InfraRed Atmospheric Sounding Interferometer (IASI)

Here, below: Introduction, Mission objectives, Heritage, Instrument description, Atmospheric composition products, More information?.

Introduction

IASI is the main payload instrument of the MetOp platform dedicated to support Numerical Weather prediction (NWP) and meteorological purposes. Besides delivering temperature and humidity data, IASI also acquires information on more than 25 other atmospheric components with high precision and is supporting the efforts of scientists monitoring Earth atmosphere composition.

The IASI instrument observes and measures twice a day the spectrum of thermal infrared radiation emitted by the Earth from a low altitude sun-synchronous polar orbit. The use of IASI data in NWP accounts for 40% of the impact of all space based observations in NWP forecasts. There are currently two IASI instruments in operation: on MetOp-A (launched 19 October 2006) and on Met-Op B (launched 17 September 2012) with the third due for launch in 2018. IASI will be followed by IASI-New Generation (NG), on-board MetOp-SG, with demonstrated performances by a factor of 2.

IASIAlcatel — IASI instrument. Copyright Alcatel Alenia Space (Source: Vandermarcq *et al.*, IASI mission implementation and status, 10th IASI conference, 2016).

Under an agreement between the French space agency “Centre National d’Etudes Spatiales” (CNES) and the European Organisation for the Exploitation of Meteorological Satellites (EUMETSAT), the former was responsible for developing the instrument and data processing software. The latter is responsible for archiving and distributing the data to the users, as well as for operating IASI itself. A technical expertise centre at CNES’s Toulouse Space Centre is tasked with monitoring the IASI system’s performance and handling any anomalies. Data are processed on the ground by Eumetsat. France is playing a pre-eminent role in the broad scientific community exploiting data from the IASI mission.

Mission objectives

The first objective of IASI is to meet the needs of the European meteorological centres and EUMETSAT. But a second major objective is also to foster the use of the data for climate (green-house gases and clouds mainly) and air quality monitoring by supporting research experts and activities in these areas.

The IASI measurements were then designed to be compatible in terms of sampling, resolution, accuracy and overall performances with the mission objectives of providing information on:

Temperature and water vapour information for Numerical Weather Prediction (NWP) models and climate research
Atmospheric composition through critical species including O3 – Ozone and other key trace gases
Surface, aerosol and cloud characteristics and green-house gases for climate purpose

Heritage

Data from polar orbiting satellites have been made freely available to the worldwide meteorological community by the USA for more than thirty years and on a fully operational basis for nearly two decades. Before 2000, the National Oceanic and Atmospheric Administration (NOAA) was responsible for the related satellite programmes by supporting two meteorological missions, one in a morning, the other in an afternoon orbit. NOAA indicated then that it would not be able to maintain the two satellite system – which is considered as the minimum for meteorological applications – beyond the year 2000.

Following discussions between the European Organisation for the Exploitation of Meteorological Satellites (EUMETSAT) and NOAA about future cooperation regarding operational meteorological satellites, it has been agreed that EUMETSAT will take over the provision and operation of the Metop series of satellites in a morning orbit while NOAA would continue to provide and operate satellites in an afternoon orbit.

The operational NOAA High Resolution Infrared Radiation Sounder (HIRS) offered a spectral resolution of about 10 cm^-1 and an accuracy of around 2.5 Kelvin for temperature and 40% for humidity.

The IASI project was identified as a priority by CNES during the Scientific Prospective Seminar in cap d’Agde (France) in 1989. EUMETSAT issued the requirements for an operational interferometer thermal infrared sounder in 1991. The related phase B started in 1996, and phases C/D in 1998. The IASI Science Plan has been prepared by members of the IASI Sounding Science Working Group, (ISSWG), a group established by CNES and EUMETSAT in 1995 with the objective of providing the scientific preparation for the IASI mission, under the coordination of its chairmen.

Instrument description

Built by Thales Alenia Space with technical oversight from CNES, IASI comprises two main elements: a spectrometer designed to resolve atmospheric infrared radiation into line spectra, and an imager to locate points to be sounded. The sophisticated nadir-viewing spectrometer is a Fourier Transform Spectrometer (FTS) based on a Michelson Interferometer coupled to an integrated imaging system. The optical interferometry process offers fine spectral samplings of the atmosphere in the infrared band between wavelengths of 3.4 and 15.5 um (from 645 to 2760 cm⁻¹) at 0.25 cm⁻¹ resolution (0.5 cm⁻¹ after apodisation). It has 8461 spectral samples that are aligned in 3 bands within the spectral range.

With a swath width on the Earth’s surface of about 2000 kilometres, global coverage is achieved in 12 hours. For optimum operation, the IASI measurement cycle is synchronised with the American AMSU (Advanced Microwave Sounding Unit) instruments. The elementary (or effective) field of view (EFOV) is defined as the useful field of view at each scan position. Each such element consists of a 2×2 circular pixel matrix of what is called instantaneous fields of view (IFOV). Each of the four pixels projected on the ground is circular and has a diameter of 12 km at nadir. The shape of the IFOV at the edge of the scan line is no longer circular: across track, it measures 39 km and along track, 20 km

IASI field of view, showing the angular range and steps, as well as the flight direction. Credit photo CNES (Source: https://www.eumetsat.int/website/home/Satellites/CurrentSatellites/Metop/MetopDesign/IASI/index.html).

Atmospheric composition products

The IASI products cover a broad range of applications. The temperature in the troposphere and lower stratosphere is retrieved under cloud-free conditions with a vertical resolution of 1 km in the lower troposphere; a horizontal resolution of 25 km, and an accuracy of 1 kelvin. The humidity of the troposphere is derived under cloud-free conditions, with a vertical resolution of 1–2 km in the lower troposphere; a horizontal resolution of 25 km, with an accuracy of 10%.

IASITemp — The sophisticated IASI instrument measures infrared radiation emitted from the surface of the Earth to derive atmospheric temperature and humidity profiles of unprecedented
accuracy and vertical resolution. The high resolution means that small concentrations of atmospheric gases can also be measured (Source: https://www.eumetsat.int/website/home/Satellites/CurrentSatellites/Metop/MetopDesign/IASI/index.html).

Other products include about 20 types of gases detected, some well quantified (O3 – Ozone, CO – Carbon monoxide, CH4 – Methane), some mostly detected (SO2 – Sulphur dioxide, HNO3, NH3 – Ammoniac). O3 – Ozone total column is retrieved under cloud-free conditions from the absorption ν₂ around 9.6 μm with an accuracy of 5%.

Near-real time of CO – Carbon monoxide is available from the EUMETSAT Atmospheric Composition (AC) Satellite Application Facilities (SAF). The Fast Optimal Retrievals on Layers for IASI (FORLI) is the dedicated algorithm developed at the Université Libre de Bruxelles (ULB) in collaboration with LATMOS.

IASICO — 8-year IASI CO – Carbon monoxide (2008-2015) by day and by night. Copyright Universite Libre de Bruxelles (ULB) (Source: George *et al.*, CO monitoring with IASI: global and local variability, 10th IASI conference, 2016).

The green-house gases CO2 – Carbon dioxide and CH4 – Methane are generally retrieved from IASI with a sensitivity in the mid-troposphere depending on the temperature contrast.

: Global monthly averaged (daytime) column average CH4 – Methane distribution for October 2015 as retrieved by RAL’s IASI methane scheme using the thermal infrared (7.9 micron) band. Copyright RAL Space IASI CH4 – Methane Processor (Source: https://www.ralspace.stfc.ac.uk//Pages/RAL-IASI-Methane-Processor.aspx).

Researchers also work on characterizing particles such as dust and ashes from IASI spectra.

IASIDust — Aerosol Optical Depth (AOD) (10 µm) from IASI over West Africa on the 22 (morning) June 2011. Copyright: Atmospheric Radiation Analysis – Laboratoire Meteorologie Dynamique/CNRS/IPSL. Winds at 925 hPa from ECMWF (Reading, UK) analyses (Source: http://ara.abct.lmd.polytechnique.fr/index.php?page=aerosols).

IASI also delivers the fractional cloud cover and cloud top temperature and pressure, and surface temperature (also called skin temperature).

More information?

IASI mission by the French space agency CNES here
EUMETSAT IASI page here
C. Camy-Peyret & John Eyre, IASI Science Plan, A Report From The IASI Sounding Science Working Group, 1998 here
EUMETSAT AC SAF: near real-time IASI CO – Carbon monoxide here
RAL Space IASI CH4 – Methane data here
IASI products delivered by the office of satellite and product operations of NOAA here
Casoli et al., 2016: F. Casoli, C. Deniel, C. Clerbaux, A. Deschamps, C. Crevoisier, and P. Tabary, IASI: Summary of a success story and perspectives, 10th IASI conference, 2016 here
George et al., 2016: M. George, J. Hadji-Lazaro, D. Hurtmans, S. Bauduin, S. Whitburn, I. Bouarar, A. Inness, and P.-F. Coheur, CO monitoring with IASI: global and local variability, 10th IASI conference, 2016 here
Vandermarcq et al., 2016: O. Vandermarcq, L. Buffet, E. Jacquette, D. Jouglet, C. Maraldi, D. Coppens, D. Klaes, IASI mission implementation and status, 10th IASI conference, 2016 here
Daily dust aerosol properties (AOD and altitude) from infrared sounders. Application to IASI from July 2007 to day-1, by Atmospheric Radiation Analysis – Laboratoire Meteorologie Dynamique/CNRS/IPSL, here