1. 08/20031 Volcanic Ash Detection and Prediction at the Met Office Helen Champion, Sarah Watkin Derrick Ryall Responsibilities Tools Etna 2002 Future

2. 08/20032 Met Office is the London VAAC VAAC = Volcanic Ash Advisory Centre

3. 08/20033 28 October 2002 1316 UTC Satellite ash detection products AVHRR –ch4 (10.8  m) - ch5 (12.0  m) –available within 30 mins Covers three areas: –Mediterranean area (Mt. Etna) –London VAAC –Iceland Frequency –3 hourly over Iceland –6 hourly over the Mediterranean

4. 08/20034 AVHRR London VAAC (ch4 -ch5)

5. 08/20035 Met Office NAME model Dispersion model –Predicts the transport of airborne pollutants –1-1000’s km, hours - days –Lagrangian particle model Emergency response –nuclear, volcano, fire, FMD Air pollution –episodes, forecasts, chemistry Source attribution –where, when, how much –source/receptor relationships –CTBTO

6. 08/20036 Volcanic Ash Graphics Three levels –FL350-FL550 –FL200-FL350 –Surface-FL200 Source –Unit release –between summit height and plume top –assumes particle size distribution T+6,12,18,24 Extent of ‘visible’ ash cloud

7. 08/20037 Additional Volcanic Ash graphics Contoured plumes Six levels Easier comparisons with imagery / observations

8. 08/20038 Recent Improvements to NAME Automated plotting threshold for visual ash cloud concentrations –Previously manual forecaster input based on obs Upgraded to use ‘New Dynamics’ version of Unified Model –3 hourly global fields to T+144, ~60km resolution –Increased vertical resolution (particularly near tropopause) Revised boundary layer turbulence schemes

9. 08/20039 Volcanic Ash - Trajectories Also provide trajectories Follow mean wind Start at several levels Quick indication of plume spread at various levels

10. 08/200310 Iceland Daily runs Improve response times and preparedness Daily simulations using NAME Release from Katla –6 hour release –0, 6, 12 & 18Z –surface to FL400 Output on six levels

11. 08/200311 Etna eruption 2002 27 Oct 2002 Etna erupted to ~FL200 Emissions continued over several days Useful case to look at –Full range of satellite imagery –Area largely cloud free Use NAME to simulate first 10 days of emissions Continuous release from surface to FL200 Compare concentrations (FL100 & FL200) with satellite imagery, particularly ch4-ch5

12. 08/200312 Etna 28/10/2002

13. 08/200313 Etna 29/10/2002

14. 08/200314 Etna 30/10/2002

15. 08/200315 Etna 31/10/2002

16. 08/200316 Etna 29/10/2002 Coloured by height (yellow=low level, red = high level)

17. 08/200317 Effect of poorly resolved volcano Inversion below summit Plume remains in free troposphere Peak not resolved Inversion above ‘model’ summit Plume also in boundary layer Inversion ActualModel

18. 08/200318 Poorly resolved orography Particular problem with isolated peaks No simple solution as NWP data will not properly represent flow around/over peak If use ‘model’ summit height column is ‘stretched’ - material spreads over twice the height, giving lower concentrations Suggest using ‘elevated’ source

19. 08/200319 Release surface to FL200 Release FL100 to FL200 Impact of poorly resolved orography

20. 08/200320 Future Work Volcanic ash detection –SEVERI on MSG (including AVHRR ch4-ch5) –15 minute imagery Automatic detection system (Helen Watkin’s talk) –Upgrade to MSG –Operational implementation Modelling –Need better definition of ‘Visual Ash Cloud’ - more appropriate would be ’concentrations hazardous to aviation’ –Include sulphur as well as ash –Ensemble approach - multiple NAME runs on ECMWF EPS members (51)

21. 08/200321 Summary Volcanic ash detection system and NAME predictions give increased confidence in operational VAAC results Etna case study demonstrates the value of these tools Issues for future work include –calibration of satellite imagery –representation of orography / height of release –definition of hazardous ash concentrations