“Council’s decision means ESO has the funds to build an ambitious and extremely powerful science machine, fully integrated with ESO’s Paranal Observatory, that meets the longer-term aspirations of the astronomy community,” says ESO Director General Xavier Barcons. Overall, 80% of the ELT’s budget is being invested in contracts with industry in ESO member states and in Chile. The funding boost will strengthen the scientific capabilities of the under-construction telescope, bringing them in line with those envisioned in the original ELT programme approved by Council in 2012. Two years later, ESO Council gave green light for ELT construction but stipulated that it should occur in two phases, with funding only committed for a fully working but less-powerful ‘Phase 1 ELT’. The revised budget includes the procurement of components originally deferred to the second phase of the project, such as the telescope’s second prefocal station, two more laser guide star systems, a set of astronomy-relevant atmospheric monitoring equipment and a small technical building at Armazones to optimise operations and maintenance activities. The new budget incorporates the impact on cost and schedule of known technical risks and includes the cost of activities needed to bring the ELT into operation as part of ESO’s Paranal Observatory. The funding boost follows an ELT total cost exercise that started in 2019. The exercise is an example of ESO’s continuous monitoring of the project and dedication to delivering a pioneering telescope that will tackle the biggest astronomical challenges of our time and make yet unimaginable discoveries. A truly international endeavour, this ambitious and exciting ESO project is made possible thanks to the organisation’s staff and governing bodies, the astronomy community, industry and scientific institutions in member states, as well as to the host state of Chile.

The first set of 18 blanks for the primary mirror of ESO’s Extremely Large Telescope have arrived safely at Safran Reosc in Poitiers, France. The contracts for casting the blanks of the mirror segments, as well as polishing, mounting and testing them, were signed in 2017 with respectively the German company SCHOTT and the French company Safran Reosc, a subsidiary of Safran Electronics & Defense. Mirror blanks are packed by six into a special wooden transport crate and six of these crates can fit inside a regular shipping container. Sophisticated shock sensors travel with the blanks to measure any sudden acceleration or shock that could affect the blanks. The shipping container with the first 18 blanks was sent from SCHOTT in Mainz, Germany, on 23 July and arrived at Safran Reosc the following day. The ELT mirror blanks are made of the low-expansion glass-ceramic Zerodur© [1] and are circular, measuring 1.5 metres across and about 5 centimetres thick. The back of each blank is flat and the front surface is concave. The blanks come in three types with slightly differently shaped front surfaces, depending on the planned location of the segment in the primary mirror. The first primary mirror segments were cast by SCHOTT in 2018. SCHOTT manufactures the blanks to approximate shape so that Safran Reosc does not need to remove too much material during the polishing process. Safran Reosc will polish the blanks before they are cut into hexagons and receive a final precise polishing using Ion Beam Figuring. When it is completed, the primary mirror will comprise 798 hexagonal segments and will have a total light-collecting area of 978 m2. In total, more than 900 segments will need to be cast and polished (including a spare set of 133 segments). Once built the ELT will be the largest ground-based telescope in operation. The telescope is being built at Cerro Armazones in the Atacama Desert of northern Chile. With a primary mirror almost 40 metres in diameter, the ELT will gather almost 100 million times more light than the human eye, which will allow scientists to tackle some of the biggest challenges in current astrophysics, such as the formation of the first stars, the assembly of the first galaxies, the characterisation of the atmospheres of Earth-like exoplanets, or the nature of dark matter and dark energy, among many other questions. Notes [1] Zerodur© was originally developed for astronomical telescopes in the late 1960s. It has an extremely low coefficient of thermal expansion, meaning that even in the case of large temperature fluctuations, the material does not expand. Chemically, Zerodur© is very resistant and can be polished to a high standard of finish. The actual reflective layer, made of aluminium or silver, is usually vaporised onto the extremely smooth surface shortly before a telescope is put into operation and is renewed at regular intervals afterwards. Many well-known telescopes with Zerodur© mirrors have been operating reliably for decades, including ESO's Very Large Telescope in Chile.