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Extremely Large Telescope

The Extremely Large Telescope (ELT) is a revolutionary ground-based optical and infrared telescope being constructed by the European Southern Observatory (ESO), featuring a 39-meter-diameter segmented primary mirror composed of 798 hexagonal segments, which will make it the world's largest telescope of its kind upon completion. Located on the summit of Cerro Armazones in Chile's Atacama Desert at an elevation of approximately 3,060 meters, the ELT employs a five-mirror optical design and advanced adaptive optics system to correct for atmospheric distortions, enabling unprecedented image sharpness and light-gathering power equivalent to over 250 times that of the Hubble Space Telescope. Construction officially began in 2014 following ESO Council approval in 2012, with the project currently over 50% complete as of early 2025, including the raising of the massive 80-meter-diameter dome and the arrival of the first main mirror segments in Chile. Technical first light is anticipated in 2029, followed by scientific operations starting in 2030. The ELT's primary scientific objectives span a broad range of astrophysical frontiers, driven by its exceptional resolution and sensitivity in the visible and near-infrared wavelengths. Key goals include the discovery and detailed characterization of Earth-like exoplanets through direct imaging and , potentially enabling the detection of biosignatures indicative of life beyond the Solar System; probing the formation and evolution of galaxies by resolving individual stars in distant systems; and investigating cosmology through studies of , , and the high-redshift . These capabilities will be realized through a suite of state-of-the-art instruments, such as the High Angular Resolution Monochromatic Imager (HARMONI) for integral field , the Mid-infrared Imager and Spectrograph () for exoplanet imaging, and the Spectrograph for Exoplanet Atmospheres () for measurements, all integrated with the telescope's sophisticated to achieve near-diffraction-limited performance. As part of ESO's complex, approximately 23 kilometers north of the existing site, the ELT represents a €1.5 billion investment in next-generation astronomy, fostering international collaboration among ESO's 16 member states and contributing to advancements in fields like and fundamental physics. Ongoing milestones in include the completion of the 4.25-meter secondary mirror and further assembly of the structure, positioning the ELT to address enduring questions about the Universe's origins and habitability upon its operational debut.

History and Development

Conception and Early Planning

The conception of the Extremely Large Telescope (ELT) originated within the (ESO) in 1997, as part of long-term planning for ground-based astronomy facilities following the completion of the (VLT). This initiative was spurred by assessments that significant scientific advancements beyond the capabilities of the (HST) and 8–10-meter-class telescopes like the VLT and Keck would require an order-of-magnitude increase in aperture size. Key motivations for the project centered on addressing limitations in observing faint and distant cosmic phenomena, including the detailed characterization of atmospheres through high-contrast imaging and , the study of in the early via resolved stellar populations, and investigations into and through weak lensing and dynamics at scales unattainable by prior observatories. These goals were outlined in preliminary science cases developed during ESO's 1997–1998 studies, emphasizing the need for enhanced light-gathering power and to complement space-based missions like and the forthcoming (JWST). In the early 2000s, ESO advanced these ideas through the (OWL) concept, which proposed a 100-meter-diameter segmented primary mirror to achieve diffraction-limited performance with integrated . Feasibility studies from 1997 to 2005 revealed technical and cost challenges with the 100-meter scale, leading to a redesign in the mid-2000s that scaled the to 42 meters and later refined it to 39.3 meters for improved practicality while retaining core scientific ambitions. Initial site surveys in the focused on atmospheric conditions in Chile's , evaluating factors such as seeing, water vapor, and altitude through comparative meteorological data collection at candidate locations including Cerro Armazones. These efforts, part of ESO's broader site evaluation working group activities starting around 2004, prioritized sites with minimal and low humidity to optimize and optical performance. To refine scientific requirements, ESO formed the ELT Science Working Group in December 2005, comprising astronomers from member states to assess instrument needs and prioritize cases like detection and . This team conducted evaluations through 2006, consolidating inputs that shaped the project's baseline design and paved the way for formal approval in the following decade.

Project Approval and Funding

The (ESO) Council formally approved the baseline design for the (ELT) on June 11, 2012, following a comprehensive cost review in 2011 that reduced the telescope's primary mirror diameter from 42 meters to 39 meters to achieve significant savings and lower technical risks. This approval marked a pivotal step after years of preparatory studies, enabling the progression to detailed planning and procurement while conditioning major contracts over €2 million on further endorsements. Funding for the ELT project originated with an initial seed allocation of €57 million in 2006, approved by the ESO Council to support three years of detailed design studies for what was then envisioned as a groundbreaking optical/ . The full construction phase received the green light in December 2014, once sufficient commitments were secured from ESO member states to meet the required funding threshold. As of 2024, the total estimated cost stands at approximately €1.5 billion, with primary funding drawn from ESO's 16 member states, including major contributions from (around 25%) and (around 15%), apportioned based on each country's share of ESO's annual budget. Ongoing contributions are documented in ESO's annual reports, ensuring steady progress toward completion. International collaboration underpins the project's financing and execution, with ESO's member states—Austria, , , , , , , , , , the Netherlands, , , , , and —providing the core support. , which joined as a full member in 2010, has been integral to this framework, contributing to both operational funding and the ELT's development without additional exemptions for the project's costs. Key partnerships include major contracts awarded to industry leaders, such as the 2017 agreement with SCHOTT in for producing the 798 Zerodur mirror blanks (plus spares) for the primary mirror, valued at hundreds of millions of euros, and the 2016 contract with the ACe Consortium (comprising , Cimolai, and EIE Group from ) for the design, manufacture, and assembly of the dome and main structure, ESO's largest-ever ground-based astronomy procurement at €400 million. These awards, representing over 80% of the budget invested in European and Chilean industry, highlight the collaborative model that has sustained the ELT's advancement.

Key Milestones and Timeline Updates

The construction of the (ELT) at Cerro Armazones in began with groundbreaking on 19 June 2014, marking the start of site preparation and leveling activities. This initial phase laid the groundwork for the observatory's infrastructure, with summit leveling completed by 2015. Subsequent key events advanced the project's core components. In May 2017, a first stone ceremony signified the commencement of the dome foundation work. Casting of the primary mirror segments began on 9 January 2018, with the first six of the 798 hexagonal segments produced by SCHOTT in ; all segments were cast by June 2024. The contract for the secondary mirror blank was awarded to SCHOTT in January 2017, with polishing contracted to Safran-Reosc in July 2016, and completion anticipated in early to mid-2025. The project reached its 50% completion milestone in 2023, encompassing significant progress on the dome structure, mirror production, and site infrastructure. Ongoing efforts include polishing the primary mirror segments and assembling the enclosure, with the first 18 segments shipped to Chile in December 2023. In 2025, recent milestones highlighted structural achievements. A topping-out ceremony on 16 April 2025 celebrated the dome reaching its highest point, with the structure of one sliding door fully installed. Installation of the giant sliding doors followed in May 2025, with the first successful movement of one door tested on 3 November 2025 to verify operational integrity. As of November 2025, construction advances with the dome structure nearly complete and focus shifting to interior assembly. The original timeline projected construction from 2014 to 2025, with first light in 2024. Updates have revised this schedule due to supply chain disruptions, technical challenges, and COVID-19 impacts, now targeting main structure completion in late 2026, telescope first light in March 2029, and scientific operations by December 2030.

Site and Construction

Location and Site Selection

The site for the (ELT) was selected as Cerro Armazones in the of , at an elevation of 3,046 meters. This decision was announced by the (ESO) Council on 26 April 2010, following a comprehensive site characterization campaign conducted from 2005 to 2008 that compared candidate locations including other sites in , , , , and the in . Key criteria guiding the selection emphasized superior astronomical conditions essential for high-resolution observations. Cerro Armazones demonstrated a median seeing of 0.67 arcseconds at 500 nm—exceeding the target threshold of less than 0.7 arcseconds—along with low precipitable water vapor content favorable for astronomy, negligible from its isolated desert setting, and adequate seismic stability to accommodate the telescope's massive structure. The site's location, just 20 kilometers from ESO's , further supported its selection by enabling shared infrastructure such as access roads, electrical power grids, and fiber optic networks, which reduce logistical costs and improve operational . Environmental factors were rigorously evaluated to minimize ecological disruption. ESO's for the project was approved by Chilean authorities in , confirming measures to protect the arid desert ecosystem and verifying that would not directly impact nearby communities. The high altitude and southern latitude of Cerro Armazones offer strategic advantages, providing clear views of the Milky Way's and southern populations that are inaccessible or poorly observable from northern sites.

Construction Phases and Progress

Construction of the (ELT) at the Cerro Armazones site in Chile's officially began in June 2014, following ESO Council approval. The project is divided into two main phases: Phase 1 focused on site preparation, access infrastructure, and the erection of the 80-meter-diameter dome enclosure, while Phase 2 involves assembly of the structure, installation of mirrors and instruments, and . Early work included developing access roads, excavating the platform, and pouring the concrete foundation for the pier and auxiliary buildings, which required nearly 9,000 cubic meters of incorporating seismic isolation devices. By 2021, the foundational structure of the dome was in place, marking substantial progress in Phase 1. As of November 2025, significant milestones have been achieved, including the full of the dome during a on 16 April 2025 and the fitting of the massive , which underwent their first successful test movement on 2 November 2025. All 798 hexagonal segments for the primary mirror (M1) had been cast by mid-2024, with polishing operations in progress at facilities in ; prototypes have achieved excellent optical quality. The 4.25-meter secondary mirror (M2) was completed in early 2025. Significant progress has been made since the 50% completion milestone in 2023, with the main structure, including mountings for mirrors and instruments, projected for completion in late 2026. The on-site workforce has peaked at over 200 personnel, utilizing modular to navigate the challenging terrain. Sustainability features, such as for auxiliary energy and water , are integrated to minimize environmental impact. Technical first light is now anticipated in March 2029.

Challenges and Delays

The construction of the (ELT) has encountered significant supply chain disruptions, particularly following the , which led to delays in the delivery of critical components such as the primary mirror segments from European suppliers between 2022 and 2024. These issues were exacerbated by global and the war in , causing supplier pressures and the insolvency proceedings of the ELT dome Cimolai starting in 2022, resulting in broader production slowdowns for elements. Technical hurdles have also posed major challenges, especially in achieving the precision alignment of the 798 hexagonal segments comprising the 39-meter primary mirror, which demands sub-nanometer accuracy to function as a unified optical surface. To address this, the (ESO) developed specialized tools, including the Phasing and Diagnostics Station (PDS), a custom system for monitoring and aligning segments during integration at the Atacama site. Additionally, testing the systems has proven complex due to the scale of the ELT, involving intricate correction across a wide and integration with deformable mirrors like the 2.4-meter M4 unit, which requires advanced calibration to mitigate atmospheric distortions effectively. Environmental and logistical factors at the remote Cerro Armazones site in the have further complicated progress, with harsh weather conditions—including high winds and occasional dust events—disrupting on-site work and contributing to equipment wear. The site's , at over 3,000 meters , has increased transportation costs and difficulties, amplifying overall expenses amid these conditions. Nearby industrial developments have raised concerns about dust emissions during their construction phases potentially affecting observatory operations, though ESO has implemented monitoring to safeguard the ELT site. Budget overruns have been a persistent issue, with the initial construction estimate of approximately €1 billion rising to €1.5 billion by due to , issues, and technical revisions. This escalation prompted ESO to secure additional in 2020, increasing the total to €1.3 billion at that time, while further adjustments addressed challenges. In response to these pressures, a 2021 redesign of optical components, including aspects of the tertiary mirror integration, was undertaken to optimize costs without compromising performance. In March 2025, ESO announced a one-year delay to the ELT's , shifting first light to March 2029 and scientific operations to late 2030, primarily due to the cumulative effects of delays, equipment failures, and extended requirements for the telescope's complex systems. This update reflects the need for thorough on-site verification to ensure reliability, building on the original that targeted completion. To mitigate these setbacks, ESO has accelerated certain manufacturing processes, including enhanced polishing protocols for remaining mirror segments, alongside parallel advancements in instrument assembly. ESO has employed robust strategies throughout the project, including a comprehensive contingency planning framework outlined in the 2012 construction proposal, which identifies, assesses, and mitigates potential issues through regular reporting and scenario analysis. This approach incorporates parallel prototyping for key instruments, allowing early detection of integration challenges and flexible to maintain momentum despite unforeseen disruptions.

Technical Design

Optical System and Mirrors

The optical system of the Extremely Large Telescope (ELT) employs a with a folded configuration, utilizing five mirrors to collect, focus, and correct incoming light from celestial sources. The primary mirror has a fast focal ratio of f/0.87, enabling a compact structure while delivering a wide 10 arcminute at the Nasmyth foci with an overall focal ratio of f/17.75. This setup, combined with integrated adaptive elements, supports an approximately 10 times sharper than that of the (VLT) in the near-infrared, fundamentally enhancing imaging capabilities for astronomical observations. At the core of the system is the primary mirror (M1), a 39-meter-diameter concave aspheric mirror composed of 798 hexagonal segments, each measuring 1.45 meters across and 50 millimeters thick, collectively providing a light-collecting area of 978 square meters. These segments, made from low-expansion ZERODUR glass-ceramic, are individually adjustable to maintain optical coherence across the surface, with each supported by a 27-point whiffletree mechanism and equipped with a warping harness featuring 9 actuators for correcting low-order aberrations like astigmatism and trefoil, plus 3 high-precision positioning actuators (PACTs) offering 2-nanometer accuracy and 10-millimeter stroke range. In total, these actuators—numbering around 9,576 across all segments—enable active co-phasing and alignment to compensate for gravitational distortions and thermal effects, ensuring the mirror behaves as a monolithic optic. The contract for manufacturing the segment blanks was awarded to SCHOTT in Germany in May 2017, with Safran Reosc in France responsible for polishing, integration, and testing. The secondary mirror (M2), positioned above M1, is a 4.25-meter-diameter with an 800-millimeter inner hole and 100-millimeter thickness, weighing 3,533 kilograms and featuring an extreme of 8,810 millimeters (f/1.1). Made from , it reflects light to the tertiary mirror while incorporating fast recentering capabilities for tip-tilt corrections, aiding in initial wavefront stabilization. The polishing and mounting contract for M2 was signed with Safran Reosc in in July 2016. The secondary mirror was completed in early 2025. The tertiary mirror (M3), a 4-meter-diameter concave optic with a 100-millimeter thickness and of 21,090 millimeters (f/2.6), relays light from M2 toward the adaptive elements, enhancing image quality through its anastigmatic properties and including fine tracking adjustments for precise alignment during observations. Also constructed from and weighing 3,258 kilograms, its design minimizes aberrations in the light path. The contract for polishing M3 was awarded to Reosc in February 2017. The quaternary mirror (M4) serves as the primary adaptive optic in the system, a 2.4-meter-diameter flat mirror inclined at 7.75 degrees and composed of six 1.95-millimeter-thick thin shells, conjugated to a height of 621 meters above M1 to correct atmospheric distortions. Equipped with over 5,000 voice coil actuators, it deforms the surface up to 50 microns with sub-100-nanometer precision, updated 1,000 times per second based on real-time wavefront measurements taken 70,000 times per second. This enables higher-order aberration correction directly in the telescope beam. Finally, the quinary mirror (M5), an elliptical flat mirror measuring 2.7 by 2.2 meters and built from six lightweight silicon-carbide segments, functions as the field's stabilizer by performing tip-tilt adjustments with milli-arcsecond accuracy up to 10 hertz, mitigating vibrations from wind, dome, and mechanics before directing light to the Nasmyth platforms. As the largest tip-tilt mirror ever constructed, it ensures stable image delivery for high-resolution science. The design and production contract for M5 was awarded to Reosc in March 2019.

Adaptive Optics and Sensors

The Extremely Large Telescope (ELT) employs advanced (AO) systems to counteract the distortions caused by Earth's atmospheric turbulence, enabling near-diffraction-limited performance across a range of wavelengths. These systems integrate multi-conjugate (MCAO) with laser guide stars (LGS) and multiple wavefront sensors to provide of the atmosphere, correcting aberrations over an extended . The design relies on a combination of natural and artificial guide stars, supplemented by high-speed deformable mirrors, to achieve high-fidelity and . At the core of the ELT's AO is the multi-conjugate adaptive optics module MORFEO, which uses six sodium guide stars to generate artificial stars by exciting sodium atoms in the at approximately 90 km altitude. These LGS, projected from the periphery of the primary mirror, form a circular constellation on the sky, enabling nearly full sky coverage for observations while requiring three natural guide stars for low-order corrections and truth wavefront sensing. The tomographic approach reconstructs the three-dimensional turbulence profile using data from these six LGS and natural stars, allowing correction across a supporting instruments like MICADO, with uniform performance over 1-2 arcminutes in the near-infrared. Wavefront sensors play a critical role in measuring atmospheric distortions in , operating at frequencies up to 500-1000 Hz to capture rapid changes. The system includes dedicated LGS wavefront sensor modules—six for the lasers—along with natural guide star sensors such as and up to three additional low-order sensors, utilizing advanced detectors like those developed with Teledyne for high-speed readout. These sensors feed data to control computers that process distortions at sub-millisecond intervals, enabling precise adjustments. Deformable mirrors provide the corrective action, with the primary AO corrector being the M4 mirror, a 2.4-meter-diameter adaptive surface composed of six thin segments. M4 features over 5,000 actuators that deform the mirror up to 1,000 times per second with nanometer precision, compensating for higher-order aberrations. Additional deformable mirrors in modules like MORFEO—up to three more—conjugate corrections at different atmospheric layers, enhancing uniformity across the field. Unlike earlier concepts, the ELT's secondary mirror (M2) is a fixed 4.25-meter optic, with adaptive functionality centralized on M4 and instrument-specific modules. The ELT's AO systems deliver significant performance gains, achieving Strehl ratios of up to 50% at 2.2 μm under optimal conditions and 30% under median seeing, approaching diffraction-limited resolution at near-infrared wavelengths from 0.5 to 2.5 μm. This correction mitigates over 80% of turbulence-induced errors in typical scenarios, vastly improving image sharpness compared to uncorrected ground-based observations. For the primary mirror's 798 hexagonal segments, alignment relies on approximately 9,000 capacitive edge sensors (in about 4,500 pairs), each providing nanometer-resolution measurements of relative , , and tilt between adjacent segments to maintain global optical coherence. These sensors, developed by the FAMES consortium (Fogale Nanotech and Micro-Epsilon), integrate into the M1 support system designed by in collaboration with partners. Integration of the AO and sensor systems will occur post-installation of the primary mirror segments, with initial testing of sensors and deformable mirrors expected at the ELT site in ahead of first light targeted for 2029. This phased approach ensures calibration of the full AO chain, including LGS projection and tomographic algorithms, under real atmospheric conditions.

Enclosure, Dome, and Infrastructure

The of the Extremely Large Telescope (ELT) consists of a massive rotating dome designed to protect the telescope from the harsh environmental conditions of the , including high winds, dust, and extreme temperature variations. The dome stands 80 meters high with a of 93 meters, covering a footprint equivalent to a , and features a thermally insulated aluminum cladding on its exterior to minimize . Its upper section rotates to align with the telescope's pointing direction, while the lower part is a fixed 11-meter-high . The structure weighs approximately 6,100 tons for the rotating and incorporates 118 seismic isolators to safeguard against earthquakes common in the region. The dome employs a clamshell-like with two large motorized slit doors, each measuring 23 by 55 meters and weighing 600 tons, that open laterally to provide a 41-meter for observations. These doors are equipped with seals and latching mechanisms to ensure a tight closure when not in use, minimizing dust ingress and wind exposure. The speed reaches up to 2 degrees per second, equivalent to a linear speed of about 5 kilometers per hour, allowing the dome to track celestial targets within 5 minutes while avoiding vibrations that could degrade image quality. Observations can be conducted from the down to 20 degrees above the horizon, optimizing access to a wide area. The mount is an alt- system comprising and altitude structures supported by a dedicated , structurally isolated from the dome to prevent transmission. The features three concentric hydrostatic oil-bearing tracks with diameters of 51 meters, 34 meters, and 6 meters, driven by linear that achieve within a few tenths of a millimeter. Encoders on these drives enable high-accuracy pointing and tracking, supporting the ELT's demanding observational requirements. An additional radial track supports the altitude , with perforated plates integrated into the to facilitate airflow around the primary mirror. Supporting infrastructure includes a retractable windscreen composed of four curved, movable panel segments that adjust based on the telescope's inclination to reduce wind buffeting on the and instruments. A ventilation system with 89 louvers covering 1,240 square flushes hot air from the enclosure, improving seeing conditions by minimizing thermal turbulence. Active thermal control is provided by a 3-megawatt system that maintains stable internal temperatures, complemented by auxiliary facilities in a 117-meter-diameter building for mirror storage, maintenance, and support systems. The enclosure's design targets dome-induced seeing of less than 0.3 arcseconds through optimized thermal management, including the and cooling systems that prevent heat buildup from affecting quality. This performance is critical at the high-elevation , where ambient seeing is around 0.67 arcseconds at 500 nanometers. Backup power via generators and fiber optic links to the Paranal control center ensure operational reliability and remote monitoring. Contracts for the dome and main structure, including the mount, were awarded in 2016 to the —comprising , Cimolai, and EIE Group—for design, fabrication, transport, assembly, and verification, marking ESO's largest-ever ground-based astronomy contract at €400 million.

Scientific Objectives and Capabilities

Primary Science Goals

The Extremely Large Telescope (ELT) is designed to address fundamental questions in astronomy, spanning the search for habitable exoplanets, the origins of the , and the processes driving evolution. By providing unprecedented sensitivity and , the ELT will enable breakthroughs in understanding the diversity of planetary systems, the epoch of , and the dynamics of stellar populations within our and beyond. A primary goal is the direct imaging and of exoplanets, particularly Earth-like worlds in habitable zones around nearby stars, to characterize their atmospheres and detect potential biosignatures such as oxygen and . The ELT will also investigate protoplanetary disks to trace planet formation processes and identify pre-biotic molecules, offering insights into the emergence of life-supporting environments. This capability will transform exoplanet science by shifting from indirect detection methods to detailed compositional analysis. In , the ELT aims to probe the early by resolving galaxies at s greater than 10, illuminating the reionization epoch when the first stars and quasars ionized the intergalactic medium. It will measure the cosmic expansion rate through techniques like drift, providing constraints on and the 's acceleration. These observations will refine models of the and the initial . For , the ELT will dissect the dynamics of satellite galaxies, mapping their stellar populations to uncover merger histories and distributions. It will also study feedback mechanisms in nearby galaxies, examining how supermassive s regulate and gas flows. Additional objectives include asteroseismology of stars to determine their ages and internal structures, as well as detailed follow-up of transient events like supernovae to probe stellar explosions and . The ELT will synergize with space-based observatories such as JWST for multi-wavelength studies of these phenomena. Legacy science programs will leverage the ELT for wide-field imaging surveys, compiling catalogs of up to 10 billion stars to study Galactic structure and across the . These efforts will also map through gravitational lensing effects on background galaxies, revealing the invisible scaffolding of the and testing theories of on cosmic scales.

Expected Performance and Resolutions

The (ELT) will feature a primary mirror with a collecting area of 978 m², approximately 18 times that of a single (VLT) Unit Telescope. This enhanced light-gathering power will enable the detection of celestial objects up to nearly 20 times fainter than those observable with a single VLT Unit Telescope under similar conditions in photon-limited scenarios (or about 4-5 times fainter in background-limited cases) or facilitate surveys that are nearly 20 times faster due to the increased photon collection rate. Equipped with advanced , the ELT will achieve a diffraction-limited of approximately 4 milliarcseconds () at a of 500 , allowing for sharp imaging of fine details in astronomical targets. Without , operational modes will support plate scales up to 10 , suitable for wider-field observations limited by atmospheric seeing at the site. The telescope will also provide spectral resolutions up to R = 20,000, enabling detailed analysis of spectral features such as those in planetary atmospheres. The ELT's Nasmyth foci will offer a field of view of 10 arcminutes for imaging instruments, supporting broad sky coverage in a single pointing. Multi-integral field unit (IFU) configurations will allow simultaneous acquisition of thousands of spectra across the field, enhancing efficiency for spectroscopic surveys. The instrument suite will cover a wavelength range from 0.37 μm in the optical to 20 μm in the mid-infrared, with overall system throughput exceeding 80% in key bands due to optimized coatings and optics. In terms of , the ELT will detect at 40th visual in about one hour of integration time for point-source , representing a substantial improvement over current facilities. For imaging, it will resolve companions up to 100 times fainter than their host in the near-infrared, leveraging high-contrast techniques. Compared to the Keck telescopes, the ELT's light grasp will be roughly 13 times greater, while its site at Cerro Armazones provides superior mid-infrared performance over the (GMT) and (TMT) due to exceptionally low atmospheric water vapor content.

Instrumentation

Planned Instruments Overview

The Extremely Large Telescope (ELT) will feature a suite of first-generation instruments designed to leverage its 39-meter for groundbreaking observations across optical and wavelengths. Four of these instruments will start to operate at or shortly after ELT technical first light, including spectrographs, imagers, and specialized cameras optimized to work in conjunction with the telescope's systems to achieve diffraction-limited performance, addressing key areas such as characterization, , and stellar populations. HARMONI, the High Angular Resolution Monolithic Optical and Near-infrared Integral Field Spectrograph, is a workhorse 3D spectrograph operating from 0.47 to 2.45 μm with spectral resolutions up to 18,000. It provides field unit (IFU) capabilities for spatially resolved of extended sources, supporting studies of atmospheres and galactic structures through its -assisted modes. MICADO, the Multi-conjugate Adaptive optics Imaging Camera for Deep Observations - Near-infrared, serves as the ELT's primary near-infrared imager in the 0.8–2.45 μm range, offering a 28 × 28 arcsecond at 4 milliarcsecond pixel scale. This AO-assisted instrument excels in high-contrast, high-resolution imaging of crowded fields, such as star clusters and distant galaxies, with capabilities for single-slit up to resolution 20,000. It will operate with the MAORY module. MAORY, the Multi-conjugate Relay, is the first-generation AO facility for the ELT, providing high-performance correction over wide fields in the near-infrared (0.8–2.45 μm). It enables diffraction-limited for MICADO and prepares for future instruments by using multiple laser guide stars and deformable mirrors to mitigate atmospheric . METIS, the Mid-infrared ELT Imager and Spectrograph, covers 3–13.5 μm for and 3–5 μm for , incorporating a for suppressing starlight to reveal faint companions. It features low- to high-resolution modes (up to R ≈ 100,000) and a nulling option, enabling direct and characterization of exoplanets and warm circumstellar material. Subsequent instruments include , the Planetary Camera and Spectrograph (formerly EPICS), a visible-to-near-infrared (0.6–2.2 μm) instrument focused on high-contrast polarimetric and for detecting and analyzing and protoplanetary disks. It employs advanced coronagraphy and to probe magnetic fields and disk structures around young stars. , the ArmazoNes high Dispersion Echelle Spectrograph (formerly HIRES), is a fiber-fed echelle spectrograph spanning 0.4–1.8 μm (goal to 2.4 μm) with a of approximately 100,000. It facilitates precise measurements for detection and high-fidelity stellar to trace chemical abundances in ancient stars. The first-generation instruments are scheduled for installation starting in 2029, coinciding with the ELT's technical first light in early 2029 and scientific operations beginning in 2030.

Instrument Development and Integration

The development of the Extremely Large Telescope (ELT) instruments involves international led by key European institutions, with HARMONI spearheaded by the in collaboration with French and Spanish partners, commencing formal agreement in September 2015. As of late 2024, HARMONI is undergoing a redefinition of its scope and changes. Similarly, MICADO is managed by the Max Planck Institute for Astronomy (MPIA) in , with an international from six countries, following a agreement signed in September 2015. These efforts, along with other first-generation instruments like and the MAORY module, engage over 20 institutions across multiple countries, fostering collaborative engineering and scientific input. Second-generation instruments such as and are in earlier development phases. Contracts for instrument development exceed €150 million in total value, allocated within the ELT's overall €1.5 billion budget, with prototypes undergoing laboratory testing to validate designs. For instance, HARMONI prototypes for adaptive optics components were tested at ESO's headquarters in Garching, Germany, in 2023, confirming system performance metrics. MICADO's final design review was completed in September 2024, paving the way for subsystem integration starting late that year at MPIA facilities. Integration of instruments into the ELT presents engineering challenges, particularly cryogenic cooling for infrared instruments like , which requires low-vibration systems to maintain detector temperatures below 4 without introducing mechanical disturbances. Alignment with the telescope's systems demands sub-micron precision to ensure correction compatibility, while on the mount is critical to mitigate disturbances from cryocoolers and platform rotations, as addressed in MICADO's rotary platform design. Testing phases include on-site mockups scheduled for 2026-2027 to simulate instrument-telescope interfaces during completion, followed by full after dome in early 2027. The ELT's modular instrument design facilitates upgrades, allowing new instruments to be incorporated post-2030 without major structural changes, supported by a allocation of approximately 20% of the total project for instrumentation and future enhancements. METIS is advancing toward shipment in 2028 following its final design review in 2024. continues development of its fiber-feeding system for enhanced stability in high-resolution across UV to near-IR wavelengths.

Comparisons and Legacy

Comparison with Other Major Telescopes

The (ELT), with its 39-meter primary mirror providing a collecting area of 978 , represents a significant advancement over contemporary giant telescopes in terms of light-gathering power and , particularly when equipped with (AO). Compared to existing facilities like the 8.2-meter (VLT) units of the (ESO) and the 10-meter Keck telescopes, the ELT offers approximately 18 times the light grasp of a single VLT unit and 12 times that of a Keck telescope, enabling the detection of fainter objects and the routine direct imaging of exoplanets in unprecedented detail. With advanced AO, the ELT is expected to achieve 5 to 10 times the resolution of these predecessors across near-infrared wavelengths, opening new regimes in high-contrast imaging and . In comparison to other planned extremely large telescopes, the ELT surpasses the (GMT) in collecting area, offering 978 m² versus the GMT's 368 m² from its seven 8.4-meter segments, which translates to roughly 2.7 times greater light-gathering capability despite the GMT's off-axis design that avoids central obstructions for improved image quality. Both projects target first light around the early , with the ELT's scientific operations slated for 2030 and the GMT on track for the early , though the GMT's segmented design emphasizes multi-conjugate for wide-field corrections similar to the ELT's approach. The (TMT), with a 30-meter and 655 m² collecting area, is more comparable in scale to the ELT but observes from in , providing superior access to targets while the ELT's Cerro Armazones in excels for southern sky observations. The TMT has faced significant legal and community-related delays, including ongoing permit challenges and protests since 2015; as of November 2025, discussions are underway for construction on an alternative on , stalling construction and pushing its first light timeline to an undetermined date beyond initial 2027 estimates, whereas the ELT remains ahead with over 50% construction progress as of early 2025.
TelescopeAperture (m)Collecting Area (m²)LocationEstimated First LightTotal Cost (approx.)
ELT39978Dec 2030€1.5 billion
GMT25.4 (effective)368Early 2030s$2.6 billion
TMT30655TBD (delayed)$3 billion
VLT (single unit)8.2531998 (operational)N/A (existing)
Keck (single)1078.51993/1996 (operational)N/A (existing)
The ELT builds on proven technologies from earlier observatories, such as segmented primary mirrors pioneered by the Keck telescopes with 36 hexagonal 1.8-meter segments, but scales this up dramatically to 798 segments of 1.45 meters each for finer control and stability. Its system advances beyond that of the 8-meter telescopes, incorporating laser guide stars and deformable mirrors with thousands of actuators to correct atmospheric distortion over wider fields, enhancing performance for integral field spectroscopy and high-resolution imaging. Cost-wise, the ELT's €1.5 billion budget reflects ESO's collaborative efficiencies among 16 member states, contrasting with the GMT's higher $2.6 billion USD figure driven by a U.S.-led model.

Potential Impact on Astronomy

The Extremely Large Telescope (ELT) is poised to drive transformative advancements in astronomy by enabling groundbreaking discoveries that could reshape our understanding of the . Among its most anticipated contributions is the potential to detect and characterize the atmospheres of habitable exoplanets, possibly confirming the first signs of life beyond through high-resolution capable of identifying biosignatures such as oxygen or . This capability stems from the ELT's systems and instruments like , which will suppress stellar glare to reveal faint planetary signals. Additionally, the ELT will refine measurements of the equation of state by surveying thousands of distant type Ia supernovae, providing crucial data to probe the and test cosmological models. The ELT will foster synergies with major observatories, enhancing multi-wavelength and multi-messenger astronomy. It is designed to complement the (JWST) by offering ground-based spectroscopic follow-up to JWST's infrared imaging, particularly for high-redshift galaxies and exoplanet studies, through instruments like that integrate JWST data for deeper analysis. Similarly, the ELT will collaborate with the via shared data pipelines for transient events, enabling rapid follow-up of sources and supernovae detected in Rubin's wide-field surveys. ESO's open-access policy ensures that ELT data, after a one-year period for principal investigators, becomes freely available worldwide through the ESO Archive Facility, promoting collaborative research and reproducibility. In education and outreach, the ELT will inspire global engagement and build capacity in astronomy. ESO's Studentship Programme and lifelong training initiatives will prepare hundreds of young astronomers and engineers for ELT operations, offering hands-on experience at ESO facilities and fostering expertise in and . Public outreach efforts, including teacher training schools and visitor programs at sites like the ESO , will engage diverse audiences with ELT discoveries, emphasizing its role in addressing fundamental questions about our cosmic origins. These programs align with ESO's commitment to developing talent, ensuring European and international in ground-based astronomy. The ELT's long-term legacy extends beyond its operational lifespan, projected to exceed 50 years, positioning it as a for future ground-based facilities. By validating segmented mirror technologies and advanced on a 39-meter scale, it will inform the design of next-generation 100-meter-class telescopes, advancing the frontiers of optical astronomy into the mid-21st century. In , where the ELT is located, ESO's investments provide substantial economic benefits, with over 80% of the —totaling more than €1.5 billion—allocated to contracts with local industries, and ongoing operations expected to generate annual economic impacts exceeding €100 million through jobs, , and . Addressing risks and ethical considerations is integral to the ELT's development. ESO actively mitigates threats to its Chilean observatories, as demonstrated by analyses opposing industrial projects that could increase by 35-50% at sites like Paranal, ensuring pristine conditions for ELT observations. The open-access data policy further promotes equitable sharing, enabling researchers from the Global South to participate via ESO's collaborative frameworks and partnerships, countering historical imbalances in astronomical access. From a 2025 perspective, despite construction delays pushing first light to 2029, the remains the flagship project for ground-based astronomy, securing Europe's position at the forefront of discoveries through the 2050s.

References

  1. [1]
    About - ELT | ESO
    ESO's Extremely Large Telescope, or ELT for short, is a revolutionary ground-based telescope that will have a 39-metre main mirror and will be the largest ...Webcams · Timeline · Location · Meet the Team
  2. [2]
    Telescope - ELT | ESO
    The giant ELT dome will house the telescope and its interior structure, providing protection from the extreme environment of Chile's Atacama Desert.
  3. [3]
    science with the european extremely large telescope - ELT - ESO
    Dec 10, 2021 · The science case for the European Extremely Large Telescope (ELT) is drawn from many areas of astronomy and it covers a huge range of topics: ...
  4. [4]
    Timeline - ELT | ESO
    The ELT's secondary mirror is expected to be completed in early-mid 2025. With a diameter of 4.25 metres, M2 will be the largest of its kind in the world. Jan ...
  5. [5]
    Science - ELT | ESO
    The Science Case for the ELT started being prepared in 2009 with the help of: the ELT Science Working Group who prepared the Design Reference Mission;; close ...
  6. [6]
    [PDF] OWL Concept Study - Eso.org
    The idea of a 100-m-class telescope origi- nated in 1997, when it was assessed that true progress in science perform- ance after HST and the 8–10-m-class. Keck ...
  7. [7]
    [PDF] Science Cases and Requirements for the ESO ELT Report of the ...
    Apr 30, 2006 · Here we make the case how future ELTs (>30m diameter) help to understand the formation and early dynamical evolution of massive stars embedded ...
  8. [8]
    [PDF] Science with Extremely Large Telescopes - ESO
    An ELT has the potential to observe such galaxy haloes in the pro- cess of formation: observations of the motion of the central galaxy and its satellites will ...
  9. [9]
    [PDF] WG3 - ELT Site Evaluation Working Group Final Report - ESO
    Apr 13, 2006 · The WG3 has been tasked to categorize site characteristics, to list all sites considered throughout the world (including Antarctica), ...
  10. [10]
    E-ELT Science Working Group - Eso.org
    The Science Working Group (SWG) was originally formed by ESO in December 2005 as one of five mixed community-ESO working groups.
  11. [11]
    ESO To Build World's Biggest Eye On The Sky
    At its meeting in Garching today, the ESO Council approved the European Extremely Large Telescope (E-ELT) Programme, pending confirmation of ...
  12. [12]
    [PDF] ELT Construction Proposal - ESO
    Apr 4, 2012 · This document presents a 1083 million euro (M€), 11-year programme for the construction of the Euro- pean Extremely Large Telescope (E-ELT), ...<|separator|>
  13. [13]
    The Rise of a Giant - ESO
    Dec 11, 2006 · This study, with a budget of 57 million euro, will make it possible to start, in three years time, the construction of an optical/infrared telescope with a ...
  14. [14]
    Green Light for E-ELT Construction - ESO
    Dec 4, 2014 · The construction of the E-ELT was approved by ESO's Council in June 2012 under the condition that contracts with a value larger than 2 million ...
  15. [15]
    FAQ | ELT - ESO
    Funding for the project was approved gradually, starting in 2014. ... ESO's Extremely Large Telescope (ELT). In March 2019, ESO signed a contract ...
  16. [16]
    German Involvement with the European Southern Observatory | ESO
    Germany currently contributes 22.44% of ESO's revenue (2021 contribution), worth 43 091 000 EUR. As of mid 2022, there are 159 German employees at ESO, 137 in ...
  17. [17]
    French Involvement with the European Southern Observatory | ESO
    France currently contributes 14.96% of ESO's revenue (2021 contribution), worth 28 728 000 EUR. As of mid 2022, there are 76 French nationals employed at ESO, ...Missing: Brazil | Show results with:Brazil
  18. [18]
    Member States - Eso.org
    The European Southern Observatory (ESO) is an intergovernmental organisation with 16 Member States. These Member States are:
  19. [19]
    ESO Signs Contracts for the ELT's Gigantic Primary Mirror
    May 30, 2017 · The German company SCHOTT will produce the blanks of the mirror segments, and the French company Safran Reosc will polish, mount and test the ...Missing: ACEC | Show results with:ACEC
  20. [20]
    ESO Signs Largest Ever Ground-based Astronomy Contract for ELT ...
    May 25, 2016 · The contract covers the design, manufacture, transport, construction, on-site assembly and verification of the dome and telescope structure.Missing: Schott blanks ACEC
  21. [21]
    Groundbreaking for the E-ELT - ESO
    Jun 19, 2014 · The E-ELT first light is planned for 2024, when it will begin to tackle the biggest astronomical challenges of our time. The giant telescope is ...Missing: date | Show results with:date
  22. [22]
    ELT (Extremely Large Telescope) - eoPortal
    This revolutionary new ground-based telescope concept will have a 39 meter main mirror and will be the largest optical/near-infrared telescope in the world.
  23. [23]
    First ELT Main Mirror Segments Successfully Cast - Eso.org
    Jan 9, 2018 · The first six hexagonal segments for the main mirror of ESO's Extremely Large Telescope (ELT) have been successfully cast by the German company SCHOTT.
  24. [24]
    ESO's Extremely Large Telescope is now half completed - Eso.org
    Jul 11, 2023 · Construction of this technically complex project is advancing at a good pace, with the ELT now surpassing the 50% complete milestone. The ...
  25. [25]
    https://www.eso.org/public/news/eso2319/
  26. [26]
    Celebrations held as dome of ESO's Extremely Large Telescope ...
    Apr 16, 2025 · Celebrations held as dome of ESO's Extremely Large Telescope reaches its peak. 16 April 2025. Reaching the top of the ELT dome ... The Topping Out ...
  27. [27]
    Installing the giant doors of the Extremely Large Telescope - ESO
    May 2, 2025 · We're currently installing the giant sliding doors that will protect the ELT from the elements during the day, and open up at night to observe the Universe.
  28. [28]
    Picture of the Week 2025 - ESO
    3 November 2025: As the construction of ESO's Extremely Large Telescope (ELT) ... important milestone: the first movement of one of the dome's giant doors.
  29. [29]
    Telescope first light for ESO's Extremely Large Telescope now ...
    Mar 14, 2025 · Telescope first light for ESO's Extremely Large Telescope now planned for March 2029. 14 March 2025. The shining dome of the ELT, and the cranes ...
  30. [30]
    Location - ELT | ESO - Eso.org
    On 26 April 2010, the ESO Council selected Cerro Armazones as the site for the planned 40-metre-class ELT. Cerro Armazones is a mountain at an altitude of 3046 ...
  31. [31]
    [PDF] E-ELT site characterization status - Eso.org
    E-ELT site characterization started in 2005, focusing on two top sites and exploring alternatives, with the work ending in December 2008.
  32. [32]
    E-ELT site characterization status - SPIE Digital Library
    Jul 10, 2008 · The site selection for the future European Large Telescope (E-ELT) is a key issue within the European proposal funded by the EC, within the ...
  33. [33]
    ELT Site - ESO
    Apr 26, 2010 · The decision on the ELT site was based on an extensive comparative meteorological investigation, which lasted several years. Various factors ...
  34. [34]
    World's biggest telescope to be located on Cerro Armazones, Chile
    Apr 28, 2010 · Various factors needed to be considered in the site selection process. Obviously, the number of clear nights, the amount of water vapor, and the ...
  35. [35]
    Chile Wins Battle to Host Mega-Telescope | Science | AAAS
    The committee came down in favor of Armazones because it had a winning combination of excellent all-round sky quality and is just 20 kilometers from ESO's Very ...
  36. [36]
    Preparing for the construction of the European Extremely Large ...
    Societal impact. Impact on the host country for the E-ELT: The E-ELT baseline site, Cerro Armazones in Chile, was chosen on the basis of stringent ...
  37. [37]
    [PDF] E-ELT PROGRAMME - ESO
    Apr 26, 2012 · 202 Site services shall be implemented in a way, which minimizes the impact on environmental conditions relevant to scientific quality and ...
  38. [38]
    Flying progress on the ELT - ESO
    Nov 28, 2022 · Construction on the world's biggest eye on the sky, ESO's Extremely Large Telescope (ELT) continues at the summit of Cerro Armazones in the Chilean Atacama ...
  39. [39]
    [PDF] ELT Status - Eso.org
    Apr 16, 2025 · We provided expert review of the ELT's engineering design to ensure its successful delivery and long-term performance as a cutting-edge ...
  40. [40]
    Last segment of the world's largest telescope mirror successfully cast
    Jun 27, 2024 · When it starts operating later this decade, ESO's ELT will be the world's largest eye on the sky. It will tackle the biggest astronomical ...
  41. [41]
    Environmental sustainability at ESO - Eso.org
    ESO is actively committed to reducing CO 2 emissions, using renewable fuel where possible, reducing pollution, saving water, and preserving the legacy of our ...
  42. [42]
    [PDF] Annual Report 2022 - ESO
    have predicted that the ELT Programme was about to enter new troubled waters. On top of the COVID-related disruption to supply chains, both rising inflation.
  43. [43]
    Covid complications and Chile unrest hit ELT schedule - Optics.org
    Dec 17, 2020 · The combination of the Covid-19 pandemic and social unrest in Chile, where the ELT is being built, meant that “first light” was now pencilled in for November ...
  44. [44]
    Aligning the mirrors of the world's largest optical telescope - ESO
    Sep 23, 2025 · The Phasing and Diagnostics Station (PDS) will monitor the ELT's optics and ensure that all segments work together as single giant mirror.
  45. [45]
    https://www.hexagon.com/resources/resource-library/measuring-mirror-segments-for-the-extremely-large-telescope
  46. [46]
    New challenges for adaptive optics: extremely large telescopes
    Another constraint comes from the telescope design. The telescope FOV of an ELT is a strong cost driver and, at the moment, a full tomographic FOV (17 arcmin) ...
  47. [47]
    Industrial mega-project in Chile threatens one of the most important ...
    Jan 24, 2025 · “Dust emissions during construction, increased atmospheric turbulence and, especially, light pollution, will have an irreparable impact on ...
  48. [48]
    A giant European telescope rises as U.S. rivals await rescue - Science
    Oct 18, 2023 · ESO's Extremely Large Telescope (ELT) under construction at sunrise in the Chilean Atacama Desert In August, the Sun rose behind the Extremely ...
  49. [49]
    Funding boost for ESO's Extremely Large Telescope
    the organisation's main governing body — brings the total cost of the project to €1.3 billion.Missing: seed | Show results with:seed<|separator|>
  50. [50]
    Mirrors - ELT | ESO
    The primary, M1, is the most spectacular: a giant 39-metre concave mirror that will collect light from the night sky and reflect it to the secondary mirror. The ...
  51. [51]
    E-ELT Optical Design - Eso.org
    Jun 16, 2011 · The optical design for the E-ELT is that of a folded three-mirror anastigmat, folding being provided by two flat mirrors sending the beam to either Nasmyth ...
  52. [52]
    Facts about the ELT - ELT | ESO - Eso.org
    Name: Extremely Large Telescope (ELT). Main mirror diameter: 39 metres. Light collecting area: 978 square metres. Number of main mirror segments: 798.Missing: workforce workers
  53. [53]
    M1 Mirror - ELT - ESO
    All in all, the M1 is a colossal system, featuring a staggering 798 segments, almost 2500 PACTs and about 9000 edge sensors (4500 pairs), not including the ...
  54. [54]
    M2 and M3 Mirrors - ELT | ESO
    The ELT's M2 mirror, with its 4.25-metre diameter, will, like many aspects of the ELT, set another record in the astronomical landscape. M2 will be the largest ...<|control11|><|separator|>
  55. [55]
    ESO Signs Contract to Polish the E-ELT Secondary Mirror
    Jul 6, 2016 · The M2 polishing contract is signed. ESO has signed a contract with the French company Reosc [1], a subsidiary of Safran Electronics ...
  56. [56]
    ESO Awards Contract to Polish the ELT Tertiary Mirror
    Feb 15, 2017 · ESO has now awarded the contract to polish the third mirror in the light path, known as M3, to the French company Reosc.Missing: ACEC | Show results with:ACEC
  57. [57]
    M4 Mirror | ELT | ESO
    ### M4 Mirror Specifications
  58. [58]
    M5 Mirror - ELT | ESO
    M4 and M5 — form part of the adaptive optics system ...
  59. [59]
    Adaptive Optics | ELT - ESO
    From the largest adaptive mirror ever built to advanced control systems, the ELT will have some of the most sophisticated technologies ever employed on a ...
  60. [60]
    MORFEO | ELT | ESO
    ### Summary of MCAO for ELT (MORFEO)
  61. [61]
    https://arxiv.org/abs/1712.04222
  62. [62]
    [PDF] designing a laser guide star wavefront sensors for the ELT - arXiv
    A fold mirror sends the 6 laser beams vertically upwards where they are individually intercepted by the six LGS Wavefront sensor Modules. (LWM). These are ...
  63. [63]
    Design achievements for actuators and sensors of the main mirror of ...
    Nov 24, 2020 · The primary mirror on the ELT, M1, is composed of 798 hexagonal segments, made of a thin glass-ceramic material.
  64. [64]
    Laser sources for ESO's ELT and GRAVITY+ now completed
    Sep 30, 2024 · ... artificial stars. These 'stars' are used to measure the blurring ... [1] The ELT can accommodate a total of eight laser guide stars. It ...
  65. [65]
    Dome - ELT | ESO
    The giant ELT dome will house the telescope and its interior structure, providing protection from the extreme environment of Chile's Atacama Desert.Missing: specifications infrastructure
  66. [66]
    Main Structure | ELT - ESO
    The largest concentric track has a diameter of 51 m, with the intermediate and central tracks having diameters of 34 m and 6 m, respectively. The tracks are ...
  67. [67]
    The ELT's dome and windscreen in action - ESO
    May 6, 2024 · The windscreen design is based on four curved plate segments that can be moved up and down depending on the inclination of the telescope. Credit ...Missing: infrastructure cooling
  68. [68]
    None
    ### Summary of Primary Science Goals for ELT (ESO ELT Science Case)
  69. [69]
    [PDF] ESO's Extremely Large Telescope (ELT)
    Thanks to this giant mirror, and other sophisticated systems, ESO's. ELT will provide images 15 times sharper than those from the NASA/ESA Hubble Space ...Missing: volume | Show results with:volume<|control11|><|separator|>
  70. [70]
    MOSAIC - ELT | ESO
    ... spectral resolving power (R~5000 and R~20,000). High multiplex mode in the near-infrared (HMM-NIR): Simultaneous integrated-light observations of 80 objects ...
  71. [71]
    [PDF] MOSAIC - (CAB), INTA
    THE HIGH MULTIPLEX AND MULTI-IFU. SPECTROGRAPH FOR THE ELT. MOSAIC. Page 2. MOSAIC: ELT'S MULTI-OBJECT SPECTROGRAPH ... THOUSANDS OF GALAXIES AT Z > 6. Page 7 ...<|control11|><|separator|>
  72. [72]
    [PDF] The European Extremely Large Telescope - NExScI
    Ground-based ELTs with AO have superb spatial resolution, and gain more than 3 magnitudes in sensitivity and more than a factor 500 in speed over 8-m ...Missing: 40th | Show results with:40th
  73. [73]
    MOSAIC: the high-multiplex and multi-IFU spectrograph for the ELT
    Dec 15, 2020 · Conceived as a multi-purpose instrument, it offers both high multiplex and multi-IFU capabilities at a range of intermediate to high spectral ...Missing: thousands | Show results with:thousands
  74. [74]
    Instruments - ELT | ESO
    After the ELT's spectacular mirrors have collected, corrected and stabilised the light from astronomical objects, it is up to the instruments to analyse it ...
  75. [75]
    HARMONI | ELT | ESO
    ### Summary of HARMONI Instrument for ELT
  76. [76]
    MICADO - ELT | ESO
    A first-generation ELT instrument, MICADO will take high-resolution images of the Universe at near-infrared wavelengths.
  77. [77]
    METIS | ELT | ESO
    ### Summary of METIS Instrument for ELT
  78. [78]
    [PDF] PCS — A Roadmap for Exoearth Imaging with the ELT - ESO
    Prior to the start of the PCS instrument project in a few years, ESO's Technology. Development Program is carrying out dedicated R&D activities concentrating.
  79. [79]
    ANDES - ELT | ESO
    The high-resolution ELT instrument ANDES, formerly known as HIRES, will allow astronomers to study astronomical objects that require highly sensitive ...
  80. [80]
    Agreement Signed for MICADO Camera for E-ELT - ESO
    Sep 18, 2015 · ESO has signed an agreement with a consortium of institutes across Europe [1], to design and construct the MICADO camera (Multi-AO Imaging ...
  81. [81]
    ELT Instrument Consortia - ESO
    Jul 10, 2025 · The MICADO project is managed by an international consortium composed of research institutes from six different countries. Opportunities for ...
  82. [82]
    HARMONI's Adaptive Optics Control System: Design and ... - ESO
    Oct 26, 2023 · We present the design and performance of the multi-AO mode AOCS for HARMONI, covering both hard and soft real time control system performance.Missing: testing | Show results with:testing
  83. [83]
    ELT MICADO instrument passes final design review - mpe.mpg.de
    Sep 3, 2024 · Integration of the various subcomponents of MICADO from the various consortium partners will start at the end of 2024 and will take place in ...
  84. [84]
    https://www.eso.org/public/announcements/ann24013/
  85. [85]
    The MICADO first light imager for the ELT: eliminating vibrations and ...
    Aug 26, 2024 · This paper presents our approach to mitigate the dynamic forces impacting the rotary platform. This platform hosts various critical components, ...
  86. [86]
    Milestone for the ELT instrument METIS: "Final Design Review ...
    May 14, 2024 · METIS is therefore the first instrument for the ELT for which this essential step has been completed. The actual FDR review already took ...Missing: polishing | Show results with:polishing
  87. [87]
    ANDES - Uppsala University
    Sep 16, 2025 · ANDES will operate under both seeing- and diffraction-limited conditions, with a flexible fiber-feeding system that allows for multiple ...
  88. [88]
    Explore the Design - Giant Magellan Telescope
    ... existing research telescopes. 368. sq m. light collection area. 320–25,000. nm. wavelength range from optical to infrared. Location. Las Campanas Peak, Chile.Missing: m2 | Show results with:m2
  89. [89]
    https://giantmagellan.org/explore-the-design/
  90. [90]
    Protest-hit Thirty Meter Telescope receives construction go-ahead in ...
    Jun 27, 2019 · Thirty Meter Telescope project clears latest legal hurdle. The TMT's timeline envisions first light for the observatory in July 2027. However ...
  91. [91]
    Giant Magellan Telescope
    The Giant Magellan Telescope is a $2.6 billion project led by a consortium of 16 universities and research institutions from the United States, Chile, Australia ...Employment · News & Events · Founders · Telescope RenderingsMissing: collecting cost
  92. [92]
    ESO's Extremely Large Telescope planned to start scientific ...
    Jun 11, 2021 · ESO's ELT will be used to push scientific boundaries in fields such as habitable exoplanet discovery, galaxy formation or the study of dark ...Missing: potential | Show results with:potential
  93. [93]
    Synergy - Mosaic ELT
    Synergy arises as JWST imaging complements MOSAIC's spectroscopy, enabling follow-up studies and providing the ultimate tool for high redshift galaxy studies.
  94. [94]
    [PDF] January 2025 - NOIRLab
    Similarly, we expect the upcoming ELTs will be the ideal complement and successors to JWST. To facilitate discussion on ELT synergies with JWST science, the ...
  95. [95]
    ESO Data Access Policy - ESO archive - Eso.org
    Nov 7, 2022 · The Principal Investigators (PIs) of successful proposals for time on ESO telescopes, and their delegates, have exclusive access to their scientific data.Missing: ELT | Show results with:ELT
  96. [96]
    ESO Science Archive - Eso.org
    ESO Science Archive. Scientific data collected at ESO's observatories is freely and openly accessible online through the ESO Science Archive.
  97. [97]
    https://noirlab.edu/public/media/archives/mirrors/pdfsm/mirror008.pdf
  98. [98]
    https://archive.eso.org/cms/eso-data-access-policy.html
  99. [99]
    Teacher Schools | ESO - Eso.org
    ESO and the ESO Supernova Planetarium & Visitor Centre have been involved in several teacher school programmes, with partners such as the EIROforum.
  100. [100]
    ELT - ESFRI Portfolio
    It encourages countries to work together to create a scientific and political capacity for development that is beyond the reach of its individual Member States.
  101. [101]
    https://www.eso.org/public/germany/blog/eso-training-programmes/
  102. [102]
    New ESO analysis confirms severe damage from industrial complex ...
    Mar 17, 2025 · The analysis reveals that INNA would increase light pollution above the Very Large Telescope (VLT) by at least 35% and by more than 50% above the south site of ...
  103. [103]
    Extremely Large Telescope - ESCAPE
    The ELT is a 40m-class telescope, the largest optical/near-infrared telescope, operated by ESO, located in Chile, and will be operational in 2025.
  104. [104]
    Announcements - ESO
    24 July 2025: The Joint Committee ESO-Government of Chile has opened its national financing fund for 2025, which will award more than 500 million Chilean pesos.