1 / 18

Cloud Microphysics

Cloud Microphysics. Dr. Corey Potvin , CIMMS/NSSL METR 5004 Lecture #1 Oct 1, 2013. Preliminaries. Primarily following Wallace & Hobbs Chap. 6 Rogers & Yau useful as parallel text (deeper explanations) Google is your friend! Will make these slides available

vivek
Download Presentation

Cloud Microphysics

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. Cloud Microphysics Dr. Corey Potvin, CIMMS/NSSL METR 5004 Lecture #1 Oct 1, 2013

  2. Preliminaries • Primarily following Wallace & Hobbs Chap. 6 • Rogers & Yau useful as parallel text (deeper explanations) • Google is your friend! • Will make these slides available • Figures from W & H unless otherwise noted • Leaving out some important details – read book! • corey.potvin@ou.edu; office #4378 (once gov’t reopens)

  3. Warm cloud microphysics

  4. Two fundamental phenomena that warm cloud microphysics theory must explain: • Formation of cloud droplets from supersaturated vapor • Growth of cloud droplets to raindrops in O(10 min) Lyndon State College

  5. Saturation vapor pressure • Increases with temperature T (Clausius-Clapeyron) • By default, refers to vapor pressure eover planar water surface within sealed container at T at equilibrium (evaporation = condensation); denoted es • BUT can also refer to equilibrium eover cloud particle surface (e.g., ei, e’) Wikipedia

  6. Saturation vapor pressure • By default, supersaturation refers to e >es, as when rising parcel cools (esdecreases) • e >es does NOT guarantee net condensation onto cloud particles – not surprising given artificiality of es! • But, esuseful as reference point when describing (super-) saturation level of air relative to cloud droplet or ice particle Lyndon State College

  7. Homogeneous nucleation • Consider supersaturated air with no aerosols • Are chance collisions of vapor molecules likely to produce droplets large enough to survive? • Consider change in energy of system ΔE due to formation of droplet with radius R • Compute R for which ΔE ≤ 0 (lazy universe always seeks equilibrium) – growth favored • Determine whether such R occur often enough

  8. How big must embryonic droplets be for growth to be favored? • Take droplet with volume V, surface area A, and nmolecules per unit volume of liquid • Consider surface energy of droplet and energy spent for condensation: Work to create unit area of droplet surface Net change in system energy Gibbs free energies – roughly, microscopic energy of system

  9. Critical radius r • Subsaturation (e < es) dΔE/dR> 0 embryonic droplets generally evaporate (all sizes) • Supersaturation(e > es) dΔE/dR< 0 for r> R sufficiently large droplets tend to grow (energy loss from condensation > energy gain from droplet surface) • R = r: droplet in unstable equilibrium with environment – small change in size will perpetuate

  10. Kelvin’s equation & curvature effect • Solve d(ΔE)/dR= 0 to relate r, e, es: • In latter equation and hereafter, e= droplet saturation vapor pressure! Otherwise, net evaporation or condensation of droplet would occur (disequilibrium). • “Kelvin” or “curvature” effect: e > esrequired for equilibrium since less energy needed for molecules to escape curved surface • Smaller droplet  larger RH (= 100 × e/es) needed Critical radius for given ambient vapor pressure Vapor pressure required for droplet of radius rto be in unstable equilibrium

  11. Heterogeneous nucleation • Some aerosols dissolve when water condenses on them - cloud condensation nuclei (CCN) • Due to relatively low water vapor pressure of solute molecules in droplet surface, solution droplet saturation vapor pressuree’ < e • Raoult’s law for ideal solution containing single solute: saturation vapor pressure of solution = saturation vapor pressure of pure solvent, reduced by mole fraction of solvent. Thus, where fis mole faction of pure water.

  12. Computing f • Vapor condenses on CCN of mass m, molecular mass Ms, forming droplet of size r • Each CCN molecule dissociates into iions • Solution density ρ’, water molecular mass Mw • Effective # moles of dissolved CCN = im/Ms • # moles pure water =

  13. Computing f(cont.)

  14. Kohler curves • Combining curvature and solute effects, can model equilibrium conditions for range of droplet sizes: Saturation ratio for solution droplet (r*, S*) – activation radius, critical saturation ratio – spontaneous growth occurs for r> r* Rogers & Yau

  15. Stable vs. unstable equilibrium • A: rincrease  RH > equilibrium RH rincreases further; similarly for rdecrease (unstable equilibrium) • B: rincrease  RH < equilibrium RH rdecreases; similarly for rincrease (stable equilibrium) • C: as in A, but droplet activated (grows spontaneously, i.e., without further RH increases) Adapted from www.physics.nmt.edu/~raymond/classes/ph536/notes/microphys.pdf

  16. Kohler curves (cont.) (r*, S*)

  17. Kohler curves (cont.) • Slightly different perspective – assume solution droplet inserted into air with ambient S • Red curve – solution droplet grows indefinitely since droplet S < ambient S • Green curve – droplet grows until stable equilibrium point “A”

  18. Two fundamental phenomena that warm cloud microphysics theory must explain: • Formation of cloud droplets from supersaturated vapor • Growth of cloud droplets to raindrops in O(10 min)

More Related