• SpaceX to launch EarthCARE climate research satellite for ESA and JAXA

    From NasaSpaceFlight@1337:1/100 to All on Tuesday, May 28, 2024 21:15:05
    SpaceX to launch EarthCARE climate research satellite for ESA and JAXA

    Date:
    Tue, 28 May 2024 20:10:44 +0000

    Description:
    The joint European-Japanese EarthCARE satellite will begin its mission to improve our understanding of Earths The post SpaceX to launch EarthCARE climate research satellite for ESA and JAXA appeared first on NASASpaceFlight.com .

    FULL STORY ======================================================================

    The joint European-Japanese EarthCARE satellite will begin its mission to improve our understanding of Earths climate Tuesday, with a launch atop a SpaceX Falcon 9 rocket. Liftoff from Space Launch Complex 4E at Vandenberg Space Force Base in California is scheduled for 3:20 PM Pacific Time (22:20 UTC).

    The Earth Cloud, Aerosol and Radiation Explorer (EarthCARE) is a joint
    project between the European Space Agency (ESA) and Japan Aerospace Exploration Agency (JAXA), and the sixth Earth Explorer mission to be
    launched as part of ESAs Living Planet Programme. The satellite, which has also been named Hakuryu or White Dragon by JAXA, carries four instruments that will study clouds and aerosols fine particles and liquid droplets suspended in Earths atmosphere and how these affect the planets climate.



    By bringing a suite of different instruments together on one satellite, EarthCARE will be able to take different types of measurements that will complement each other, allowing scientists to build a better understanding of how clouds and atmospheric aerosols interact with solar radiation and how
    this affects the planets radiation balance the difference between the energy that the Earth gains from the Sun and what it radiates into space.

    Scientists have known for a long time that clouds have an impact on Earths radiation balance, both in terms of reflecting sunlight back into space and
    in absorbing heat that would otherwise have been radiated into space. The height and structure of the cloud, its water content, and the presence of different types of aerosol can alter the way in which it interacts with this system. By building a complete picture of the internal structure of clouds, EarthCARE will help to refine models used to predict changes in Earths climate.



    The 2,200 kg EarthCARE satellite was developed by a multi-national
    consortium, with Airbus Defence and Space serving as its prime contractor. Power for the mission will be generated by a single deployable solar array, which is 11 m in length. The satellite is expected to operate for at least three years in a circular Sun-synchronous orbit at an altitude of 393 km and at an inclination of 97 degrees. See Also EarthCARE Updates SpaceX Missions Section L2 SpaceX Section Click here to Join L2

    Development of the satellite began in 2008, with the signing of a contract between ESA and Astrium Satellites, which became part of Airbus in 2013. The four instruments were built separately before being shipped for integration with the rest of the spacecraft. Testing was carried out at the European
    Space Research and Technology Centre in the Netherlands, before final checkouts at Airbuss facility in Friedrichshafen, Germany. In March 2024, the satellite was shipped to the launch site.

    EarthCAREs four instruments consist of an atmospheric LIDAR (ATLID), a cloud profiling radar (CPR), a multispectral imager (MSI), and a broadband radiometer (BBR). Atmospheric LIDAR (light detection and ranging) is used to measure the altitudes of cloud tops and aerosols. The instrument uses a
    laser, which emits 26-nanosecond ultraviolet pulses at a wavelength of 355
    nm, and a 62 cm telescope as a receiver. Pulses from the laser will be transmitted into the atmosphere, where they will be scattered by particles
    and water molecules. Some of this will be reflected back towards the
    receiver, with the round-trip time used to calculate the altitude at which scattering occurred. Comparing the wavelength of the scattered light to the emitted light will also help to determine the type of scattering that
    occurred and, therefore, infer the type of particle that caused it to be scattered.

    The ATLID instrument aboard EarthCARE was built by Airbus and has a mass of about 500 kg.

    CPR will allow EarthCARE to penetrate clouds, collecting data on their vertical structure. This instrument is a major part of JAXAs contribution to the mission and was built by Japans NEC Corporation. CPR will use millimeter-wave Doppler radar, broadcasting 3.3 microsecond pulses at a frequency of 94 gigahertz into the atmosphere. Signals that are scattered
    back are received using the instruments 2.5 m antenna. As well as allowing
    the internal structure of the clouds to be determined, studying how the
    signal has been Doppler-shifted will also enable measurements of the vertical motion of the cloud and elements of its structure. LAUNCHING SOON

    The #EarthCARE satellite carries four instruments for observations of clouds and aerosols with four synergistic sensing methodologies.

    The instruments provide key measurements to answer critical scientific questions related to the role that clouds and pic.twitter.com/4GqCnoNRve

    ESA Earth Observation (@ESA_EO) May 26, 2024



    Constructed by Thales, in the UK, BBR consists of three telescopes measuring the flux of radiation detected from the Earth. One of its telescopes points
    in the nadir direction that is, directly downwards towards the Earth while the others will target points along the satellites track that are ahead of
    and behind its current position. This allows observations of the same point
    to be made from three different angles as the satellite moves along its
    orbit.

    Each telescope has a single mirror and a linear sensor. A rotating chopper drum alternates the telescopes view between unfiltered light, a filter that only lets in short-wave radiation, and a constant-temperature surface to help maintain calibration.

    The short-wave filter restricts BBRs measurements to only radiation from the Sun that has been reflected by the Earth. Subtracting this value from the total reading without the filter will allow the amount of long-wave radiation emitted by the Earth itself to be calculated. These readings are important
    for monitoring the planets radiation balance.

    MSI is an imaging system consisting of two individual cameras with a common electrical and control segment, developed by Surrey Satellite Technology Ltd in the UK. A thermal infrared camera operates in three different wavelength channels, while a second camera produces images in visible, near-infrared,
    and two short-wave infrared channels. Observations using MSI underpin the
    data from EarthCAREs other instruments by providing context to the data collected by ATLID and CPR and spectral data to help calibrate BBRs measurements. MSI has a resolution of up to 500 m, covering a 150 km swath of the Earths surface. The EarthCARE satellite, pictured being removed from its shipping container after arrival at Vandenberg. (Credit: ESA)

    EarthCARE will be launched by SpaceX aboard a Falcon 9 rocket, a two-stage vehicle consisting of a reusable booster and an expendable second stage. The launch will take place from Space Launch Complex 4E (SLC-4E) at Vandenberg Space Force Base in California .

    The booster that will be used for the EarthCARE mission is B1081.7, which
    will be making its seventh flight with this launch. B1081 first flew on Aug. 26, 2023, carrying Dragon Endurance on the Crew-7 mission to the
    International Space Station, following this up with the CRS-29 Cargo Dragon mission in November. After launching a group of Starlink satellites in December, its fourth launch carried NASAs PACE satellite to orbit in February . B1081 was next used for the Transporter-10 rideshare launch in March, which marked its first launch from Vandenberg, before its most recent mission, another Starlink launch, on April 7.

    ESA had originally selected the Soyuz rocket to deploy EarthCARE, with the launch to have been conducted by Arianespace from the Centre Spatial Guyanais in Kourou, French Guiana. Following Russias 2022 invasion of Ukraine, Arianespaces partnership with Russia to carry out Soyuz launches ended, and the launch was moved to the new Vega-C rocket. This was then changed again in 2023 to Falcon 9, a decision which was made both because of delays following Vega-Cs failed launch in December 2022 , and modifications that would have been required to its payload fairing to accommodate the EarthCARE satellite.

    Falcon 9 will fly a return-to-launch-site (RTLS) profile, with the first
    stage coming back to land at Landing Zone 4 (LZ-4) close to the launch pad after completing its role in Tuesdays mission. The ability to recover and reuse the first stage has contributed greatly to Falcon 9s success: since its maiden flight in June 2010, it has already established itself as one of the most-flown rockets ever built. By some metrics, EarthCARE will mark the 350th flight or mission of the Falcon 9 and Falcon Heavy family: the former if
    2020s suborbital Crew Dragon In-Flight Abort (IFA) test is included in the count; and the latter if the 2016 Amos 6 mission, which saw the rocket
    explode on the launch pad during preparations for a static-fire test two days before the scheduled launch, is included instead.

    Despite its high flight rate, Falcon 9 has also proven itself one of the most reliable rockets in service. Aside from Amos 6, it has only suffered one in-flight failure and one additional partial failure to date, and has made
    320 consecutive successful launches since Amos 6 across the Falcon 9 and Falcon Heavy vehicles the latter using two additional boosters burning in parallel with the first stage to enable it to launch heavier payloads into higher orbits. Render of Falcon 9s second stage and EarthCARE, at fairing separation. (Credit: ESA/P. Carril)

    For Tuesdays mission, the single-core Falcon 9 will be sufficient to place EarthCARE into its planned Sun-synchronous orbit, with enough performance
    left over to enable the boosters return to the launch site. Falcon 9 uses
    RP-1 kerosene propellant with liquid oxygen (LOX) as the oxidizer. Propellant and LOX loading takes place during the final 35 minutes of the countdown,
    with the first stages nine Merlin-1D engines igniting about three seconds before the planned liftoff time, or T0. After lifting off, Falcon will fly a southerly course downrange.

    The first stage will power the ascent for about two and a half minutes before shutting down, separating, and beginning its flight back to LZ-4. The second stage will light its Merlin Vacuum engine a version of the Merlin optimized for use in space to continue the mission. Shortly afterward, the payload fairing will separate from around EarthCARE at the nose of the rocket. The second stage will burn for a little over six minutes to reach EarthCAREs planned orbit, with spacecraft separation coming around ten minutes after liftoff.

    Once separated from the Falcon 9, EarthCARE will need to deploy its solar array and other key systems and begin on-orbit testing and commissioning before it can enter service.

    (Lead image: Falcon 9 on the pad at SLC-4E with EarthCARE encapsulated
    inside the payload fairing. Credit: Pauline Acalin for NSF)

    The post SpaceX to launch EarthCARE climate research satellite for ESA and JAXA appeared first on NASASpaceFlight.com .



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