ENTRAINMENT and MICROPHYSICS in RICO Cu

ENTRAINMENT and MICROPHYSICS in RICO Cu Hermann Gerber NASA/GISS Workshop Sept. 2006

CLASSICAL ENTRAINMENT CONCEPT Erosion (Detrainment) Rising Toroidal Thermal Entrainment X Scorer, R.S., and F.H. Ludlam: 1953: Bubble theory of penetrative convection. Q.J. Roy. Meteor. Soc., 79, 317-341. (Blyth, A.M., et al., 1988: J. Atmos. Sci., 45, 3944-3964.) (Baker, B., A., 1992: J. Atmos. Sci., 49, 387-404.) (Damiani, et al, 2006: J. Atmos. Sci., 63, 1432-1450)

MICROPHYSICS ISSUES 1. Homogenous or inhomogeneous mixing? 2. What about entrained CCN? 4.Super-AdiabaticDrops? 3. Entrainment scales?

HOMOGENOUS MIXING INHOMOGENEOUS MIXING ADIABATIC PEAK SUPER ADIABATIC (Lasher-Trapp, S., W. Cooper, and A. Blyth, 2005: QJRMS, 195-220)

RICO FLIGHTS

CONDITIONAL SAMPLING FOR ACTIVE TURRETS VERTICAL VELOCITY IS POSITIVE (~80%) IN AREA WITHLWC TOP OF CLOUD IS VISIBLE IN FORWARD-LOOKING VIDEO CLOUD IS TRAVERSED NEAR CLOUD TOP A SINGLE TURRET IS TRAVERSED (Raga, G.B., et al, 1990: J. Atmos. Sci., 47, 338-355.)

(m)

PVM FSSP Fast FSSP

PVM

10-cm RESOLUTION (1000 Hz) LWC DATA PVM

INHOMOGENEOUS EXTREME HOMOGENEOUS c or (Brenguier, J.-L.,and F. Burnet, 1996: 12th Int. Conf. Clouds and Precip; Zurich; 67-70) (Gerber, H., et al, 2001: J. Atmos. Sci., 58, 497-503) (Burnet,F., and J.-L. Brenguier, 2006: J. Atmos. Sci., in print) (Schleuter, M.H., 2006: Master’s Thesis, U. of Utah)

(Blyth A.M., and J. Latham, 1991: J.A.S., 48, 2367-2371) (Gerber, H., et al, 2000: 13th Int.Conf. Clouds and Precip., Reno, NV, 105-108)

COMPOSITE OF 35 Cu IN

COMPOSITE FRACTIONAL ENTRAINMENT RICO, RF12 .0062 djc /dz = -e (jc- je) e = fractional entrain. j = scalar = qT e =environment c = cloud

COMPOSITE TKE DISSIPATION TKE (diss. rate) = [v’(rms)]3/L v’ = gust velocity L = penetration length = 40m TKE INHOMOGENEOUS

CLOUD EDGE 1000 Hz -60 -50 -40 -30 -20 -10 0 10 20 (Brenguier, J.-L, 1993: J. Appl. Meteor., 32, 783-793)

COMPOSITE OF ENTRAINED PARCEL LENGTH (Brenguier, J-L, and W.W. Grabowski, 1993: J. Atmos. Sci., 50, 120-136) (Kreuger, S.K., et al, 1997: J. Atmos. Sci., 54, 2697-2712)

COMPOSITE OF ENTRAINED PARCEL PENETRATION

ENTRAINMENT CONCEPT ENTRAINMENT SHEATH DILUTION DOMINATES RH HALO? VORTEX RINGS? NO HOLES SMALL PARCELS X SUPER-ADIABATIC DROPS? NEW CCN ACTIVATION

TURRET SPECTRA

THANK YOU hgerber6@comcast.net

SPARE SLIDES FOLLOW

Cu (Courtesy of Dr. Jim Hudson)

RELAXATION TIME ANALYSIS tDrop(s)= 4r2 / [4x10-10 x (1-S)] tTurb.(s) = (D2 / TKEdiss.)1/3 D = entrained parcel width (m) r = droplet radius [10--5 (m)] tDrop(s) >> 1 R = HOMOGENEOUS MIXING tTurb.(s) tDrop(s) << 1 R = INHOMOGENEOUS MIXING tTurb.(s)

RELAXATION TIME RATIO, R CLOUD #21 S .77 .99 tdrop(s) 5 100 D(m) 2 20 2 20 tturb(s) 8.5 40 8.5 40 R .59 .1212 2.5

(Damiani, R., G. Vali, and S. Haimov, 2006: J.A.S., 1432-1450)

ENTRAINMENT and MICROPHYSICS in RICO Cu

ENTRAINMENT and MICROPHYSICS in RICO Cu

Presentation Transcript

Cloud Microphysics

ENTRAINMENT and MICROPHYSICS in RICO Cu

Microphysics in mesoscale snowbands

Cloud Microphysics

Cloud Microphysics

Entrainment in stratocumulus clouds

WG3a activities in cloud microphysics and radiation

Cloud microphysics

MICROPHYSICS AND OPTICS IN TRADE-WIND CUMULUS

Cohesion, Entrainment and Task Success in Educational Dialog

LIMITS OF ENTRAINMENT

Clouds and cloud microphysics

entrainment

Chemistry, microphysics, transport

Microphysics Parameterizations

Entrainment in SDS

Ice Microphysics in CAM

Cloud Microphysics