Presentation is loading. Please wait.

Presentation is loading. Please wait.

Prograde patterns in rotating convection and implications for the dynamo Axel Brandenburg (Nordita, Copenhagen  Stockholm) Taylor-Proudman problem Near-surface.

Published byTheresa Little Modified over 8 years ago

Similar presentations

Presentation on theme: "Prograde patterns in rotating convection and implications for the dynamo Axel Brandenburg (Nordita, Copenhagen  Stockholm) Taylor-Proudman problem Near-surface."— Presentation transcript:

1 Prograde patterns in rotating convection and implications for the dynamo Axel Brandenburg (Nordita, Copenhagen  Stockholm) Taylor-Proudman problem Near-surface shear layer Relation to any interior depth? Prograde pattern speed Pattern speed of supergranulation

2 2 Internal angular velocity from helioseismology spoke-like at equ. d  /dr>0 at bottom ? d  /dr<0 at top

3 3 Departure from Taylor-Proudman <0 + - Brandenburg et al. (1992, A&A 265, 328) warmer pole first pointed out by Durney & Roxburgh

4 4 Near-surface shear d  /dr >> (Kippenhahn 1963) Expected when radial plumes important Kitchatinov & Rüdiger (2005, AN 326, 379)

5 5 Application to the sun: spots rooted at r/R=0.95 Benevolenskaya, Hoeksema, Kosovichev, Scherrer (1999) Pulkkinen & Tuominen (1998)  =  AZ  =(180/  ) (1.5x10 7 ) (2  10 -8 ) =360 x 0.15 = 54 degrees!

6 6 In the days before helioseismology Angular velocity (at 4 o latitude): –very young spots: 473 nHz –oldest spots: 462 nHz –Surface plasma: 452 nHz Conclusion back then: –Sun spins faster in deaper convection zone –Solar dynamo works with d  /dr<0: equatorward migr

7 7 The path toward the overshoot dynamo scenario Since 1980: dynamo at bottom of CZ –Flux tube’s buoyancy neutralized –Slow motions, long time scales Since 1984: diff rot spoke-like –d  /dr strongest at bottom of CZ Since 1991: field must be 100 kG –To get the tilt angle right Spiegel & Weiss (1980) Golub, Rosner, Vaiana, & Weiss (1981)

8 Is magnetic buoyancy a problem? Stratified dynamo simulation in 1990 Expected strong buoyancy losses, but no: downward pumping Tobias et al. (2001)

9 Magnetic buoyancy for strong tubes Brandenburg et al. (2001)

10 10 Arguments against and in favor? Flux storage Distortions weak Problems solved with meridional circulation Size of active regions Neg surface shear: equatorward migr. Max radial shear in low latitudes Youngest sunspots: 473 nHz Correct phase relation Strong pumping (Thomas et al.) 100 kG hard to explain Tube integrity Single circulation cell Too many flux belts* Max shear at poles* Phase relation* 1.3 yr instead of 11 yr at bot Rapid buoyant loss* Strong distortions* (Hale’s polarity) Long term stability of active regions* No anisotropy of supergranulation in favor against Tachocline dynamosDistributed/near-surface dynamo Brandenburg (2005, ApJ 625, 539)

11 11 Cycle dependence of  (r,  )

12 12 Simulations of near-surface shear Unstable layer in 0<z<1 0 o latitude 4x4x1 aspect ratio 512x512x256 Prograde pattern speed, but rather slow (Green & Kosovichev 2006)

13 Convection with rotation Inv. Rossby Nr. 2  d/u rms =4 (at bottom, <1 near top)

14 14 Vertical velocity profiles Ro -1 about 5 at bottom …less than 1 at the top Mean flow Exactly at equator mean flow monotonous

15 15 Simulations of near-surface shear 4x4x1 aspect ratio 512x512x256 0 o lat 15 o lat negative u y u z stress  negative shear

16 16 Explained by Reynolds stress negative u y u z stress  negative shear Vanishing total stress (…,+b.c.) find: good fit parameter:

17 Horizontal flow pattern Stongly retrograde motions Plunge into prograde shock y x

18 18 Prograde propagating patterns Slope: 0.064 (=pattern speed)

19 19 No relation to interior speed Prograde pattern speed versus interior speed

20 20 Not so clear from snapshots Entropy at z=0.9d

21 21 Relation to earlier work Prograde patterns seen in Doppler measurements of supergranulation Busse (2004) found prograde patterns from rotating convection with l-hexagons Green & Kosovichev (2005) found prograde patterns (<20m/s) from radial shear Toomre et al. reported 3% prograde speed in ASH Hathaway et al. (2006) explained Doppler measurements as projection effect –But this doesn’t explain time-distance measurements or sunspot proper motion

22 22 Conclusions to avoid Taylor-Proudman  need warm pole Radial deceleration near surface –Dominance of plumes Magnetic (and other) tracers –Relation to certain depth? Negative shear reproduced by simulations –Explained by Reynolds stresses –But strong prograde pattern speed –No relation to any depth!

Download ppt "Prograde patterns in rotating convection and implications for the dynamo Axel Brandenburg (Nordita, Copenhagen  Stockholm) Taylor-Proudman problem Near-surface."

Similar presentations

The solar dynamo(s) Fausto Cattaneo Center for Magnetic Self-Organization in Laboratory and Astrophysical Plasmas Chicago 2003.

The solar dynamo(s) Fausto Cattaneo Center for Magnetic Self-Organization in Laboratory and Astrophysical Plasmas Chicago 2003.
Historical Development of Solar Dynamo Theory Historical Development of Solar Dynamo Theory Arnab Rai Choudhuri Department of Physics Indian Institute.

Historical Development of Solar Dynamo Theory Historical Development of Solar Dynamo Theory Arnab Rai Choudhuri Department of Physics Indian Institute.
The Origin of the Solar Magnetic Cycle Arnab Rai Choudhuri Department of Physics Indian Institute of Science.

The Origin of the Solar Magnetic Cycle Arnab Rai Choudhuri Department of Physics Indian Institute of Science.
2011/08/302011 ILWS Science Workshop1 Solar cycle prediction using dynamos and its implication for the solar cycle Jie Jiang National Astronomical Observatories,

2011/08/ ILWS Science Workshop1 Solar cycle prediction using dynamos and its implication for the solar cycle Jie Jiang National Astronomical Observatories,
1 The Sun as a whole: Rotation, Meridional circulation, and Convection Michael Thompson High Altitude Observatory, National Center for Atmospheric Research.

1 The Sun as a whole: Rotation, Meridional circulation, and Convection Michael Thompson High Altitude Observatory, National Center for Atmospheric Research.
The Sunspot Cycle, Convection Zone Dynamics, and the Solar Dynamo

The Sunspot Cycle, Convection Zone Dynamics, and the Solar Dynamo
Planetary tides and solar activity Katya Georgieva

Planetary tides and solar activity Katya Georgieva
1. 2 Apologies from Ed and Karl-Heinz 3 4 5 6.

1. 2 Apologies from Ed and Karl-Heinz
Scientific astrology: planetary effects on solar activity Katya Georgieva Solar-Terrestrial Influences Lab., Bulgarian Academy of Sciences In collaboration.

Scientific astrology: planetary effects on solar activity Katya Georgieva Solar-Terrestrial Influences Lab., Bulgarian Academy of Sciences In collaboration.
Coronal Mass Ejections - the exhaust of modern dynamos Examples: systematic swirl (helicity) Measuring it quantitatively Connection with the dynamo Axel.

Coronal Mass Ejections - the exhaust of modern dynamos Examples: systematic swirl (helicity) Measuring it quantitatively Connection with the dynamo Axel.
Simulation of Flux Emergence from the Convection Zone Fang Fang 1, Ward Manchester IV 1, William Abbett 2 and Bart van der Holst 1 1 Department of Atmospheric,

Simulation of Flux Emergence from the Convection Zone Fang Fang 1, Ward Manchester IV 1, William Abbett 2 and Bart van der Holst 1 1 Department of Atmospheric,
Physics 681: Solar Physics and Instrumentation – Lecture 20 Carsten Denker NJIT Physics Department Center for Solar–Terrestrial Research.

Physics 681: Solar Physics and Instrumentation – Lecture 20 Carsten Denker NJIT Physics Department Center for Solar–Terrestrial Research.
Solar Turbulence Friedrich Busse Dali Georgobiani Nagi Mansour Mark Miesch Aake Nordlund Mike Rogers Robert Stein Alan Wray.

Solar Turbulence Friedrich Busse Dali Georgobiani Nagi Mansour Mark Miesch Aake Nordlund Mike Rogers Robert Stein Alan Wray.
Global Convection Modeling (where are we heading and how does this impact HMI?) Mark Miesch HAO/NCAR, JILA/CU (Sacha Brun, Juri Toomre, Matt Browning,

Global Convection Modeling (where are we heading and how does this impact HMI?) Mark Miesch HAO/NCAR, JILA/CU (Sacha Brun, Juri Toomre, Matt Browning,
On the Cause of Solar Differential Rotation Ling-Hsiao Lyu Institute of Space Science, National Central University 呂凌霄 中央大學太空科學研究所 太陽差動自轉的成因.

On the Cause of Solar Differential Rotation Ling-Hsiao Lyu Institute of Space Science, National Central University 呂凌霄 中央大學太空科學研究所 太陽差動自轉的成因.
Dynamical Implications Juri Toomre, JILA Helioseis: Deborah Haber, Brad Hindman + Rick Bogart, Douglas Gough, Frank Hill, Jesper Schou, Mike Thompson Dynamics:

Dynamical Implications Juri Toomre, JILA Helioseis: Deborah Haber, Brad Hindman + Rick Bogart, Douglas Gough, Frank Hill, Jesper Schou, Mike Thompson Dynamics:
High Altitude Observatory (HAO) – National Center for Atmospheric Research (NCAR) The National Center for Atmospheric Research is operated by the University.

High Altitude Observatory (HAO) – National Center for Atmospheric Research (NCAR) The National Center for Atmospheric Research is operated by the University.
Introduction to Space Weather Jie Zhang CSI 662 / PHYS 660 Spring, 2012 Copyright © The Sun: Magnetism Feb. 09, 2012.

Introduction to Space Weather Jie Zhang CSI 662 / PHYS 660 Spring, 2012 Copyright © The Sun: Magnetism Feb. 09, 2012.
The Sun’s internal rotation Michael Thompson University of Sheffield

The Sun’s internal rotation Michael Thompson University of Sheffield
THE CIRCULATION DOMINATED SOLAR DYNAMO MODEL REVISITED Gustavo A. Guerrero E. (IAG/USP) Elisabete M. de Gouveia Dal Pino (IAG/USP) Jose D. Muñoz (UNAL)

THE CIRCULATION DOMINATED SOLAR DYNAMO MODEL REVISITED Gustavo A. Guerrero E. (IAG/USP) Elisabete M. de Gouveia Dal Pino (IAG/USP) Jose D. Muñoz (UNAL)

Similar presentations

Ads by Google