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Today, at 17:07 local time (Pacific) on 10 April (01:07 BST/02:07 CEST on 11 April), NASA's Orion spacecraft and its crew splashed down safely in the Pacific Ocean, marking the successful end of the Artemis II mission, humankind's first journey around the Moon since Apollo 17 in 1972.

ESA's European Service Module powered the spacecraft over 1 million kilometres through in deep space, providing air and water for the astronauts, generating electrical power via its four solar arrays, maintaining thermal control and delivering propulsion.

Mostly built by European industry under ESA leadership, the European Service Module was assembled by Airbus Defence and Space in Bremen, Germany, with contributions from companies across 13 European countries, involving 20 main contractors and over 100 European suppliers.

Throughout the mission, European engineers supported operations around the clock from ESA's centres in the Netherlands and Germany, as well as alongside NASA teams in Houston, ensuring Orion and its crew completed their journey safely around the Moon and back home.

An international research team boarded ESA’s 86th parabolic flight campaign in May 2025 with ultralight graphene aerogels, then hit them with light during zero gravity phases to observe their reaction under space-like conditions.  

Inside a vacuum chamber, a continuous laser beamed on three small cubes made of graphene aerogel. A high-speed camera recorded the action through glass tubes. This video has been slowed down 10 times; each experiment run lasted 30 milliseconds. 

The effect of the laser during the microgravity phases was startling: the graphene samples shot forward instantly. Another finding was the ability to control the propulsion by tuning the light beam. The stronger the laser, the greater the acceleration.  

Under Earth’s gravity conditions, the aerogels barely moved at all. The results, published in Advanced Science, demonstrate that microgravity unlocks the potential of light propulsion for graphene aerogels in terms of velocity, thrust and distance.   

Lasers could one day steer solar sails and adjust a satellite’s position in outer space, thanks to graphene. 

Graphene aerogels are ultralight, highly porous materials that merge graphene’s exceptional electrical conductivity with the structural advantages of aerogel architecture. They maintain strong mechanical performance despite their low density.  

Researchers at the Université Libre de Bruxelles (ULB) in Belgium and Khalifa University in the United Arab Emirates (UAE) led the study.

This timelapse was published by ESA astronaut Sophie Adenot on her social media with the following caption:

[EN] Another experiment, and another timelapse! This time, I’m working with the Fluid Science Laboratory (FSL), one of the science facilities inside ESA’s Columbus module.

The experiment is called PASTA-3 and investigates the formation and evolution of emulsions over time when there is no gravity to interfere. Emulsions are mixtures of two or more liquids that do not usually mix, such as oil and water.

During this session, I installed 3 experiment containers with new samples inside the FSL. Each PASTA sample has a different concentration of surfactant (an agent that helps liquids mix) and Xanthan Gum in addition to a water and oil mixture.

This experiment helps scientists better understand and model the fundamental physics of emulsions. That knowledge has numerous applications on Earth, including:
improving food quality and shelf life (milk, dough, mayonnaise, candy…), enhancing the stability and effectiveness of medicines (including vaccines) and cosmetics, optimising processes in industrial and advanced manufacturing sectors (oil, chemicals …).

PASTA-3 is one of the 36 European experiments I get to work on during my mission! Go science!

(PASTA is short for PArticle STAbilised emulsions experiment.)

[FR] Nouvelle expérience, et nouveau timelapse ! Cette fois-ci, cela se passe dans le Fluid Science Laboratory (FSL), l’une des installations scientifiques situées à l’intérieur du module Columbus de l’ESA.

L’expérience s’appelle PASTA 3 : elle étudie la formation et l’évolution des émulsions au fil du temps en l’absence de gravité. Une émulsion, c’est un mélange de deux ou plusieurs liquides qui ne se mélangent pas facilement, comme l’huile et l’eau.

Lors de cette session, j’ai installé trois lots de nouveaux échantillons dans le FSL. Chaque échantillon PASTA présente une concentration différente de tensioactif (un agent qui aide les liquides à se mélanger) et de gomme xanthane, en plus d’un mélange d’eau et d’huile.

Cette expérience aide les scientifiques à mieux comprendre et modéliser la physique fondamentale des émulsions avec à la clé de nombreuses applications sur Terre, comme par exemple:
l’amélioration de la qualité des aliments et de leur durée de conservation (lait, pâte, mayonnaise, confiseries…), le renforcement de la stabilité et de l’efficacité des médicaments (y compris les vaccins) et des cosmétiques, l’optimisation des procédés industriels et de fabrication avancée (pétrole, chimie…).

PASTA 3 est l’une des 36 expériences européennes sur lesquelles j’ai la chance de travailler durant ma mission ! Vive la science !

(PASTA est l’abréviation de PArticle STAbilised emulsions experiment.)

The European Space Agency and the Chinese Academy of Sciences are joining hands to uncover how Earth defends itself against dangerous particles and radiation from the Sun.

It’s the first time we will have images and videos of what happens when this solar wind crashes into our magnetic field. Smile will witness this interaction in action, using four onboard instruments to watch the drama unfold.

Life can only exist as we know it when nestled safe inside this giant magnetic bubble surrounding our planet. By imaging the bubble as a whole for the first time, Smile will help us build up the fundamental understanding that space weather forecasting will ultimately depend on.

Learn more about Smile.

Artemis II launched on 2 April at 00:35 CEST, (18:35 local time on 1 April), sending astronauts around the Moon for the first time in over 50 years. At the heart of the mission is ESA's European Service Module, which powers, propels and sustains the Orion spacecraft and its crew on their journey around the Moon and safely back to Earth.

Since their arrival aboard the International Space Station on 14 February 2026, ESA astronaut Sophie Adenot and NASA astronaut Jack Hathaway have already carried out two sessions of EchoFinder, an experiment developed by the French space agency CNES for the εpsilon mission. Each session takes about 3 to 4 hours, including the 30 minutes of installation/setup and 30 minutes of wrap-up shown in this timelapse.

EchoFinder tackles a simple yet crucial challenge for the future of human space exploration: how can astronauts perform a reliable ultrasound scan without medical training and without real-time support from a doctor?

EchoFinder is a software assistant that combines augmented reality and artificial intelligence. The augmented reality interface guides the astronaut by showing exactly where to position the ultrasound probe on the body. Once the probe is correctly placed, an artificial intelligence system takes over to identify the organs and record the images. In the future, these images would be sent to medical teams on Earth for diagnosis.

This technology was developed with upcoming space missions in mind, where communication delays would make remote assistance from a specialist impossible. It also has promising applications on Earth, for example on ships at sea, in submarines, or in remote areas without immediate access to medical expertise.

In the second webinar of the Monitoring Climate Change from Space series, Anny Cazenave (LEGOS), Science Leader of the Sea Level Climate Change Initiative (CCI) project, explores the dynamics of global, regional, and local sea level rise. She explains the data processing and retrieval algorithms behind satellite-derived Essential Climate Variables (ECVs) and examines the primary drivers of sea level change, including ocean warming and land ice melt, in the context of human-induced climate change. The webinar also highlights additional coastal factors, such as ground subsidence, that can amplify sea level rise, and discusses future scenarios and their potential impacts on coastal communities. 

Join our latest monthly webinar series showcasing the latest climate science from the ESA-CCI ECV projects. Find out more: https://climate.esa.int/en/climate-change-initiative-training/webinars/