Dynamo theory and magneto-rotational instability
19
Dynamo theory and Dynamo theory and magneto-rotational magneto-rotational instability instability Axel Brandenburg (Nordita) seed field primordial (decay) diagnostic interest (CMB) AGN outflows MRI driven galactic LS dynamo helicity losses
-
Upload
maite-hamilton -
Category
Documents
-
view
22 -
download
3
description
Dynamo theory and magneto-rotational instability. diagnostic interest (CMB). primordial (decay). seed field. Axel Brandenburg (Nordita). AGN outflows MRI driven. galactic LS dynamo. helicity losses. The primordial alternative: Decay of field growth of scale. - PowerPoint PPT Presentation
Transcript of Dynamo theory and magneto-rotational instability
Dynamo theory and Dynamo theory and magneto-rotational instabilitymagneto-rotational instability
Axel Brandenburg (Nordita)
seedfield
primordial (decay)
diagnostic interest (CMB)
AGN outflows MRI driven
galacticLS dynamo
helicity losses
2
The primordial alternative:The primordial alternative:Decay of field Decay of field growth of scale growth of scale
• Starting point: EW phase transition t=10-10 s, B=1024 G
• Horizon scale very short: ~ 3 cm
• With cosmological expansion: ~ 1 AU
• Can field grow to larger scales?
3
Inverse cascade of magnetic helicityInverse cascade of magnetic helicity
kqp EEE |||||| kqp HHH and
||2 pp HpE ||2 qq HqE Initial components fully helical: and
||||||2|||| qpkkqp HHkHkEHqHp
),max(||||
||||qp
HH
HqHpk
qp
qp
argument due to Frisch et al. (1975)
k is forcedto the left
4
3-D simulations3-D simulations
Initial slope E~k4
Christensson et al.(2001, PRE 64, 056405)
helical vsnonhelical
5
Helical decay law:Helical decay law:Biskamp & MBiskamp & Müüller (1999)ller (1999)
constELH
LELU // 2/33 tE d/d
HELEtE //d/d 2/52/3 3/2 tE
6
Revised helical decay lawRevised helical decay law
HkH H22
sI tHE 22/1/||
H not exactly constant
rHH ttkk 00 /Assume power law
H follows power law iff r=1/2; thenstH 2
2diff
20
20 / HHH tktks
M. Christensson, M. Hindmarsh, A. Brandenburg: 2005, AN 326, 393M. Christensson, M. Hindmarsh, A. Brandenburg: 2005, AN 326, 393
7
All length scales scale similarlyAll length scales scale similarlyintegral scalehel. scale|H|/M
M/|C|
HHttR /)( EEttQ /)(
should be s should be ½+2s
stE 22/1 m/25 Rs
ss is correction is correctionfor finite Rfor finite Rmm
s
R Q
1/Rm
seedfield
primordial (decay)
diagnostic interest (CMB)
AGN outflows MRI driven
galacticLS dynamo
helicity losses
weak by comparison
Accretion discsCorona heated by MRIOutflow (+also magn tower)
9
Alfven and slow magnetosonic wavesAlfven and slow magnetosonic wavescoupled to rotation and shearcoupled to rotation and shear
xyzy
xzx
yzxx
xzyx
bquBb
uBb
bBuqu
bBuu
'0
'0
'0
'0
2
2
0222 22A
2A
22A
24 qq
kvAA
Vertical field B0
Dispersion relation
Alfven frequency:
qrr )(
effect ofrotation,
effect ofshear: q
10
March 23, 1965: Gemini 3March 23, 1965: Gemini 3Gus Grissom & John Young: docking with Agena space craft
jiii Kr
GM
i
rrrr 3
22K
22A 2 q
232 p
Space craft experiment
MRI (Balbus & Hawley 1991)
Tidal disruption of a starAnalogies:
11
Nonlinear shearing sheet simulationsNonlinear shearing sheet simulationsDynamo makes its own turbulence
5123 resolution
divergentspectrum
12
Vertical stratificationVertical stratification
Brandenburg et al. (1996)
const turb ss cHc
HczHc ss )(turb z-dependence of
13
Heating near disc boundaryHeating near disc boundary
Turner (2004)
radp
radp
gasp
2
2...J
u
t
Tcv
022 / Bu
weak z-dependence of energy density
0/ BJ where
14
Alternative: Magnetisation from quasars?Alternative: Magnetisation from quasars?
10,000 galaxies for 1 Gyr, 1044 erg/s each
G182
tV
cMN
F
FB sw
kin
poyntrms
Similar figure also for outflows from protostellar disc
B. von Rekowski, A. Brandenburg, W. Dobler,B. von Rekowski, A. Brandenburg, W. Dobler,
A. Shukurov, 2003 A. Shukurov, 2003 A&A A&A 398398, , 825-844825-844
Poynting flux
205.0 scM
seedfield
primordial (decay)
diagnostic interest (CMB)
AGN outflows MRI driven
galacticLS dynamo
helicity losses
weak by comparison
Dynamo saturationRm dependent??Helicity losses essential
16
Close boxClose box, no shear, no shear: resistively limited saturation: resistively limited saturation
Significant fieldalready after
kinematicgrowth phase
followed byslow resistive
adjustment
0 bjBJ
0 baBA
0221 f
bB kk
021211 f
bB kkBlackman & Brandenburg (2002, ApJ 579, 397)
Brandenburg & SubramanianPhys. Rep. (2005, 417, 1-209)
17
Connection with Connection with effect: effect: writhe with writhe with internalinternal twist as by-product twist as by-product
clockwise tilt(right handed)
left handedinternal twist
Yousef & BrandenburgA&A 407, 7 (2003)
031 / bjuω both for thermal/magnetic
buoyancy
Helicity fluxes in the presence of shearHelicity fluxes in the presence of shear
geometryhere relevantto the sun
Mean field withno helicity, e.g.
Mean field:azimuthalaverage
...
JWB t
Rogachevskii & Kleeorin (2003)
UW
kjikji BBu 4 ,C F
Vishniac & Cho (2001, ApJ 550, 752)Subramanian & Brandenburg (2004, PRL 93, 20500)
19
ConclusionsConclusions
• Primordial: B2~t-1/2 (if fully helical), not B2~t-2/3 • Outflows: via MRI-heated corona• Dynamo: j.b saturation
– even for WxJ effect– (only shear, no stratification)
• Helical outflows necessary• Possible for shear flow
1046 Mx2/cycle(for the sun)
