ESA Top Multimedia

On 17 January, the Artemis II Space Launch System rocket and Orion spacecraft were rolled out from the Vehicle Assembly Building at NASA's Kennedy Space Center in Florida, to Launch Pad 39B. The 6.5-km journey took around 12 hours and was carried out using NASA's crawler-transporter, which has been moving rockets to launch pads for over 50 years.

At the top of the rocket sits the Orion spacecraft, bearing the ESA and NASA logo and designed to carry four astronauts on a 10-day lunar flyby mission. Artemis II will be the first crewed flight of the Artemis programme and the first time humans have ventured towards the Moon in over 50 years.

Their journey depends on our European Service Module, built by industry from more than 10 countries across Europe. This powerhouse will take over once Orion separates from the rocket, supplying electricity from tis four seven-metre-long solar arrays, providing air and water for the crew, and performing key propulsion burns during the mission, including the critical trans-lunar injection that sends the spacecraft and its crew on their trajectory towards the Moon.

ESA project astronaut Sławosz Uznański-Wiśniewski captured these stunning timelapse videos during his 20-day stay aboard the International Space Station as part of Axiom Mission 4, known as Ignis. Filmed from the Cupola – the Space Station’s iconic seven-windowed observation module – the footage showcases breathtaking views of Earth and the Moon from orbit.

Launched on 25 June 2025 aboard a SpaceX Dragon spacecraft, Sławosz conducted 13 experiments proposed by Polish institutions in collaboration with ESA, plus three ESA-led investigations. These spanned human research, materials science, biology, biotechnology and technology demonstrations.

The Ax-4 mission marks the second commercial human spaceflight for an ESA project astronaut. Ignis was sponsored by the Polish government and supported by ESA, the Polish Ministry of Economic Development and Technology (MRiT) and the Polish Space Agency (POLSA).   

Access the related broadcast quality footage. 

After being selected to join the ESA Academy Experiments programme, three student teams from universities across Europe were invited to carry out the experimental part of their research projects in ESA’s test facilities with support and guidance from experts.

For their experiments, the student teams made use of ESA’s ORBIT facility – a part of the Orbital Robotic Laboratory (ORL) located at ESTEC, the agency’s technical heart in the Netherlands. ORBIT consists of a 43 m² ultra-flat floor – the height difference between its lowest and highest points is less than a millimetre.

The Skywalker team from Aalborg University, Denmark, used the simulated two-dimensional microgravity environment to test the reinforcement learning algorithms they have developed for their robotic arm. Their project aims to demonstrate the concept of autonomous crawling in microgravity.

In the very first ORBIT facility experiment involving human participants, the V-STARS team from Birkbeck, University of London, and the University of Kent, UK, investigated the relationship between the human vestibular system (region of the inner ear responsible for body balance) and the perception of verticality in a microgravity environment.

The GRASP team from Sapienza University of Rome, Italy, explored an innovative approach to performing manoeuvres with non-cooperative objects in space. The robotic arm they have developed themselves is sporting an adhesive gripper inspired by geckos.

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To land on the right foot on the Red Planet, European engineers have been dropping a skeleton of the four-legged ExoMars descent module at various speeds and heights on simulated martian surfaces.

Watch a quick sequence of some of the drops from different angles. For over a month, Thales Alenia Space and Airbus teams ran dozens of vertical drops using a full-scale model of the landing platform at the ALTEC facilities in Turin, Italy. 

This first series of tests involved dropping the model onto both hard and soft surfaces, the latter filled with powdery, Mars-like soil.  The team changed the speed and height of the falls by a few centimetres. 

During the test campaign, the four legs replicated the structure and dimensions of those that will fly to Mars. The lightweight, deployable legs are interconnected and equipped with shock absorbers to withstand the impact.

Another goal of the campaign was to verify the performance of the touchdown sensors. A system installed in all four legs detects when the spacecraft approaches the surface and triggers the shutdown of the descent engines after a soft landing.  

The landing legs are crucial gear for the safe touchdown of the ExoMars Rosalind Franklin rover mission in 2030, alongside parachutes and engines that will slow the spacecraft’s descent onto Mars. 

While Thales Alenia Space is the industrial lead of the mission, Airbus provides the landing platform and ALTEC offers technical support.

Romanian company ATD Aerospace RS SRL is developing a 10 kN rocket engine that can be re-ignited and adjust its thrust. This builds on the 1 kN engine they developed with support from the European Space Agency (ESA).

Before working with ESA, ATD had already created several engines in the 0.5–1 kN range, which paved the way for their later developments. This project is part of ESA’s Future Launchers Preparatory Programme (FLPP), that helps develop the technology for future for space transportation systems. By conceiving, designing and investing in technology that doesn’t exist yet, this programme is reducing the risk entailed in developing untried and unproven projects for space.

The firing test seen here shows a water-cooled version as it cycles from 100% thrust to 60% and back to 100%. The test, conducted in Romania in 2025 saw the engine perform as expected. The engine uses hypergolic propellants, which are ideal for spacecraft or rockets that need to store fuel for extended periods.

Turned upside down, the engine could suspend 1000-kg on Earth, the weight of typical hippopotamus. Used as intended it could slow the descent of a rocket stage and ensure a soft touchdown.

Various sensors were used during the test firings to characterise the engine and its functions.

The development involves three designs, starting with an uncooled engine demonstration, a next version that is cooled with water, as seen in this video, and finally a self-contained engine that incorporates its own cooling.

The European Space Agency is financing the development up to the successful test of the final regenerative cooled-engine, reaching a technology readiness level of five with a smaller-scale test firing (TRL5).

As a new year begins, let’s take a look at what’s ahead for the European Space Agency in 2026. From Earth to the farthest reaches of the Solar System, 2026 marks a year of firsts that continue to shape the future of space.

As she flew 400 km above Earth at hypersonic speed, NASA astronaut Jeanette Epps caught a gigantic spark with blue and red flashes shooting upwards.  

This video shows a blue jet propagating into space towards the upper layers of the atmosphere. The beam of light is followed by red flashes spreading like tentacles across the sky.  

You can watch the magnificent show at different speeds, but in reality, it lasted less than a second.  

Jeanette directed a high-resolution camera from the International Space Station towards a summer thunderstorm. With the camera set at the fastest frame rate for slow-motion video, she managed to record the giant jet in all its splendour.   

What the astronaut captured from orbit in July 2024 is rarely visible on Earth because it takes place above the clouds, at altitudes between 40 and 80 kilometres. This powerful yet elusive electrical phenomenon is known as a Transient Luminous Event (TLE). 

ESA astronaut Andreas Mogensen captured the first pulsating jet from space a decade ago, providing a new perspective on electrical activity at the top of thunderstorms. Scientists began to learn what types of clouds trigger such phenomena and how they impact the chemistry of the atmosphere. 

Her recording is part of the Thor-Davis experiment designed to investigate lightning in the upper atmosphere and how it might affect the concentration of greenhouse gases. The experiment is called Thor after the god of thunder, lightning and storms in Nordic mythology, and is led by the Danish Technical University (DTU) together with ESA. 

Lightning triggers powerful electrical bursts in our atmosphere almost every second, yet the inner workings of these forces of nature are still not fully understood. Capturing such phenomena is vital for scientists researching Earth’s weather systems.