ice giant atmospheres: clouds and dynamics · ice giant atmospheres: clouds and dynamics peter read...
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![Page 1: Ice giant atmospheres: clouds and dynamics · Ice giant atmospheres: clouds and dynamics Peter Read University of Oxford, UK . With thanks to . Leigh Fletcher, Michael Roman, Pat](https://reader035.vdocuments.us/reader035/viewer/2022081408/605fb98fe83bf326c15cc179/html5/thumbnails/1.jpg)
Ice giant atmospheres: clouds
and dynamics
Peter Read
University of Oxford, UK
With thanks to
Leigh Fletcher, Michael Roman, Pat Irwin…..
c
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Plan • Introduction
• Overview of ice giants,
• Atmospheric structure • Sources of buoyancy, radiative-convective equilibrium models, clouds and
condensibles
• Zonal mean circulation and dynamics • Simple models cf observations • Observed u, T, thermal winds and composition
• Waves and eddies • Convective storms, large vortices, large- and small-scale waves • 3D GCMs?
• Outstanding problems
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Some numbers
Uranus Neptune
Mean solar distance (AU) 19.2 30.2
Orbital eccentricity 0.046 0.009
Orbital period (yrs) 84.01 164.79
Northern summer solstice 1985.8 1913.7
Obliquity (degs) 97.77 29.32
Rotation period (hrs) 17h 14m 16h 06m
Equatorial radius (km/Earth radii) 25,559/4.01 24,764/3.88
g (m/s2) 8.87 11.15
Emission/insolation <1.06 2.52
Rossby radius of deformation (km) 3000-7000? 3000-7000?
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Atmospheric thermal structure
• Radiative-convective equilibrium • Solar heating from above • Weak internal heat from below? • Model assuming dry convective
adjustment (allowing for o-p H2 conversion)
• RCE models (Marley & McKay 1999) • Near-adiabatic deep troposphere and
~isothermal stratosphere • B assumes no aerosols and uniform CH4 • A allows for aerosol absorption & variable
CH4
• Still some disagreement in stratosphere with observations…
Uranus Neptune
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Cloud layers
• Model using equilibrium cloud condensation models • Adiabatic lifting of air parcel of
prescribed composition from deep levels up to tropopause
• Composition assumed enriched in condensables
• Multiple cloud decks • No NH3? • Probably dissolved in H2O or
combined with H2S….
• Stratospheric hazes? • Higher hydrocarbons? [C2H6, C2H2
etc.]
Uranus
Super-critical
Irwin (2009) IPPW2019 5
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Cloud layers
• Model using equilibrium cloud condensation models • Adiabatic lifting of air parcel of
prescribed composition from deep levels up to tropopause
• Composition assumed enriched in condensables
• Multiple cloud decks • No NH3? • Probably dissolved in H2O or
combined with H2S….
• Stratospheric hazes? • Higher hydrocarbons? [C2H6, C2H2
etc.]
Neptune
Super-critical
Irwin (2009) IPPW2019 6
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Incoming solar radiation
• Solar heating varies with latitude and season • Impact on zonal mean circulation?
• Depends on radiative adjustment timescale
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Radiative adjustment timescales? (1990) Li et al. (2018)
??
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Schematic annual mean circulation driven by solar heating…?
• Uranus • Neptune
SP E NP SP E NP
?? Strat. Deep trop.
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Observations: Ice Giant Winds
250 m/s prograde maxima
-50 m/s retrograde maxima
200 m/s prograde maxima
-400 m/s retrograde maxima
Neptune
Sanchez-Lavega et al. (2018)
Sromovsky et al. (2015)
Uranus How deep? • <1000km or
<3000 bars (Kaspi et al. 2013)
Conserve angular momentum from latitude where u = 0 • Uranus: u(0)~-150 m/s • Neptune: u(0)~-1200 m/s! • Implies
dynamically active eddies…?
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Linear diagnostic 2D model (Conrath et al. 1990)
or
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18.6 µm
VISIR observations in 2006
Observations: The Voyager Picture • 25-50 µm spectra (H2-He continuum)
• Uranus 1986 (left, Orton et al., 2015)
• Neptune 1989 (right, Fletcher et al., 2014)
• 80-800 mbar only:
• Mid-latitude upwelling; warm equator; warm poles.
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General Circulation of an Ice Giant - Schematic
Flasar et al., 1987
Flasar et al. (1987)
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Equator-to-Pole Contrasts: Troposphere
• Schematic doesn’t explain equator-to-pole contrasts in gaseous composition: • Methane (from near-IR
reflectivity – Karkoschka, Irwin, Sromovsky, et al.) in 1-4 bar range
• NH3/H2S (from microwave emission - Hofstadter, de Pater, et al.)
• Contrasts are likely to be at p>1 bar, potentially very deep.
Sromovsky et al. (2015)
VLA
Hofstadter et al. (2003)
De Pater et al. (2014)
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General Circulation of an Ice Giant - Schematic
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General Circulation of an Ice Giant - Schematic
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Gas Giant Prograde Jets • …Are locations of eddy
momentum flux convergence. • Balanced by Coriolis force on
meridional flow, equatorward across prograde jet.
• This is unknown for ice giants.
• Would imply jets strengthen with height in mid-troposphere. • Warm mid-latitudes and cool
equator.
Showman and de Pater 2005
Flow convergence between two cells at cloud-tops in belts
Vallis 2006
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General Circulation of an Ice Giant - Schematic
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General Circulation of an Ice Giant - Schematic
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Neptune and Uranus polar vortices?
• Neptune has hot spot over south pole
• Compact polar vortex cf Saturn
• Uranus? • Not clear….?
• Why not…?
Ephemeral dark storms & Great Dark Spot seen by Voyager 2, Karkoschka
(2011).
Neptune, 2006 VLT/VISIR 17.6 µm
(Troposphere)
Neptune, VLT/VISIR, 2008,
7.9 µm (Stratosphere)
10.0 µm
11.3 µm
12.8 µm
15.0 µm
18.0 µm
21.0 µm
12.8 µm
21.0 µm
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Voyager (1986)
Keck II telescope (Sromovsky et al. 2012))
Keck Telescope in 2014 (De Pater et al. 2015) Eddies, waves and storms: Uranus
• Major changes recently from Voyager era (1986) • Seasonal shift from
northern summer -autumn?
• Induces convection around ~1-2 bar?
HST (2018 – Amy Simon) IPPW2019 21
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Eddies, waves and storms: Uranus
Sromovsky et al. (2015)
• Polar cap (convective?) spots (cf Saturn?) • ”Scalloped” wave train just south of equator
• Equatorial Rossby waves? IPPW2019 22
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Eddies, waves and storms: Neptune
• Transient dark spots with bright companion clouds (CH4?)
• Convective streaks and spots (mainly midlatitudes)
De Pater et al. (2014)
Voyager (1989)
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Small-scale gravity waves (Neptune)
Voyager 2 (Hinson et al. 1993)
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Uranus and Neptune in GCMs? • Primitive equations
in a ‘weather layer’ (Liu & Schneider 2010)
• Realistic (sort-of!) solar and internal heating, planetary radius and rotation rates
• BUT…… • Base at only 3 bars! • “MHD” bottom drag • Earth-like obliquity…. • Relatively weak zonal
flows….
• Plenty of room for improvement!
U vorticity
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Outstanding challenges for future probes? - many uncertainties!
• Zonal winds at depth • How do they vary (in space and time)? • Roles of solar insolation vs internal heating? – radiative fluxes…?
• Global transport circulations • How to reconcile thermal and compositional variations? • Widely different patterns in stratosphere and troposphere?
• Zonal bands • How are they driven and maintained? • Role of waves and eddies – local or non-local inverse energy cascades?
Which kinds of eddy?
• Large vortices • Origin and maintenance, Life cycles? • Why only on Neptune?
• Seasonal storms • Origin and driving processes? • Moist convection? How deep?
• Small-scale processes? • Gravity waves? • Layered convection?
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