Page 1© Crown copyright 2006 Overview of VAAC Activities Claire Witham SACS Workshop 3 October 2006
Page 2© Crown copyright 2006 Outline Introduction VAAC Role Current tools London VAAC Case study Acknowledgements: Raul Romero (ICAO Secretariat), Nigel Gait (London VAAC) and Helen Champion (Met Office)
Page 3© Crown copyright 2006 Introduction
Page 4© Crown copyright 2006 Volcanic Hazards to Aircraft Volcanic clouds can contain: Rock fragments, fine particles (ash), corrosive gases (incl. SO 2 ), water vapour Ash is a major hazard to aviation: Abrasive; clogs sensors Melts in engines (melting point ~1100C) SO 2 is also a hazard: Corrosive
Page 5© Crown copyright 2006 Encounters 90+ aircraft damaged by ash clouds 7+ cases of in-flight loss of power Three 747’s have lost all engines (Indonesia 1982, Alaska 1989) Pinatubo - aircraft damaged >1000km from eruption Average 10 eruptions per year reach flight levels Economic cost estimation of US$ 250 Million between Avoidance of ash clouds only safe procedure for aircraft, but: in cloud or at night cannot be seen not visible on radar
Page 6© Crown copyright 2006 Response to Hazard To face the threat, ICAO established: Guidelines for dissemination of information on volcanic ash to pilots Contingency arrangements for diversion of aircraft Formal amendments to ICAO Annexes and PANS The ICAO Volcanic Ash Warning Study Group (VAWSG) in 1982 The International Airways Volcano Watch (IAVW) to enable: International arrangements for monitoring and providing warnings to aircraft of volcanic ash in the atmosphere
Page 7© Crown copyright 2006 History Difficulty in providing accurate info out to 12 hrs led to: Designation of VAACs, on advice from WMO SIGMET and outlook Operational procedures developed Involvement of other international organisations Establishment of IAVWOPSG (2003) Recent developments of graphical output Responsibilities outlined in Annex 3 (November 1998) Operational procedures included in the Handbook of the IAVW (Doc 9766)
Page 8© Crown copyright 2006 Structure of the IAVW Two areas of responsibility: Observing Detection of eruptions and volcanic ash by a range of sources Notification to MWOs, ACCs & VAACs Warning Volcanic ash advisories (by VAACs) Alphanumeric and graphical format SIGMETs (by MWOs) NOTAMs/ASHTAMs (by ACCs)
Page 9© Crown copyright 2006 Operational Observations Three components of observing network: Ground-based component Difficulties in receiving initial notification Air-reporting component Operating well in general Further work is necessary Space-based component Satellite data critical Scope for improvement Role for SACS
Page 10© Crown copyright 2006 VAAC Role
Page 11© Crown copyright 2006 VAAC Designation To ensure rapid warnings to aviation the IAVW set-up 9 Volcanic Ash Advisory Centres (VAACs), including London and Toulouse VAAC responsibilities to aviation users: Utilise satellite data, Pilot reports (PIREPS) etc to detect and track ash clouds Use trajectory/dispersion models to forecast ash plumes
Page 12© Crown copyright 2006 Warning component VAAC Provider States Areas of responsibility determined by the coverage of satellite information Main international airways covered first Organised tracks with adequate coverage Future coverage to protect dynamic and flexible operations. Adequate coverage with the extension of areas of responsibility of VAACs Toulouse and Washington
Page 13© Crown copyright 2006 Areas of Responsibility
Page 14© Crown copyright 2006 VAAC Role Aim is to forecast location of ‘ash cloud mass’ and issue warnings to aviation SO 2 and sulphuric acid also pose a hazard and may indicate position of dilute ash Hazard depends on Eruption rate Concentration of ash/SO 2 Particle size Moisture
Page 15© Crown copyright 2006 Advisories Information made available as text messages - Volcanic Ash Advisory Statements (VAAS) VAAS used to issue SIGMETS, NOTAMS/ASHTAMS to aviation users Contain: General info - volcano involved, summit height etc Source of information used (e.g. satellite, webcams) Description of ash cloud - density, area & height Current cloud movements and forecast Updated 6 hourly
Page 16© Crown copyright 2006 Advisories Example of Volcanic Ash Advisory Effectiveness: In general satisfactory Difficulties in some areas with absence of SIGMETs Subject: FVUK01 EGRR FVUK01 EGRR VOLCANIC ASH ADVISORY ISSUED: /0600Z VAAC: LONDON VOLCANO: GRIMSVOTN LOCATION: N6416W01716 AREA: ICELAND SUMMIT ELEVATION: 1725M ADVISORY NUMBER: 2004/03 INFORMATION SOURCE: ICELANDIC MET SERVICE AVIATION COLOUR CODE: UNKNOWN ERUPTION DETAILS: VAAC LONDON HAS RECEIVED CONFIRMED REPORTS THAT THE GRIMSVOTN VOLCANO HAS ERUPTED, ESTIMATED START /2200Z. THE ICELANDIC MET OFFICE CONFIRM THAT THE ASH CLOUD HAS REACHED FL400. OBS ASH DATE/TIME: 02/0600Z. OBS ASH CLOUD: ASH JUST SHOWING ON LATEST SATELLITE IMAGERY, APPROX 25KM WIDE FROM N6416W01716 TO N6630W01400, MOV NE AROUND 50KT. FCST ASH CLOUD + 6HR: 02/1200Z SFC/FL200 N6416W01716-N6900W01400-N7200W00500-N7200E00200-N6600W N6424W FL200/350 N6416W01716-N6930W00900-N7200E00400-N6800E01400-N6400E N6700W00300-N6416W FL350/550 N6416W01716-N7100E00100-N6800E01200-N6500E01200-N6700W N6416W FCST ASH CLOUD + 12HR: 02/1800Z
Page 17© Crown copyright 2006 Current Tools
Page 18© Crown copyright 2006 Resources Used by VAAC Forecasters Reports from Meteorological Offices and Geological Surveys Satellite imagery: visible and infrared polar & geostationary processed satellite imagery to detect ash TOMS/OMI aerosol and SO 2 Standard forecasting tools (including detailed met forecasts) PIREPS (pilot reports) Ground observations, webcams Weather radar Seismic activity Atmospheric dispersion modelling (requires input data) Forecaster experience from training, rehearsals and prior eruptions
Page 19© Crown copyright 2006 Satellite Ash Detection Products Routinely received AVHRR data are used to generate a volcanic ash product ch4 (10.8 m) - ch5 (12.0 m) available within 30 mins MSG images every 15 minutes Data covering four areas automatically generated and displayed on London VAAC internal web : Iceland and London VAAC area of responsibility (updated ~ every 3 hours) Mediterranean area (Mt. Etna) (~ every 6 hours) Central Africa Caribbean AVHRR ch4-ch5 (BT BT 12.0 ) < 0 volcanic ash AVHRR ch4-ch5 (BT BT 12.0 ) > 0 water & ice
Page 20© Crown copyright 2006 Other Products Radar data (courtesy of the Icelandic Meteorological Office) Seismic data Local observations
Page 21© Crown copyright 2006 Data Available During Eruptions All data sources have limitations… Ground/aircraft observations generally only available in daytime Data scarce for remote eruption locations Satellite ash detection hindered by cloud Weather radar data has limited range and detection capabilities Reliance on modelling when other data limited
Page 22© Crown copyright 2006 Modelling Volcanic Ash Clouds Aim is to predict location and movement of ‘visual ash cloud’ Lagrangian and Eulerian dispersion models Run on 3-D meteorology from NWP models Rapid run times Only data source that provides a forecast
Page 23© Crown copyright 2006 Prescribed Parameters The minimum parameters required to initialise VAAC models are: Eruption latitude Eruption longitude Crater height Eruption height Start-time of eruption Output is required every 6-hours for ‘visual’ volcanic ash for flight level slices: surface-FL200, FL200-FL350, FL350-FL550 and surface-FL550
Page 24© Crown copyright 2006 Model Uncertainties Unfortunately ‘visual ash’ is not defined and depends on Concentration and type of particles particle size humidity ? Even if ‘visual’ was defined in terms of a concentration, we rarely know the source term so defaults required. Validation of model output is difficult
Page 25© Crown copyright 2006 London VAAC
Page 26© Crown copyright 2006 London VAAC Operated 24-7 by forecasters at the UK Met Office (based in Exeter) Tools developed by R&D scientists at the Met Office Regular consultation between forecasters and R&D Area covered is the North Atlantic, including Iceland Busiest oceanic air traffic corridor in the world
Page 27© Crown copyright 2006 Volcanoes in London VAAC Area of strong volcanic activity - 19 volcanoes active in the last 10,000 years Approx. one eruption every 2-3 years in the area Recent major eruptions in 1996,1998, 2000, 2004 NASA aircraft damaged in 2000
Page 28© Crown copyright 2006 The NAME dispersion model Atmospheric Lagrangian particle dispersion model 3D met data from global NWP model Range: km hours-days Predicts: 3D air concentrations Extent of visual ash cloud Deposition Output: T+6,12,18, 24 Four levels
Page 29© Crown copyright 2006 Daily runs Daily simulations using NAME Improve response times and preparedness Releases from Katla and Grimsvotn 6 hour release At 0, 6, 12 & 18Z surface to FL400 Output on six levels
Page 30© Crown copyright 2006 Case Study
Page 31© Crown copyright 2006 Grimsvötn Eruption Grimsvötn, Iceland erupted on the evening of 1 Nov 2004 Broke through Vatnajokull ice cap at 22:50 <1 km long fissure Eruption column to km Ash deposited over Iceland and Scandinavia Second, low intensity, phase of eruption 3-4 Nov. Little observation data available at the time Plume on the afternoon of 2/11/04. (Image from
Page 32© Crown copyright 2006 Infrared AVHRR image from 03:45 UTC on 2/11/2004 showing the plume in the early stages of the eruption. Iceland Meteosat-8 (MSG) cloud top height image showing the large amount of cloud overlying the area on 2/11/04.
Page 33© Crown copyright 2006 Comparison of NAME to SO 2 Data Several hours after the start of the eruption SO 2 slant column data from SCIAMACHY NAME volcanic ash Surface – FL550 composite
Page 34© Crown copyright 2006 Comparison cont’d Two and a half days after the start of the eruption SO 2 slant column data from SCIAMACHY NAME volcanic ash Surface – FL550 composite
Page 35© Crown copyright 2006 Summary
Page 36© Crown copyright 2006 Summary VAACs set-up to detect, track and forecast volcanic ash clouds Satellite data is a primary source of information on plume location Previous focus has been on detecting ash Increased awareness of potential hazard from SO 2 and sulphuric acid Satellite SO 2 data for Grimsvotn and other eruptions crucial in verifying modelled long- range plume transport