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Solar and Heliospheric Observatory

The Solar and Heliospheric Observatory () is a collaborative space mission between and the (ESA) designed to investigate the Sun's interior, atmosphere, surface, and the surrounding , providing continuous observations from a vantage point 1.5 million kilometers from . Launched on December 2, 1995, aboard an Atlas IIAS rocket from , was originally planned as a two-year mission but has far exceeded expectations, remaining operational as of November 2025 with extensions supporting research and forecasting. The , with a of 1,850 kilograms and panels generating 1,150 watts, orbits in a around the Sun- L1 , enabling uninterrupted viewing without 's occlusion. SOHO carries 12 specialized instruments, contributed by international teams, to probe different aspects of solar physics; nine are led by European principal investigators and three by U.S. ones, including the Michelson Doppler Imager (MDI) for helioseismology, the Large Angle and Spectrometric Coronagraph (LASCO) for imaging the corona, and the Coronal Diagnostic Spectrometer (CDS) for atmospheric analysis. These tools have enabled detailed mapping of solar oscillations to reveal internal structures, monitoring of coronal mass ejections (CMEs) for alerts, and detection of origins, transmitting over 1,000 images daily via NASA's Deep Space Network. Built by Marconi Space under ESA management and operated from NASA's , the mission has overcome challenges like a 1998 communications blackout and gyroscope failures through innovative . Key achievements include the of over 5,000 comets—more than any other —through LASCO's wide-field views, insights into subsurface gas flows and dynamics driving activity, and observations of massive eruptions impacting , the , and Mars in 2021. SOHO's data has advanced understanding of variability, contributing to predictions of events like the sunspot cycle and enhancing protections for satellites and power grids against geomagnetic storms. As it approaches its 30th anniversary, SOHO continues to serve as a cornerstone for , bridging observations with broader studies.

Mission Background

Launch and Development

The Solar and Heliospheric Observatory (SOHO) mission emerged from ESA's Horizon 2000 long-term scientific program, where it was selected in May 1984 as the first cornerstone project dedicated to solar and heliospheric studies, marking the beginning of formal planning for this comprehensive solar observation effort. NASA joined as a full partner in the late 1980s, contributing the launch vehicle and elements of mission operations, while ESA led spacecraft development; this collaboration represented the first major joint solar mission between the two agencies, involving contributions from scientists and engineers across 14 European countries and the United States. Phase B industrial definition studies commenced on December 1, 1989, refining the mission design, followed by the main development phase (Phase C/D) in early 1991, which encompassed payload integration and spacecraft assembly. The spacecraft was constructed by a consortium led by prime contractor Matra Marconi Space (now ), with facilities in the and handling major assembly and integration tasks; the total mission cost approximated nearly $1 billion in 1990s dollars, shared between ESA and , with the latter covering about $477 million for launch and operations support. proceeded through structured milestones, including the completion of the structural model in and the engineering model in early , ensuring compliance with rigorous requirements. This multinational effort highlighted innovative partnerships, as firms built the core platform while international teams developed the scientific instruments under consortia from nine and three U.S. institutions. Pre-launch preparations culminated in extensive environmental testing to verify the spacecraft's resilience, including vibration tests on the structural and engineering models conducted at Intespace in , , in 1993 and 1994, which simulated launch stresses to confirm structural integrity. Thermal vacuum and thermal balance tests followed at ESA's European Space Research and Technology Centre (ESTEC) in , , replicating the vacuum and temperature extremes of space to validate thermal control systems and instrument performance under operational conditions. These tests were critical to the assembly, integration, and verification program, addressing potential issues like contamination and ensuring readiness for deployment. SOHO launched successfully on December 2, 1995, at 08:08 UTC from Air Force Station, , aboard a NASA-provided Atlas IIAS , initiating a transit phase that positioned the spacecraft in a around the Sun-Earth L1 on February 14, 1996.

Primary Objectives

The Solar and Heliospheric Observatory () mission encompasses three primary scientific pillars aimed at advancing understanding of and its influence on the . These include helioseismology to probe the Sun's interior through analysis of global oscillations, investigation of the solar atmosphere encompassing the , transition region, and via imaging and , and in-situ measurements of the and to examine particle flows and their origins. Within helioseismology, SOHO seeks to measure the Sun's internal rotation rates, map subsurface flows, and determine the structure and chemical composition from the core to the by detecting and variations associated with and . For the solar atmosphere, key goals involve mapping magnetic field structures and their evolution, studying density, temperature, and fields through and line , and tracking dynamic phenomena such as coronal mass ejections (CMEs) to understand coronal heating and mass outflows. The heliospheric component focuses on analyzing solar wind composition, energy distributions, speed variations, and anisotropies in , including the of ions and energetic particles, to link these processes to solar atmospheric activity. The nominal mission duration was planned for two years, from 1996 to 1998, to capture baseline data during the phase of the 11-year . SOHO's positioning at the Sun-Earth L1 enables continuous, uninterrupted observations of the Sun, free from Earth's day-night cycles and atmospheric interference that affect ground-based or Earth-orbiting telescopes.

Spacecraft and Orbit

Design Specifications

The Solar and Heliospheric Observatory () spacecraft features a robust design optimized for long-term observation from the Sun-Earth L1 , with a total launch mass of 1850 kg, including approximately 250 kg of for propulsion and attitude control maneuvers. The spacecraft's structure consists of a hexagonal service module and payload module, measuring 4.3 m in height along the Sun-pointing axis, 2.7 m in breadth, and 3.7 m in width, with deployed solar arrays spanning 9.5 m to accommodate the power demands of its instruments and subsystems. This configuration, built primarily by Matra Marconi Space under ESA leadership with contributions, ensures stability and efficiency in the space environment. The power subsystem relies on twin solar array wings that generate up to 1500 W of electrical power at the beginning of the mission, regulated to a 28 V bus with protections against and undervoltage conditions. Two 20 Ah nickel-cadmium (NiCd) batteries provide during potential power interruptions, though the L1 position allows near-continuous solar illumination. The system includes three-domain regulation—shunt for excess power, battery discharge for low loads, and charge modes—to maintain reliable operation over the mission's extended duration. Thermal control is achieved through a combination of passive and active elements, including , radiators for heat dissipation, and adjustable electric heaters to keep critical components within an operational range of -20°C to +40°C. The onboard software, running on the attitude and orbit processor, monitors temperatures and activates heaters as needed to protect the module and service interfaces from variations. This design prevents thermal deformation at key interfaces, such as maintaining the payload-service module junction at 20°C ± 2.5°C. Attitude and orbit control is provided by a three-axis stabilization system, achieving pointing accuracy of 1 arcsecond over short periods using star trackers, fine-pointing Sun sensors, and initially three gyroscopes for precise . Four reaction wheels handle fine adjustments, supplemented by thrusters for larger corrections and maintenance, with in thruster branches to ensure reliability. Following the loss of gyroscopes in 1998, the system transitioned to a gyroless mode relying on star trackers and sensors, demonstrating its adaptive design. The command and data handling subsystem employs a 16-bit MIL-1750A in a redundant configuration, with duplicated S-band transponders and receivers to safeguard against single-point failures in and commanding. This architecture, based on ADA software, manages housekeeping functions, data formatting, and autonomous , such as off-pointing alerts via the Fine Sun Pointing Anomaly Action Detector (FSPAAD) at 5° deviation. Overall, these specifications enable SOHO's uninterrupted monitoring since its launch.

L1 Halo Orbit

The Solar and Heliospheric Observatory (SOHO) operates in a around the Sun-Earth , located approximately 1.5 million kilometers sunward from . This configuration positions SOHO in a dynamically stable region where the gravitational influences of the Sun and balance, allowing the spacecraft to maintain a looped to the Earth-Sun line. The has an amplitude of roughly 667,000 km in the y-direction ( to the Sun-Earth line), 206,000 km in the x-direction, and 120,000 km in the z-direction, corresponding to about 0.0045 overall. Its is approximately 178 days, enabling SOHO to remain synchronized with 's motion around while providing a consistent vantage point for solar observations. SOHO was inserted into this on February 14, 1996, following its launch on December 2, 1995, and a series of mid-course corrections, including burns on December 3-4, 1995, and January 4, 1996. The insertion utilized the spacecraft's bipropellant propulsion system to achieve the precise velocity and trajectory needed for the halo path, ahead of schedule and with minimal fuel expenditure. To sustain the orbit against subtle perturbations from solar radiation pressure and other forces, station-keeping are performed approximately every 8 weeks, coinciding with the spacecraft's crossings of the x-z plane. These adjustments typically require a delta-v of about 0.09 m/s per , resulting in an annual total of less than 1 m/s, executed via the spacecraft's thrusters. This orbital design offers key advantages for uninterrupted solar monitoring, including an unobstructed view of the Sun without interference from 's occultation or atmospheric effects. The L1 position ensures minimal gravitational perturbations, promoting long-term stability, and facilitates near-real-time data relay to due to the short light-travel time of about 5 seconds. Critically, the was selected to keep SOHO perpetually outside 's shadow, guaranteeing constant solar illumination for power generation and thermal control. The mission's initial hydrazine fuel budget of 251 kg was planned for at least 10 years of operations beyond the primary two-year design life, a margin that has supported extensions well into the 2020s with approximately 113 kg remaining as of 2018, sufficient for continued operations through the end of 2025.

Instruments

Remote-Sensing Instruments

The remote-sensing instruments on the Solar and Heliospheric Observatory () provide detailed imaging and spectroscopic observations of the Sun's atmosphere, enabling studies of its structure, dynamics, and evolution without direct contact. These instruments collectively cover (EUV) to ultraviolet (UV) wavelengths, capturing phenomena from the to the extended . By blocking or filtering intense solar light, they reveal faint emissions from prominences, flares, coronal mass ejections (CMEs), and flows, contributing to understandings of solar heating, wind acceleration, and activity cycles. The Extreme Ultraviolet Imaging Telescope (EIT) images the solar transition region and inner in four narrow EUV bandpasses: 171 (Fe IX/X, ~1 ), 195 (Fe XII, ~1.5 ), 284 (Fe XV, ~2 ), and 304 (He II, ~0.08 ). With a scale of 2.6 arcseconds across a 1024 x 1024 array, providing an effective spatial resolution of approximately 5 arcseconds, EIT detects dynamic features such as prominences, flares, active regions, filaments, , bright points, and polar plumes. These full-disk or subfield images support comparative analyses of coronal plasma and turbulent lower atmosphere, often coordinated with other instruments. The Large Angle and Spectrometric (LASCO) consists of three (C1, , and ) that block the disk using an occulting disk to create an artificial , allowing imaging of the from 1.1 to 32 radii. C1 images from 1.1 to 3 radii, from 2 to 6 radii (approximately 4.2 million km), and from 3.7 to 32 radii (approximately 22 million km). This setup enables measurements of CME propagation speeds, reaching up to 2,000 km/s, as well as observations of coronal streamers and the early . LASCO's wide-field white-light and spectrometric capabilities have been essential for tracking eruptions and their heliospheric impacts. The Ultraviolet Coronagraph Spectrometer (UVCS) performs high-resolution spectroscopic observations of the corona from 1.3 to 12 solar radii, focusing on UV emission lines such as H I Lyα at 121.6 nm and lines from ions including O VI, Si XII, and Mg X. Equipped with three telescopes, two toric grating spectrometers, and a visible light polarimeter, UVCS measures outflow velocities up to 400 km/s, electron temperatures, plasma densities, and velocity distributions of protons and minor ions. These data address key questions on solar wind generation, coronal heating, and acceleration processes in the corona's source regions. The Coronal Diagnostic Spectrometer (CDS) uses EUV spectroscopy in the 150–800 Å range to probe the solar atmosphere, deriving plasma parameters like temperature, density, flows, and abundances through analysis of spectral emission lines. Featuring a Wolter-Schwarzschild telescope feeding two detectors—the Normal Incidence Spectrometer (NIS) for 308–633 Å and the Grazing Incidence Spectrometer (GIS) for 151–785 Å—it achieves spatial resolutions down to a few arcseconds and temporal resolutions as fine as 1 second. CDS diagnostics cover plasma temperatures from about 10,000 K to 2 million K, revealing dynamics in the chromosphere, transition region, and corona. The Solar Ultraviolet Measurements of Emitted Radiation () instrument provides high-resolution far-UV from 50 to 161 nm, measuring intensities and profiles of EUV lines to diagnose in the through the inner . It enables assessments of densities, temperatures ranging from 10,000 K to over 2 million K, flows, , wave motions, and acceleration. 's capabilities, including raster scans and sit-and-stare modes, support studies of atmospheric structures and non-thermal line broadenings indicative of explosive events and spicules. The Solar Wind Anisotropies (SWAN) instrument maps the full sky in Lyman-α (121.6 nm) to observe the interplanetary glow of neutral , which is modulated by the , enabling of speed, density, and anisotropies across the up to several . Consisting of two identical scanning sensor heads with 1° , SWAN provides global views of heliospheric structures and has contributed to discoveries through its wide-field UV . The Global Oscillations at Low Frequency () instrument probes the deep solar interior by detecting Doppler shifts in the sodium D absorption lines (at 589.0 nm and 589.6 nm), targeting low-degree p-mode s in the frequency range of 1-4 mHz. Operating as a resonant spectrometer, it achieves high to global variations, enabling studies of rotational dynamics and convective flows below the surface. 's long-term observations have refined models of structure and oscillation mode asymmetries. The Variability of and Gravity Oscillations () experiment includes three-channel sunphotometers measuring total and spectral in blue (402 nm), green (500 nm), and red (862 nm) bands, supplemented by a oscillation imager for granulation-scale variations. These photometers track fluctuations with precision better than 10 , supporting helioseismic analysis of modes and long-term variability. 's absolute radiometers provide a continuous record of total since 1996, revealing correlations with activity cycles. The Michelson Doppler Imager (MDI) produces full-disk maps of solar surface velocity and by measuring Doppler shifts and Zeeman splitting in the Ni I 6768 line, achieving a of 4 arcseconds. It resolves line-of-sight velocities up to ±5 km/s and longitudinal with sensitivities around 10 G, facilitating studies of photospheric flows and magnetic evolution. MDI data have been instrumental in mapping the of the solar , revealing radial uniformity in rotation rates with faster equatorial speeds of about 460 nHz compared to polar rates of 300 nHz.

In-Situ Instruments

The in-situ instruments aboard the directly sample particles in the and , enabling detailed analysis of solar plasma composition and energetic particle fluxes. These instruments complement remote-sensing capabilities by providing local measurements that reveal the origins and of , such as suprathermal particles from flares and shocks. Key systems include particle analyzers for ions and electrons. The Charge, Element, and Isotope Analysis System (CELIAS) measures the composition of solar wind ions, including species like , oxygen, and iron, across a range of 1-200 atomic mass units (amu) and an energy-per-charge range of 0.5-25 keV/e. It employs time-of-flight sensors to resolve , isotopic, and charge-state distributions, offering in-situ diagnostics of solar wind variability and suprathermal particle acceleration. This data has been crucial for studying solar wind heavy ion abundances and their implications for coronal heating processes. The Cosmic and Solar Terrestrial Particle Experiment (COSTEP) detects protons and electrons originating from solar flares and interplanetary shocks, covering energy ranges of approximately 5-200 MeV per nucleon. It includes the Electron Proton Helium Instrument (EPHIN) for spectral measurements of electrons (0.25-8.7 MeV) and protons/helium (4.3-53 MeV/n), aiding in the identification of particle acceleration mechanisms during transient events. COSTEP's observations contribute to understanding steady-state solar atmospheric processes and the connectivity between solar eruptions and heliospheric disturbances. The Energetic and Relativistic Nuclei and (ERNE) instrument observes high-energy particles from solar energetic particle (SEP) events, measuring energy spectra for with atomic numbers Z=1-30 to distinguish solar-originated particles from galactic cosmic rays. It focuses on relativistic and ions up to several hundred MeV/nucleon, providing insights into acceleration sites near and particle propagation in the inner . ERNE data have quantified SEP fluences and compositions during events, highlighting differences between cycles 23 and 24.

Development Contributors

The Solar and Heliospheric Observatory (SOHO) was developed as a collaborative effort between the European Space Agency (ESA) and NASA, with the spacecraft constructed by an industrial team led by prime contractor Matra Marconi Space (now EADS Astrium) under ESA's overall management. The project involved contributions from industrial companies across 14 European countries, emphasizing ESA's leadership in spacecraft procurement, integration, and testing. NASA provided the launch vehicle and supported mission operations, while European national space agencies such as CNES in France and DARA in Germany contributed to instrument funding and development. SOHO's 12 instruments were developed by international consortia from 15 countries, involving 29 institutes and over 1,500 scientists worldwide. Nine instruments were led by principal investigators, with three under U.S. leadership, supported by large engineering teams and more than 200 co-investigators. Key examples include the Coronal Diagnostic Spectrometer (CDS), led by A. Fludra at the Rutherford Appleton Laboratory in the UK; the Solar Ultraviolet Measurements of Emitted Radiation (SUMER), headed by W. Curdt at the Max Planck Institute for Solar System Research in ; and the Global Oscillation at Low Frequency (), directed by P. Boumier at the Institut d'Astrophysique Spatiale in . U.S.-led instruments featured the Large Angle and Spectrometric Coronagraph (LASCO), with R. Howard at the Naval Research Laboratory; the Ultraviolet Coronagraph Spectrometer (UVCS), led by J. L. Kohl at the ; and the Michelson Doppler Imager (MDI), under P. H. Scherrer at . ESA project scientist Bernhard Fleck oversaw coordination across the consortia. Funding for SOHO totaled nearly $1 billion, with contributing approximately $477 million for instruments, launch, and operations, and ESA covering the remainder through its member states. Post-launch operations were managed primarily from in , with support from ESA's (ESOC) for payload and science coordination.

Operations

Earth Communication

The Solar and Heliospheric Observatory (SOHO) relies on a dedicated telecommunications system to transmit , tracking, and data to , utilizing S-band frequencies for all communications. The features a pointable high-gain (HGA) with a 0.8-meter diameter dish for primary data downlink, complemented by two fixed low-gain antennas (LGAs) for backup coverage during attitude maneuvers or anomalies. These antennas operate in the S-band range, with downlink frequencies of 2.2–2.29 GHz for and data, and uplink frequencies of 2.025–2.110 GHz for commands, enabling reliable signal transmission from the L1 . Data transmission occurs primarily through NASA's Deep Space Network (DSN), which uses large parabolic antennas at three complexes: Goldstone (California, USA), (Spain), and (Australia) to receive signals from SOHO's position approximately 1.5 million kilometers sunward of . Typical daily contacts total 8–12 hours, consisting of one extended 8-hour pass and several shorter 1–2-hour passes, allowing for the downlink of stored and while minimizing gaps in coverage. The maximum data rate reaches 160 kbit/s in high-rate mode (e.g., for the Michelson Doppler Imager during intensive observations), with standard rates at 40 kbit/s for routine science ; real-time modes can achieve up to 200 kbit/s for priority events. Ground operations are coordinated by NASA's SOHO Operations Center (SMOCC) at Goddard Space Flight Center (GSFC) in Maryland, USA, which handles spacecraft commanding, telemetry processing, and payload coordination, while the European Space Operations Centre (ESOC) in Darmstadt, Germany, supports tracking and orbit determination. Error correction is implemented using Reed-Solomon coding combined with convolutional encoding, a standard for DSN missions to ensure data integrity over the interplanetary link despite potential noise or interference. For critical solar events such as coronal mass ejections (CMEs), SOHO switches to real-time downlink mode, enabling near-immediate data relay with a propagation delay of 3–8 minutes attributable to the one-way light travel time from the L1 position. The stable L1 halo orbit facilitates consistent line-of-sight geometry for these communications, reducing the need for frequent antenna repointing.

Data Access and Public Outreach

SOHO data undergoes processing from raw telemetry, designated as Level 0, to higher-level products including calibrated (Level 1) and science-ready (Level 2) datasets, handled jointly by and ESA facilities such as the Solar Data Analysis Center (SDAC) at and the SOHO Science Archive at the European Space Astronomy Centre (ESAC). These processed data are made accessible to researchers worldwide through the Virtual Solar Observatory (VSO), a distributed system that federates archives for querying and retrieval. Public access to SOHO observations is facilitated via the mission's official website at sohowww.nascom.nasa.gov, which hosts near-real-time images of solar activity and downloadable movies from key instruments such as the Large Angle and Spectrometric Coronagraph (LASCO) and the Extreme-ultraviolet Imaging Telescope (EIT). The site's public image , operational since the mission's inception in 1996, features curated selections of , enabling broad dissemination of visual data to educators, enthusiasts, and the general public. Outreach efforts emphasize and , notably through the Sungrazer Project, a NASA-supported initiative where volunteers analyze LASCO images to identify sungrazing comets; to date, have confirmed over 5,000 such discoveries using SOHO data. Additionally, SOHO contributes to like annual Sun-Earth Day events, which include lectures, exhibits, and resources highlighting solar influences on Earth to promote public awareness of . The mission's data have supported extensive scientific output, with over 5,000 peer-reviewed papers published based on observations, including more than 300 annually during its initial operational years following .

Scientific Achievements

Key Milestones and Discoveries

One of the earliest breakthroughs from 's helioseismology observations came in , when data from the Michelson Doppler Imager (MDI) enabled the construction of the first three-dimensional map of the Sun's interior rotation, revealing patterns extending deep into the . This mapping confirmed the existence of the tachocline, a thin shear layer at the base of the where rotation transitions from differential in the outer layers to nearly uniform in the radiative interior, providing critical evidence for solar dynamo models. SOHO's remote-sensing instruments contributed significantly to understanding coronal heating mechanisms, with observations from the Solar Ultraviolet Measurements of Emitted Radiation (SUMER) and Ultraviolet Coronagraph Spectrometer (UVCS) detecting outflows in the accelerating to speeds of approximately 200 km/s at heights around 2 radii. These measurements indicated that wave dissipation or other non-thermal processes drive the rapid heating and acceleration of in the solar atmosphere, challenging earlier models and highlighting the role of in maintaining coronal temperatures millions of degrees hotter than the surface. In coronal mass ejection (CME) studies, SOHO's Large Angle and Spectrometric (LASCO) has imaged over 20,000 events since 1996, allowing researchers to track their evolution from the solar surface to interplanetary space and establish direct links between Earth-directed CMEs and geomagnetic storms that disrupt power grids and satellites. This extensive catalog has improved forecasting by quantifying CME speeds, masses, and magnetic orientations, demonstrating that faster ejections (often exceeding 1000 km/s) pose the greatest risk to Earth's . SOHO data have refined models of the , revealing how speeds vary from 300 km/s in equatorial streamers to 800 km/s originating from polar , with in-situ measurements confirming acceleration profiles tied to open structures. These observations have validated multi-fluid simulations, showing that damping provides the primary energy input for fast wind streams, influencing heliospheric dynamics and modulation. Recent operational milestones underscore SOHO's enduring impact, including the discovery of its 5,000th in March 2024 from LASCO images, a Marsden-group sungrazer identified by citizen Hanjie Tan. In October 2024, SOHO captured detailed views of C/2023 A3 (Tsuchinshan-ATLAS) during its perihelion passage, highlighting the mission's serendipitous role in transient object detection. Extending into 2025, the spacecraft imaged the bright C/2024 G3 (ATLAS) grazing the Sun on January 13, further demonstrating its contributions to multi-wavelength beyond core solar .

Comet Discoveries

The Solar and Heliospheric Observatory (SOHO) has unexpectedly become the most prolific comet discoverer in history, primarily through its Large Angle and Spectrometric Coronagraph (LASCO) and Solar Wind Anisotropies (SWAN) instruments, which detect sungrazing comets as they approach the Sun and become visible against the corona or in the solar wind. These instruments capture images where comets appear as bright streaks or blobs, often too close to the Sun for ground-based telescopes to observe beforehand. Over 5,000 comets have been discovered using SOHO data since its launch in 1995, accounting for more than half of all known comets with determined orbits. More than 95% of known members of the Kreutz sungrazer family—comets on highly elliptical orbits that pass within a few solar radii of the Sun—have been identified by SOHO, transforming our understanding of this ancient comet group originating from a single progenitor that fragmented millennia ago. The discoveries began shortly after SOHO's operational phase, with the first comet, C/1996 Q2 (SOHO-1), identified in LASCO C3 images on August 20, 1996, by mission scientist Shane Stezelberger. This marked the start of an ongoing program formalized in through the NASA-funded , a initiative in collaboration with the (ESA), which invites volunteers worldwide to scan SOHO images for new s via an online tool. By enabling remote participation, the has democratized , with amateurs contributing the majority of finds—nearly 95% of SOHO comets have been reported by non-professionals. Notable milestones include the 2,000th comet in 2010 and the 4,000th in June 2020, both Kreutz group members spotted by citizen scientists. SOHO's observations have revealed dynamic behavior, as these sungrazers often vaporize completely near perihelion due to intense solar heating, releasing gases and dust that interact with the and . This process provides unique in-situ data on composition and solar , as instruments like LASCO and the Coronagraph Spectrometer (UVCS) analyze the ejected material. For instance, studies of vaporized comets have yielded measurements of speeds and heavy ion abundances at close distances. Additionally, SOHO has resolved longstanding debates on family dynamics by identifying new subgroups, such as the Kracht group in 2004 and confirming orbits in the Marsden and Meyer groups, revealing fragmentation patterns and orbital evolution driven by solar tides and non-gravitational forces. Recent examples include the 5,000th , a Marsden group member discovered on March 25, 2024, by citizen Hanjie Tan, highlighting SOHO's continued role in expanding the of near-Sun objects.

Operational History

1998 Contact Loss

On June 25, 1998, at 04:38 UT, contact with the () was lost during a routine and sequence, as the unexpectedly lost and began spinning. The incident stemmed from a failed command sequence that included a ground software error in the configuration, which omitted the respin enablement for A and set an overly sensitive fault detection on B, leading to its erroneous shutdown by ground operators. As a result, SOHO entered a and spun at approximately 7 degrees per second around an axis tilted from its nominal orientation. The total loss of contact lasted about 39 days until initial re-acquisition on August 3, 1998, followed by a partial operational period of roughly three months until full , during which all scientific instruments were offline except for a low-rate beacon signal. ESA and recovery teams, utilizing 's Deep Space Network (DSN) and the Arecibo radar, detected a faint signal from the spinning in late July 1998, confirming its position and state. Subsequent efforts involved precise burns on September 16 to reduce the rate to 0.86 degrees per second and recalibration of the remaining gyros, restoring nominal pointing by September 25, 1998. The fault was ultimately traced to the ground software error introduced in a 1997 update, highlighting deficiencies in operational procedures and status monitoring. Post-recovery, approximately 95% of SOHO's functionality was restored, enabling continued science operations, though the LASCO instrument's C1 coronagraph was permanently lost due to damage from the uncontrolled spin. The recovery effort involved international collaboration.

Mission Extensions and End

Originally planned for a two-year duration following its launch in December 1995, the Solar and Heliospheric Observatory () mission has been extended multiple times by and ESA to capitalize on its ongoing scientific productivity. The first extension, approved in 1998 prior to the contact loss incident, prolonged operations until June 2003 to encompass the peak of 23. Subsequent approvals extended the mission to 2007, allowing coverage of a full ; to December 2012 in 2009; to December 2016 in 2013; and most recently to December 31, 2025, in 2020, subject to a mid-term review. As of November 2025, remains in operation at the L1 , with several of its 12 instruments functional despite challenges from aging components, including degraded batteries and the legacy effects of gyroscope failures mitigated through software updates in 1999. The spacecraft's propellant reserves are projected to suffice until the planned mission conclusion, and no additional extensions beyond December 31, 2025, were announced by ESA's Science Programme Committee in October 2025. SOHO has operated for nearly 30 years beyond its original two-year design life, enabling observations across more than two full 11-year cycles and contributing to over 6,000 peer-reviewed publications. In preparation for mission end, ESA and are transferring SOHO's comprehensive data archive to the Data Portal to ensure long-term accessibility for future research. Successor missions such as 's and ESA's reference SOHO's baseline measurements of activity and heliospheric phenomena as foundational context for their in-situ investigations.

References

  1. [1]
    About the SOHO Mission - Solar and Heliospheric Observatory - NASA
    SOHO, the Solar & Heliospheric Observatory, is a project of international collaboration between ESA and NASA to study the Sun from its deep core to the outer ...
  2. [2]
    ESA - SOHO - European Space Agency
    The SOHO mission is a joint ESA/NASA project. Launch date: December 1995; Status: Operational; Orbit: Slow orbit around Lagrange point L1; Observes: The Sun's ...
  3. [3]
    ESA - SOHO overview - European Space Agency
    The SOHO mission is a joint ESA/NASA project. What's special? Every day SOHO sends thrilling images from which research scientists learn about the Sun's nature ...
  4. [4]
    Solar and Heliospheric Observatory Homepage
    A new way of looking at the Sun. JHelioviewer is new visualization software that enables everybody, anywhere to explore the Sun.The Very Latest SOHO Images · Space Weather · About the SOHO Mission · Hotshot
  5. [5]
    The SOHO Mission: an Overview - ADS
    SOHO is a three-axis stabilized spacecraft with a total mass of 1850 kg; 1150 W of power will be provided by the solar panels. The payload weighs about 640 kg ...
  6. [6]
    NASA Launches the Solar and Heliospheric Observatory - EBSCO
    SOHO was designed to send data on the Sun back to Earth at the rate of one thousand images a day, beamed to the radio dishes of NASA's Deep Space Network around ...
  7. [7]
    SOHO - PMOD/WRC
    Mission Objectives. SOHO is designed to study the internal structure of the Sun, its extensive outer atmosphere and the origin of the solar wind, the stream of ...<|control11|><|separator|>
  8. [8]
    The SOHO Payload and Its Testing - European Space Agency
    The Solar and Heliospheric Observatory (SOHO) mission was first proposed in November 1982 as a comprehensive, high-resolution spectroscopic investigation of the ...
  9. [9]
    The SOHO Mission: an Overview - Astrophysics Data System
    ... ESA and NASA. At its meeting on 6-7 February 1986 the Science Programme ... 14 months later, in early 1991, the industrial development phase (Phase C/D) started.
  10. [10]
    Long-Lived SOHO Celebrates a Milestone - Sky & Telescope
    Dec 13, 2005 · ... spacecraft ever built. The hard-working $1.2 billion Solar and Heliospheric Observatory(SOHO) satellite blasted into space in 1995 to a ...
  11. [11]
    [PDF] Saving SOHO - Solar and Heliospheric Observatory
    Of SOHO's nearly $1-billion cost, NASA picked up $477 million and ESA paid the rest. Weighing in at 1,875 kg, the satel lite stretches about 8 m across with ...
  12. [12]
    SOHO - The Trip to the L1 Halo Orbit - European Space Agency
    SOHO was launched from Cape Canaveral in Florida on 2 December 1995 at 03:08 Eastern Standard Time by a NASA-provided Atlas IIAS launcher (the launch window on ...Missing: transit | Show results with:transit
  13. [13]
    SOHO - NASA Science
    Launched in December 1995, the joint NASA-ESA Solar and Heliospheric Observatory mission (SOHO), was designed to study the Sun inside out.
  14. [14]
    [PDF] SOHO Science Operations Plan - Solar and Heliospheric Observatory
    Mission Overview. 1.1 Scienti c objectives. The SOHO satellite is a solar observatory to study: the structure, chemical composition, and dynamics of the solar ...
  15. [15]
    [PDF] SOHO Media fact sheet - NASA
    Mass: 1850 kilograms at launch. SOHO was built for ESA by industrial companies in 14 European countries, led by Prime Contractor Matra Marconi (now Astrium). ...Missing: $1.2 billion
  16. [16]
    [PDF] TheSolarandHeliosphericObserv...
    Abstract. The SOHO spacecraft was successfully launched by an Atlas IIAS from the Eastern Range on December 2, 1995. After a short time in a nearly.<|separator|>
  17. [17]
    SOHO (Solar and Heliospheric Observatory) - eoPortal
    SOHO is an ESA/NASA collaborative mission within ESA's `Solar Terrestrial Science Program' (STSP), and it is also part of ISTP (International Solar Terrestrial ...
  18. [18]
    The SOHO Spacecraft - European Space Agency
    SOHO's nominal operational lifetime is 29 months, including the four months of the transfer phase and one month of in-orbit commissioning. It carries ...
  19. [19]
    SOHO in an orbit - Solar and Heliospheric Observatory
    SOHO moves around the Sun in step with the Earth, by slowly orbiting around the First Lagrangian Point (L1), where the combined gravity of the Earth and Sun<|control11|><|separator|>
  20. [20]
    [PDF] SUN-EARTH L1 REGION HALO-TO-HALO ORBIT AND HALO-TO ...
    THE SOHO MISSION HALO ORBIT​​ SOHO's halo orbit is referred to as a Class 2 orbit, indicating that its sense of revolution about L1 is counter-clockwise as seen ...
  21. [21]
    None
    ### Summary of SOHO's L1 Halo Orbit Details
  22. [22]
    SOHO Instruments - NASA
    This is a list of links to in depth information about the on-board instruments, the teams that built and operate them and their scientific goals.
  23. [23]
    SOHO Extreme ultraviolet Imaging Telescope (EIT)
    Dec 10, 2001 · The EIT is a normal-incidence, multilayer telescope of novel design. A paper describing the instrument (Delaboudinière et al. 1996, Solar ...
  24. [24]
    About the Very Latest SOHO Images
    LASCO (Large Angle Spectrometric Coronagraph) is able to take images of the solar corona by blocking the light coming directly from the Sun with an occulter ...
  25. [25]
    UVCS - Dataset provided by the European Space Agency
    The purpose of the UVCS instrument is to provide a body of data that can be used to address a broad range of scientific questions regarding the nature of the ...
  26. [26]
    CDS - Dataset provided by the European Space Agency
    The Coronal Diagnostic Spectrometer is designed to probe the solar atmosphere through the detection of spectral emission lines in the extreme ultraviolet ...
  27. [27]
    Dataset provided by the European Space Agency
    ### Summary of SUMER Instrument, UV Spectroscopy, and Plasma Diagnostics
  28. [28]
    SOHO/Charge, Element, and Isotope Analysis System (CELIAS ...
    The CELIAS instrument is designed to study the composition of the solar wind (SW) and of solar and interplanetary energetic particles on SOHO.
  29. [29]
    The CELIAS instrument - IEAP CAU Kiel
    Introduction. The CELIAS instrument is designed to study the composition of the solar wind (SW) and of solar and interplanetary energetic particles on SOHO.
  30. [30]
    Solar wind measurements with SoHO: the CELIAS/MTOF Proton ...
    MTOF determines high resolution mass spectra of heavy solar wind ions and uses a very wide bandwidth energy-per-charge analyzer to maximize counting ...
  31. [31]
    Details for Instrument COSTEP - WMO OSCAR
    Nov 10, 2021 · Acronym, COSTEP. Full name, Suprathermal & Energetic Particle Analyzer. Purpose, Observation of energetic particles in the solar wind.
  32. [32]
    EPHIN - sensor unit - IEAP CAU Kiel
    The EPHIN sensor is a multi-element array of solid state detectors with anticoincidence to measure energy spectra of electrons in the range 250 keV to > 8.7 MeV ...<|separator|>
  33. [33]
    SOHO/Comprehensive Suprathermal and Energetic Particle ...
    COSTEP addresses scientific objectives related to the following phenomena: Steady state processes in the solar atmosphere; Energy release and particle ...<|separator|>
  34. [34]
    Energetic particle experiment ERNE | Solar Physics
    ERNE is at the upper end in energy among the SOHO particle instruments. The instrument will measure the energy spectra of elements in the range Z=1–30. The ...
  35. [35]
    SOHO/Energetic and Relativistic Nuclei and Electron (ERNE) Data ...
    ERNE will investigate the solar atmosphere by detecting charged particles produced in various solar energy release processes.
  36. [36]
    Iron-rich solar particle events measured by SOHO/ERNE during two ...
    The particle observations were made with the Energetic and Relativistic Nuclei and Electron (ERNE) instrument onboard the Solar and Heliospheric Observatory ( ...
  37. [37]
    Global solar Doppler velocity determination with the GOLF/SoHO ...
    The Global Oscillation at Low Frequencies (GOLF) experiment is a resonant scattering spectrophotometer on board the Solar and Heliospheric Observatory (SoHO) ...
  38. [38]
    Global Oscillations at Low Frequency from the SOHO mission (GOLF)
    The GOLF experiment on the SOHO mission aims to study the internal structure of the sun by measuring the spectrum of global oscillations in the frequency ...
  39. [39]
    GOLF / SoHO - CEA-Irfu
    Tri-phonic helioseismology comparison of solar p modes observed by the helioseismology instruments aboard SOHO, Toutain T., Appourchaux T., Baudin F., et al ...
  40. [40]
    Photospheric activity of the Sun with VIRGO and GOLF
    The VIRGO instrument is composed of three Sun photometers (SPM) at 402 nm (BLUE channel), 500 nm (GREEN channel), and 862 nm (RED channel). The VIRGO/SPM ...
  41. [41]
    VIRGO Data Products Archived Webpage - PMOD/WRC
    The VIRGO Experiment has two types of radiometers to measure total solar irradiance (TSI): DIARAD and PMO6V. The former has been developed and built by IRMB, ...
  42. [42]
    SOHO/Variability of Solar Irradiance and Gravity Oscillations (VIRGO ...
    The VIRGO Experiment on the ESA/NASA SOHO Mission has three types of instruments to measure total solar irradiance (TSI) with the absolute radiometers DIARAD ...
  43. [43]
    Observing with MDI - Michelson Doppler Imager
    Jan 5, 2000 · The Zeeman splitting is determined by the difference between the Doppler shifts calculated from the filtergram components taken separately in ...Missing: effects | Show results with:effects
  44. [44]
    The Solar Oscillations Investigation - Michelson Doppler Imager
    The Michelson Doppler Imager Instrument MDI is based on a modification of the Fourier Tachometer technique (Brown, 1980; Evans, 1980). MDI uses a refracting ...<|separator|>
  45. [45]
    Downloads - SOHO-Gallery: Best Of SOHO
    Evidently the convection zone rotates uniformly along a radius with all depths showing the differential rotation seen at the surface. Below the convection zone ...Missing: MDI | Show results with:MDI
  46. [46]
    The History of the SOHO Mission - European Space Agency
    The Solar and Heliospheric Observatory, SOHO, is the most comprehensive space mission ever devoted to the study of the Sun and its nearby cosmic environment ...
  47. [47]
    [PDF] SOHO - Solar and Heliospheric Observatory
    Jun 30, 2003 · SOHO is a three-axis stabilised spacecraft that constantly faces the Sun. Its design is based on a modular concept with two main elements: the ...
  48. [48]
    ESA - SOHO operations - European Space Agency
    SOHO was built by industrial companies in 14 European countries, led by Matra-Marconi (now Astrium). SOHO is a three-axis stabilised spacecraft. The service ...
  49. [49]
    Introduction
    1) During 10 months per year the DSN will provide Nominal S/C Coverage, which consists of one 8-hour contact period and three 1.3-hour contact periods every day ...Missing: daily | Show results with:daily
  50. [50]
    https://www.aanda.org/articles/aa/full_html/2016/05/aa27462-15/aa27462-15.html
  51. [51]
    [PDF] Large Antennas of the Deep Space Network - DESCANSO
    Feb 13, 2002 · Telecommunications and Mission Operations Progress Report 42-139, ... 34-Meter Beam-Waveguide Antennas,” Telecommunications and Mission.
  52. [52]
    Processing Levels - The SOHO/LASCO Instrument Homepage
    LEVEL 0 ("LZ") ... Processing involving multiple images, such as a polarization, color analysis or on/offline combinations, are considered Level 2 processing.Missing: ESA | Show results with:ESA
  53. [53]
    SOHO Science Archives
    SOHO Science Archive at ESAC. SOHO Science Archive via VSO. LATEST DATA UPDATES AND HOLDINGS (GSFC instance). INSTRUMENT, LATEST DATA, UPDATED ON. CDS, 2014-09 ...Missing: processing Virtual Server
  54. [54]
    Virtual Solar Observatory
    You can search for data by time interval, physical observables, instruments, data archives, spectral range, or common terms.Missing: SOHO | Show results with:SOHO
  55. [55]
    The Very Latest SOHO Images
    Real time images, The Sun now, SOHO Movie Theater, MPEG movies, GIF movies, About These Images, The Very Latest SOHO Images
  56. [56]
    SOHO-Gallery
    Comets · Animations · Observation Series · Sunspots & Solar Activity · Flares & CMEs · Filaments & Prominences. PRESENTATION STOCK. SOHO Slide Presentation.<|separator|>
  57. [57]
    Sun-Earth Days and SOHO 5th Anniversary - SOHO Hotshots
    The 27-28 April SOHO scientists will organize exhibits and lectures to promote public awareness of the dynamics of our Sun and its influence on the Earth.Missing: educational resources
  58. [58]
    [PDF] 10 Years of SOHO - Solar and Heliospheric Observatory
    NASA launched SOHO on 2 December. 1995, inserting it into a halo orbit around the L1 Lagrangian point in February. 1996. The SOHO Experiment Operations.
  59. [59]
    NASA release on MDI/GONG tachocline paper
    Mar 30, 2000 · SOHO is a project of international cooperation between the European Space Agency and NASA. GONG is an international project led by the U.S. ...
  60. [60]
    [PDF] Solar and Heliospheric Observatory (SOHO) (1995)
    While the primary objective of SOHO/MDI was to obtain spatially resolved velocity time series of the solar atmosphere for the helioseismic study of the Sun's ...<|separator|>
  61. [61]
    Solar Wind Variations - NASA/Marshall Solar Physics
    The solar wind speed is high (800 km/s) over coronal holes and low (300 km/s) over streamers. These high and low speed streams interact with each other and ...
  62. [62]
    ESA, NASA Solar Observatory Discovers Its 5000th Comet
    Mar 27, 2024 · Most of the 5,000 comets discovered using SOHO have been found with the help of an international cadre of volunteer comet hunters – many with no ...
  63. [63]
    ESA/NASA's SOHO Spies Bright Comet Making Debut in Evening Sky
    Oct 11, 2024 · The tail of comet C/2023 A3 Tsuchinshan-ATLAS spanned the view of the Solar and Heliospheric Observatory (SOHO) on Oct. 10, 2024. ESA/NASA. The ...
  64. [64]
    'Prettiest Comet I've Ever Seen': Watch A Comet Graze The Sun
    Jan 23, 2025 · Comet C/2024 G3 (ATLAS) zipped close to the sun on Jan. 13 and put on quite a show for NASA's Solar and Heliospheric Observatory spacecraft.
  65. [65]
    Solar spacecraft 'SOHO' discovers its 5,000th comet | Space
    Mar 29, 2024 · The milestone 5,000th comet was found by citizen scientist Hanjie Tan, an astronomy Ph.D. student in Prague, Czech Republic, who has been part ...
  66. [66]
    SOHO comets: 20 years and 3000 objects later - Journals
    May 29, 2017 · We present a summary of the more than 3000 sungrazing and near-Sun comets discovered in coronagraph images returned by the Solar and Heliospheric Observatory ( ...Missing: gallery | Show results with:gallery
  67. [67]
    Comets Discovered in Solar Satellite Imagery - Sky Hunt
    The first sungrazing comet to have been discovered by SOHO was C/1996 Q2 (SOHO), or SOHO-1. It was discovered by SOHO/LASCO C3 images by Shane Stezelberger ...
  68. [68]
    Sungrazer Project - Navy.mil
    The Sungrazer Project is a NASA-funded program than enables the discovery and reporting of previously unknown comets in the ESA/NASA SOHO and NASA STEREO ...SOHO Meyer Group Comets... · SOHO Kracht-Group Comets... · Project Information
  69. [69]
    ESA, NASA Solar Observatory discovers its 5,000th comet - Phys.org
    Mar 27, 2024 · On March 25, 2024, a citizen scientist in the Czech Republic spotted a comet in an image from the Solar and Heliospheric Observatory (SOHO) ...<|control11|><|separator|>
  70. [70]
    SOHO Spots 2000th Comet - Naval Research Laboratory (NRL)
    Since it launched on December 2, 1995 to observe the sun, SOHO has more than doubled the number of comets for which orbits have been determined over the last ...
  71. [71]
    SOHO comets: 20 years and 3000 objects later - PMC
    The overwhelming majority of SOHO discoveries have been made by amateur astronomers and enabled by the NASA-funded Sungrazing Comets Project, which was ...
  72. [72]
    POPULATION OF SOHO/STEREO KREUTZ SUNGRAZERS AND ...
    Oct 30, 2013 · We examine properties of the population of SOHO/STEREO (dwarf) Kreutz sungrazing comets from 2004 to 2013, including the arrival rates, peculiar gaps,Missing: percentage | Show results with:percentage
  73. [73]
    NRL's Sungrazer Project Discovers 5000th Comet
    Mar 25, 2024 · ... NASA) Solar and Heliospheric Observatory (SOHO). The 5,000th discovery was made by amateur astronomer Hanjie Tan from Guangzhou, China, who ...
  74. [74]
    [PDF] SOHO's Recovery – An Unprecedented Success Story
    The SOHO mission is a major element of the joint ESA/NASA International Solar Terrestrial Programme (ISTP). ESA was responsible for the spacecraft's ...
  75. [75]
    SOHO MISSION INTERRUPTION FAILURE INVESTIGATION
    The SOHO spacecraft was built in Europe by an industrial team led by Matra Marconi Space (MMS) with instruments provided by nine European and three American ...
  76. [76]
    [PDF] The Million Mile Rescue - Office of Safety and Mission Assurance
    Nov 1, 2008 · SOHO's attitude progressively destabilized until all communication was lost in the early hours of June 25,. 1998. It took three months to ...
  77. [77]
    SOHO is pointing at the Sun again - ESA
    In April 1998, SOHO's scientists celebrated two years of successful operations, and the decision of ESA and NASA to extend the mission to 2003. The extension ...
  78. [78]
    SOHO Mission Extension - ESA Science & Technology
    The new funding ensures that SOHO plays a leading part in the fleet of solar spacecraft scheduled for launch over the next few years.Missing: split | Show results with:split
  79. [79]
    Fact Sheet - ESA Science & Technology
    Nov 3, 2020 · SOHO is a three-axis stabilised spacecraft. It is made up of two ... Dimensions: breadth and width: 3.65 × 3.65 m, span with solar ...Missing: exact | Show results with:exact
  80. [80]
    SOHO - Gunter's Space Page
    Sep 2, 2025 · The mission of SOHO is confirmed throughout 2025, after which it will likely be phased out (following the launch of a next-generation solar ...Missing: exact | Show results with:exact
  81. [81]
    No additional extensions for the Solar and Heliospheric Observatory ...
    Oct 14, 2025 · No additional extensions for the Solar and Heliospheric Observatory (SOHO) beyond 2025-Dec-31 have been announced.
  82. [82]
    SOHO's pioneering 25 years in orbit - Phys.org
    Dec 2, 2020 · Almost 6000 papers have now appeared in refereed journals based on SOHO data, many of them representing significant progress in our ...Missing: peer- reviewed
  83. [83]
    Heliophysics Data - NASA Science
    Open-access gateway to thousands of datasets from NASA Heliophysics missions offering sophisticated analyses and modeling tools and documentation resources.Missing: SOHO | Show results with:SOHO
  84. [84]
    SOHO and the Parker Solar Probe Join Forces to study the Sun
    Nov 15, 2017 · It will approach the Sun to within 10 solar radii (approximately 6 million km from the surface). For comparison, SOHO's LASCO C3's field-of-view ...Missing: references | Show results with:references