83,931 research outputs found
Transport of inertial particles by Lagrangian coherent structures : application to predator-prey interaction in jellyfish feeding
We use a dynamical systems approach to identify coherent structures from often chaotic motions of inertial particles in open flows. We show that particle Lagrangian coherent structures (pLCS) act as boundaries between regions in which particles have different kinematics. They provide direct geometric information about the motion of ensembles of inertial particles, which is helpful to understand their transport. As an application, we apply the methodology to a planktonic predator–prey system in which moon jellyfish Aurelia aurita uses its body motion to generate a flow that transports small plankton such as copepods to its vicinity for feeding. With the flow field generated by the jellyfish measured experimentally and the dynamics of plankton described by a modified Maxey–Riley equation, we use the pLCS to identify a capture region in which prey can be captured by the jellyfish. The properties of the pLCS and the capture region enable analysis of the effect of several physiological and mechanical parameters on the predator–prey interaction, such as prey size, escape force, predator perception, etc. The methods developed here are equally applicable to multiphase and granular flows, and can be generalized to any other particle equation of motion, e.g. equations governing the motion of reacting particles or charged particles
Flavor Asymmetry of the Nucleon Sea
Recent deep inelastic scattering and Drell-Yan experiments have revealed a
surprisingly large asymmetry between the up and down sea quark distributions in
the nucleon. The current status of the flavor asymmetry of the nucleon sea is
reviewed. Implications of various theoretical models and possible future
measurements are also discussed.Comment: 9 pages, 3 figures. Invited paper presented at the "16th
International Conference on Few-Body Problem in Physics" March 200
Sharp sensitivity bounds for mediation under unmeasured mediator-outcome confounding
It is often of interest to decompose a total effect of an exposure into the
component that acts on the outcome through some mediator and the component that
acts independently through other pathways. Said another way, we are interested
in the direct and indirect effects of the exposure on the outcome. Even if the
exposure is randomly assigned, it is often infeasible to randomize the
mediator, leaving the mediator-outcome confounding not fully controlled. We
develop a sensitivity analysis technique that can bound the direct and indirect
effects without parametric assumptions about the unmeasured mediator-outcome
confounding
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