Your search keyword '"Ganapathy, Rajesh"' showing total 8 results

1. A shape-driven reentrant jamming transition in confluent monolayers of synthetic cell-mimics.

Author

Arora, Pragya, Sadhukhan, Souvik, Nandi, Saroj Kumar, Bi, Dapeng, Sood, A. K., and Ganapathy, Rajesh

Subjects

MONOMOLECULAR films, CELL morphology, WOUND healing, FLUIDIZATION, EPITHELIUM, TISSUES

Abstract

Many critical biological processes, like wound healing, require densely packed cell monolayers/tissues to transition from a jammed solid-like to a fluid-like state. Although numerical studies anticipate changes in the cell shape alone can lead to unjamming, experimental support for this prediction is not definitive because, in living systems, fluidization due to density changes cannot be ruled out. Additionally, a cell's ability to modulate its motility only compounds difficulties since even in assemblies of rigid active particles, changing the nature of self-propulsion has non-trivial effects on the dynamics. Here, we design and assemble a monolayer of synthetic cell-mimics and examine their collective behaviour. By systematically increasing the persistence time of self-propulsion, we discovered a cell shape-driven, density-independent, re-entrant jamming transition. Notably, we observed cell shape and shape variability were mutually constrained in the confluent limit and followed the same universal scaling as that observed in confluent epithelia. Dynamical heterogeneities, however, did not conform to this scaling, with the fast cells showing suppressed shape variability, which our simulations revealed is due to a transient confinement effect of these cells by their slower neighbors. Our experiments unequivocally establish a morphodynamic link, demonstrating that geometric constraints alone can dictate epithelial jamming/unjamming. Living cell collectives can jam and unjam through many pathways, yet the details remain elusive. Arora et al. design a monolayer of deformable cell-mimics composed of chiral active granular ellipsoids confined in flexible paper rings and show a re-entrant jamming transition mediated solely by cell shape change. [ABSTRACT FROM AUTHOR]

Published

2024

2. Tuning the performance of a micrometer-sized Stirling engine through reservoir engineering.

Author

Roy, Niloyendu, Leroux, Nathan, Sood, A. K., and Ganapathy, Rajesh

Subjects

HEAT engines, STIRLING engines, OPTICAL tweezers, ENGINEERING, ENGINES, COLLOIDS

Abstract

Colloidal heat engines are paradigmatic models to understand the conversion of heat into work in a noisy environment - a domain where biological and synthetic nano/micro machines function. While the operation of these engines across thermal baths is well-understood, how they function across baths with noise statistics that is non-Gaussian and also lacks memory, the simplest departure from the thermal case, remains unclear. Here we quantified the performance of a colloidal Stirling engine operating between an engineered memoryless non-Gaussian bath and a Gaussian one. In the quasistatic limit, the non-Gaussian engine functioned like a thermal one as predicted by theory. On increasing the operating speed, due to the nature of noise statistics, the onset of irreversibility for the non-Gaussian engine preceded its thermal counterpart and thus shifted the operating speed at which power is maximum. The performance of nano/micro machines can be tuned by altering only the nature of reservoir noise statistics. Micro scale heat engines may be subjected to quite intriguing scenarios. Roy et al superimpose artificial random kicks on an optically trapped colloid, emulating a memoryless non-gaussian reservoir that markedly alters the conditions under which the engine performs at optimum efficiency. [ABSTRACT FROM AUTHOR]

Published

2021

3. Measurements of growing surface tension of amorphous–amorphous interfaces on approaching the colloidal glass transition.

Author

Ganapathi, Divya, Nagamanasa, K. Hima, Sood, A. K., and Ganapathy, Rajesh

Abstract

There is mounting evidence indicating that relaxation dynamics in liquids approaching their glass transition not only become increasingly cooperative, but the relaxing regions also become more compact in shape. Of the many theories of the glass transition, only the random first-order theory—a thermodynamic framework—anticipates the surface tension of relaxing regions to play a role in deciding both their size and morphology. However, owing to the amorphous nature of the relaxing regions, even the identification of their interfaces has not been possible in experiments hitherto. Here, we devise a method to directly quantify the dynamics of amorphous–amorphous interfaces in bulk supercooled colloidal liquids. Our procedure also helped unveil a non-monotonic evolution in dynamical correlations with supercooling in bulk liquids. We measure the surface tension of the interfaces and show that it increases rapidly across the mode-coupling area fraction. Our experiments support a thermodynamic origin of the glass transition. [ABSTRACT FROM AUTHOR]

Published

2018

4. Viscoelastic nature of Au nanoparticle-PDMS nanocomposite gels.

Author

GUPTA, RITU, NAGAMANASA, HIMA, GANAPATHY, RAJESH, and KULKARNI, GIRIDHAR

Subjects

VISCOELASTICITY, GOLD nanoparticles, POLYDIMETHYLSILOXANE, POLYMERIC nanocomposites, SOL-gel processes, CURING

Abstract

A stable gel of Au nanoparticles in polydimethylsiloxane (PDMS) nanocomposite is prepared by employing the curing agent of PDMS elastomer as a reducing agent for the formation of Au nanoparticles by an in-situ process. The viscoelastic nature of these gels is very sensitive to the Au nanoparticle loading and the synthetic temperature conditions. Even a very low Au content of 0.09 wt% is sufficient enough to bring in the transition from sponge state to gel state at room temperature. Higher synthetic temperature also forms sponge formation. Infrared and ultraviolet-visible spectroscopy measurements have provided insight into PDMS crosslinking and nanoparticle formation, respectively. The optimization of the gel properties can have direct influence on the processability of Au nanoparticle-PDMS nanocomposite gels, with interesting implications in electronic, optical and microfluidic devices. [ABSTRACT FROM AUTHOR]

Published

2015

5. Direct measurements of growing amorphous order and non-monotonic dynamic correlations in a colloidal glass-former.

Author

Hima Nagamanasa, K., Gokhale, Shreyas, Sood, A. K., and Ganapathy, Rajesh

Subjects

GLASS, COLLOIDS, FIRST-order phase transitions, RELAXATION phenomena, OPTICAL tweezers, GLASS transitions, AMORPHOUS substances

Abstract

The transformation of flowing liquids into rigid glasses is thought to involve increasingly cooperative relaxation dynamics as the temperature approaches that of the glass transition. However, the precise nature of this motion is unclear, and a complete understanding of vitrification thus remains elusive. Of the numerous theoretical perspectives devised to explain the process, random first-order theory (RFOT; refs , ) is a well-developed thermodynamic approach, which predicts a change in the shape of relaxing regions as the temperature is lowered. However, the existence of an underlying 'ideal' glass transition predicted by RFOT remains debatable, largely because the key microscopic predictions concerning the growth of amorphous order and the nature of dynamic correlations lack experimental verification. Here, using holographic optical tweezers, we freeze a wall of particles in a two-dimensional colloidal glass-forming liquid and provide direct evidence for growing amorphous order in the form of a static point-to-set length. We uncover the non-monotonic dependence of dynamic correlations on area fraction and show that this non-monotonicity follows directly from the change in morphology and internal structure of cooperatively rearranging regions. Our findings support RFOT and thereby constitute a crucial step in distinguishing between competing theories of glass formation. [ABSTRACT FROM AUTHOR]

Published

2015

6. Order and chaos in soft condensed matter.

Author

Sood, A. K. and Ganapathy, Rajesh

Subjects

*QUANTUM perturbations, *SURFACE active agents, *COLLOIDS, *SHEAR (Mechanics), *SALT

Abstract

Soft matter, like colloidal suspensions and surfactant gels, exhibit strong response to modest external perturbations. This paper reviews our recent experiments on the nonlinear flow behaviour of surfactant worm-like micellar gels. A rich dynamic behaviour exhibiting regular, quasi-periodic, intermittency and chaos is observed. In particular, we have shown experimentally that the route to chaos is via Type-II intermittency in shear thinning worm-like micellar solution of cetyltrimethylammonium tosylate where the strength of flow-concentration coupling is tuned by the addition of sodium chloride. A Poincaré first return map of the time series and the probability distribution of laminar length between burst events show that our data are consistent with Type-II intermittency. The existence of a 'Butterfly' intensity pattern in small angle light scattering (SALS) measurements performed simultaneously with the rheological measurements confirms the coupling of flow to concentration fluctuations in the system under study. The scattered depolarised intensity in SALS, sensitive to orientational order fluctuations, shows the same time-dependence (like intermittency) as that of shear stress. [ABSTRACT FROM AUTHOR]

Published

2006

7. Cooperatively rearranging regions change shape near the mode-coupling crossover for colloidal liquids on a sphere.

Author

Singh, Navneet, Sood, A. K., and Ganapathy, Rajesh

Subjects

CURVED surfaces, LIQUID surfaces, CONDENSED matter, SPHERES, LIQUIDS

Abstract

The structure and dynamics of liquids on curved surfaces are often studied through the lens of frustration-based approaches to the glass transition. Competing glass transition theories, however, remain largely untested on such surfaces and moreover, studies hitherto have been entirely theoretical/numerical. Here we carry out single particle-resolved imaging of dynamics of bi-disperse colloidal liquids confined to the surface of a sphere. We find that mode-coupling theory well captures the slowing down of dynamics in the moderate to deeply supercooled regime. Strikingly, the morphology of cooperatively rearranging regions changed from string-like to compact near the mode-coupling crossover—a prediction unique to the random first-order theory of glasses. Further, we find that in the limit of strong curvature, Mermin–Wagner long-wavelength fluctuations are irrelevant and liquids on a sphere behave like three-dimensional liquids. A comparative evaluation of competing mechanisms is thus an essential step towards uncovering the true nature of the glass transition. The static and dynamic behavior of condensed phases residing on curved surfaces can be fundamentally different from their counterparts in Euclidean space. Singh et al. test several competing glass theories on colloidal liquids confined to the surface of a sphere and show they behave like 3D bulk liquids. [ABSTRACT FROM AUTHOR]

Published

2020

8. Growing dynamical facilitation on approaching the random pinning colloidal glass transition.

Author

Gokhale, Shreyas, Hima Nagamanasa, K., Ganapathy, Rajesh, and Sood, A. K.

Published

2014