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Robin Hogan, Chris Westbrook

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We propose ice is modelled as oblate spheroids rather than spheres ... Solid-ice oblate spheroid. Sphere: 30 ... This supports the model of oblate spheroids ... – PowerPoint PPT presentation

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Title: Robin Hogan, Chris Westbrook


1
The importance of ice particle shape and
orientation for spaceborne radar retrievals
  • Robin Hogan, Chris Westbrook
  • University of Reading
  • Lin Tian
  • NASA Goddard Space Flight Center
  • Phil Brown
  • Met Office

2
Introduction and overview
  • To interpret 94-GHz radar reflectivity in ice
    clouds we need
  • Particle mass Rayleigh scattering up to 0.5
    microns Z?? mass2
  • Particle shape non-Rayleigh scattering above
    0.5 microns, Z also depends on the dimension of
    the particle in the direction of propagation of
    the radiation
  • Traditional approach
  • Ice particles scatter as spheres (use Mie theory)
  • Diameter equal to the maximum dimension of the
    true particle
  • Refractive index of a homogeneous mixture of ice
    and air
  • New observations to test and improve this
    assumption
  • Dual-wavelength radar and simultaneous in-situ
    measurements
  • Differential reflectivity and simultaneous
    in-situ measurements
  • Consequences
  • Up to 5-dB error in interpretted reflectivity
  • Up to a factor of 5 overestimate in the IWC of
    the thickest clouds

3
Dual-wavelength ratio comparison
10 GHz, 3 cm
10 GHz, 3 cm
94 GHz, 3.2 mm
94 GHz, 3.2 mm
Difference
  • NASA ER-2 aircraft in tropical cirrus

4
Characterizing particle size
  • An image measured by aircraft can be approximated
    by a...
  • Sphere (but which diameter do we use?)
    Spheroid (oblate or prolate?)

Note Dmax ? Dlong Dmean(DlongDshort)/2
5
Error 1 Rayleigh Z overestimate
  • Brown and Francis (1995) proposed masskg0.0185
    Dmeanm1.9
  • Appropriate for aggregates which dominate most
    ice clouds
  • Rayleigh reflectivity Z ? mass2
  • Good agreement between simultaneous aircraft
    measurements of Z found by Hogan et al (2006)
  • But most aircraft data world-wide characterized
    by maximum particle dimension Dmax
  • This particle has Dmax 1.24 Dmean
  • If Dmax used in Brown and Francis relationship,
    mass will be 50 too high
  • Z will be too high by 126 or 3.6 dB
  • Explains large part of ER-2 discrepancy

6
Particle shape
Randomly oriented in aircraft probe
  • We propose ice is modelled as oblate spheroids
    rather than spheres
  • Korolev and Isaac (2003) found typical aspect
    ratio a Dshort/Dlong of 0.6-0.65
  • Aggregate modelling by Westbrook et al. (2004)
    found a value of 0.65

Horizontally oriented in free fall
7
Error 2 Non-Rayleigh overestimate
Spheroid
Sphere
8
Independent verification Z dr
  • A scanning polarized radar measures differential
    reflectivity, defined as Zdr 10log10(Zh/Zv)

Dshort/Dlong
Solid-ice oblate spheroid
Dependent on both aspect ratio and density (or
ice fraction) If ice particles were spherical,
Zdr would be zero!
Solid-ice sphere
Sphere 30 ice, 70 air
9
Chilbolton 10-cm radar UK aircraft
  • Reflectivity agrees well, provided Brown
    Francis mass used with Dmean
  • Differential reflectivity agrees reasonably well
    for oblate spheroids

10
Z dr statistics
  • One month of data from a 35-GHz (8-mm wavelength)
    radar at 45 elevation
  • Around 75 of ice clouds sampled have Zdrlt 1 dB,
    and even more for clouds colder than -15C
  • This supports the model of oblate spheroids
  • For clouds warmer than -15C, much higher Zdr is
    possible
  • Case studies suggest that this is due to
    high-density pristine plates and dendrites in
    mixed-phase conditions (Hogan et al. 2002, 2003
    Field et al. 2004)

11
Consequences for IWC retrievals
  • Empirical formulas derived from aircraft will be
    affected, as well as any algorithm using radar

Raw aircraft data
Empirical IWC(Z,T) fit
Spheres with D Dmax Hogan et al. (2006) fit New
spheroids
Note the mass of the particles in these three
examples are the same
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