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Copyright © 2010 R. R. Dickerson & Z.Q. Li 1 AOSC 620 Cloud Nucleation Russell Dickerson 2014 Rogers and Yau, Chapt. 6.

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Presentation on theme: "Copyright © 2010 R. R. Dickerson & Z.Q. Li 1 AOSC 620 Cloud Nucleation Russell Dickerson 2014 Rogers and Yau, Chapt. 6."— Presentation transcript:

1 Copyright © 2010 R. R. Dickerson & Z.Q. Li 1 AOSC 620 Cloud Nucleation Russell Dickerson 2014 Rogers and Yau, Chapt. 6

2 Copyright © 2010 R. R. Dickerson & Z.Q. Li 2

3 3 Questions on the Effects of Aerosols on Clouds and Precipitation ● Why do many people think aerosols inhibit deep convective cloud formation?

4 Copyright © 2010 R. R. Dickerson & Z.Q. Li 4 Opposing Effects of Aerosols on Clouds and Precipitation ● How do radiative and micro-physical effects of aerosols compete? How does suppression of precp change buoyancy? How does freezing change buoyancy?

5 Copyright © 2010 R. R. Dickerson & Z.Q. Li 5 Opposing Effects of Aerosols on Clouds and Precipitation ● How do radiative and micro-physical effects of aerosols compete? How does suppression of precp change buoyancy? negative impact. How does freezing change buoyancy? a) if normal precp then freezing enhances buoyancy. b) If suppressed precp (too many ccn) then freezing generates even more buoyancy.

6 Liquid Water Cloud VDR Yorks et al., 2011

7 Copyright © 2010 R. R. Dickerson & Z.Q. Li 7 Opposing Effects of aerosols on Clouds and Precipitation (Rosenfeld et al., Science 2008) Radiative Effects: ● Aerosols aloft shield the Earth’s surface from radiation and stabilize the atmosphere wrt convection and the moisture is advected away. ( Park et al., JGR, 2001; Ramanathan et al., Science, 2001 ) ● Increased numbers of CCN slow the conversion of droplets into raindrops and inhibit precipitation, but ingestion of large particles such as sea salt appears to enhance precip. ( Radke et al., Science, 1989; Rosenfeld et al., Science, 2002 ) ● Total water vapor is conserved so suppression of precip here means more rain there.

8 Copyright © 2010 R. R. Dickerson & Z.Q. Li 8 The Rain according to Rosenfeld (microphysical effects) ● The extra CCN in hazy air make for more, smaller droplets in the early stages of a convective cloud. ● The smaller droplets travel higher and more reach colder levels where they are more likely to release latent heat of freezing and increase buoyancy – haze means more instability for the same amount of rain. ● Even though aerosols slow the conversion of cloud droplets into rain drops, convection is eventually invigorated. ● With cold-based clouds (< 0 o C) most of the water is frozen already and there is no enhancement of precip.

9 Published by AAAS D. Rosenfeld et al., Science 321, 1309 -1313 (2008) Fig. 2. Evolution of deep convective clouds developing in the pristine (top) and polluted (bottom) atmosphere

10 Wet (Pseudo-Adiabatic) Parcel Theory (no mixing). ● If all the water in excess of the saturation vapor pressure immediately condenses and precipitates out, then buoyancy is zero all the way up; this is the reference for CAPE calculations. ● If all the water is held in the cloud, then buoyancy becomes more negative with altitude. ● If all the water in excess of the saturation vapor pressure immediately condenses and freezes at T < – 4 o C then buoyancy is enhanced. ● If precip is suppressed until the parcel reaches T = – 4 o C then buoyancy is enhanced further. The following figure shows an example with the LCL at 960 hPa and 22 o C.

11 Published by AAAS D. Rosenfeld et al., Science 321, 1309 -1313 (2008) Fig. 3. The buoyancy of an unmixed adiabatically raising air parcel Energy released in J kg -1. ←Cloud base no precp.  suppressed precp.   All precp frozen

12 Copyright © 2010 R. R. Dickerson & Z.Q. Li 12 Who wins – radiation or microphysics? Particles in the accumulation mode with a diameter around 500 nm are most effective at increasing AOT, but CCN can be almost any size – it is the number that matters. Does CCN correlate with AOT?

13 Published by AAAS D. Rosenfeld et al., Science 321, 1309 -1313 (2008) Fig. 1. Relations between observed aerosol optical thickness at 500 nm and CCN concentrations at supersaturation of 0.4% from studies where these variables have been measured simultaneously, or where data from nearby sites at comparable times were available

14 Who wins – radiation or microphysics? ● From this empirical relationship we can estimate the number of CCN as a function of AOT. ● If the count of CCN is 10 4 cm -3 then AOT ~ 1.0 and radiation reaching the Earth’s surface is reduced by an e-folding. ● CAPE reaches a maximum at CCN ~ 1200 cm -3 (AOT ~ 0.25) ; adding more aerosols will inhibit convection. Bell (GSFC) et al., (JGR, 2008; “Why do tornados and hailstorms rest on weekends?” 2011) showed a weekday/weekend effect.

15 Published by AAAS D. Rosenfeld et al., Science 321, 1309 -1313 (2008) Fig. 4. Illustration of the relations between the aerosol microphysical and radiative effects

16 Who wins – radiation or microphysics? ● From this empirical relationship we can estimate the number of CCN as a function of AOT. ● If the count of CCN is 10 4 cm -3 then AOT ~ 1.0 and radiation reaching the Earth’s surface is reduced by an e-folding. ● CAPE reaches a maximum at CCN ~ 1200 cm -3 (AOT ~ 0.25) ; adding more aerosols will inhibit convection. Bell (GSFC) et al., (JGR, 2008) showed a weekday/weekend effect.

17

18 From Rosenfeld and Bell, 2011

19 Copyright © 2010 R. R. Dickerson & Z.Q. Li19 Let’s get quantitative; Rogers & Yau, Chapt 6.

20 Copyright © 2010 R. R. Dickerson & Z.Q. Li 20 Phase Change & Nucleation Process (inhibited by surface tension) Liquid Condensation Vapor Evaporation Solid Deposition Sublimation Vapor Solid Freezing Melting Liquid

21 Copyright © 2010 R. R. Dickerson & Z.Q. Li 21 Condensation In theory, a cloud droplet may not be formed until pure water vapor is over saturated by a few hundreds per cent. In nature, super-saturation rate rarely exceeds a few tenths per cent. The reason lies in the presence of plentiful of water cloud nuclei.

22 Copyright © 2010 R. R. Dickerson & Z.Q. Li 22 Deposition In theory, a cloud droplet may be frozen at a temperature at 0 o C. In nature, super-cooled water droplets of temperature well below the freezing point are often observed. The reason lies in the lack of ice water cloud nuclei.

23 Copyright © 2010 R. R. Dickerson & Z.Q. Li 23 The coverage of this lecture Derivation of equilibrium water vapor pressure for a small droplet of pure water vs pure bulk water; -Homogenous nucleation Derivation of equilibrium water vapor pressure for a small droplet of solution water vs pure water. -Heterogeneous nucleation Aerosol and CCN

24 Copyright © 2010 R. R. Dickerson & Z.Q. Li 24 Questions to be addressed: 1.How is an embryonic cloud droplet formed and maintained? 2.Why do cloud droplets have a rather narrow range in size? 3.How can a cloud exist for certain period of time?

25 Copyright © 2010 R. R. Dickerson & Z.Q. Li 25 * Surface tension = work required to increase surface area by one unit. * Store potential energy. * Volume of liquid tends to assume minimum area-to-volume. * Small masses  Spherical droplets. For a droplet to form by condensation from the vapor, the surface tension, , must be overcome by a strong gradient of vapor pressure. The Clausius-Claperon equation describes the equilibrium condition for bulk water and its vapor, which does not apply to small droplet. Homogeneous Nucleation

26 Copyright © 2010 R. R. Dickerson & Z.Q. Li 26

27 Copyright © 2010 R. R. Dickerson & Z.Q. Li 27

28 Copyright © 2014 R. R. Dickerson & Z.Q. Li 28 Surface tension causes internal pressure The surface tensions for a solute is lower than that of pure water by up to one-third, which was attributed to dissolved organics or ions.

29 Copyright © 2010 R. R. Dickerson & Z.Q. Li 29 Surface energy associated with curved surface has impact on equilibrium vapor pressure and rate of evaporation. Let equilibrium vapor pressure over a flat surface be e s. And over a curved surface be e sr. Consider droplet in equilibrium with environment, temperature = T and vapor pressure = e c Derivation of the Kelvin (1870) Equation - Curvature effect on saturation

30 Copyright © 2010 R. R. Dickerson & Z.Q. Li 30

31 Copyright © 2010 R. R. Dickerson & Z.Q. Li 31

32 Copyright © 2010 R. R. Dickerson & Z.Q. Li 32 Remember dq = du + pdv

33 Copyright © 2010 R. R. Dickerson & Z.Q. Li 33

34 Copyright © 2010 R. R. Dickerson & Z.Q. Li 34

35 Copyright © 2010 R. R. Dickerson & Z.Q. Li 35 Kelvin’s Equation, R&Y Eq 6.1

36 Copyright © 2010 R. R. Dickerson & Z.Q. Li 36 The relative humidity and supersaturation (both with respect to a plane surface of pure water) for pure water droplets.

37 Copyright © 2010 R. R. Dickerson & Z.Q. Li 37 An embryonic cloud droplet (molecular cluster) can be formed by collision of water vapor molecules. Once it exists, it may grow or decay depending on ambient water vapor pressure. S = e/e s (∞). e>e sr, the droplet tends to grow, e<e sr, the droplet tends to decay. So, the droplet must be big enough for it to endure. We will show that the critical radius (S is supersaturation) is:

38 Copyright © 2010 R. R. Dickerson & Z.Q. Li 38 Köhler curve S * - critical saturation ratio r * - critical radius Haze ← → Activated nucleus Kelvin Curve 

39 Fair Weather Cumulus Fair weather cumulus 1 pm EST July 7, 2007, a smoggy day

40 1.0 0.5 0.0 MPLNET Level 1 Signals: GSFC May 3, 2001 Uncalibrated Attenuated Backscatter (km sr)-1

41 Copyright © 2010 R. R. Dickerson & Z.Q. Li 41

42 Copyright © 2010 R. R. Dickerson & Z.Q. Li 42

43 Copyright © 2010 R. R. Dickerson & Z.Q. Li 43 Köhler Equation -

44 Copyright © 2010 R. R. Dickerson & Z.Q. Li 44

45 Copyright © 2010 R. R. Dickerson & Z.Q. Li 45

46 Copyright © 2010 R. R. Dickerson & Z.Q. Li 46 M* Mole fraction of water in the solution

47 Copyright © 2010 R. R. Dickerson & Z.Q. Li 47

48 Copyright © 2010 R. R. Dickerson & Z.Q. Li 48

49 Copyright © 2010 R. R. Dickerson & Z.Q. Li 49

50 Copyright © 2010 R. R. Dickerson & Z.Q. Li 50

51 Copyright © 2010 R. R. Dickerson & Z.Q. Li 51

52 Copyright © 2010 R. R. Dickerson & Z.Q. Li 52 Kelvin Curve Köhler Curve

53 Copyright © 2010 R. R. Dickerson & Z.Q. Li 53

54 Copyright © 2010 R. R. Dickerson & Z.Q. Li 54 Theoretical computations of the growth of cloud condensation nuclei by condensation in a parcel of air rising with a speed of 60 cm s -1. A total of 500 CCN cm -3 was assumed with im/Ms values as indicated; m the mass of material dissolved in the droplet, M s the molecular weight of the material, and i its van't Hoff factor. Note how the droplets that have been activated (brown, blue and purple curves) approach a monodispersed size distribution after just 100 s.

55 Copyright © 2010 R. R. Dickerson & Z.Q. Li 55 Next lecture will show where these trends come from.

56 Copyright © 2010 R. R. Dickerson & Z.Q. Li 56

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