distribution of liquid water in orographic mixed-phase clouds

Distribution of Liquid Water in Orographic Mixed-Phase Clouds

Diana ThatcherMentor: Linnea Avallone

LASP REU 2011

Outline

• Introduction

• Experiment

• Important Instruments

• 1st Area of Interest

• 2nd Area of Interest

• Conclusion

Orographic Clouds• Formed when mountains force moist air upward• Variety of interesting structures possible

Orographic wave clouds over Long’s Peak

Mixed-Phase Clouds

• Water is present in solid, liquid, and vapor forms• Typical temperatures: 0 to –30 ºC

– Liquid is supercooled

• Formed in a variety of situations– Stratiform clouds in polar regions

– Frontal systems

– Convective cloud systems

– Orographic forcing systems

Particle Formation

• Ice particles in areas of supercooled liquid water can undergo:– Riming (growth)– Splintering (multiplication)

• Affects resulting cloud structure and precipitation

• Results depend on cloud temperature and saturation

Example of a Mixed-Phase Cloud

Importance of Study

• Past studies mainly focus on:– Arctic mixed-phase clouds– Effect of aerosols on mixed phase clouds

• More knowledge is necessary to create accurate climate models– Complex effects of topography– Microphysics of liquid and solid particle formation

• Results could aid in the prediction of icing conditions

Icing Hazards

• Supercooled liquid water < 0 ºC

• Easily freezes to outside of aircrafts– Major difficulties for pilots

Colorado Airborne Mixed-Phase Cloud Study (CAMPS)

• Includes data from instruments on University of Wyoming King Air research aircraft

– Numerous sensors

– Wyoming Cloud Radar

– Wyoming Cloud Lidar

• Provides in-situ and remote sensing for liquid water, ice crystals, and other microphysical properties

Cloud Droplet Spectra - FSSP

Forward Scattering Spectrometer Probe

• Measures particle size distributions

• Detects how a particle scatters light

• 2.0 – 47 μm

Particle Imaging Instruments2-D Cloud and Precipitation Probes

• Measures particle size distribution• Image is created from a shadow

when particle passes through a laser• Pattern recognition algorithms

deduce the shape of particle• 25 – 800 μm (2-DC)• 200 – 6400 μm (2-DP)

Icing IndicatorRosemount Icing Detector (Model 871)

• Detects supercooled liquid water

• Cylinder vibrates at frequency of 40 Hz– As ice accumulates, the frequency decreases

• Cylinder is heated to melt ice

• Process is repeated

My Area of Study• February 19th and 20th, 2011

• Area over Muddy Mountain, Wyoming

• High amounts of snowfall

Flight Path

6 levels– 3 legs each

1st Area of Interest

Features:

• Updrafts

• Small particles

• Liquid water

Radar and Lidar

Vertical Wind Velocity

Particle Size Distribution

Large Particles Small Particles

Nearly 100X decrease in mean particle diameter!

Liquid Water Content• Increase in liquid water content during updrafts,

with a slight lag of less than 1 minute

• Water droplets are much smaller than ice crystals, coinciding with particle size distribution

• Temperature: -16 °C– Icing conditions

2nd Area of Interest

• Over edge of peak

• Updrafts/Downdrafts

• Liquid Water

• Small Particles

Radar and Lidar

Vertical Wind Velocity

Particle Size and Liquid Water Content

• Increase in small particles• Increase in liquid water• Again, particle formation processes are at

work

Conclusion

In mixed-phase clouds, areas of increased liquid water content are likely to occur in areas of strong updrafts, with a slight lag between the peak velocity and peak liquid water content.

Sudden increases in liquid water content are accompanied by a drastic change in the particle size distribution, with a sharp decrease in the concentration of ice crystals and a simultaneous increase in small liquid droplets, indicating the formation of new particles.

Future Work

• Obtain particle image data– Determine ice crystal structures– Determine particle formation processes

• Expand to a greater variety of cases– Determine limits, such as temperature or vapor

saturation– Further analyze the effects of topography

Questions?

References

• Hogan, R. J., Field, P. R., Illingworth, A. J., Cotton, R. J. and Choularton, T. W. (2002), Properties of embedded convection in warm-frontal mixed-phase cloud from aircraft and polarimetric radar. Quarterly Journal of the Royal Meteorological Society, 128: 451–476. doi: 10.1256/003590002321042054

• http://www.eol.ucar.edu/raf/Bulletins/B24/fssp100.html

• http://www.eol.ucar.edu/raf/Bulletins/B24/2dProbes.html

• http://www.eol.ucar.edu/raf/Bulletins/B24/iceProbe.html

Image Sources

• http://ww2010.atmos.uiuc.edu/%28Gh%29/guides/mtr/cld/dvlp/org.rxml

• http://www.flickr.com/photos/wxguy_grant/4823374536/

• http://www.ucar.edu/news/releases/2006/icing.shtml

• http://www.askacfi.com/24/review-of-aircraft-icing-procedures.htm

• http://en.wikipedia.org/wiki/Wikipedia:Picture_of_the_day/September_26,_2006

• http://www.cas.manchester.ac.uk/resactivities/cloudphysics/results/riming/

• http://www.eol.ucar.edu/raf/Bulletins/B24/fssp100.html

• http://www.eol.ucar.edu/raf/Bulletins/B24/2dProbes.html

• http://www.eol.ucar.edu/raf/Bulletins/B24/iceProbe.html