Please use this identifier to cite or link to this item: http://dr.iiserpune.ac.in:8080/xmlui/handle/123456789/10949
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dc.contributor.advisorBHATTACHARYAY, ARIJIT-
dc.contributor.authorAAKASH, AAKASH-
dc.date.accessioned2026-05-05T07:15:52Z-
dc.date.available2026-05-05T07:15:52Z-
dc.date.issued2026-05-
dc.identifier.citation155en_US
dc.identifier.urihttp://dr.iiserpune.ac.in:8080/xmlui/handle/123456789/10949-
dc.description.abstractThis thesis explores the transport of particles and fluids through soft micro- and nanochannels with spatiotemporally undulating walls, a problem that sits at the intersection of biological transport and the design of next-generation nanofluidic devices. To study these systems, the work combines analytical perturbation theory for low-Reynolds-number flows with computational Langevin dynamics, capturing how thermal fluctuations, wall interactions, and external driving forces work together to shape transport. The research is presented in three parts. First, we investigate an entropic flashing ratchet model, demonstrating that asymmetric surface fluctuations alone can drive directed particle transport. Our results identify optimal conditions for this phenomenon, showing it is maximally efficient for 10 nm particles in a water-like medium at room temperature. Second, we analyze the competition between pressure-driven bulk flow and surface-driven boundary flow in a soft nanochannel. We develop a perturbation analysis that delineates these two regimes and derive a dimensionless parameter that quantifies the flow crossover, a result critical for applications in particle filtration and trapping. In the final part, we develop a hydrodynamic ratchet model. Here, we demonstrate that carefully designed wall undulations can generate an asymmetric flow field capable of rectifying Brownian motion, resulting in a steady net particle drift. This mechanism provides a promising route for achieving controlled transport through purely hydrodynamic means. We derive the structure of fluid flow in this microchannel and the Boundary modes sustaining this fluid flow structure. Since surface-driven flow becomes stronger near the channel boundary, the presence of surface undulations is crucial when studying fluid or particle transport in a channel. This mechanism provides a promising route for achieving controlled transport through purely hydrodynamic means. Overall, the thesis advances our theoretical understanding of particle transport in soft, confined environments and offers a quantitative framework that could guide the development of new nanofluidic pumps and separation devices.en_US
dc.description.sponsorshipCouncil of Scientific and Industrial Research (CSIR), India, funded this research through Grant No. 09/936(0296)/2021-EMR-I.en_US
dc.language.isoen_USen_US
dc.subjectFluid transporten_US
dc.subjectParticle transporten_US
dc.subjectLangevin equationen_US
dc.subjectDirected transporten_US
dc.subjectUndulating microchannelen_US
dc.subjectUndulating nanochannelen_US
dc.subjectLow Reynolds number hydrodynamicsen_US
dc.titleInvestigation of Fluid and Particle Transport in Undulating Micro- and Nanochannelsen_US
dc.typeThesisen_US
dc.description.embargoNo Embargoen_US
dc.type.degreeInt.Ph.Den_US
dc.contributor.departmentDept. of Physicsen_US
dc.contributor.registration20172026en_US
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