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EART164: PLANETARY ATMOSPHERES. Francis Nimmo. Last Week – Radiative Transfer. Black body radiation, Planck function, Wien’s law Absorption, emission, opacity, optical depth Intensity, flux Radiative diffusion, convection vs. conduction Greenhouse effect Radiative time constant.
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EART164: PLANETARY ATMOSPHERES Francis Nimmo
Last Week – Radiative Transfer Black body radiation, Planck function, Wien’s law Absorption, emission, opacity, optical depth Intensity, flux Radiative diffusion, convection vs. conduction Greenhouse effect Radiative time constant
Radiative transfer equations Absorption: Optical depth: Greenhouse effect: Radiative Diffusion: Rad. time constant:
Next 2 Weeks – Dynamics • Mostly focused on large-scale, long-term patterns of motion in the atmosphere • What drives them? What do they tell us about conditions within the atmosphere? • Three main topics: • Steady flows (winds) • Boundary layers and turbulence • Waves • See Taylor chapter 8 • Wallace & Hobbs, 2006, chapter 7 also useful • Many of my derivations are going to be simplified!
Dynamics at work 13,000 km 30,000 km 24 Jupiter rotations
Other examples Saturn Venus Titan
Definitions & Reminders Ideal gas: “meridional” N y v dP = - r g dz Hydrostatic: R f E x u R is planetary radius, Rg is gas constant H is scale height “zonal/ azimuthal” “Easterly” means “flowing from the east” i.e. an westwards flow. Eastwards is always in the direction of spin
Coriolis Effect • Coriolis effect – objects moving on a rotating planet get deflected (e.g. cyclones) • Why? Angular momentum – as an object moves further away from the pole, r increases, so to conserve angular momentum w decreases (it moves backwards relative to the rotation rate) • Coriolis accel. = - 2 W x v(cross product) = 2 W v sin(f) • How important is the Coriolis effect? Deflection to right in N hemisphere f is latitude is a measure of its importance (Rossby number) e.g. Jupiter v~100 m/s, L~10,000km we get ~0.03 so important
Hadley Cells • Coriolis effect is complicated by fact that parcels of atmosphere rise and fall due to buoyancy (equator is hotter than the poles) High altitude winds Surface winds • The result is that the atmosphere is broken up into several Hadley cells (see diagram) • How many cells depends on the Rossby number (i.e. rotation rate) cold hot Fast rotator e.g. Jupiter Slow rotator e.g. Venus Med. rotator e.g. Earth Ro~0.03 (assumes v=100 m/s) Ro~50 Ro~0.1
Zonal Winds Schematic explanation for alternating wind directions. Note that this problem is not understood in detail.
Really slow rotators hot cold • Important in the upper atmosphere of Venus • Likely to be important for some exoplanets (“hot Jupiters”) – why? A sufficiently slowly rotating body will experience DTday-night > DTpole-equator In this case, you get thermal tides (day-> night)
Thermal tides • These are winds which can blow from the hot (sunlit) to the cold (shadowed) side of a planet Solar energy added = t=rotation period, R=planet radius, r=distance (AU) 4pR2CpP/g Atmospheric heat capacity = Where’s this from? Extrasolar planet (“hot Jupiter”) So the temp. change relative to background temperature Small at Venus’ surface (0.4%), larger for Mars (38%)
Governing equation • Winds are affected primarily by pressure gradients, Coriolis effect, and friction (with the surface, if present): f =2Wsin f (Units: s-1) u=zonal velocity (x-direction) v=meridional velocity (y-direction) Normally neglect planetary curvature and treat the situation as Cartesian:
Geostrophic balance • In steady state, neglecting friction we can balance pressure gradients and Coriolis: Flow is perpendicular to the pressure gradient! L L wind • The result is that winds flow along isobars and will form cyclones or anti-cyclones • What are wind speeds on Earth? • How do they change with latitude? pressure Coriolis isobars H
Rossby number • This is called the Rossby number • It tells us the importance of the Coriolis effect • For small Ro, geostrophy is a good assumption For geostrophy to apply, the first term on the LHS must be small compared to the second Assuming u~v and taking the ratio we get
Rossby deformation radius • Short distance flows travel parallel to pressure gradient • Long distance flows are curved because of the Coriolis effect (geostrophy dominates when Ro<1) • The deformation radius is the changeover distance • It controls the characteristic scale of features such as weather fronts • At its simplest, the deformation radius Rd is (why?) Taylor’s analysis on p.171 is dimensionally incorrect • Here vprop is the propagation velocity of the particular kind of feature we’re interested in • E.g. gravity waves propagate with vprop=(gH)1/2
Ekman Layers • This drag deflects the air in a near-surface layer known as the boundary layer (to the left of the predicted direction in the northern hemisphere) • The velocity is zero at the surface with drag no drag pressure Coriolis isobars H Geostrophic flow is influenced by boundaries (e.g. the ground) The ground exerts a drag on the overlying air
Ekman Spiral where W is the rotation angular frequency and n is the (effective) viscosity in m2s-1 • The wind direction and magnitude changes with altitude in an Ekman spiral: Actual flow directions Increasing altitude Expected geostrophic flow direction The effective thickness d of this layer is
Cyclostrophic balance u R • If we balance the centrifugal force against the poleward pressure gradient, we get zonal winds with speeds decreasing towards the pole: f The centrifugal force (u2/r) arises when an air packet follows a curved trajectory. This is different from the Coriolis force, which is due to moving on a rotating body. Normally we ignore the centrifugal force, but on slow rotators (e.g. Venus) it can be important E.g. zonal winds follow a curved trajectory determined by the latitude and planetary radius
“Gradient winds” • In some cases both the centrifugal (u2/r) and the Coriolis (2W x u) accelerations may be important • The combined accelerations are then balanced by the pressure gradient • Depending on the flow direction, these gradient winds can be either stronger or weaker than pure geostrophic winds Insert diagram here Wallace & Hobbs Ch. 7
Thermal winds This is not obvious. The key physical result is that the slopes of constant pressure surfaces get steeper at higher altitudes (see below) z P2 N cold Large H y P2 P1 Small H u(z) P1 hot hot cold x Example: On Earth, mid-latitude easterly winds get stronger with altitude. Why? Source of pressure gradients is temperature gradients If we combine hydrostatic equilibrium (vertical) with geostrophic equilibrium (horizontal) we get:
Mars dynamics example so u y R f Does this make sense? Latitudinal extent?Venus vs. Earth vs. Mars Combining thermal winds and angular momentum conservation (slightly different approach to Taylor) Angular momentum: zonal velocity increases polewards Thermal wind: zonal velocity increases with altitude
Key Concepts Hadley cell, zonal & meridional circulation Coriolis effect, Rossby number, deformation radius Thermal tides Geostrophic and cyclostrophic balance, gradient winds Thermal winds