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Deep convection --- transition and tails
J. David Neelin1,2,
Katrina Hales1, Ole Peters1,5, Ben Lintner1,2,7,
Baijun Tian1,4, Chris Holloway3, Rich Neale10, Qinbin Li1,
Li Zhang1, Sam Stechmann6, Prabir Patra8, Mous Chahine9
1Dept.
of Atmospheric Sciences & 2Inst. of Geophysics and Planetary Physics, UCLA
3University of Reading
4Joint Institute for Regional Earth System Science and Engineering, UCLA
5Imperial College, Grantham Inst.
6Dept. Of Mathematics, UCLA
7Dept. of Environmental Sciences, Rutgers
8Frontier Research Center for Global Change, Japan
9Jet Propulsion Laboratory
10National Center for Atmospheric Research
• Characterizing transition to deep convection
• Long tails in distributions of column tracers
2. Transition to strong convection
• Convective quasi-equilibrium assumptions: Above onset threshold,
convection/precip. increase keeps system close to onset Arakawa &
Schubert 1974; Betts & Miller 1986; Moorthi & Suarez 1992; Randall & Pan 1993; Zhang &
McFarlane 1995; Emanuel 1993; Emanuel et al 1994; Bretherton et al. 2004; …
• Pick up a function of buoyancy-related fields – temperature T &
moisture (here column integrated moisture w)
• Elsewhere: Onset of strong convection conforms to list of
properties for continuous phase transition with critical
phenomena (Peters & Neelin 2006, Nature Physics); mesoscale implications
(Peters, Neelin & Nesbitt 2009, JAS)
• Stochastic convective schemes (and old-fashioned schemes too)
need to better characterize the transition to deep convection
Transition to strong, deep convection: Background
• Precip increases with column water vapor at monthly, daily
time scales (e.g., Bretherton et al 2004). What happens at shorter
time scales needed for stochastic convective parameterization,
and for strong precip/mesoscale events?
• Simple e.g. of convective closure (Betts-Miller 1996) shown for
vertical integral:
Precip = (w - wc( T) + x)/tc
(if positive, zero otherwise)
w vertical integrated column water vapor
wc convective threshold, dependent on temperature T
tc time scale of convective adjustment
Stochastic modification x ( Lin &Neelin, 2000)
Precip. dependence on tropospheric temperature &
column water vapor from TMI*
•Averages
conditioned on
vert. avg. temp.
^
T, as well as w
E. Pacific
(T 200-1000mb from
ERA40 reanalysis)
•Power law fits
above critical:
P(w)=a(w-wc)b
wc changes,
same b
•[note more data
points at 270, 271]
*TMI: Tropical Rainfall Measuring Mission Microwave Imager (Hilburn and Wentz 2008),
20N-20S
Neelin, Peters & Hales, 2009, JAS
Collapsed statistics for observed precipitation
• Precip. mean & variance dependence on w normalized by
critical value wc; occurrence probability for precipitating
points (for 4 T values); Event size distribution at Nauru
Neelin, Peters, Lin, Holloway & Hales, Phil Trans. Roy. Soc. A, 2008
Example from Manna (1991) lattice model
(hopping particles—not a model of convection! 20x20 grid shown)
• Activity (order parameter) & variance dependence on
particle density (tuning parameter) [conserving case]
• Occurrence probability (log scale; very Gaussian) & event
size distribution [self organizing case]
Neelin, Peters, Lin, Holloway & Hales, Phil Trans. Roy. Soc. A, 2008
TMI precipitation and column water vapor spatial
correlations
TMI-AMSRE precipitation and column water vapor
temporal correlations
Entraining convective available potential energy and
precipitation binned by column water vapor, w
• buoyancy & precip.
pickup at high w
•boundary layer and
lower free troposph.
moisture contribute
comparably*
•consistent with importance
of lower free tropospheric
moisture (Austin 1948;
Yoneyama and Fujitani 1995; Wei
et al. 1998; Raymond et al. 1998;
Sherwood 1999; Parsons et al.
2000; Raymond 2000; Tompkins
2001; Redelsperger et al. 2002;
Derbyshire et al. 2004; Sobel et al.
2004; Tian et al. 2006)
*Brown & Zhang 1997 entrainment; scheme and microphysics
affect onset value, though not ordering. Holloway & Neelin, JAS,
2009
Neelin, Peters, Lin, Holloway & Hales, Phil Trans. Roy. Soc. A, 2008
Obs. Freq. of occurrence of w/wc (precipitating pts)
Eastern Pacific for various tropospheric temperatures
•Peak just below critical pt.  self-organization toward wc
•But exponential tail above critical pt.  more large events
• with Gaussian core, akin to forced tracer advection- diffusion problems
(e.g. Shraiman & Siggia 1994, Pierrehumbert 2000, Bourlioux & Majda 2002)
Gaussian core
Critical
Exponential tail
Passive tracer advection-diffusion---probability
density function from simple flow configuration
“Vertical” flow (across gradient) const in vertical, sinusoidal in horizontal,
Gaussian in time; horizontal flow constant in space, sinusoid in time
Varying
Peclet
number
Pe=
S. Stechmann following methods of Bourlioux & Majda 2002 Phys. Fluids
Passive tracer advection-diffusion---probability
density function from simple flow configuration
“Vertical” flow (across gradient) const in vertical, sinusoidal in horizontal,
Gaussian in time; horizontal flow constant in space, sinusoid in time
Varying
autocorrelation-time
t´jof flow
High Peclet number
(low diffusivity)
Pe=104
Adapted from Bourlioux & Majda 2002 Phys. Fluids
TMI probability density function for observed
column water vapor
Anomalies relative to monthly mean, tropical oceans 20S-20N
~exponential
on high side
Gaussian core
(fit at half power)
Analysis: Baijun Tian
NCEP reanalysis daily column water vapor
probability density function
• Anomalies relative to 30-day running mean
• Asymmetric exponential tails, assoc. with ascent/descent
• Low precip.: symmetric exponential tails
Analysis:
Ben Lintner
Distribution of Column-int. MOPITT CO obs. &
GEOS-Chem simulations 20S-20N & subregions
2000-2005
2001-2006
~exponential
tails
Analysis: B. Tian, Q. Li, L. Zhang
Distribution of daily CO2 anomalies
• AIRS retrievals
(Chahine et al 2005, 2008)
(Analysis: Ben Lintner)
• GEOS-Chem
simulations
projected on AIRS
weighting functions
(Analysis: Qinbin Li, Li Zhang)
Summary
• These statistics for precipitation and buoyancy related
variables at short time scales provide promising means to
quantify the transition to tropical deep convection --- collapse
of dependences on temperature and water vapor to simple
forms is handy; properties known to appear together in much
simpler systems--- it should be possible to capture these in
stochastic convection schemes
• Tracer distributions consistent with simple prototypes; core
with stretched exponential tails ubiquitous for various tracers
• Corroborating evidence that the forced tracer advection
problem, with the leading effect due to maintained vertical
gradient, creates the long tails above critical in column water
vapor--- TBD: implications for extreme events