerically to identify different parameter regimes where soliton-like pulses of particles ``surf'' the phase boundary or where the interface ``sweeps'' particles from one domain to another. We also consider an extended model that includes agglomeration of the particles and observe formation of periodic structures as a prototypical example of hierarchical self assembly. Results are compared with experimental observations of transport by isolated phase boundaries., Comment: 11 pages, 6 figures

Published
2023

2. Fractal generation in a two-dimensional active-nematic fluid

Author

Mitchell, Kevin A., Tan, Amanda J., Arteaga, Jorge, and Hirst, Linda S.

Subjects
Condensed Matter - Soft Condensed Matter, Nonlinear Sciences - Chaotic Dynamics
Abstract

Active fluids, composed of individual self-propelled agents, can generate complex large-scale coherent flows. A particularly important laboratory realization of such an active fluid is a system composed of microtubules, aligned in a quasi-two-dimensional (2D) nematic phase, and driven by ATP-fueled kinesin motor proteins. This system exhibits robust chaotic advection and gives rise to a pronounced fractal structure in the nematic contours. We characterize such experimentally derived fractals using the power spectrum and discover that the power spectrum decays as $k^{-\beta}$ for large wavenumbers $k$. The parameter $\beta$ is measured for several experimental realizations. Though $\beta$ is effectively constant in time, it does vary with experimental parameters, indicating differences in the scale-free behavior of the microtubule-based active nematic. Though the fractal patterns generated in this active system are reminiscent of passively advected dye in 2D chaotic flows, the underlying mechanism for fractal generation is more subtle. We provide a simple, physically inspired mathematical model of fractal generation in this system that relies on the material being locally compressible, though the total area of the material is conserved globally. The model also requires that large-scale density variations be injected into the material periodically. The model reproduces the power spectrum decay $k^{-\beta}$ seen in experiments. Linearizing the model of fractal generation about the equilibrium density, we derive an analytic relationship between $\beta$ and a single dimensionless quantity $r$, which characterizes the compressibility.

Published
2021
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3. Submersed Micropatterned Structures Control Active Nematic Flow, Topology and Concentration

Author

Thijssen, Kristian, Khaladj, Dimitrius, Aghvami, S. Ali, Gharbi, Mohamed Amine, Fraden, Seth, Yeomans, Julia M., Hirst, Linda S., and Shendruk, Tyler N.

Subjects
Condensed Matter - Soft Condensed Matter, Physics - Biological Physics
Abstract

Coupling between flows and material properties imbues rheological matter with its wide-ranging applicability, hence the excitement for harnessing the rheology of active fluids for which internal structure and continuous energy injection lead to spontaneous flows and complex, out-of-equilibrium dynamics. We propose and demonstrate a convenient, highly tuneable method for controlling flow, topology and composition within active films. Our approach establishes rheological coupling via the indirect presence of fully submersed micropatterned structures within a thin, underlying oil layer. Simulations reveal that micropatterned structures produce effective virtual boundaries within the superjacent active nematic film due to differences in viscous dissipation as a function of depth. This accessible method of applying position-dependent, effective dissipation to the active films presents a non-intrusive pathway for engineering active microfluidic systems., Comment: 16 pages; 5 main-text-figures; 5-supplemental-figures

Published
2021
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4. Using Curved Fluid Boundaries to Confine Active Nematic Flows

Author

Khaladj, Dimitrius A and Hirst, Linda S

Subjects
Physical Sciences, active nematic, biopolymer, liquid crystal, fluorescence microscopy, topological defects, Mathematical sciences, Physical sciences
Abstract

Actively driven, bundled microtubule networks, powered by molecular motors have become a useful framework in which to study the dynamics of energy-driven defects, but achieving control of defect motions is still a challenging problem. In this paper, we present a method to confine active nematic fluid using wetting to curve a layer of oil over circular pillars. This geometry, in which submersed pillars impinge on an oil-water interface, creates a two-tier continuous active layer in which the material is confined above, and surrounds the pillars. Active flows above the pillars are influenced by the circular geometry and exhibit dynamics similar to those observed for active material confined by hard boundaries, e.g., inside circular wells. The thin oil layer beneath the active material is even thinner in the region above the pillars than outside their boundary, consequently producing an area of higher effective friction. Within the pillar region, active length scales and velocities are decreased, while defect densities increase relative to outside the pillar boundary. This new way to confine active flows opens further opportunities to control and organize topological defects and study their behavior in active systems.

Published
2022

5. Active nematic order and dynamic lane formation of microtubules driven by membrane-bound diffusing motors

Author

Memarian, Fereshteh L, Lopes, Joseph D, Schwarzendahl, Fabian Jan, Athani, Madhuvanthi Guruprasad, Sarpangala, Niranjan, Gopinathan, Ajay, Beller, Daniel A, Dasbiswas, Kinjal, and Hirst, Linda S

Subjects
Biochemistry and Cell Biology, Engineering, Biological Sciences, Bioengineering, 1.1 Normal biological development and functioning, Animals, Biomechanical Phenomena, Diffusion, Kinesins, Kinetics, Lipid Bilayers, Microscopy, Fluorescence, Microtubules, Swine, Tubulin, active matter, liquid crystal, active nematic, biopolymers
Abstract

Dynamic lane formation and long-range active nematic alignment are reported using a geometry in which kinesin motors are directly coupled to a lipid bilayer, allowing for in-plane motor diffusion during microtubule gliding. We use fluorescence microscopy to image protein distributions in and below the dense two-dimensional microtubule layer, revealing evidence of diffusion-enabled kinesin restructuring within the fluid membrane substrate as microtubules collectively glide above. We find that the lipid membrane acts to promote filament-filament alignment within the gliding layer, enhancing the formation of a globally aligned active nematic state. We also report the emergence of an intermediate, locally ordered state in which apolar dynamic lanes of nematically aligned microtubules migrate across the substrate. To understand this emergent behavior, we implement a continuum model obtained from coarse graining a collection of self-propelled rods, with propulsion set by the local motor kinetics. Tuning the microtubule and kinesin concentrations as well as active propulsion in these simulations reveals that increasing motor activity promotes dynamic nematic lane formation. Simulations and experiments show that, following fluid bilayer substrate mediated spatial motor restructuring, the total motor concentration becomes enriched below the microtubule lanes that they drive, with the feedback leading to more dynamic lanes. Our results have implications for membrane-coupled active nematics in vivo as well as for engineering dynamic and reconfigurable materials where the structural elements and power sources can dynamically colocalize, enabling efficient mechanical work.

Published
2021

6. Directional, Low-Energy Driven Thermal Actuating Bilayer Enabled by Coordinated Submolecular Switching.

Author

Leveille, Michael, Shen, Xinyuan, Fu, Wenxin, Jin, Ke, Acerce, Muharrem, Wang, Changchun, Bustamante, Jacqueline, Casas, Anneka Miller, Feng, Yuan, Ge, Nien-Hui, Hirst, Linda S, Ghosh, Sayantani, and Lu, Jennifer Qing

Subjects
conformational change, dibenzocycloocta-1, 5-diene, negative thermal expansion, thermal actuator, thermal energy harvesting, dibenzocycloocta-1, 5-diene, Bioengineering, Affordable and Clean Energy
Abstract

The authors reveal a thermal actuating bilayer that undergoes reversible deformation in response to low-energy thermal stimuli, for example, a few degrees of temperature increase. It is made of an aligned carbon nanotube (CNT) sheet covalently connected to a polymer layer in which dibenzocycloocta-1,5-diene (DBCOD) actuating units are oriented parallel to CNTs. Upon exposure to low-energy thermal stimulation, coordinated submolecular-level conformational changes of DBCODs result in macroscopic thermal contraction. This unique thermal contraction offers distinct advantages. It's inherently fast, repeatable, low-energy driven, and medium independent. The covalent interface and reversible nature of the conformational change bestow this bilayer with excellent repeatability, up to at least 70 000 cycles. Unlike conventional CNT bilayer systems, this system can achieve high precision actuation readily and can be scaled down to nanoscale. A new platform made of poly(vinylidene fluoride) (PVDF) in tandem with the bilayer can harvest low-grade thermal energy and convert it into electricity. The platform produces 86 times greater energy than PVDF alone upon exposure to 6 °C thermal fluctuations above room temperature. This platform provides a pathway to low-grade thermal energy harvesting. It also enables low-energy driven thermal artificial robotics, ultrasensitive thermal sensors, and remote controlled near infrared (NIR) driven actuators.

Published
2021

7. Colloidal structure and proton conductivity of the gel within the electrosensory organs of cartilaginous fishes.

Author

Phillips, Molly, Wheeler, Alauna C, Robinson, Matthew J, Leppert, Valerie, Jia, Manping, Rolandi, Marco, Hirst, Linda S, and Amemiya, Chris T

Subjects
Biological sciences, Colloids, Materials science, Neuroanatomy, Neuroscience, Sensory neuroscience, Zoology, 1.1 Normal biological development and functioning, Generic health relevance
Abstract

Cartilaginous fishes possess gel-filled tubular sensory organs called Ampullae of Lorenzini (AoL) that are used to detect electric fields. Although recent studies have identified various components of AoL gel, it has remained unclear how the molecules are structurally arranged and how their structure influences the function of the organs. Here we describe the structure of AoL gel by microscopy and small-angle X-ray scattering and infer that the material is colloidal in nature. To assess the relative function of the gel's protein constituents, we compared the microscopic structure, X-ray scattering, and proton conductivity properties of the gel before and after enzymatic digestion with a protease. We discovered that while proteins were largely responsible for conferring the viscous nature of the gel, their removal did not diminish proton conductivity. The findings lay the groundwork for more detailed studies into the specific interactions of molecules inside AoL gel at the nanoscale.

Published
2021

8. Directed assembly of magnetic and semiconducting nanoparticles with tunable and synergistic functionality.

Author

Bartolo, Mark, Amaral, Jussi J, Hirst, Linda S, and Ghosh, Sayantani

Subjects
Bioengineering, Nanotechnology, Biochemistry and Cell Biology, Other Physical Sciences
Abstract

The ability to fabricate new materials using nanomaterials as building blocks, and with meta functionalities, is one of the most intriguing possibilities in the area of materials design and synthesis. Semiconducting quantum dots (QDs) and magnetic nanoparticles (MNPs) are co-dispersed in a liquid crystalline (LC) matrix and directed to form self-similar assemblies by leveraging the host's thermotropic phase transition. These co-assemblies, comprising 6 nm CdSe/ZnS QDs and 5-20 nm Fe3O4 MNPs, bridge nano- to micron length scales, and can be modulated in situ by applied magnetic fields

Published
2019

9. Topological chaos in active nematics

Author

Tan, Amanda J, Roberts, Eric, Smith, Spencer A, Olvera, Ulyses Alvarado, Arteaga, Jorge, Fortini, Sam, Mitchell, Kevin A, and Hirst, Linda S

Subjects
Mathematical Sciences, Physical Sciences, Fluids & Plasmas
Published
2019

10. Membrane mediated motor kinetics in microtubule gliding assays.

Author

Lopes, Joseph, Quint, David A, Chapman, Dail E, Xu, Melissa, Gopinathan, Ajay, and Hirst, Linda S

Subjects
Microtubules, Animals, Swine, Kinesin, Lipid Bilayers, Adenosine Triphosphate, Microscopy, Fluorescence, Fluorescence Recovery After Photobleaching, Diffusion, Protein Binding, Kinetics, Image Processing, Computer-Assisted, Brain Disorders, 1.1 Normal biological development and functioning, Generic Health Relevance, Biochemistry and Cell Biology, Other Physical Sciences
Abstract

Motor-based transport mechanisms are critical for a wide range of eukaryotic cell functions, including the transport of vesicle cargos over long distances. Our understanding of the factors that control and regulate motors when bound to a lipid substrate is however incomplete. We used microtubule gliding assays on a lipid bilayer substrate to investigate the role of membrane diffusion in kinesin-1 on/off binding kinetics and thereby transport velocity. Fluorescence imaging experiments demonstrate motor clustering on single microtubules due to membrane diffusion in the absence of ATP, followed by rapid ATP-induced dissociation during gliding. Our experimental data combined with analytical modeling show that the on/off binding kinetics of the motors are impacted by diffusion and, as a consequence, both the effective binding and unbinding rates for motors are much lower than the expected bare rates. Our results suggest that motor diffusion in the membrane can play a significant role in transport by impacting motor kinetics and can therefore function as a regulator of intracellular transport dynamics.

Published
2019

11. Nanoparticle-based hollow microstructures formed by two-stage nematic nucleation and phase separation.

Author

Riahinasab, Sheida T, Keshavarz, Amir, Melton, Charles N, Elbaradei, Ahmed, Warren, Gabrielle I, Selinger, Robin LB, Stokes, Benjamin J, and Hirst, Linda S

Subjects
Bioengineering, Nanotechnology, MD Multidisciplinary
Abstract

Rapid bulk assembly of nanoparticles into microstructures is challenging, but highly desirable for applications in controlled release, catalysis, and sensing. We report a method to form hollow microstructures via a two-stage nematic nucleation process, generating size-tunable closed-cell foams, spherical shells, and tubular networks composed of closely packed nanoparticles. Mesogen-modified nanoparticles are dispersed in liquid crystal above the nematic-isotropic transition temperature (TNI). On cooling through TNI, nanoparticles first segregate into shrinking isotropic domains where they locally depress the transition temperature. On further cooling, nematic domains nucleate inside the nanoparticle-rich isotropic domains, driving formation of hollow nanoparticle assemblies. Structural differentiation is controlled by nanoparticle density and cooling rate. Cahn-Hilliard simulations of phase separation in liquid crystal demonstrate qualitatively that partitioning of nanoparticles into isolated domains is strongly affected by cooling rate, supporting experimental observations that cooling rate controls aggregate size. Microscopy suggests the number and size of internal voids is controlled by second-stage nucleation.

Published
2019

12. Deformation and chaining of flexible shells in a nematic solvent

Author

DeBenedictis, Andrew, Rodarte, Andrea L., Hirst, Linda S., and Atherton, Timothy J.

Subjects
Condensed Matter - Soft Condensed Matter
Abstract

A micrometer-scale elastic shell immersed in a nematic liquid crystal may be deformed by the host if the cost of deformation is comparable to the cost of elastic deformation of the nematic. Moreover, such inclusions interact and form chains due to quadrupolar distortions induced in the host. A continuum theory model using finite elements is developed for this system, using mesh regularization and dynamic refinement to ensure quality of the numerical representation even for large deformations. From this model, we determine the influence of the shell elasticity, nematic elasticity and anchoring condition on the shape of the shell and hence extract parameter values from an experimental realization. Extending the model to multi-body interactions, we predict the alignment angle of the chain with respect to the host nematic as a function of aspect ratio, which is found to be in excellent agreement with experiments and greatly improves upon previous theoretical predictions., Comment: 6 pages, 5 figures

Published
2017
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15. Phase Transition-Driven Nanoparticle Assembly in Liquid Crystal Droplets.

Author

Melton, Charles N, Riahinasab, Sheida T, Keshavarz, Amir, Stokes, Benjamin J, and Hirst, Linda S

Subjects
nanoparticle, nematic liquid crystal, phase transition, quantum dot, self-assembly, Nanotechnology, Bioengineering, Materials Engineering
Abstract

When nanoparticle self-assembly takes place in an anisotropic liquid crystal environment, fascinating new effects can arise. The presence of elastic anisotropy and topological defects can direct spatial organization. An important goal in nanoscience is to direct the assembly of nanoparticles over large length scales to produce macroscopic composite materials; however, limitations on spatial ordering exist due to the inherent disorder of fluid-based methods. In this paper we demonstrate the formation of quantum dot clusters and spherical capsules suspended within spherical liquid crystal droplets as a method to position nanoparticle clusters at defined locations. Our experiments demonstrate that particle sorting at the isotropic-nematic phase front can dominate over topological defect-based assembly. Notably, we find that assembly at the nematic phase front can force nanoparticle clustering at energetically unfavorable locations in the droplets to form stable hollow capsules and fractal clusters at the droplet centers.

Published
2018

16. Modeling deformation and chaining of flexible shells in a nematic solvent with finite elements on an adaptive moving mesh

Author

DeBenedictis, Andrew, Atherton, Timothy J, Rodarte, Andrea L, and Hirst, Linda S

Subjects
Nuclear and Plasma Physics, Engineering, Physical Sciences, Mathematical sciences, Physical sciences
Abstract

A micrometer-scale elastic shell immersed in a nematic liquid crystal may be deformed by the host if the cost of deformation is comparable to the cost of elastic deformation of the nematic. Moreover, such inclusions interact and form chains due to quadrupolar distortions induced in the host. A continuum theory model using finite elements is developed for this system, using mesh regularization and dynamic refinement to ensure quality of the numerical representation even for large deformations. From this model, we determine the influence of the shell elasticity, nematic elasticity, and anchoring condition on the shape of the shell and hence extract parameter values from an experimental realization. Extending the model to multibody interactions, we predict the alignment angle of the chain with respect to the host nematic as a function of aspect ratio, which is found to be in excellent agreement with experiments.

Published
2018

17. Understanding the role of transport velocity in biomotor-powered microtubule spool assembly

Author

Tan, Amanda J., Chapman, Dail E., Hirst, Linda S., and Xu, Jing

Subjects
Quantitative Biology - Biomolecules, Physics - Biological Physics
Abstract

We examined the sensitivity of microtubule spools to transport velocity. Perhaps surprisingly, we determined that the steady-state number and size of spools remained constant over a seven-fold range of velocities. Our data on the kinetics of spool assembly further suggest that the main mechanisms underlying spool growth vary during assembly.

Published
2016
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18. A Simple Experimental Model to Investigate Force Range for Membrane Nanotube Formation

Author

Lor, Chai, Lopes, Joseph D., Mattson-Hoss, Michelle K., Xu, Jing, and Hirst, Linda S.

Subjects
Quantitative Biology - Biomolecules, Condensed Matter - Soft Condensed Matter, Physics - Biological Physics
Abstract

The presence of membrane tubules in living cells is essential to many biological processes. In cells, one mechanism to form nanosized lipid tubules is via molecular motor induced bilayer extraction. In this paper, we describe a simple experimental model to investigate the forces required for lipid tube formation using kinesin motors anchored to DOPC vesicles. Previous related studies have used molecular motors actively pulling on the membrane to extract a nanotube. Here, we invert the system geometry; molecular motors are used as static anchors linking DOPC vesicles to a two-dimensional microtubule network and an external flow is introduced to generate nanotubes facilitated by the drag force. We found that a drag force of ~7 pN was sufficient for tubule extraction for vesicles ranging from 1 to 2 um in radius. By our method, we found that the force generated by a single molecular motor was sufficient for membrane tubule extraction from a spherical lipid vesicle.

Published
2016
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19. Plasmon-actuated nano-assembled microshells.

Author

Quint, Makiko T, Sarang, Som, Quint, David A, Keshavarz, Amir, Stokes, Benjamin J, Subramaniam, Anand Bala, Huang, Kerwyn Casey, Gopinathan, Ajay, Hirst, Linda S, and Ghosh, Sayantani

Subjects
Bioengineering, Nanotechnology, Biochemistry and Cell Biology, Other Physical Sciences
Abstract

We present three-dimensional microshells formed by self-assembly of densely-packed 5 nm gold nanoparticles (AuNPs). Surface functionalization of the AuNPs with custom-designed mesogenic molecules drives the formation of a stable and rigid shell wall, and these unique structures allow encapsulation of cargo that can be contained, virtually leakage-free, over several months. Further, by leveraging the plasmonic response of AuNPs, we can rupture the microshells using optical excitation with ultralow power (

Published
2017

22. Liquid crystals in living tissue

Author

Hirst, Linda S and Charras, Guillaume

Subjects
Engineering, Physical Sciences, Condensed Matter Physics, General Science & Technology
Published
2017

24. Nanoparticle microstructures templated by liquid crystal phase-transition dynamics

Author

Riahinasab, Sheida T, Elbaradei, Ahmed, Keshavarz, Amir, Stokes, Benjamin J, and Hirst, Linda S

Subjects
Engineering, Communications Engineering, Electronics, Sensors and Digital Hardware, Physical Sciences, Atomic, Molecular and Optical Physics, Liquid crystals, nanocomposites, nanoparticles, quantum dots, phase transition, nematic, Communications engineering, Electronics, sensors and digital hardware, Atomic, molecular and optical physics
Published
2017

27. Understanding the role of transport velocity in biomotor-powered microtubule spool assembly

Author

Tan, Amanda J, Chapman, Dail E, Hirst, Linda S, and Xu, Jing

Subjects
Chemical Sciences, Chemical sciences
Abstract

We examined the sensitivity of microtubule spools to transport velocity. Perhaps surprisingly, we determined that the steady-state number and size of spools remained constant over a seven-fold range of velocities. Our data on the kinetics of spool assembly further suggest that the main mechanisms underlying spool growth vary during assembly.

Published
2016

28. Effects of Low Concentrations of Docosahexaenoic Acid on the Structure and Phase Behavior of Model Lipid Membranes.

Author

Lor, Chai and Hirst, Linda S

Subjects
DHA, X-ray diffraction, gel phase, lipid bilayer, Chemical Engineering, Civil Engineering, Environmental Engineering
Abstract

In this paper we report an X-ray diffraction study on the phase behavior of binary lipid mixtures of 1-palmitoyl-2-docosahexaenoyl-sn-glycero-3-phosphoethanolamine (DHA-PE) and 1,2-dipalmitoyl-sn-glycero-3-phosphocholine (DPPC) at low concentrations below 5.0 mol% DHA-PE. Our results show that DHA-PE induces phase separation into a DHA rich liquid crystalline (Lα) phase and a DHA poor gel (Lβ') phase at overall DHA-PE concentrations as low as 0.1 mol%. In addition, we find that the structure of the Lβ' phase, from which the DHA-PE molecules are largely excluded, is modified in the phase-separated state at low DHA-PE concentrations, with a decrease in bilayer thickness of 1.34 nm for 0.1 mol% at room temperature, compared to pure DPPC bilayers. This result is contrary to that seen in similar studies on mono-unsaturated lipids where an increase in bilayer thickness is observed. The surprising effect of such low DHA-PE concentrations on membrane structure may be important in understanding the role of highly polyunsaturated lipids in biological membrane-based structures and similar artificial surfactant systems.

Published
2015

29. Stability and instability for low refractive-index-contrast particle trapping in a dual-beam optical trap

Author

Huff, Alison, Melton, Charles N, Hirst, Linda S, and Sharping, Jay E

Subjects
(060.2310) Fiber optics, (140.7010) Laser trapping, Optical Physics, Materials Engineering
Abstract

A dual-beam optical trap is used to trap and manipulate dielectric particles. When the refractive index of these particles is comparable to that of the surrounding medium, equilibrium trapping locations within the system shift from stable to unstable depending on fiber separation and particle size. This is due to to the relationship between gradient and scattering forces. We experimentally and computationally study the transitions between stable and unstable trapping of poly(methyl methacrylate) beads for a range of parameters relevant to experimental setups involving giant unilamellar vesicles. We present stability maps for various fiber separations and particle sizes, and find that careful attention to particle size and configuration is necessary to obtain reproducible quantitative results for soft matter stretching experiments.

Published
2015

30. All-optical switching of nematic liquid crystal films driven by localized surface plasmons

Author

Quint, Makiko T, Delgado, Silverio, Paredes, John H, Nuno, Zachary S, Hirst, Linda S, and Ghosh, Sayantani

Subjects
Optical Physics, Electrical and Electronic Engineering, Communications Technologies, Optics
Abstract

We have demonstrated an all-optical technique for reversible in-plane and out-of-plane switching of nematic liquid crystal molecules in few micron thick films. Our method leverages the highly localized electric fields ("hot spots") and plasmonic heating that are generated in the near-field region of densely packed gold nanoparticle layers optically excited on-resonance with the localized surface plasmon absorption. Using polarized microscopy and transmission measurements, we observe this switching from homeotropic to planar over a temperature range starting at room temperature to just below the isotropic transition, and at on-resonance excitation intensity less than 0.03 W/cm(2). In addition, we controllably vary the in-plane directionality of the liquid crystal molecules in the planar state by altering the linear polarization of the incident excitation. Using discrete dipole simulations and control measurements, we establish spectral selectivity in this new and interesting perspective for photonic application using low light power.

Published
2015

31. Self-assembled nanoparticle micro-shells templated by liquid crystal sorting

Author

Rodarte, Andrea L, Cao, Blessing H, Panesar, Harmanpreet, Pandolfi, Ronald J, Quint, Makiko, Edwards, Lauren, Ghosh, Sayantani, Hein, Jason E, and Hirst, Linda S

Subjects
Macromolecular and Materials Chemistry, Engineering, Chemical Sciences, Nanotechnology, Bioengineering, Physical Sciences, Chemical Physics, Chemical sciences, Physical sciences
Abstract

A current goal in nanotechnology focuses on the assembly of different nanoparticle types into 3D organized structures. In this paper we report the use of a liquid crystal host phase in a new process for the generation of micron-scale vesicle-like nanoparticle shells stabilized by ligand-ligand interactions. The constructs formed consist of a robust, thin spherical layer, composed of closely packed quantum dots (QDs) and stabilized by local crystallization of the mesogenic ligands. Ligand structure can be tuned to vary QD packing within the shell and made UV cross-linkable to allow for intact shell extraction into toluene. The assembly method we describe could be extended to other nanoparticle types (metallic, magnetic etc.), where hollow shell formation is controlled by thermally sorting mesogen-functionalized nanoparticles in a liquid crystalline host material at the isotropic to nematic transition. This process represents a versatile method for making non-planar 3D nano-assemblies.

Published
2015

32. Magnetic field induced quantum dot brightening in liquid crystal synergized magnetic and semiconducting nanoparticle composite assemblies

Author

Amaral, Jose Jussi, Wan, Jacky, Rodarte, Andrea L, Ferri, Christopher, Quint, Makiko T, Pandolfi, Ronald J, Scheibner, Michael, Hirst, Linda S, and Ghosh, Sayantani

Subjects
Macromolecular and Materials Chemistry, Chemical Sciences, Engineering, Physical Sciences, Materials Engineering, Nanotechnology, Bioengineering, Chemical Physics, Chemical sciences, Physical sciences
Abstract

The design and development of multifunctional composite materials from artificial nano-constituents is one of the most compelling current research areas. This drive to improve over nature and produce 'meta-materials' has met with some success, but results have proven limited with regards to both the demonstration of synergistic functionalities and in the ability to manipulate the material properties post-fabrication and in situ. Here, magnetic nanoparticles (MNPs) and semiconducting quantum dots (QDs) are co-assembled in a nematic liquid crystalline (LC) matrix, forming composite structures in which the emission intensity of the quantum dots is systematically and reversibly controlled with a small applied magnetic field (

Published
2015

33. Dye-integrated cholesteric photonic luminescent solar concentrator

Author

Rodarte, Andrea L, Cisneros, Fredy, Hirst, Linda S, and Ghosh, Sayantani

Subjects
luminescent solar concentrators, optical devices, cholesteric, fluorescent dye, Optical Physics, Physical Chemistry (incl. Structural), Nanoscience & Nanotechnology
Abstract

We have developed organic dye-integrated thin-film liquid crystalline photonic luminescent solar concentrators (LSCs), where the chirality of the liquid crystal (LC) results in the formation of a one-dimensional photonic cavity. By varying the different LSC parameters, including dye concentration, spectral position of the photonic band-gap and the LC phase, and by using spectroscopic and electrical characterisation, we have systematically studied the effects of self-absorption, incident absorption and confinement of down-converted emission on optical efficiency. Our results demonstrate that the efficiency of our LSCs is significantly enhanced in the LC phase when the photonic band-gap is at long wavelengths (>600 nm), overcoming associated low incident absorption and higher self-absorption. We reach the significant conclusion that focusing on improving the confinement of dye-emitted photons, rather than on increasing incident absorption, is a more promising route to enhancing thin-film LC-based LSC performance. © 2014 © 2014 Taylor & Francis.

Published
2014

34. Designing highly tunable semiflexible filament networks.

Author

Pandolfi, Ronald J, Edwards, Lauren, Johnston, David, Becich, Peter, and Hirst, Linda S

Subjects
Polymers, Phase Transition, Fractals, Elasticity, Molecular Dynamics Simulation, Fluids & Plasmas, Mathematical Sciences, Physical Sciences, Engineering
Abstract

Semiflexible polymers can generate a range of filamentous networks significantly different in structure from those seen in conventional polymer solutions. Our coarse-grained simulations with an implicit cross-linker potential show that networks of branching bundles, knotted morphologies, and structural chirality can be generated by a generalized approach independent of specific cross-linkers. Network structure depends primarily on filament flexibility and separation, with significant connectivity increase after percolation. Results should guide the design of engineered semiflexible polymers.

Published
2014

35. Tuning Quantum‐Dot Organization in Liquid Crystals for Robust Photonic Applications

Author

Rodarte, Andrea L, Nuno, Zachary S, Cao, Blessing H, Pandolfi, Ronald J, Quint, Makiko T, Ghosh, Sayantani, Hein, Jason E, and Hirst, Linda S

Subjects
Macromolecular and Materials Chemistry, Chemical Sciences, Physical Chemistry, Nanotechnology, Bioengineering, fluorescence, ligand exchange, liquid crystals, photoluminescence, quantum dots, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Physical Chemistry (incl. Structural), Theoretical and Computational Chemistry, Chemical Physics, Macromolecular and materials chemistry, Physical chemistry
Abstract

Mesogenic ligands have the potential to provide control over the dispersion and stabilization of nanoparticles in liquid crystal (LC) phases. The creation of such hybrid materials is an important goal for the creation of soft tunable photonic devices, such as the LC laser. Herein, we present a comparison of isotropic and mesogenic ligands attached to the surface of CdSe (core-only) and CdSe/ZnS (core/shell) quantum dots (QDs). The mesogenic ligand's flexible arm structure enhances ligand alignment, with the local LC director promoting QD dispersion in the isotropic and nematic phases. To characterize QD dispersion on different length scales, we apply fluorescence microscopy, X-ray scattering, and scanning confocal photoluminescent imaging. These combined techniques demonstrate that the LC-modified QDs do not aggregate into the dense clusters observed for dots with simple isotropic ligands when dispersed in liquid crystal, but loosely associate in a fluid-like droplet with an average interparticle spacing >10 nm. Embedding the QDs in a cholesteric cavity, we observe comparable coupling effects to those reported for more closely packed isotropic ligands.

Published
2014

36. Quantum dot /liquid crystal composite materials: self-assembly driven by liquid crystal phase transition templating

Author

Rodarte, Andrea L, Pandolfi, Ronald J, Ghosh, Sayantani, and Hirst, Linda S

Subjects
Macromolecular and Materials Chemistry, Engineering, Chemical Sciences, Nanotechnology, Bioengineering, Physical Chemistry (incl. Structural), Materials Engineering, Macromolecular and materials chemistry, Physical chemistry, Materials engineering
Abstract

The isotropic to nematic liquid crystal (LC) phase transition is used to create organized assemblies of CdSe/ZnS core/shell quantum dots (QDs). Under controlled conditions, well dispersed QDs are expelled from the ordered domains of nematic LC into the remaining isotropic domains. The final LC phase produces three dimensional QD assemblies that are situated at the defect points in the LC volume. Through the luminescence of the QDs we are able to track the movement of the nanoparticles as the phase is formed as well as spectrally probe the resulting QD assemblies. Forster resonance energy transfer (FRET) measurements, combined with small angle X-ray scattering (SAXS) data reveal that the QD assemblies have a consistent inter-particle spacing of approximately 7.6 nm. Additionally, the location of the assemblies is shown to be controllable by utilizing beads as defect nucleation points. © The Royal Society of Chemistry 2013.

Published
2013

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