ESC seminar No. 14

Initial Hydrodynamic Results from Princeton Magnetorotational Instability Experiment

Date
February 2(Thu.), 2006, 13:30-14:30
Place
Conference Room, 1F Earth Simulator Research building, YES
Speaker
Dr. Hantao Ji (Principal research physicist at Princeton Plasma Physics Laboratory, Princeton University)
Language
English

Abstract

Rapid angular momentum transport in accretion disks has been a longstanding astrophysical puzzle. Molecular viscosity is inadequate to explain observationally inferred accretion rates. Since Keplerian flow profiles are linearly stable in hydrodynamics, there exist only two viable mechanisms for the required turbulence: nonlinear hydrodynamic instability or magnetohydrodynamic instability. The latter, also know as magnetorotational instability(MRI), is regarded as a dominant mechanism for rapid angular momentum transport in hot accretion disks ranging from quasars and X-ray binaries to cataclysmic variables. The former has been proposed mainly for colder protoplanetary disks, whose Reynolds numbers are typically large. Despite their popularity, however, both candidate mechanisms have been rarely demonstrated and studied in the laboratory. In this talk, I will describe initial results from a laboratory experiment in a short Taylor-Couette flow geometry ongoing at Princeton intended for such purposes. Based on the knowledge leant through prototype experiments and simulations, the apparatus contains novel features for better controls of the boundary-driven secondary flows (Ekman circulation). Initial results on hydrodynamic stability have shown, somewhat surprisingly, robust quiescence of the Keplerian-like flows and minimal angular momentum transport with million Reynolds numbers, casting questions on viability of the nonlinear hydrodynamic instability. This project is supported by U.S. DoE, NSF, and NASA.

Contact

Dr. Akira Kageyama Group Leader
Solid Earth Simulation Research Group
Computational Earth Science Research Program
Earth Simulator Center TEL:045-778-5856
e-mail: kage