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Spektr-RG
Спектр-РГ
Artist's impression of the deployed Spektr-RG
Mission typeX-ray astronomy[1]
OperatorRussian Space Research Institute, German Aerospace Center
COSPAR ID2019-040A Edit this at Wikidata
SATCAT no.44432
Websitesrg.iki.rssi.ru
Mission durationPlanned: 6.5 years[1]
Elapsed: 6 years, 3 months, 21 days
Spacecraft properties
BusNavigator[2]
ManufacturerNPO Lavochkin, Max Planck Institute for Extraterrestrial Physics
Launch mass2,712 kg (5,979 lb)[1]
Payload mass1,210 kg (2,670 lb)[1]
Power1.8 kW
Start of mission
Launch date13 July 2019, 12:31 (2019-07-13UTC12:31) UTC[1][3]
RocketProton-M[1]
Launch siteBaikonur Site 81/24
Orbital parameters
Reference systemSun–Earth L2
RegimeHalo orbit
Main telescope
TypeeROSITA: Wolter
WavelengthsX-ray
Instruments
eROSITA, ART-XC
Spektr program

Spektr-RG (Russian: Спектр-РГ, Spectrum + Röntgen + Gamma; also called Spectrum-X-Gamma, SRG, SXG) is a Russian–German high-energy astrophysics space observatory which was launched on 13 July 2019.[4] It follows on from the Spektr-R satellite telescope launched in 2011.[5]

Background

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The original idea for this X-ray observatory satellite orbiting above Earth's atmosphere, which filters X-rays, was first proposed in the 1980s by Rashid Sunyaev of the Space Research Institute of the USSR Academy of Sciences. Twenty institutions from twelve countries came together to design a large observatory with five telescopes. However, after the collapse of the Soviet Union, the mission was abandoned due to cost-cutting from the Russian space program Roscosmos. The project was resurrected in 2003 with a scaled-down design.[6]

Overview

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eROSITA overview animation from the German Aerospace Center showing the Spektr-RG mission profile

The primary instrument of the mission is eROSITA, built by the Max Planck Institute for Extraterrestrial Physics (MPE) in Germany. It is designed to conduct a seven-year X-ray survey,[7] the first in the medium X-ray band less than 10 keV energies, and the first to map an estimated 100,000 galaxy clusters.[8] This survey may detect new clusters of galaxies and active galactic nuclei. The second instrument, ART-XC, is a Russian high-energy X-ray telescope capable of detecting supermassive black holes.[8]

Spacecraft

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The Spektr-RG mission concept was published in 2005.[9] Construction was finished in 2016, and by mid-2018 it was under integration and testing. It was scheduled to be launched in June 2019 but was delayed to 12 July, before the flight was postponed at the last moment. It launched the next day, 13 July 2019, from Baikonur Site 81/24.[1] The observatory was integrated into a Navigator satellite bus,[10] produced by NPO Lavochkin.[11]

Mission profile and orbit

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The spacecraft entered an orbit around the Sun, circling the Sun-Earth L2 Lagrangian point in a halo orbit, about 1.5 million kilometres away from Earth. Cruise to that location took three months, during which the two telescopes were checked out and calibrated. The next four years were planned to be spent performing eight all-sky surveys. As a goal, the three years after that are planned for observations of selected galaxy clusters and AGNs (Active Galactic Nuclei).[12]

On Monday 21 October 2019, Spektr-RG completed a 100-day cruise to L2-point. On 17 October 2019, the main eROSITA instrument achieved first light.[13] The first light image of ART-XC was taken on July 30, 2019.[14]

The operations of eROSITA were suspended on 26 February 2022 after the Russian invasion into Ukraine upon request from Germany. At the time, eROSITA had completed four of its planned eight full-sky surveys.[15]

In March 2022, Russia said they turned off one of the two telescopes aboard Spektr-RG (presumably eROSITA) upon request from Germany.[16] In June, Dmitry Rogozin, the head of Roscosmos, said he planned to unilaterally seize control of the German telescope, saying German officials' "don't have a moral right to halt this research for humankind" and that they had "pro-fascist views".[17] However Russian astrophysicist Rashid Sunyaev said doing so could damage the instrument and would add to mistrust.[17]

In 2023 it was published that Spektr-RG found 17 new AGNs.[18] In 2025 it was published that Spektr-RG found additional 11 new AGNs.[19]

Instruments

[edit]
Spektr-RG instruments. eROSITA is the larger mirrors on the bottom left and ART-XC is the smaller mirrors on the top right.
Instruments on the Spektr-RG observatory
eROSITA[7] ART-XC[20]
Organisation MPE IKI / VNIIEF
Telescope type Wolter Wolter
Wavelength X-ray X-ray
Mass 810 kg 350 kg
Sensitivity range 0.3–10 keV 4–30 keV
Field of view 1 degree 30 arcminutes
Angular resolution 15 arcseconds 45 arcseconds
Sensor area 2,400 cm2 at 1 keV 450 cm2 at 8 keV

Optical mission support

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Spektr-RG on a 2020 stamp of Russia

Russian

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German

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See also

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  • IXPE—a high-resolution X-ray telescope measuring polarization of X-rays
  • List of X-ray space telescopes
  • ROSAT—observed at similar X-ray energies in the 1990s
  • TAUVEX—an instrument originally planned for Spektr-RG; it was built but never flown

References

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[edit]
Revisions and contributorsEdit on WikipediaRead on Wikipedia

Spektr-RG

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from Grokipedia
Spektr-RG, also designated Spectrum-Roentgen-Gamma (SRG), is a Russian-German space-based observatory dedicated to high-energy , launched on 13 July 2019 from the aboard a . The operates in a around the Sun-Earth L2 , approximately 1.5 million kilometers from Earth, providing a stable thermal environment shielded from solar interference. The mission's core instruments comprise two grazing-incidence telescopes: eROSITA, a German-developed wide-field imager sensitive to soft s in the 0.3–10 keV range for detecting extended sources like galaxy clusters, and ART-XC, a Russian hard operating in the 4–30 keV band for surveying point-like high-energy emitters such as active galactic nuclei. These enable the first imaging all-sky survey in the medium-to-hard regime, projected to catalog up to a million active galactic nuclei and hundreds of thousands of galaxy clusters across the . Since commissioning, Spektr-RG has completed multiple all-sky scans, yielding discoveries of new cosmic sources and enabling analyses of large-scale , including that probe dynamics. Geopolitical strains following Russia's 2022 invasion of disrupted German data processing for eROSITA, shifting reliance to Russian operations for ART-XC, yet the observatory persisted in generating peer-reviewed results into 2025, including identifications of novel active galactic nuclei.

Development and Background

Mission Concept and Planning

The Spektr-RG (Spectrum-Roentgen-Gamma, SRG) mission concept emerged in the early as the Spectrum-X/G (SXG) project, envisioned as a high-energy observatory for imaging surveys of the sky to probe cosmic phenomena such as clusters and active galactic nuclei. The design prioritized wide-field instruments to detect obscured supermassive black holes and map large-scale structures in the 0.5-11 keV energy band, addressing limitations in prior missions by enabling deeper all-sky coverage from a stable around the Sun-Earth . Initial plans targeted a 1999 launch, but economic disruptions following the Soviet Union's dissolution stalled progress, leading to project suspension. Revival occurred in 2004 amid renewed Russian investment in space science, with the mission redefined as SRG under the Federal Space Program's fundamental research section. The mission definition document, released in September 2005, formalized objectives including the first comprehensive all-sky survey to identify approximately 100,000 galaxy clusters and facilitate studies of and through follow-up observations. Planning integrated two primary wide-field telescopes—Russia's ART-XC for harder s (up to 30 keV) and Germany's eROSITA for softer energies—alongside provisions for pointed observations of transient events. International coordination shaped early planning, with a signed in March 2007 between and Germany's DLR to divide responsibilities: handling the bus, launch, and ART-XC, while led eROSITA development at the Institute for Extraterrestrial Physics. A detailed bilateral agreement followed on August 18, 2009, securing funding and technical exchanges; additional U.S. support via a February 2011 reimbursable agreement provided mirror modules for ART-XC, and ESA contributed ground communications. The baseline timeline aimed for a 2016 launch on a rocket from , with a minimum seven-year operational life to execute four all-sky surveys, though budget reallocations later prompted adjustments, including the 2008 removal of a planned UK-led wide-field due to funding shortfalls.

International Collaboration

The Spektr-RG mission emerged from a bilateral partnership between and , with leading the project in coordination with the (DLR). A formal agreement on cooperation for the Spektr-Rentgen-Gamma orbital observatory was established between and DLR, specifying responsibilities for development, launch, and operations. This accord was detailed during the MAKS International and Salon in on August 18, 2009, marking the mission as a joint Russian-German endeavor in high-energy . Russia's contributions included the spacecraft platform, developed by the Lavochkin Association, the ART-XC crafted by the Space Research Institute (IKI) in , and the launch vehicle that deployed the observatory on July 13, 2019, from . Germany provided the eROSITA , designed and built by the Institute for Extraterrestrial Physics (MPE) under DLR oversight, enabling complementary soft X-ray observations to ART-XC's harder X-ray focus. The instruments were integrated to perform an all-sky survey, with data-sharing protocols outlined in the original operational agreement between IKI and German partners. Initial collaboration extended to minor U.S. involvement, with scientists at NASA's assisting in science data processing alongside the primary partners. However, geopolitical tensions following Russia's invasion of in 2022 led DLR to suspend cooperation, including remotely deactivating eROSITA's detector in March 2022, though Russia later announced unilateral reactivation plans. Despite these disruptions, the mission's foundational international framework facilitated its launch and early survey phases, yielding joint scientific outputs prior to the rift.

Technical Development and Delays

The Spektr-RG mission originated from the Spectrum-X/Gamme (SXG) project conceived in the early by Soviet/Russian space authorities, with an initial launch target of 1999, but it was effectively shelved due to post-Soviet economic turmoil and funding shortfalls that disrupted broader Russian space programs. In 2002, the SXG mission was formally cancelled amid these constraints, prompting a redesign and revival as Spektr-RG (SRG) around 2004-2005, with formal international agreements accelerating development: a between and Germany's DLR in March 2007, followed by a detailed bilateral pact on August 18, 2009. The spacecraft platform, based on NPO Lavochkin's satellite bus, incorporated three-axis stabilization, a of approximately 2,650 kg at launch (including 300 kg of ), and power generation exceeding 1,500 W for payload operations, with structural elements like carbon-fiber composites sourced from Obninsk's Technologiya enterprise. Instrument development emphasized complementary X-ray capabilities: the Russian ART-XC telescope, led by the Space Research Institute (IKI) in collaboration with the All-Russian Scientific Research Institute for Experimental Physics (VNIIEF), featured seven mirror modules with cadmium telluride detectors for 5-30 keV energies, undergoing ground calibrations from 2014 to 2018 at facilities including NASA/MSFC's Stray Light Facility; delivery to NPO Lavochkin occurred on December 27, 2016. The German eROSITA telescope, developed by the Max Planck Institute for Extraterrestrial Physics (MPE), comprised seven mirror modules for 0.2-10 keV observations with contributions from NASA (four mirror modules delivered by summer 2014), and was fully assembled in Munich before air shipment to Moscow on January 20, 2017. Integration challenges arose from adapting the Navigator bus for the combined payload, including thermal management via multi-layer insulation and heat pipes, while a planned third instrument, the UK-led Lobster-Wide Field Telescope (LWFT), was dropped in 2008 due to British budget cuts. Development encountered repeated delays, initially from the economic crises that halted SXG progress, then post-revival slips due to funding inconsistencies and technical hurdles; public launch commitments shifted from around 2006 to 2016, with early 2015 issues—including unspecified instrument delivery shortfalls and spacecraft tailoring needs at —pushing the target to March 2017 and requiring an additional nine months for reconfiguration. Further postponements stemmed from protracted calibrations and , extending ART-XC readiness into 2018, before final pre-launch preparations aligned for a booster rollout. In 2019, operational delays included a June 21 scrub due to battery drainage on the Block DM upper stage, rescheduling to July 13 after diagnostics confirmed no hardware faults. These setbacks, while common in complex missions amid international supply chains, extended the overall timeline by over a from revival but preserved core scientific viability through phased milestones.

Mission Objectives and Design

Scientific Goals

The primary scientific goal of the Spektr-RG mission is to perform an all-sky survey in the 0.3–11 keV energy band with unprecedented sensitivity, enabling the detection of approximately 100,000 massive galaxy clusters and around 3 million active galactic nuclei (AGN) powered by supermassive black holes at galaxy centers. This survey, led by the eROSITA telescope, aims to map the large-scale structure of the by tracing the distribution of hot intergalactic gas in galaxy clusters and cosmic filaments, thereby probing the effects of and on cosmic evolution. The data will facilitate cosmological studies, including constraints on the Hubble constant and the growth of structure over cosmic time. Complementary objectives include identifying hundreds of thousands of emitting stars with active coronae and accreting white dwarfs, tens of thousands of star-forming galaxies, and numerous previously undetected sources such as obscured AGN and transient events. The ART-XC telescope extends observations into the harder regime of 6–30 keV, enhancing sensitivity to heavily absorbed sources, including Compton-thick AGN and high-energy transients like gamma-ray bursts. Detailed pointed observations of selected targets will yield high-cadence timing and to examine accretion processes around black holes and neutron stars, the physics of hot plasma in interstellar and intergalactic media, and the evolution of supermassive black holes. Through these efforts, Spektr-RG seeks to advance understanding of high-energy astrophysical phenomena across a broad range of scales, from Galactic objects to the distant .

Spacecraft Architecture

The Spektr-RG spacecraft utilizes the multi-purpose bus developed by NPO Lavochkin, featuring a 3-axis stabilized configuration optimized for precise pointing in its around the Sun-Earth L2 point. The platform has a wet mass of approximately 2712 kg, accommodating a scientific mass of 1170 kg, for a total launch mass exceeding 3800 kg. Its design incorporates a geometrically stable frame to mount the two primary telescopes, ART-XC and eROSITA, ensuring minimal structural deformation and during operations. The attitude and orbit control subsystem (AOCS) employs star trackers, gyroscopic sensors, reaction wheels, and thrusters to achieve a pointing accuracy of 2 arcminutes and stabilization within ±2.5 arcseconds, with a maximum reorientation velocity of 0.25° per second. is provided by a -based system pressurized with , carrying 360 kg of to maintain the and perform station-keeping maneuvers over the mission lifetime. Power generation relies on deployable solar panels delivering up to 1870 , supplemented by a 55 Ah battery for periods and peak loads, with the system supplying 27 ± 1.35 V to science instruments requiring up to 1500 W. control encompasses , heat pipes, and electrical heaters to maintain operational temperatures, including cooling eROSITA detectors to -80°C. Communications utilize an X-band radiocomplex for and data downlink at rates up to 512 Kbit/s, managed by an onboard control system with redundant computing and memory units. The architecture supports a design life of at least 5 years, with goals extending to 7.5 years.

Orbit and Operational Profile

Spektr-RG was inserted into an initial highly elliptical Earth orbit following its launch on July 13, 2019, from , with an apogee of approximately 200,000 km and perigee of 500 km to facilitate early operations and trajectory adjustments. Subsequent maneuvers, including a lunar , transferred the to a small-amplitude around the Sun-Earth L2 , approximately 1.5 million km from Earth, enabling stable, uninterrupted observations free from Earth's atmospheric and radiation interference. The has a period of about 6 months, with periodic corrections performed to maintain positioning and optimize observational conditions against solar and geomagnetic disturbances. The operational profile centers on continuous sky scanning and targeted pointing, leveraging the L2 halo orbit's stability for eROSITA's all-sky surveys in the 0.3–10 keV band and ART-XC's complementary hard observations up to 30 keV. Pointing accuracy is maintained within arcminutes, with the spacecraft's attitude enabling slews between survey fields and guest observer targets, while solar arrays and batteries support power demands during the nominal 7-year mission lifetime. Data downlink occurs via a 512 kbit/s link to Russian ground stations, with operations divided into phases: calibration, four all-sky surveys by eROSITA over the mission, and flexible allocations for pointed observations comprising up to 30% of the schedule. As of 2025, the mission remains active beyond initial projections, though fuel constraints and instrument performance have prompted adjustments in survey depth and maintenance strategies.

Instruments

Mikhail Pavlinsky ART-XC Telescope

The Mikhail Pavlinsky ART-XC (Astronomical Roentgen Telescope – X-ray Concentrator) is a hard imaging instrument on the Spektr-RG observatory, operating in the 4–30 keV energy band to enable the first true imaging all-sky survey using grazing-incidence optics in this regime. It consists of seven identical, co-aligned modules, each with 28 nested confocal and conic mirror shells coated in iridium for X-ray reflection via grazing incidence, with shells measuring 580 millimeters in length. Developed by the Space Research Institute of the Russian Academy of Sciences (IKI RAN), ART-XC represents Russia's inaugural Wolter-type grazing-incidence X-ray telescope launched into space. The instrument focuses photons onto cadmium telluride (CdTe) detectors in the focal plane, which provide high quantum efficiency and enable event filtering for particle-induced noise. The design yields a field of view of 36 arcminutes in diameter per module and an on-axis angular resolution of approximately 30 arcseconds half-power diameter at 8 keV. The telescope bears the name of Mikhail N. Pavlinsky (1959–2020), its founder, project manager, and initial , who served as deputy director of IKI RAN and head of its High Energy Astrophysics Department; the renaming was formalized in September 2020. Pavlinsky's leadership ensured the instrument's focus on high-sensitivity hard observations to detect faint extragalactic sources and transient Galactic phenomena, such as those involving accreting compact objects. ART-XC complements the eROSITA by extending coverage to harder X-rays, facilitating joint all-sky surveys for studies of obscured active galactic nuclei, clusters, and high-energy transients with improved localization and measurements up to 30 keV. Its modular array enhances collecting area while maintaining imaging fidelity, supporting multiple sky scans over the mission lifetime for time-domain .

eROSITA Telescope

The eROSITA (extended Roentgen Survey with an Imaging Telescope Array) telescope is the core soft X-ray instrument aboard the Spektr-RG observatory, developed by the Max Planck Institute for Extraterrestrial Physics (MPE) in Germany as part of a Russian-German collaboration. It features seven co-aligned, identical Wolter-I type mirror modules, each comprising 54 nested, electroformed nickel shells coated with iridium (initially planned as gold but optimized for better reflectivity). These modules focus X-rays onto pn-junction charge-coupled device (pnCCD) detectors in the focal plane, with each camera array consisting of four pnCCD chips covering a 3.3 cm × 3.3 cm area at a focal length of 1.6 meters. eROSITA operates across the 0.2–10 keV energy range, prioritizing soft to medium X-rays up to 8 keV for imaging, with a large effective area exceeding 2500 cm² at 1 keV and a of about 1° diameter. The angular achieves a half-energy width of 15–30 arcseconds, while the spectral reaches approximately 130 eV at 6 keV , enabled by the pnCCD's low noise and high quantum efficiency. An onboard calibration source using provides periodic in-flight verification of detector performance. The telescope's design emphasizes high survey speed and sensitivity, roughly 25 times greater than the ROSAT all-sky survey in the 0.5–2 keV band, facilitating the detection of extended diffuse sources like galaxy clusters alongside point sources. Following the Spektr-RG launch on July 13, 2019, eROSITA achieved first light in October 2019, with initial calibration confirming nominal mirror alignment and detector functionality despite minor pointing challenges from spacecraft dynamics. This enables eROSITA to conduct multiple all-sky surveys, mapping over a million X-ray sources to trace cosmic large-scale structure and constrain dark energy models through cluster counts and redshift evolution.

Launch and Deployment

Pre-Launch Preparations

The eROSITA telescope underwent final calibration at the PANTER X-ray test facility in Neuried, , in April 2016, before being fully integrated in November 2016 and transported to , , on January 20, 2017, for incorporation into the Spektr-RG at in . The ART-XC telescope, featuring X-ray mirror modules fabricated by NASA Marshall Space Flight Center under a February 2011 agreement with the , was delivered to on December 27, 2016. Instrument integration into the spacecraft platform followed a series of ground tests at , completed by April 2019. Spacecraft assembly began after construction concluded in 2016, with integrated testing extending through mid-2018, encompassing electrical functional checks from May 3 to 21, 2018, and thermal-vacuum environmental simulations in July 2018 to verify performance under space-like conditions. These preparations addressed the mission's requirements for operation at the Sun-Earth L2 Lagrange point, including propulsion system validation for insertion and thermal management for the sensitive detectors. The completed Spektr-RG observatory was shipped to the on April 25, 2019, where eROSITA underwent additional verification upon arrival on April 26. Final pre-launch activities included comprehensive ground testing of the integrated , propellant loading, and mating to the at Site 81/24, with the campaign delayed from an initial March-April 2019 target due to organizational changes at and technical verifications.

Launch Sequence

The Spektr-RG spacecraft was launched atop a launch vehicle configured with a Block DM-03 upper from Launch Complex 81/24 at the in . Liftoff occurred at 12:30:57 UTC on , 2019, during the mission's third launch window of the day. The ascent profile followed the standard sequence, with the first igniting at liftoff to propel the stack eastward over the Tyuratam missile range, followed by separations, payload jettison after approximately two minutes, and sequential burns of the second and third s. The Block DM-03 upper then performed burns to achieve an initial parking orbit and subsequent transfer trajectory toward the Sun-Earth L2 Lagrange point, with the entire injection sequence lasting 1 hour, 59 minutes, and 55 seconds from liftoff. Spektr-RG, with a launch mass of 2,712.5 kg including propellants, separated successfully from the Block DM-03 at approximately 14:30 UTC, marking the completion of the launch phase and the start of the spacecraft's autonomous cruise to its operational around L2, a journey expected to take about three months.

Initial Operations and Calibration

Following launch on July 13, 2019, the underwent initial deployment of its solar arrays and communication antennas, with all onboard systems reported nominal within hours. The three-month cruise phase to the Sun-Earth L2 point included support system checks, preliminary telescope alignment, and early instrument testing, culminating in insertion into a on October 21, 2019. Commissioning operations, focused on verifying spacecraft subsystems such as control, power distribution, and attitude control, were completed by mid-October 2019, ahead of the and performance verification (CalPV) phase. The eROSITA telescope's commissioning began post-arrival at L2, with activation of all seven mirror modules and camera systems by October 13, 2019, following and filter wheel operations. First light was achieved on October 15, 2019, via observations of the , including supernova remnant , confirming basic functionality despite single-event upsets (SEUs) in camera electronics causing intermittent downtime and light leaks in two modules (TM5 and TM7) that degraded low-energy response below 0.5 keV. In-flight calibration during the CalPV phase (mid-September to mid-December 2019) involved over 100 targeted pointings and scans of celestial sources to refine effective area, , and spectral response, building on pre-launch ground tests at the PANTER and PUMA facilities; particle-induced background exceeded pre-flight models above 2 keV. For the ART-XC telescope, initial activation and commissioning commenced in early December 2019, with the seven modules powered on and tested for hard (4–30 keV) sensitivity and background rejection via cadmium-zinc-telluride detectors. scans verified mirror alignment and detector uniformity using known sources, enabling the start of scanning mode on December 8, 2019, which transitioned into the first all-sky survey by June 2020 without major anomalies reported during this phase. Test observations, such as the eFEDS mini-survey, were conducted in late 2019 to validate joint eROSITA-ART-XC performance ahead of full survey operations. Overall, initial operations confirmed the observatory's readiness for its four-year survey program, with eROSITA entering continuous scanning on December 13, 2019.

Operations and Data Collection

All-Sky Surveys

The all-sky survey phase of the Spektr-RG mission commenced on December 18, 2019, following the spacecraft's arrival at the Sun-Earth L2 Lagrange point and initial calibration, with both eROSITA and ART-XC telescopes scanning the along great-circle paths. This phase was designed to last four years, encompassing eight half-yearly scans to achieve deep X-ray coverage across the 0.3–11 keV band for eROSITA and the 4–30 keV band for ART-XC, enabling the detection of diffuse emissions, galaxy clusters, and compact sources with sensitivities far exceeding prior missions like ROSAT. The surveys prioritize uniform sky coverage, with each scan overlapping previous ones to build cumulative exposure and reduce Poisson noise, ultimately aiming to catalog millions of sources and map large-scale cosmic structures. eROSITA's surveys have yielded the deepest all-sky maps to date in the soft band, with the first scan (eRASS:1) completed on , , after 184 days of operation, identifying over one million point-like sources and resolving extended features such as the Milky Way's halo. Subsequent scans progressed to eRASS:2 through eRASS:4 by early 2022, accumulating deeper data that revealed tens of thousands of clusters—key tracers of distribution—and facilitated the release of preliminary catalogs in , including source positions, fluxes, and spectral properties derived from multi-epoch observations. By the fourth scan, eROSITA had achieved an effective exposure enabling flux limits around 10^{-14} erg cm^{-2} s^{-1} in the 0.5–2 keV range for equatorial fields, surpassing ROSAT by a factor of 25 in sensitivity. ART-XC contributed complementary hard X-ray coverage during the initial scans, providing the first all-sky survey in the 4–30 keV regime with grazing-incidence , detecting transient sources and obscured active galactic nuclei missed by softer instruments. However, a mirror module failure in one of its seven telescopes occurred shortly after launch in 2019, reducing effective area by about 14% and limiting full-band performance, though surveys continued with the remaining modules to map sky regions like the in the 4–12 keV band. Science operations for both instruments were paused after the fourth eROSITA scan in March 2022 due to geopolitical factors stemming from the Russia-Ukraine conflict, halting further planned surveys despite the mission's baseline extending to 2023 for the full eight scans. Data from completed scans have been processed through German and Russian ground segments, with eROSITA products emphasizing cluster cosmology and source variability, while ART-XC data focus on high-energy populations, though international collaboration and data sharing remain constrained.

Targeted Observations

In the planned operational profile of Spektr-RG, targeted observations—also referred to as pointed observations—constitute a dedicated phase following the completion of the primary all-sky survey series, allocated approximately 2.5 years to enable deeper scrutiny of specific celestial objects identified or prioritized from survey data. These observations involve stabilizing the spacecraft's attitude to focus both the eROSITA and ART-XC telescopes on discrete targets, such as active galactic nuclei, galaxy clusters, or transient phenomena, allowing for higher sensitivity and in the 0.2–12 keV (eROSITA) and 4–30 keV (ART-XC) energy bands compared to the scanning survey mode. Target selection emphasizes follow-up on high-interest sources, including those requiring multi-wavelength coordination for distance measurements and physical characterization, with ART-XC explicitly supporting a pointed mode alongside survey and scan configurations to optimize flux detection amid variable particle background. Pre-survey calibration and early operations included pointed-like exposures on select fields to verify instrument performance, yielding initial science products such as the eROSITA Early Data Release encompassing nearly 100 individual pointings across 29 fields, which facilitated studies of diverse sources prior to full survey initiation. Specific examples of targeted science include eROSITA's five dedicated observations of the (NGC 104), analyzing resolved sources within the cluster core to probe low-mass X-ray binaries and stellar populations. Similarly, ART-XC conducted deep pointed surveys of the , producing catalogs of point sources via maximum likelihood detection methods tailored for crowded fields, revealing hundreds of hard emitters including candidate cataclysmic variables and active stars. These efforts demonstrated the telescopes' efficacy for resolving faint, extended, or variable emissions not fully captured in all-sky scans. Geopolitical disruptions interrupted the full implementation of the targeted phase; eROSITA operations were suspended on February 26, 2022, after four all-sky surveys, amid tensions following Russia's invasion of , with Russian operators deactivating the German instrument despite prior joint agreements. ART-XC, under Russian control, persisted with additional surveys and opportunistic pointings, such as detections of new active galactic nuclei and transients like accreting millisecond pulsars, but the absence of a formalized guest observer program limited broader community access to proposed targets. As of 2025, no comprehensive post-survey targeted campaign has proceeded for the full duo of instruments, constraining deeper investigations into survey legacies like massive galaxy clusters or cosmological probes.

Ground Support and Data Handling

The Spektr-RG mission operations are coordinated from the Mission Control Center (MCC) located at NPO Lavochkin in Khimki, near Moscow, Russia, which handles spacecraft control, flight dynamics, and overall mission planning. Ground stations under Roscosmos, including facilities for telemetry reception, support daily command uplinks and scientific data downlinks, with sessions lasting approximately one hour for ART-XC data and 2.5 to 4 hours for eROSITA, including telescope health checks. Onboard data, accumulated at up to 2 Mbps via telemetry links, are transmitted once per day to these Russian ground receiving stations before further distribution. For the ART-XC telescope, scientific data analysis, reduction, and archiving are managed at the Space Research Institute (IKI) science data center in , which performs near real-time monitoring and processes raw data into calibrated event lists and source catalogs. The ART-XC onboard data processing unit collects and stores detector outputs prior to downlink, after which ground pipelines apply maximum likelihood methods for source detection, as used in surveys like the deep field. eROSITA data, received at Russian ground stations, are forwarded in real time via socket connections to the operations center and then to the German Science Data Center (GSDC) at the Institute for Extraterrestrial Physics (MPE) in , , for specialized processing. The eSASS at GSDC handles , event , screening, and attitude reconstruction, enabling the production of all-sky survey catalogs with nearly 930,000 sources in initial releases. Data products, including images and spectra, are archived and made publicly available through the GSDC, supporting collaborative analysis while adhering to mission data rights agreements between Russian and German partners.

Scientific Achievements

Key Discoveries and Findings

The SRG/eROSITA all-sky survey (eRASS:1), spanning September 2019 to June 2020, produced the largest and deepest catalog to date, identifying nearly 930,000 point-like and extended sources across the sky. This included over 12,000 clusters and groups, enabling precise measurements of their luminosities, temperatures, and spatial distributions for cosmological parameter constraints, such as the matter density and equation of state. Additionally, approximately 700,000 active galactic nuclei (AGN) were cataloged in the Western Galactic Hemisphere, revealing population properties like functions and obscuration fractions that inform models of growth. Targeted analyses from eRASS:1 data uncovered extended structures such as the eROSITA bubbles—two giant, bipolar cavities emanating from the Milky Way's , spanning roughly 8,000–14,000 parsecs in height and filled with hot, low-density plasma, likely driven by past nuclear starburst or AGN activity. These features, detected in diffuse soft emission, provide evidence for energetic feedback processes shaping the over millions of years. Further findings include the identification of quasi-periodic oscillations in light curves from quasars, indicating pulsating behavior in supermassive holes with periods of hours to days, potentially linked to instabilities in accretion disks. In 2025, observations with Spektr-RG confirmed eleven new AGN among dozens of candidate sources, characterized by high luminosities (10^43–10^45 erg/s) and spectral ratios consistent with obscured accretion. These discoveries, derived from the partial survey data before operational pauses in 2022, highlight eROSITA's sensitivity to faint, extended emissions despite mission constraints from propulsion failures and geopolitical tensions.

Contributions to X-ray Astronomy

The Spektr-RG mission has advanced by delivering comprehensive all-sky surveys in both soft and hard X-ray regimes through its primary instruments, eROSITA and ART-XC. These surveys provide deeper sensitivity and wider coverage than prior missions, enabling the detection of previously unresolved sources and structures essential for understanding cosmic evolution. eROSITA's first all-sky survey, completed between September 2019 and October 2020, identified approximately one million sources, representing nearly ten times the number detected by the ROSAT mission. With a sensitivity about 25 times greater than ROSAT in the 0.2–10 keV band, eROSITA resolved faint extended emissions and point sources, including hundreds of thousands of active galactic nuclei (AGN) and galaxy clusters. These data have supported analyses of large-scale cosmic structure, detecting galaxy clusters to redshifts exceeding z=1 and refining models of via baryon acoustic measurements and cluster abundance constraints. Subsequent eROSITA scans have deepened these maps, facilitating studies of features like the Local Hot Bubble's temperature profile at energies below 0.2 keV when combined with auxiliary data. The instrument's all-sky coverage has also enabled systematic searches for massive activity, identifying candidates through variability and spectral properties in survey data. Complementing eROSITA, the ART-XC telescope conducted the first true imaging all-sky survey in the 4–30 keV hard band, achieving high to pinpoint obscured sources invisible at softer energies. This has expanded the census of high-energy emitters, including transient phenomena and Compton-thick AGN, enhancing multi-wavelength follow-up and population statistics. Collectively, Spektr-RG's observations have produced the most detailed full-sky atlas to date, marking all major clusters and transforming empirical constraints on astrophysical processes from stellar remnants to cosmological scales.

Publications and Data Releases

The SRG/eROSITA Data Release 1 (), released in 2024 by the German eROSITA , comprises the eRASS:1 all-sky survey data from the telescope's first six months of operations (December 2019 to June 2020), covering approximately 23,000 square degrees with seven bands between 0.2 and 2.3 keV. This release includes catalogues of over 900,000 point-like sources and around 10,000 clusters and groups, derived from photometry and source detection algorithms, alongside mosaic images, light curves, and spectra for verified detections. The data products are hosted at the German eROSITA and mirrored at the HEASARC, enabling public access for further analysis of cosmic background, active galactic nuclei, and large-scale structure. Coordinated with DR1, over 50 peer-reviewed publications emerged in 2024, addressing source catalogues, instrumental calibration, and early scientific interpretations, such as the eROSITA Final Equatorial-Depth Survey (eFEDS) yielding insights into cluster cosmology and demographics. Key works include analyses of the first catalogue, which detected 10,000 clusters with redshifts up to z=1.5, enhancing constraints on parameters through number counts and weak lensing cross-correlations. For the ART-XC telescope, publications have emphasized instrument characterization and targeted detections rather than comprehensive releases, including a 2021 paper detailing its 4–30 keV imaging capabilities and in-flight calibration using bright sources like Cen X-3, achieving of 45 arcseconds and sensitivity limits of 10^{-12} erg cm^{-2} s^{-1} in deep fields. Additional results cover transient events, such as the ART-XC detection of GRB 210619B on June 19, 2021, with a peak flux in the 40–120 keV band, contributing to multi-wavelength follow-up studies. As of 2025, no equivalent all-sky data release for ART-XC has been publicly announced, with research focused on pointed observations and simulations of extragalactic surveys. Operations for both instruments faced interruptions from 2022 onward due to geopolitical constraints on data sharing, restricting releases to pre-existing survey segments.

Challenges and Controversies

Technical and Operational Issues

The development of Spektr-RG faced significant technical hurdles, including delays in telescope assembly stemming from supply chain disruptions linked to the Russian-Ukrainian conflict and incompatibilities between German eROSITA and Russian ART-XC electronics integrated with the spacecraft bus. These issues, compounded by spacecraft communications system malfunctions, postponed the launch multiple times and required adjustments to mission parameters. A battery anomaly on the forced a scrub of the planned June 21, 2019, liftoff from , with subsequent diagnostics identifying the fault and enabling a successful launch on July 13, 2019, aboard a rocket. The cumulative pre-launch delays reduced the guaranteed mission lifespan from seven years to 6.5 years to account for expended testing and integration time. Post-launch commissioning verified thermal control, electrical systems, and detector functionality for both eROSITA and ART-XC, with ART-XC showing only negligible polarization effects (≤1%) during two days of . However, eROSITA exhibited minor operational anomalies emerging after commissioning, including variations during the first all-sky survey (eRASS1), which necessitated specific in pipelines. During subsequent surveys, the mission team addressed pointing and thermal stability challenges through adjusted operational strategies, maintaining survey progress despite the dynamics around the Sun-Earth L2 point requiring precise propellant management for maneuvers. No catastrophic hardware failures were reported for either instrument prior to geopolitical interruptions.

Geopolitical and Collaborative Tensions

The Spektr-RG mission, featuring the Russian ART-XC and the German eROSITA instrument, exemplified pre-2022 international in between and the (DLR), with data processing shared via joint agreements. However, Russia's full-scale invasion of on February 24, 2022, prompted immediate geopolitical repercussions, as Western sanctions and condemnations extended to scientific partnerships. On February 26, 2022, directed the suspension of eROSITA operations, placing the instrument in hibernation to comply with prohibitions on with Russian entities. This action followed 's ministry order on March 1, 2022, to halt all ties with , effectively ending joint oversight despite eROSITA having completed four of eight planned all-sky surveys. Roscosmos complied by deactivating eROSITA at Germany's request, though the spacecraft remained under Russian control, allowing continued operations for ART-XC independently. Tensions escalated in June 2022 when discussions of reactivating eROSITA without German involvement surfaced, drawing unanimous opposition from the Russian scientific community, which emphasized adherence to original bilateral protocols for instrument use and data handling. These disputes highlighted asymmetries in mission control—Russia managed and power, while held expertise in eROSITA and analysis—exacerbating challenges in data rights and publication, as Russian ground stations retained raw but joint interpretation ceased. The fallout underscored broader strains on post-Cold War space cooperation, with prior delays in Spektr-RG's development linked to 2014 Crimean tensions halting production briefly after the rocket arrived at . By , sanctions limited access to Western components and funding, isolating Russian segments while German teams pivoted to alternative missions, though ART-XC persisted in targeted observations under auspices. No formal resolution to collaborative access has emerged, reflecting entrenched geopolitical divisions over the conflict.

Criticisms of Mission Management

The Spektr-RG mission's development was marred by repeated delays stemming from inadequate integration of international components. Incompatibilities between German eROSITA electronics and Russian systems, compounded by flaws in the spacecraft's communications , postponed the launch multiple times from its initial 2014 target. A mid-project shift in launch site from to added further setbacks, highlighting deficiencies in contingency planning and supply chain coordination under oversight. Final assembly in 2017 encountered critical snags, resulting in a six-month launch deferral and public recriminations among Russian contractors and agencies, indicative of fragmented accountability in project execution. These accumulated delays forced a formal reduction in the spacecraft's nominal orbital lifespan from seven to 6.5 years to accommodate revised timelines. Launch operations in 2019 revealed ongoing management lapses, including a scrubbed Proton-M liftoff on June 21 due to an undisclosed technical anomaly detected pre-countdown, underscoring insufficient pre-flight verification protocols. Post-launch orbit corrections were complicated by visibility constraints from ground stations, a direct consequence of earlier postponements that altered the mission's ballistic profile without adequate redesign. Within Russia's space sector, Spektr-RG's travails have been linked to systemic Roscosmos shortcomings, such as obsolete infrastructure, staff shortages, and leadership decisions prioritizing short-term fixes over robust engineering foresight. Internal critiques note disapproval of Roscosmos's handling, reflecting a pattern of underinvestment in skilled personnel and facilities that hampered timely resolution of astrophysics-specific platform adaptations.

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