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ESA Top Multimedia

ESA Top Multimedia

Topography of Arcadia Planitia

Topography of Arcadia Planitia

Fire and deforestation linked

The combination of long-term, high-resolution satellite datasets from ESA’s Climate Change Initiative is offering unprecedented insights into the South American Gran Chaco – one of the world’s most endangered dry forest ecosystems. These advanced observations reveal, in striking detail, how fire is accelerating widespread deforestation across the region. The animation shows high-resolution land cover and fire maps from satellites from1990 to 2019 over the Gran Chaco in South America. Notice the clear and repeated pattern: deforestation regularly precedes fire in the same location one or two years later. The shapes and timing match with striking precision – suggesting a human influence.

Read full storySatellite records expose fire driving Gran Chaco transformation

Protecting coastlines

While satellites have revolutionised our ability to measure sea level with remarkable precision, their data becomes less reliable near coasts – where accurate information is most urgently needed. To address this critical gap, ESA’s Climate Change Initiative Sea Level Project research team has reprocessed almost two decades of satellite data to establish a pioneering network of ‘virtual’ coastal stations. These stations now provide, for the first time, reliable and consistent sea-level measurements along coastlines.

Read full story: First sea-level records for coastal community protection 

High-contrast coronograph image of TWA 7b

High-contrast coronograph image of TWA 7b

The beginning of Ignis Mission

These are the highlights of the launch on Axiom Mission 4 (Ax-4) of ESA project astronaut Sławosz Uznański-Wiśniewski from Poland to the International Space Station. The mission is called Ignis.

A SpaceX Falcon 9 rocket lifted off from launch pad 39A at NASA’s Kennedy Space Center in Florida, USA, on 25 June 2025.

Sławosz is mission specialist on the Dragon spacecraft. The other crew members are Shubhanshu Shukla from India and Tibor Kapu from Hungary. They fly under the command of Peggy Whitson from USA.

Sponsored by the Polish government and supported by ESA, the Polish Ministry of Economic Development and Technology (MRiT), and the Polish Space Agency (POLSA), the mission will include an ambitious technological and scientific programme with several experiments led by ESA and proposed by the Polish space industry.

Liftoff of Axiom Mission 4

The Axiom Mission 4 (Ax-4) crew lifts off to the International Space Station atop a SpaceX Falcon 9 rocket from launchpad 39A at NASA’s Kennedy Space Center in Florida, USA, on 25 June at 02:31 EDT, local time (07:31 BST/08:31 CEST).

ESA project astronaut Sławosz Uznański-Wiśniewski travels to his new home in space in the Dragon spacecraft. Sławosz is part of Axiom Mission 4 alongside Peggy Whitson (USA), Shubhanshu Shukla (India) and Tibor Kapu (Hungary).

During their journey on the Dragon spacecraft to the orbital outpost Sławosz and Tibor will serve as mission specialists, Shubhanshu will be the crew’s pilot and Peggy will be commander.

The Polish project astronaut is the second of a new generation of European astronauts to fly on a commercial human spaceflight opportunity with Axiom Space. Sponsored by the Polish government and supported by ESA, the Polish Ministry of Economic Development and Technology (MRiT), and the Polish Space Agency (POLSA), the mission will include an ambitious technological and scientific programme with several experiments led by ESA and proposed by the Polish space industry. The mission, known as Ignis will officially begin once Sławosz  enters the Station.

Sławosz Uznański-Wiśniewski was selected in November 2022 as a member of the ESA astronaut reserve and joined ESA as a project astronaut on 1 September 2023 for training familiarisation at ESA’s European Astronaut Centre in Cologne, Germany.

P160C fires with success

The P160C qualification motor was successfully tested on 24 April 2025 at the European Spaceport in French Guiana, on the solid-propellant booster test stand (BEAP) operated by the French Space Agency (CNES). The successful test firing of the first P160C motor is a major milestone in the development of the future upgrades of Europe’s Ariane 6 and Vega launchers.

The new motor is one meter longer than the previous P120C version and carries over 14 tonnes more solid fuel, increasing considerably Ariane 6 and Vega performance, their payload capacity and their competitiveness.

The extended design of P160C included making the motor one meter longer without affecting the connection interfaces to the Ariane 6 launcher’s central core. These development efforts go hand-in-hand with upgrades to industrial production at ArianeGroup, Avio and their partners, alongside the ongoing production and ramp-up of the P120C motor for upcoming Ariane 6 and Vega-C launches.

The P160C is an upgrade of the P120C motor developed jointly by ArianeGroup and Avio through their 50/50 joint-venture Europropulsion and is one of the world’s largest carbon-fibre one-piece solid-propellant rocket motors. The development programme is managed and funded by the European Space Agency.

Outlook for ESA's Earth Observation programmes – CM25

This session focused on the outlook for ESA’s Earth observation programmes as regards what is planned to be proposed to Member States for funding at the next Ministerial Council in November. Topics covered included the general context of the Ministerial Council, Earth observation programmes and initiatives open for Member State subscription as well as ESA’s scientific and commercial plans.

Watch more videos from the Living Planet Symposium 2025.

MTG-S1 and Copernicus Sentinel-4 media briefing

This media briefing for Meteosat Third Generation Sounder (MTG-S1) satellite and the Copernicus Sentinel-4 instrument took place today during ESA’s Living Planet Symposium, one of the world’s leading Earth observation conferences.  

It provided an opportunity for members of the press to meet members of the two mission teams, as well as ESA Director of Earth Observation Programmes Simonetta Cheli.  

Phil Evans, Director General of Eumetsat, Mauro Facchini, the European Commission’s Head of Earth Observation Unit, and Florence Rabier, Director General at ECMWF, were also present.  

The MTG-S1 satellite and the Copernicus Sentinel-4 instrument are set to launch on a SpaceX Falcon 9 rocket from Cape Canaveral, Florida, no earlier than July 2025. 

Watch more videos from the Living Planet Symposium 2025.

Breaking barriers by working together in Earth science

ESA’s Living Planet Symposium, one of the world’s leading Earth observation conferences, opened on 23 June in Vienna. This plenary session took place on Tuesday, 24 June.

The session focused on what barriers, if any, are present in creating and maintaining effective partnerships, either bilaterally or multilaterally.

Panellists:

  • Tidiane Ouattara - President, AfSA
  • Paul Bate - CEOS Chair; DG, UKSA
  • Kandasri Limpakom - Deputy Executive Director, GISTDA
  • Christian Feichtinger - Executive Director, IAF
  • Hironori Maejima - Senior Chief Officer of EO missions, JAXA
  • Karen St Germain - Earth Science Division Director, NASA
  • Ariel Blanco - Director Space Information Infrastructure Bureau, PhilSA
  • Lorant Czaran - Scientific Affairs Officer, UNOOSA

Watch more videos from the Living Planet Symposium 2025.

Solar corona viewed by Proba-3’s ASPIICS

Solar corona viewed by Proba-3’s ASPIICS

The Sun and its corona viewed by Proba-2, Proba-3 and SOHO

The Sun and its corona viewed by Proba-2, Proba-3 and SOHO

Solar corona viewed by Proba-3’s ASPIICS

Solar corona viewed by Proba-3’s ASPIICS

Solar corona viewed by Proba-3’s ASPIICS

Solar corona viewed by Proba-3’s ASPIICS

Proba-3’s artificial solar eclipse

Proba-3’s artificial solar eclipse

SPICE sees movement at the Sun's south pole

SPICE sees movement at the Sun's south pole

Solar Orbiter's world-first views of the Sun's south pole

Solar Orbiter's world-first views of the Sun's south pole

Solar Orbiter's view of the Sun's south pole

Solar Orbiter's view of the Sun's south pole

SPICE sees the Sun's south pole

SPICE sees the Sun's south pole

PHI's pole-to-pole view of the Sun's magnetic field

PHI's pole-to-pole view of the Sun's magnetic field

Why Solar Orbiter is angling towards the Sun's poles

Why Solar Orbiter is angling towards the Sun's poles

PHI sees mixed-up magnetism at the Sun's south pole

Since 2025, Solar Orbiter is the first Sun-watching spacecraft to ever get a clear look at the Sun's poles. It discovered that at the south pole, the Sun’s magnetic field is currently a mess.  

This image shows a magnetic field map from Solar Orbiter's Polarimetric and Helioseismic Imager (PHI) instrument, centred on the Sun's south pole. Blue indicates positive magnetic field, pointing towards the spacecraft, and red indicates negative magnetic field.  

There are clear blue and red patches visible right up to the Sun's south pole, indicating that there are different magnetic polarities present (north and south). This happens only for a short time during each solar cycle, at solar maximum, when the Sun’s magnetic field flips and is at its most active. After the field flip, a single magnetic polarity should slowly build up and take over the Sun’s poles.  

Solar Orbiter will be watching the Sun throughout its calming-down phase. In 5–6 years from now, the Sun will reach its next solar minimum, during which its magnetic field is at its most orderly and the Sun has the lowest levels of activity.  

Read the full story

Solar Orbiter is a space mission of international collaboration between ESA and NASA. Solar Orbiter's Polarimetric and Helioseismic Imager (PHI) instrument is led by the Max Planck Institute for Solar System Research (MPS), Germany.  

[Image description: This image shows a magnetic map of the Sun's south pole filled with small red and blue dots scattered across a pale-yellow background. The red and blue colours represent opposite magnetic polarities on the Sun. A set of lines – indicating solar longitude – radiate outward from Sun's south pole near the centre of the image, like spokes on a wheel, dividing the circle into sections.]

Vega-C liftoff in slow-mo

ESA’s state-of-the-art Biomass satellite launched aboard a Vega-C rocket from Europe’s Spaceport in Kourou, French Guiana. The rocket lifted off on 29 April 2025 at 11:15 CEST (06:15 local time).

In orbit, this latest Earth Explorer mission will provide vital insights into the health and dynamics of the world’s forests, revealing how they are changing over time and, critically, enhancing our understanding of their role in the global carbon cycle. It is the first satellite to carry a fully polarimetric P-band synthetic aperture radar for interferometric imaging. Thanks to the long wavelength of P-band, around 70 cm, the radar signal can slice through the whole forest layer to measure the ‘biomass’, meaning the woody trunks, branches and stems, which is where trees store most of their carbon.

Vega-C is the evolution of the Vega family of rockets and delivers increased performance, greater payload volume and improved competitiveness.

Access the related broadcast quality video material

Up close and loud: Vega-C liftoff with Biomass

ESA’s state-of-the-art Biomass satellite launched aboard a Vega-C rocket from Europe’s Spaceport in Kourou, French Guiana. The rocket lifted off on 29 April 2025 at 11:15 CEST (06:15 local time).

In orbit, this latest Earth Explorer mission will provide vital insights into the health and dynamics of the world’s forests, revealing how they are changing over time and, critically, enhancing our understanding of their role in the global carbon cycle. It is the first satellite to carry a fully polarimetric P-band synthetic aperture radar for interferometric imaging. Thanks to the long wavelength of P-band, around 70 cm, the radar signal can slice through the whole forest layer to measure the ‘biomass’, meaning the woody trunks, branches and stems, which is where trees store most of their carbon.

Vega-C is the evolution of the Vega family of rockets and delivers increased performance, greater payload volume and improved competitiveness.

Access the related broadcast quality video material.

Vega-C takes Biomass to the sky

ESA’s state-of-the-art Biomass satellite has launched aboard a Vega-C rocket from Europe’s Spaceport in French Guiana. The rocket lifted off on 29 April 2025 at 11:15 CEST (06:15 local time).

In orbit, this latest Earth Explorer mission will provide vital insights into the health and dynamics of the world’s forests, revealing how they are changing over time and, critically, enhancing our understanding of their role in the global carbon cycle. It is the first satellite to carry a fully polarimetric P-band synthetic aperture radar for interferometric imaging. Thanks to the long wavelength of P-band, around 70 cm, the radar signal can slice through the whole forest layer to measure the ‘biomass’, meaning the woody trunks, branches and stems, which is where trees store most of their carbon.

Vega-C is the evolution of the Vega family of rockets and delivers increased performance, greater payload volume and improved competitiveness.

Access the related broadcast quality video material.

Biomass launch highlights

ESA’s state-of-the-art Biomass satellite launched aboard a Vega-C rocket from Europe’s Spaceport in Kourou, French Guiana. The rocket lifted off on 29 April 2025 at 11:15 CEST (06:15 local time).

In orbit, this latest Earth Explorer mission will provide vital insights into the health and dynamics of the world’s forests, revealing how they are changing over time and, critically, enhancing our understanding of their role in the global carbon cycle. It is the first satellite to carry a fully polarimetric P-band synthetic aperture radar for interferometric imaging. Thanks to the long wavelength of P-band, around 70 cm, the radar signal can slice through the whole forest layer to measure the ‘biomass’, meaning the woody trunks, branches and stems, which is where trees store most of their carbon.

Vega-C is the evolution of the Vega family of rockets and delivers increased performance, greater payload volume and improved competitiveness.

Access the related broadcast quality video material.

Press conference: Biomass launch on Vega-C

Watch the replay of the press conference following the launch of ESA's Biomass satellite aboard the Vega-C rocket from Europe's Spaceport in Kourou on 29 April 2025.

In orbit, this latest Earth Explorer mission will provide vital insights into the health and dynamics of the world’s forests, revealing how they are changing over time and, critically, enhancing our understanding of their role in the global carbon cycle. It is the first satellite to carry a fully polarimetric P-band synthetic aperture radar for interferometric imaging. Thanks to the long wavelength of P-band, around 70 cm, the radar signal can slice through the whole forest layer to measure the ‘biomass’, meaning the woody trunks, branches and stems, which is where trees store most of their carbon.

Vega-C is the evolution of the Vega family of rockets and delivers increased performance, greater payload volume and improved competitiveness.

Replay: Biomass launch coverage

ESA’s state-of-the-art Biomass satellite launched aboard a Vega-C rocket from Europe’s Spaceport in Kourou, French Guiana. The rocket lifted off on 29 April 2025 at 11:15 CEST (06:15 local time).

In orbit, this latest Earth Explorer mission will provide vital insights into the health and dynamics of the world’s forests, revealing how they are changing over time and, critically, enhancing our understanding of their role in the global carbon cycle. It is the first satellite to carry a fully polarimetric P-band synthetic aperture radar for interferometric imaging. Thanks to the long wavelength of P-band, around 70 cm, the radar signal can slice through the whole forest layer to measure the ‘biomass’, meaning the woody trunks, branches and stems, which is where trees store most of their carbon.

Vega-C is the evolution of the Vega family of rockets and delivers increased performance, greater payload volume and improved competitiveness.

Access the related broadcast quality video material.

ESA’s Biomass mission launches on Vega-C

ESA’s state-of-the-art Biomass satellite has launched aboard a Vega-C rocket from Europe’s Spaceport in French Guiana. The rocket lifted off on 29 April 2025 at 11:15 CEST (06:15 local time).

In orbit, this latest Earth Explorer mission will provide vital insights into the health and dynamics of the world’s forests, revealing how they are changing over time and, critically, enhancing our understanding of their role in the global carbon cycle. It is the first satellite to carry a fully polarimetric P-band synthetic aperture radar for interferometric imaging. Thanks to the long wavelength of P-band, around 70 cm, the radar signal can slice through the whole forest layer to measure the ‘biomass’, meaning the woody trunks, branches and stems, which is where trees store most of their carbon.

Vega-C is the evolution of the Vega family of rockets and delivers increased performance, greater payload volume and improved competitiveness.

Access the related broadcast quality video material.

Biomass on Vega-C launch pad gantry retraction

A view from the launch pad with Vega-C flight VV26 ready for liftoff as the mobile building that surrounds the rocket rolls away to reveal the rocket to the skies, 29 April 2025. On the rocket is ESA’s Biomass mission.

The mobile building allows Vega-C’s four stages to be assembled on the launch pad in security and offers protection from the elements. The 50-metre high structure weighs over 1000 tonnes, and a hydraulic system drives wheels on an 80-m rail track. The gantry is powered by two electric motors of some 70 kW capacity, these operate the hydraulic pumps supplying pressurised oil to six wheels.

Biomass is one of ESA’s Earth Explorer missions and, like other Earth Explorers, it uses advanced space technology to provide new data. Biomass will advance our understanding of forests and their importance in the carbon cycle and climate.

We already know that forests play a vital role in Earth’s carbon cycle by absorbing and storing large amounts of carbon dioxide. This helps to regulate the planet’s temperature. Data from Biomass will help us produce more accurate estimates of how much carbon is contained in forests' organic matter, or biomass, and reduce uncertainties in carbon stock and flux estimates, including those related to land-use change, forest loss, and regrowth.

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