Observations of volcanic ash by lidar and MODIS Robin Hogan University of Reading Last updated: 20 April 2010.

Slides:

Advertisements

Similar presentations

The University of Reading Helen Dacre The Prediction And Observation Of Volcanic Ash Clouds During The Eyjafjallajökull Eruption Helen Dacre and Alan Grant.

Advertisements

The University of Reading Helen Dacre AGU Dec 2008 Boundary Layer Ventilation by Convection and Coastal Processes Helen Dacre, Sue Gray, Stephen Belcher.

Vertical distribution of ash at source Time-height plots of mass concentration at Chilbolton. The height above the summit into which ash particles are.

Robin Hogan Alan Grant, Ewan O’Connor,

Robin Hogan, Chris Westbrook University of Reading Lin Tian NASA Goddard Space Flight Center Phil Brown Met Office Why it is important that ice particles.

Lidar observations of mixed-phase clouds Robin Hogan, Anthony Illingworth, Ewan OConnor & Mukunda Dev Behera University of Reading UK Overview Enhanced.

Robin Hogan, Chris Westbrook University of Reading, UK Alessandro Battaglia University of Leicester, UK Fast forward modelling of radar and lidar depolarization.

Ewan OConnor, Robin Hogan, Anthony Illingworth Drizzle comparisons.

Proposed new uses for the Ceilometer Network

1 Do Polluted Clouds Have Sharper Cloud Edges? Christine Chiu, Julian Mann, Robin Hogan University of Reading Alexander Marshak, Warren Wiscombe NASA Goddard.

Ewan OConnor, Robin Hogan, Anthony Illingworth, Nicolas Gaussiat Radar/lidar observations of boundary layer clouds.

Convection Initiative discussion points What info do parametrizations & 1.5-km forecasts need? –Initiation mechanism, time-resolved cell size & updraft.

Anthony Illingworth, + Robin Hogan, Ewan OConnor, U of Reading, UK and the CloudNET team (F, D, NL, S, Su). Reading: 19 Feb 08 – Meeting with Met office.

Radar/lidar observations of boundary layer clouds

Robin Hogan & Julien Delanoe

Robin Hogan Anthony Illingworth Ewan OConnor Nicolas Gaussiat Malcolm Brooks University of Reading Cloudnet products available from Chilbolton.

Robin Hogan Department of Meteorology University of Reading Cloud and Climate Studies using the Chilbolton Observatory.

Robin Hogan, Richard Allan, Nicky Chalmers, Thorwald Stein, Julien Delanoë University of Reading How accurate are the radiative properties of ice clouds.

Robin Hogan, Chris Westbrook University of Reading Lin Tian NASA Goddard Space Flight Center Phil Brown Met Office The importance of ice particle shape.

Robin Hogan & Anthony Illingworth Department of Meteorology University of Reading UK Parameterizing ice cloud inhomogeneity and the overlap of inhomogeneities.

Robin Hogan Ewan OConnor Anthony Illingworth Department of Meteorology, University of Reading UK PDFs of humidity and cloud water content from Raman lidar.

Robin Hogan Ewan OConnor Damian Wilson Malcolm Brooks Evaluation statistics of cloud fraction and water content.

Robin Hogan Ewan OConnor Anthony Illingworth Nicolas Gaussiat Malcolm Brooks Cloudnet Evaluating the clouds in European forecast models.

Application of Cloudnet data in the validation of SCIAMACHY cloud height products Ping Wang Piet Stammes KNMI, De Bilt, The Netherlands CESAR Science day,

Exploiting multiple scattering in CALIPSO measurements to retrieve liquid cloud properties Nicola Pounder, Robin Hogan, Lee Hawkness-Smith, Andrew Barrett.

A Dictionary of Aerosol Remote Sensing Terms Richard Kleidman SSAI/NASA Goddard Lorraine Remer UMBC / JCET Short.

JERAL ESTUPINAN National Weather Service, Miami, Florida DAN GREGORIA National Weather Service, Miami, Florida ROBERTO ARIAS University of Puerto Rico.

Matthew Shupe Ola Persson Paul Johnston Cassie Wheeler Michael Tjernstrom Surface-Based Remote-Sensing of Clouds during ASCOS Univ of Colorado, NOAA and.

Remote sensing of Stratocumulus using radar/lidar synergy Ewan O’Connor, Anthony Illingworth & Robin Hogan University of Reading.

Atmospheric Measurements at Capel Dewi field station Prof. Geraint Vaughan.

1 Cloud Droplet Size Retrievals from AERONET Cloud Mode Observations Christine Chiu Stefani Huang, Alexander Marshak, Tamas Várnai, Brent Holben, Warren.

Using microwave radiometer and Doppler lidar data to estimate latent heat Chris. Collier 1, Jenny Davis 1, Fay Davies 1 and Guy Pearson 1,2 1. Centre for.

Aerosols and climate Rob Wood, Atmospheric Sciences.

Initial 3D isotropic fractal field An initial fractal cloud-like field can be generated by essentially performing an inverse 3D Fourier Transform on the.

Ben Kravitz November 5, 2009 LIDAR. What is LIDAR? Stands for LIght Detection And Ranging Micropulse LASERs Measurements of (usually) backscatter from.

1 Satellite Remote Sensing of Particulate Matter Air Quality ARSET Applied Remote Sensing Education and Training A project of NASA Applied Sciences Pawan.

Direct Radiative Effect of aerosols over clouds and clear skies determined using CALIPSO and the A-Train Robert Wood with Duli Chand, Tad Anderson, Bob.

Remote-sensing of the environment (RSE) ATMOS Analysis of the Composition of Clouds with Extended Polarization Techniques L. Pfitzenmaier, H. Russchenbergs.

1 Satellite Remote Sensing of Particulate Matter Air Quality ARSET Applied Remote Sensing Education and Training A project of NASA Applied Sciences Pawan.

© Crown copyright Met Office Future Upper-Air Network Development (FUND)-Integration TECO 2008 St Petersburg Russia Catherine Gaffard, John Nash, Alec.

Gerd-Jan van Zadelhoff & Dave Donovan Comparing ice-cloud microphysical properties using Cloudnet & ARM data.

, UTC. Supercooled liquid water Moments only from „principal peak“; can change between liquid and ice peak depending on which one is.

08/20031 Volcanic Ash Detection and Prediction at the Met Office Helen Champion, Sarah Watkin Derrick Ryall Responsibilities Tools Etna 2002 Future.

The Atmosphere.

Anthony Illingworth, Robin Hogan, Ewan O’Connor, U of Reading, UK Nicolas Gaussiat Damian Wilson, Malcolm Brooks Met Office, UK Dominique Bouniol, Alain.

Observations of volcanic ash by lidar, MODIS and surface air-quality measurements Robin Hogan University of Reading Last updated: 18 April 2010.

Evaluating forecasts of the evolution of the cloudy boundary layer using radar and lidar observations Andrew Barrett, Robin Hogan and Ewan O’Connor Submitted.

RICO Modeling Studies Group interests RICO data in support of studies.

Robin Hogan Ewan O’Connor The Instrument Synergy/ Target Categorization product.

Matthew Shupe Ola Persson Paul Johnston Duane Hazen Clouds during ASCOS U. of Colorado and NOAA.

The University of Reading Helen Dacre The Eyjafjallajökull eruption: How well were the volcanic ash clouds predicted? Helen Dacre and Alan Grant Robin.

KNMI 35 GHz Cloud Radar & Cloud Classification* Henk Klein Baltink * Robin Hogan (Univ. of Reading, UK)

Cloudnet Observing Stations Instrumentation C L Wrench Cloudnet Final Symposium – 12 October 2005.

CLOUD PHYSICS LIDAR for GOES-R Matthew McGill / Goddard Space Flight Center April 8, 2015.

Retrieval of Cloud Phase and Ice Crystal Habit From Satellite Data Sally McFarlane, Roger Marchand*, and Thomas Ackerman Pacific Northwest National Laboratory.

Modelling and observations of droplet growth in clouds A Coals 1, A M Blyth 1, J-L Brenguier 2, A M Gadian 1 and W W Grabowski 3 Understanding the detailed.

Mobile Integrated Profiling System (MIPS) Observations of Boundary Layer and Water Vapor Variations around Boundaries and Storms Kevin Knupp University.

UNIVERSITY OF BASILICATA CNR-IMAA (Consiglio Nazionale delle Ricerche Istituto di Metodologie per l’Analisi Ambientale) Tito Scalo (PZ) Analysis and interpretation.

© Crown copyright Met Office Cloud observations at Cardington Simon Osborne (OBR, Cardington) OBR Conference, 11 th -13 th December 2012.

1 Judith Agnew CCLRC Rutherford Appleton Laboratory Radio Communications Research Unit UV Raman lidar Chilbolton Observatory Review April

LIDAR Ben Kravitz November 5, 2009.

Observations of the Arctic boundary layer clouds during ACSE 2014

Volcanic Ash Detection and Prediction at the Met Office

Cloud Property Retrievals over the Arctic from the NASA A-Train Satellites Aqua, CloudSat and CALIPSO Douglas Spangenberg1, Patrick Minnis2, Michele L.

Group interests RICO data required

Mike Pavolonis (NOAA/NESDIS/STAR)

CALIPSO Total Attenuated Backscatter 532 nm 7 June 2006 Volcanic plume

CALIPSO First-Light Observations – All 3 Lidar Channels

Group interests RICO data in support of studies

EART10160 data analysis lecture 2: the normal distribution and central limit theorem Dr Paul Connolly.

Presentation transcript:

Observations of volcanic ash by lidar and MODIS Robin Hogan University of Reading Last updated: 20 April 2010

Thursday 15 th, 1329 Summary from MODIS images Icelandic wind from northwest Further images: Volcanic ash

Friday 16 th, 1234 Volcano obscured by clouds Dilute volcanic ash measured over southern England and the Netherlands with lidar

Saturday 17 th, 1317 Wind at Iceland from the north Volcanic ash heading south behind a cold front Cold front Volcanic ash No depolarizing aerosol observed over Chilbolton or Cabauw

Sunday 18 th, 1222 Northerly winds weakening Is this the ash above the cloud? Weakening front Not much sign in the MODIS image, but depolarizing aerosol observed at Chilbolton and Cabauw just above the boundary layer

Monday 19 th, 1305 New ash entering a low pressure system

Observations on Friday 16 th April

16 April: 1044 UTC NASA MODIS radiometer

16 April: 1224 UTC NASA MODIS radiometer Stationary colours in the sea (sediment and algae) x Chilbolton x Cabauw Volcanic ash

Chilbolton Doppler lidar: 16 April Descending volcanic ash? Vertical velocity shows turbulence in boundary layer and also in ash layer Mixes into turbulent boundary layer Background aerosol particles in the boundary layer (0-1 km)

Chilbolton Doppler lidar: 16 April Descending volcanic ash? Mixes into turbulent boundary layer Spherical liquid droplets have very low depolarization Ash is non-spherical so strongly depolarizing Background aerosol particles in the boundary layer (0-1 km)

Aerosol optical depth: 16 April Aerosol optical depth at several wavelengths from the Chilbolton sun photometer, courtesy Charles Wrench of STFC Descending volcanic ash? Mixes into turbulent boundary layer Background aerosol particles in the boundary layer (0-1 km)

Chilbolton UV lidar: 16 April Descending volcanic ash? Mixes into turbulent boundary layer Ash is non-spherical so strongly depolarizing Background aerosol particles in the boundary layer (0-1 km) Spherical hydrated aerosol with minimal depolarization

Chilbolton lidar ceilometer: 16 April Chilbolton has three routinely operating lidars –1500 micron Doppler/polarization lidar (previous slides) –905 nm lidar ceilometer –355 nm (UV) polarization lidar (previous slide) Can use the wavelength dependence of the scattering to estimate particle size –The following slides are from Ewan OConnor and Chris Westbrook, University of Reading...

Colour ratios for each combination Less than 1 Greater than 1 Close to 1 Note contrast with ordinary boundary layer aerosol

Colour ratios: 355/905 Less than 1 Calculations for different possible refractive indices: median diameter greater than 800 microns Note contrast with ordinary boundary layer aerosol

Colour ratios: 905/1500 Greater than 1 Upper bound ~2 microns assuming not liquid water Note contrast with ordinary boundary layer aerosol Calculations for different possible refractive indices: median diameter greater than 800 microns

Colour ratios Less than 1 Greater than 1 Close to 1 Note contrast with ordinary boundary layer aerosol Suggests median diameter is between 0.8 m and 2m Further analysis will narrow this down… Upper bound ~2 microns assuming not liquid water Calculations for different possible refractive indices: median diameter greater than 800 microns

Just using two colours: 355/1500 nm Assumed ash refractive index 1.5 – 0.001i: volcanic ash is microns in diameter (similar result for more absorbing ash)

Sun photometer derived size distribution Courtesy of Charles Wrench, STFC Large-particle mode peaks at 3 microns radius: in good agreement with lidar-derived values

Surface sulphur dioxide Are the spikes due to volcanic ash? Timing is good over London but a bit late at other locations In fact, the Met Office Unified and NAME models can both reproduce this spike WITHOUT volcanic ash, implying that this is an ordinary boundary layer pollution episode! The amounts are much less that UK air quality objective (1 hr average exceeds 350 g m -3 less than 24 times per year) Mixing event at Chilbolton: 15.00, 16 th Apr

Aerosol particles (PM10s) No convincing sign of ash

Ultraviolet EZ-lidar, Cardington Bedfordshire, 16 th April This plot was produced by the University of Manchester, NCAS and FGAM.

RIVM Caeli lidar, Netherlands, 16 th April Courtesy of Arnoud Apituley RIVM Caeli lidar, Netherlands, 16 th April Courtesy of Arnoud Apituley This lidar is not operated all the time but has Raman capability Further images here: Volcanic ash just above boundary-layer

Cabauw EZ-lidar, Netherlands, 16 th April Courtesy of David Donovan, KNMI Cabauw EZ-lidar, Netherlands, 16 th April Courtesy of David Donovan, KNMI Ash appears not to mix into the boundary layer as it did over Chilbolton… As over Chilbolton, ash much more depolarizing than ordinary boundary-layer aerosol

Calipso lidar 16 th April

Simultaneous MODIS image Calipso swath Boundary-layer clouds Volcanic ash? Ash higher at leading (southern) edge, explaining the descending appearance to ground- based lidar

Observations on Saturday 17 th April

Chilbolton Doppler lidar: 17 April Further images at Normal aerosol particles in the boundary layer: no further sign of volcanic ash…

Chilbolton UV lidar, 17 April Normal aerosol particles in the boundary layer: no further sign of volcanic ash…

Observations on Sunday 18 th April

Chilbolton Doppler lidar: 18 April Is this volcanic ash? Doppler lidar shows that it sits above the turbulent boundary-layer in the morning, which is why it is not immediately entrained into the boundary layer

Aerosol optical depth at several wavelengths from the Chilbolton sun photometer, courtesy Charles Wrench of STFC Chilbolton UV lidar: 18 th April Depolarization implies it is volcanic ash Entrained into and diluted by existing boundary-layer aerosol when boundary layer grows?

Sun photometer sizes, 18 th April

Cabauw EZ-lidar, Netherlands, 18 th April Courtesy of David Donovan, KNMI Cabauw EZ-lidar, Netherlands, 18 th April Courtesy of David Donovan, KNMI Similar signature observed by UV lidar at Cabauw De Bilt radiosonde put midday boundary-layer top at ~1 km

Cabauw EZ-lidar, Netherlands, 18 th April Courtesy of David Donovan, KNMI Cabauw EZ-lidar, Netherlands, 18 th April Courtesy of David Donovan, KNMI Further images: Another layer coming in?

Observations on Monday 19 th April

Chilbolton Doppler lidar, 19 th April Deeper more dilute layer of volcanic ash above the boundary layer?

Chilbolton UV lidar, 19 th April Deeper more dilute layer of volcanic ash above the boundary layer? Weaker depolarizing signature