Optical Tweezers Microrheology Maps the Dynamics of Strain-Induced Local Inhomogeneities in Entangled Polymers

Khan, Manas; Regan, Kathryn; Robertson‐Anderson, Rae M.

doi:10.1103/physrevlett.123.038001

Cited by 25 publications

(22 citation statements)

References 38 publications

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“…Chirality plays an essential role in several biological, chemical and nanotechnological applications 46 . Our results for the particle rotation open the way for the characterization of the local chiral response at the nanoscale, that nicely interconnects with already existing local probing techniques to determine viscoelastic properties 47 , 48 and micro-rheological properties of small particles 49 – 52 .…”

supporting

confidence: 68%

Theory of optical tweezing of dielectric microspheres in chiral host media and its applications

Ali

Dutra

Pinheiro

et al. 2020

Sci Rep

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We report for the first time the theory of optical tweezers of spherical dielectric particles embedded in a chiral medium. We develop a partial-wave (Mie) expansion to calculate the optical force acting on a dielectric microsphere illuminated by a circularly-polarized, highly focused laser beam. When choosing a polarization with the same handedness of the medium, the axial trap stability is improved, thus allowing for tweezing of high-refractive-index particles. When the particle is displaced off-axis by an external force, its equilibrium position is rotated around the optical axis by the mechanical effect of an optical torque. Both the optical torque and the angle of rotation are greatly enhanced in the presence of a chiral host medium when considering radii a few times larger than the wavelength. In this range, the angle of rotation depends strongly on the microsphere radius and the chirality parameter of the host medium, opening the way for a quantitative characterization of both parameters. Measurable angles are predicted even in the case of naturally occurring chiral solutes, allowing for a novel all-optical method to locally probe the chiral response at the nanoscale.

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supporting

confidence: 68%

Theory of optical tweezing of dielectric microspheres in chiral host media and its applications

Ali

Dutra

Pinheiro

et al. 2020

Sci Rep

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“…Similar behavior has been seen for entangled linear DNA in which nonlinear micro-strains compress polymers in front of the moving bead, thereby increasing the local entanglement density while leaving dilute regions in its wake. 63 This effect may also explain the emergent sustained elasticity.…”

Section: Resultsmentioning

confidence: 97%

Unexpected entanglement dynamics in semidilute blends of supercoiled and ring DNA

et al. 2020

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Blends of polymers of different topologies, such as ring and supercoiled, naturally occur in biology and often exhibit emergent viscoelastic properties coveted in industry. However, due to their complexity, along with the difficulty of producing polymers of different topologies, the dynamics of topological polymer blends remains poorly understood. We address this void by using both passive and active microrheology to characterize the linear and nonlinear rheological properties of blends of relaxed circular and supercoiled DNA. We characterize the dynamics as we vary the concentration from below the overlap concentration c* to above (0.5c* to 2c*). Surprisingly, despite working at the dilute-semidilute crossover, entanglement dynamics, such as shear-thinning, elastic plateaus, and multiple relaxation modes, emerge. Finally, blends exhibit an unexpected sustained elastic response to nonlinear strains not previously observed even in wellentangled linear polymer solutions.

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“…Recent experiments with micron-sized colloidal probes dragged through different types of complex fluids (wormlike micelles, polymer solutions, and entangled λ-phage DNA) with an optical trap, revealed a rich transient recoil dynamics after the trap was removed [17][18][19][20][21][22]. Notably, experiments with slightly different shearing protocols demonstrated different relaxation behaviors, even when the same viscoelastic material was studied.…”

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confidence: 99%

Recoil experiments determine the eigenmodes of viscoelastic fluids

Ginot¹,

Caspers²,

Kumar³

et al. 2022

Preprint

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We experimentally investigate the recoil dynamics of a colloidal probe particle after shearing it with constant velocity through a viscoelastic fluid. The recoil displays two distinct timescales which are in excellent agreement with a microscopic model built on a particle being linked to two bath particles by harmonic springs. This model yields analytical expressions which reproduce all experimental protocols, including additional waiting periods before particle release. Notably, two sets of timescales appear, corresponding to reciprocal and nonreciprocal eigenmodes of the model.

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Optical Tweezers Microrheology Maps the Dynamics of Strain-Induced Local Inhomogeneities in Entangled Polymers

Cited by 25 publications

References 38 publications

Theory of optical tweezing of dielectric microspheres in chiral host media and its applications

Theory of optical tweezing of dielectric microspheres in chiral host media and its applications

Unexpected entanglement dynamics in semidilute blends of supercoiled and ring DNA

Recoil experiments determine the eigenmodes of viscoelastic fluids

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