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Widescreen Test Pattern (16:9)

Widescreen Test Pattern (16:9). Aspect Ratio Test (Should appear circular). 4x3. 16x9. Spiral Structure in Galaxies. Suprit Singh (Talk for the course: Galactic Dynamics). 12 th March 2010. Overview. Spiral Structure Basics Lin- Shu Hypothesis Geometry The Winding Problem

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Widescreen Test Pattern (16:9)

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  1. Widescreen Test Pattern (16:9) Aspect Ratio Test (Should appear circular) 4x3 16x9

  2. Spiral Structure in Galaxies Suprit Singh (Talk for the course: Galactic Dynamics) 12th March 2010

  3. Overview • Spiral Structure Basics • Lin-Shu Hypothesis • Geometry • The Winding Problem • Pattern Speed • Wave Mechanics of Differentially rotating disks • Kinematic Density Waves • Dispersion Relation • Local Stability of Disks

  4. Spiral Structure: Basics I

  5. The Lin-Shu Hypothesis • Lin and Shu suggested that the spiral arms can be thought of in terms of density waves: compressions and rarefactions in the distribution of stars. • Coupling this with Lindblad's ideas and the hypothesis that spiral patterns are long lived lead to the Lin-Shu hypothesis that spiral structure is just a stationary density wave. • Unfortunately, Lin & Shu were only half right: spiral patterns are density waves, but they're definately not stationary!

  6. Geometry • We can characterize spiral structure in terms of rotational symmetry. If I(R,f) is the observed intensity distribution in a disk then if I(R, f+2p/m) = I(R,f) • (i.e. a rotation by 2p/m radians leaves the galaxy looking the same) then the galaxy (and spiral pattern) is said to have m-fold symmetry and m arms (m > 0). • Most galaxies have m = 2 and the predominance of two-armed galaxies is something that any good theory of spiral structure should be able to explain.

  7. The Winding Problem I • The pitch angle at some radius R is defined as the angle between a tangent to the spiral arm and the circle R = constant. • It's useful to define a function describing a mathematical curve which runs along the center of an arm. • If we have m arms we can write this as • The function f(R; t) is known as the shape function and allows us to define a radial wavenumber

  8. The Winding Problem II • The pitch angle is then and for galaxy with flat rotation curve • W(R)R = 200km/s at R = 5 kpc and after 10 Gyr the pitch angle would be 0.14. This is much smaller than any observed galaxy and is known as the winding problem.

  9. The Pattern Speed • In the Lin-Shu hypothesis, the sprial arms are a density wave pattern that rotates rigidly. We can then always move to a rotating frame with some angular frequency Wp in which the pattern remains stationary. This pattern speed is not the same as the rotational frequency of the disk. • The radius at which Wp = W (R) is known as the corotation radius. At smaller radii, W (R) > Wp . • Observationally, dust lanes are seen to lie on the inside of arms as defined by bright stars. If this reflects a time lag between the point of maximum compression of gas and the formation of stars it suggests that gas is flowing into arms from the inside. Since most arms are trailing this implies that the gas is rotating faster than the spiral pattern. Therefore, spiral patterns (at least those in grand design spirals) must be inside corotation. • Measuring the pattern speed is, in general, difficult (its a pattern, not a physical object) and relies on the assumption that there is in fact a well-defined pattern speed.

  10. Wave Mechanics of Differentially rotating disks II

  11. Kinematic Density Waves • Any particle orbitting in an axissymmetric galaxy will execute a periodic orbit with some well defined period Tr. During this time, the azimuthal angle will increase by some amount Df (not necessarily equal to 2p). • The corresponding radial and aziumthal frequencies areWr = 2p/Tr and Wf = 2p/Tf • We can consider the orbit in a frame which rotates with frequency Wp. In this frame, the azimuthal position of the particle if fp=f-Wptthen in one radial period Dfp = Df - WpTr . Choose Wp such that orbit is closed.

  12. The Lin-Shu Theory

  13. Tight Winding Approximation

  14. Potential of the Spiral Pattern I

  15. Potential of the Spiral Pattern II

  16. Dispersion Relation I

  17. Dispersion Relation II

  18. Dispersion Relation III

  19. Dispersion Relation IV

  20. Dispersion Relation V

  21. Dispersion Relation VI

  22. Lets first see why WKB works? Dispersion Relation VII (??) Not yet! Condition for ILR • Pattern rotates at constant speed: it is a growing mode of oscillations • The waves propagate in a part of the galaxy bordered by resonances and/or turning-points which deflect waves. • That part acts as a resonant cavity for waves. Waves grow in the stellar disk but saturate due to the transfer of wave energy to gas disk. • Waves grow between the Inner Lindblad Resonance and Corotational Res. • CR region acts as an amplifier of waves due to over-reflection Density waves may exist in this ‘resonant cavity’ Two ILRs, one inner and one outer One OLR.

  23. Dispersion Relation VII (Finally!!)

  24. Local Stability of Disks (Toomre)

  25. References : Binney and Tremaine. Galactic Dynamics 2nd Edition Bertin and Lin. Spiral Structure in Galaxies My friend Google for Images/Videos That’s all Folks. Thanks for your kind attention* *after a ‘Galactic’ amount of spiraling 

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