Thales Alenia Space (TAS), the joint-venture between Thales (67%) and Leonardo (33%), announces the signing of a €26.1 million phase 1 contract with the European Space Agency (ESA) related to the development of LISA’s telescopes. Made up of three satellites, the LISA (Laser Interferometer Space Antenna) mission will be the first European space observatory capable of detecting and studying gravitational waves generated by extreme cosmic events.  

This latest announcement follows the signing of two other contracts related to the same mission. In June 2025 (see AVIONEWS), TAS announced a contract with prime contractor OHB System AG to provide several critical elements, including the spacecraft avionics and control software, the telecommunication system, and the drag-free and attitude control system (DFACS). In January 2026, the company was also selected by OHB System AG to provide the propulsion subsystem. 

Thales Alenia Space’s optical excellence at the service of space exploration 

In France, TAS and Thales SESO, which are responsible for developing the optical payload telescopes, will make a major contribution to the mission.   

Based on its globally renowned expertise in the design and manufacture of advanced optical technologies, Thales Alenia Space has been selected by the European Space Agency (ESA) to conduct Phase 1 for the development of the six telescopes, which is expected to proceed in three phases.  

As prime contractor, the jv will be responsible for the development, design, assembly, and testing of the telescopes. The manufacture of the six telescopes, made entirely of Zerodur, will present an unprecedented technological challenge. 

It is only the combined expertise in design and manufacturing of Thales SESO and Thales Alenia Space, along with Zerodur’s extremely low thermal sensitivity, that will enable the picometer-level stability required by LISA mission. 

For this initial development contract, TAS will be able to draw on the longstanding expertise of Thales SESO, Europe’s leading supplier of ultra-lightweight Zerodur® mirrors. 

Thales SESO will be responsible for the procurement, machining, and polishing of the optics and structure. In addition, TAS and Thales SESO will jointly be responsible for assembling the telescopes, aligning the optics, and conducting environmental and performance tests. 

With more than 200 Zerodur Space mirrors manufactured and flying, Thales SESO is among the world top leaders for optical surface precision achieved through polishing, with 0.2 nanometers reached over the 230-mm diameter surface of the mirrors made for Virgo (the European ground gravitational wave detector) —a level of precision that is priceless for the LISA mission. 

LISA: the first space-based observatory for the study of gravitational waves 

LISA (Laser Interferometer Space Antenna) is a unique space exploration mission by the European Space Agency (ESA) designed to detect gravitational waves directly from space. This space observatory will detect the tiniest distortions in spacetime caused by gravitational waves generated by the acceleration of massive objects, as predicted by Albert Einstein’s theory of general relativity in 1916, with a sensitivity and within a very low frequency range (between 0.1 mHz and 100 mHz), inaccessible to existing ground-based measurement facilities such as LIGO in the United States and VIRGO in Europe, due to their limited size and seismic interferences. 

Its mission will provide a new opportunity to understand the early universe that existed before the formation of stars and galaxies, as well as celestial phenomena such as the interaction of compact stars or the merger of supermassive black holes at the centers of galaxies. 

It consists of a constellation of three satellites, each spaced 2.5 million kilometers apart, forming an equilateral triangle and each carrying two test masses. These three satellites are linked by six laser beams, thus forming a massive optical interferometer. These inter-satellite laser beams will measure the displacement of these masses with an accuracy on the order of a picometer (smaller than an atom). 

The mission satellites benefit from the experience gained during the LISA Pathfinder program, launched in 2015, which successfully demonstrated the ability to maintain test masses in a state of “free fall” with exceptional precision. The same precision propulsion system, also used for ESA’s Gaia and Euclid missions, will ensure that each satellite keeps the laser interferometer beams pointed toward the other satellites with the utmost precision. 

LISA will employ advanced laser interferometry measurement techniques to study astrophysical phenomena involving massive and distant systems, thereby offering unprecedented opportunities to explore and understand our universe. The three satellites are scheduled to launch in 2035 aboard an Ariane 6 rocket. 

LISA mission: Thales Alenia Space’s contribution 

TAS will provide prime contractor OHB System AG with several mission-critical elements, including the spacecraft avionics and control software, the telecommunication system, and the drag-free and attitude control system (DFACS). The joint-venture will be responsible for the design, manufacture, assembly, integration, and testing of the propulsion subsystem for the LISA mission. Thales Alenia Space is also responsible for ensuring the exceptional electromagnetic, radiation, and self-gravity operational environment for the payload, essential to mission performance, for which Thales Alenia Space is also managing the budgets. 

Thales Alenia Space in Turin, Italy, as member of the LISA Core Team makes use of the experience and design solutions inherited from the five-year study phase led by Thales Alenia Space as the prime contractor. Its facility, in Gorgonzola, Italy, will develop the On Board Computer and the Mass Memory in the same integrated unit. In the United Kingdom, the company is supplying the propulsion system, while France is responsible for developing the telescopes in collaboration with Thales SESO. Its teams in Switzerland are involved in developing part of the instrument's electronics and of the Constellation Acquisition System for LISA. 

Leonardo is also contributing with its technologies to the mission with some key equipment, such as the micro propulsion assemblies, a highly precise system of thrusters used to control the satellite’s attitude with extreme accuracy. Other company sites will also have the opportunity to contribute to the LISA mission, supplying spacecraft subsystems or equipment.