A powerful and unusually persistent radio burst from the Sun has captured the attention of scientists after lasting an astonishing 19 days, smashing the previous known record for this type of solar event. First detected in August 2025, the phenomenon initially appeared routine before continuing far longer than researchers believed possible. Using a network of spacecraft spread across the inner solar system, NASA and international teams traced the source of the signal to an enormous magnetic structure in the Sun’s atmosphere, opening new paths for understanding how dangerous solar activity develops and spreads through space.
Scientists Realized Something Was Different When the Signal Would Not Stop
Type IV solar radio bursts are not rare events. They are produced when clouds of energetic electrons become trapped inside magnetic fields in the Sun’s outer atmosphere, emitting radio waves as they move. Most of these bursts fade within hours or a few days. This one did not. Scientists monitoring the Sun in August 2025 watched the signal continue day after day, eventually reaching a duration of 19 days. The previous record had lasted only five days, making the new event a major outlier in solar physics research.
Researchers quickly understood that they were observing something exceptional. The persistence of the burst suggested that the magnetic environment surrounding the event remained stable for far longer than normal. Such conditions are difficult to maintain on the Sun, where magnetic structures are constantly shifting, collapsing, and reconnecting. The event immediately raised questions about what could sustain trapped electrons for nearly three weeks without dissipating the radio emission.
Event overview of the 19 day corotating type IV continuum. (a) Solar Orbiter/RPW dynamic spectrum (Window 1). (b) Wind/WAVES and (c) Parker Solar Probe/FIELDS flux (Window 2; Wind-Parker Solar Probe overlap). (d) Parker Solar Probe circular polarization V/I (negative values correspond to left-hand circular polarization). (e) STEREO-A/WAVES flux (Window 3). (f) STEREO-A circular polarization V/I. (g)–(i) STEREO-A wavevector azimuth, colatitude, and apparent source size. The apparent cutoff at 2 MHz reflects the direction-finding data product limitation.
Credit: Astrophysical Journal Letters
The radio waves themselves posed no direct threat to Earth. Yet the same magnetic systems responsible for Type IV bursts are often linked to violent solar eruptions capable of launching charged particles into space. Those particles can interfere with satellites, disrupt communications, damage spacecraft electronics, and expose astronauts to increased radiation. Understanding how these magnetic structures behave is therefore deeply connected to modern space weather forecasting efforts.
NASA And International Spacecraft Followed the Burst Across the Solar System
The scale of the observation effort became one of the most remarkable parts of the discovery. According to NASA, no single spacecraft could continuously observe the event for its full duration because the Sun’s rotation gradually moved the source region out of view. Scientists solved this challenge by combining observations from several missions positioned at different locations throughout the inner solar system.
The investigation relied on data from NASA’s Parker Solar Probe, STEREO, and Wind spacecraft, alongside the joint ESA/NASA Solar Orbiter mission. As the Sun rotated, the radio burst passed into the viewing range of different spacecraft one after another, allowing researchers to maintain nearly continuous monitoring across the 19-day period. This multi-spacecraft tracking strategy gave scientists one of the most complete observational records ever assembled for a Type IV burst.
WCRS localization and observing geometry. (a) Polar view with spacecraft positions (red filled square: STEREO-A; green: Wind/Earth; orange: Parker Solar Probe; purple: Solar Orbiter); the radial coordinate is logarithmic. Colored wedges indicate the propagation directions and full angular widths of three fast CMEs, with onset times and sheath (shock-front) speeds from the NASA/CCMC DONKI CME catalog (coronagraph-based fits from available viewpoints). We use these catalog fits for timing/geometry context only; uncertainties are larger for the farside CME1, and we do not attempt a detailed CME reconstruction. (b)–(d) WCRS source trajectories (close-side ray-sphere solutions) for 975, 1475, and 1925 kHz, projected onto the HEEQ equatorial (x–y) plane and color coded by time during Window 3. (e) Spacecraft heliolongitudes vs. time; horizontal bars mark the three type IV visibility windows.
Credit: Astrophysical Journal Letters
Researchers also introduced a new analysis technique using observations from STEREO to pinpoint the source of the signal more accurately than before. The team traced the burst to a massive magnetic structure known as a helmet streamer, a towering feature extending outward from the Sun’s corona. Helmet streamers are often associated with regions where solar material and magnetic energy accumulate before being released into space. Their large scale and relatively stable magnetic configuration may explain how electrons remained trapped long enough to sustain the extraordinary radio emission.
A Chain of Explosive Solar Eruptions May Have Fueled the Event
Scientists believe the long-lived burst was likely energized by a sequence of three major coronal mass ejections erupting from the same active region of the Sun. Coronal mass ejections, often called CMEs, are giant explosions that hurl billions of tons of plasma and magnetic fields into space at extreme speeds. When several CMEs emerge from the same region in rapid succession, they can reinforce and reshape surrounding magnetic structures.
Researchers suspect that this chain of eruptions continuously replenished the trapped population of energetic electrons inside the helmet streamer. Instead of fading naturally, the radio burst may have been repeatedly re-energized each time a new CME passed through the region. That process could explain why the event survived for nearly three weeks without collapsing.
PFSS context for the long-duration type IV event, computed from ADAPT/GONG boundary maps with source-surface radius Rss = 2.5 R⊙. Left panels: radial magnetic field Br at the PFSS source surface (red: Br > 0, blue: Br < 0); the source-surface PIL is shown in black. Squares mark the Carrington longitude/latitude of each observing spacecraft projected onto the source surface at representative times in the three visibility windows: (a) Solar Orbiter (2025 August 21 21:30 UT), (b) Wind and Parker Solar Probe (2025 September 4 23:00 UT), and (c) STEREO-A (2025 September 8 04:45 UT). Right panels: PFSS field lines traced from r = 1.2 R⊙ and rendered from the corresponding spacecraft viewpoint; closed field lines are white and open field lines are colored by polarity (red: Br > 0, blue: Br < 0). The PIL is located roughly ∼90° eastward of each projected spacecraft longitude at these epochs, suggesting that the relevant helmet streamer lies near the visible east limb from each viewpoint.
Credit: Astrophysical Journal Letters
The finding offers scientists an important clue about how large magnetic systems on the Sun evolve over time. It also highlights the possibility that long-duration radio bursts may serve as indicators of prolonged magnetic instability capable of generating repeated solar eruptions. Such activity can influence space weather conditions throughout the solar system, especially during periods of heightened solar activity as the Sun approaches the peak of its current solar cycle.
The Discovery Could Improve Future Space Weather Forecasting
The results, published in Astrophysical Journal Letters, are already helping researchers refine methods used to identify dangerous solar conditions before they impact Earth and spacecraft. Long-lasting radio bursts could become valuable markers for regions capable of producing repeated eruptions and sustained particle acceleration. Detecting those signals earlier may improve forecasting models used by satellite operators, mission planners, and space agencies worldwide.
The event also demonstrates the growing importance of coordinated observations between spacecraft operating far from Earth. Missions such as Parker Solar Probe and Solar Orbiter are transforming scientists’ ability to study the Sun from multiple perspectives at once. Instead of relying on a single observational point, researchers can now reconstruct solar activity across vast regions of space with unprecedented detail.
As solar activity intensifies during the current cycle, scientists expect more unusual events to emerge. Yet few anticipated witnessing a radio burst that would continue for 19 consecutive days. The discovery has already challenged assumptions about the lifespan of Type IV bursts and revealed how complex magnetic structures can sustain energetic activity much longer than existing theories predicted.