1 / 30

Scientific astrology: planetary effects on solar activity

Scientific astrology: planetary effects on solar activity. Katya Georgieva Solar-Terrestrial Influences Lab., Bulgarian Academy of Sciences In collaboration with P.A. Semi. IHY-ISWI Š ibenic, Croatia, 7-13 September 2009.

ulric
Download Presentation

Scientific astrology: planetary effects on solar activity

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Scientific astrology: planetary effects on solar activity Katya Georgieva Solar-Terrestrial Influences Lab., Bulgarian Academy of Sciences In collaboration with P.A. Semi IHY-ISWI Šibenic, Croatia, 7-13 September 2009

  2. “…the conclusion seems to be inevitable, that my conjecture that the variations of spot-frequency depend on the influences of Venus, Earth, Jupiter and Saturn, will not prove to be wholly unfounded. The prepondering planet Jupiter will in such case mainly determine the length and height of the wave of the spot-period; Saturn will cause small variations in the length and height; and finally, the earth and Venus will change the smooth wave-line into a ripped one”. Wolf (1859)

  3. Solar inertial motion about the barycenter of the solar system Tidal forces from the planets on the solar surface Two mechanisms for planetary influences on solar activity Sun’s axial rotation (or spin) changes due to changes in the Sun’s orbital revolution (speed along its orbit about the solar system barycenter) because of the varying distance from the barycenter Gravitational forces depending on the relative positions of the planets

  4. Solar inertial motion about the barycenter of the solar system Physics not clear: no mechanism to explain the exchange between rotation and revolution Tidal forces from the planets on the solar surface Forces very small: 1012 times smaller than the Sun’s own gravity; the same during Maunder minimum Problems with the two mechanisms

  5. Our approach: • Based on the solar dynamo theory, study the relation between the dynamics of the Sun and solar activity • Look for possible planetary influences that could affect solar dynamicsaspectsrelevant to solar activity • Check whether these influences indeed correlate with solar activity

  6. Basic concept • Planetary influences do NOTcause solar activity. • Solar (and stellar) magnetic activity is a natural consequence of the presence of a convective envelope • Planetary influences can only modulate solar activity

  7. The importance of a convective envelope • convection of conducting plasma  generation of dipolar magnetic field • convection + rotation  differential rotation (therefore no differential rotation in the radiative zone) • differential rotation  meridional circulation

  8. How the solar dynamo operates Poloidal to toroidal field (-effect) Dipolar, or poloidal magnetic field in sunspot min Differential rotation stretches the poloidal field in azimuthal direction at the base of the solar convective zone (~0.7 Rs)E-W (toroidal) component of the field The buoyant magnetic field tubes rise up, piercing the surface at two spots (sunspots) with opposite magnetic polarities.

  9. Toroidal to poloidal (-effect) Babkock-Leighton mechanism Coriolis force during the flux tube emergence  sunspot pairs tilted to the E-W direction Late in the sunspot cycle: leading spots diffuse across the equator  cancel with the opposite polarity leading spots in the other hemisphere. • excess trailing spots flux carried to the poles cancels the flux of the previous cycle accumulates to form the poloidal field of the next solar cyclewith the opposite polarity

  10. Differential rotation Meridional circulation Important solar dynamo parameters

  11. Role of the differential rotation • Poloidal to toroidal field (rotation at the base of the convective zone) • Bigger shear stronger toroidal field  higher sunspot number (Howe, 2005)

  12. Role of the meridional circulation:surface circulation -Toroidal to poloidal field: higher Vsurf  less time for the leading-polarity flux to diffuse across the equator  less uncanceled trailing-polarity fluxreaches the pole weaker poloidal field  lower sunspot number from it (Wang, 2004) Vsurf after sunspot max anticorrelated with the amplitude of the next sunspot max (note the reversed scale)

  13. Role of the meridional circulation:deep circulation - poloidal to toroidal field: evaluated circulation speed 2 regimes of operation (Yeates, Nandy and Mackay, 2008): Diffusion dominated (high diffusivity, low speed): higher Vdeep less time for diffusive decay of the poloidal field  more generation of toroidal field  higher sunspot number Advection dominated (low diffusivity, high speed): diffusive decay less important  higher Vdeep  less time to induct toroidal field at the tachocline  lower sunspot number • higher Vdeep = higher sunspot max • diffusion-dominated regime

  14. The sequence of relations • Good negative correlation (r=-0.75) between Vsurf and the following Vdeep possible manifestation of the Malkus-Proctor mechanism

  15. The sequence of relations • Good correlation (r=0.81) between Vdeep and the following sunspot max ( toroidal field) Indication that solar dynamo operates in diffusion dominated regime

  16. The sequence of relations NO correlation between the sunspot max ( toroidal field) and the speed of the following surface poleward circulationVdeep

  17. The sequence of relations • Vsurf  Bpol  Vdeep  Btor…and the chain breaks  Vsurf is the factor which rules the amplitude of the sunspot cycle and through its influence on Vdeep, also the period of the sunspot cycle What factor modulates Vsurf?

  18. This dynamo mechanism works without any planetsWhat if the star has a planet? The simplest case: one planet on a circular orbit in the star’s equatorial plane But we are interested in the horizontal, not in the vertical component of the tidal force In the case of the Sun, the elevation caused by all planets together is very small The elevation is due to the vertical component of the tidal force For one only planet, all vectors directed to the planet’s subpoint

  19. the case of the Sun with a number of planets The tidal forces depend on the distance and relative positions of the major tide-creating planets (Jupiter, Earth, Venus, Mercury) which change with time view from the pole (elevation)

  20. Tidal acceleration in the horizontal plane Meridional acceleration can change the meridional circulation speed ~ 10 m/s

  21. Tidal forces create acceleration in both zonal and meridional directions Zonal acceleration can change the rotation • speed ~2000 m/s • important for the magnetic field generation at the base of the convective zone (0.7 R) where: - the tidal force decreases with depth as d2 - the density is ~ gr/cm3 -both eastward and westward = 0 average over a solar rotation Meridional acceleration can change the meridional circulation • speed ~ 10 m/s • important for the magnetic field generation at the surface where: - the tidal force is maximum - the density is ~ 10-5 gr/cm3 -always equatorward

  22. evaluation of the magnitude • a = F/ • F ~ 10-10 N/kg •  ~ 10-5 gr/cm3 = 10-2 kg/m3  a ~ 10-8 m/s2 • t ~ 108 s  dVsurf ~ m/s Corresponds to the observed variation of Vsurf

  23. The average tidal force depends on the period when the surface meridional circulation carries the flux to the poles

  24. bigger meridional tidal force = higher sunspot number of the next cycle

  25. conclusion • Planetary tides modulate the long-term variations of solar activity through modulation of the speed of the large-scale surface meridional circulation • Bigger meridional tidal force = slower poleward surface circulation = higher sunspot maximum

  26. Forecast???

  27. Thanks for your attention

  28. Supporting material

  29. Estimation of the speed of the solar meridional circulation from geomagnetic data Double-peaked cycle of geomagnetic activity: one peak in sunspot max, the second one on the sunspot decline phase • The lag between the peaks has been changing in the last century (Kishcha et al., 1999; Echer et al., 2004) • Sunspot max peak – max in sporadic geomagnetic activity (solar toroidal field) • Sunspot decline phase peak – max in recurrent geomagnetic activity (solar poloidal field)

  30. Highest aa max on sunspot decline phase occurs when the trailing polarity flux has reached the pole  the time from sunspot max to aa max = the time it takes the surface meridional circulation to carry the flux from sunspot max latitudes to the pole (PINK) The time between aa max and next sunspot max = the time for the flux to sink to the base of the convective zone, to be carried by the deep meridional circulation to sunspot max latitudes and to emerge as the sunspots of the next cycle (BLUE)

More Related