The cosmos is not a tranquil place, and the space weather of distant stars is beginning to reveal its dramatic influence on orbiting planets. Among the most energetic phenomena in stellar environments are coronal mass ejections, massive expulsions of magnetised plasma capable of reshaping planetary atmospheres and magnetic fields. While the Sun has provided a laboratory for decades of study, little was known about similar events on stars beyond our Solar System, leaving the potential effects on exoplanets largely speculative. Recent observations have begun to bridge this gap, offering the first direct evidence of a stellar coronal mass ejection and providing insight into its possible implications for planets orbiting M dwarfs, the most common type of star in the galaxy.
How scientists caught evidence of a stellar coronal mass ejection
A recent study published in Nature reports the first unambiguous detection of a TypeII radio burst originating from the M dwarf StKM1-1262. TypeII bursts are associated with super-Alfvénic coronal mass ejections, where a shockwave propels plasma into interplanetary space, effectively disconnecting it from the host star’s magnetic field. Observed at low radio frequencies, the burst lasted approximately two minutes, sweeping from 166 to 120 megahertz, and displayed high circular polarization, indicating fundamental plasma emission. This detection confirms that massive plasma ejections occur on stars other than the Sun, allowing scientists to measure properties of the expelled material directly, rather than relying on indirect inferences based on solar analogues. Such measurements provide a benchmark for understanding the energy, velocity, and frequency of these events across different types of stars, offering unprecedented empirical data.
Could stellar storms erase alien atmospheres ,
The proximity of planets within the conventional habitable zones of M dwarfs makes them particularly vulnerable to coronal mass ejections. Unlike the Earth, which orbits at a safe distance from the Sun, planets around M dwarfs often lie much closer to their host star. Plasma ejected from StKM1-1262 was estimated to reach densities of 3×108 electrons per cubic centimeter at three stellar radii, creating ram pressures capable of compressing planetary magnetospheres even if the planet has a strong terrestrial magnetic field. Such conditions could strip atmospheres over time, exposing surfaces to high-energy radiation and altering the chemical composition essential for life. Observational evidence of these events allows researchers to establish empirical benchmarks for the frequency and intensity of CMEs in these environments, critical for assessing exoplanetary habitability.
Why magnetic fields matter for stellar space weather
The characteristics of a star’s magnetic field play a central role in determining the trajectory and impact of a coronal mass ejection. StKM1-1262 exhibits a poloidal-dipolar, non-axisymmetric magnetic topology with an average surface field of approximately 300 gauss. The study estimated an upper limit of 19 gauss for the magnetic field at the location of the ejected plasma, which influences the propagation and eventual dispersal of the material. Understanding these magnetic structures is vital, as strong fields can confine plasma, preventing it from reaching orbiting planets, while weaker fields allow more energetic particles to escape. Observing how these magnetic interactions vary among stars provides essential context for modeling the space weather environments of exoplanetary systems, as well as the potential long-term atmospheric evolution of planets exposed to repeated CME impacts.
How often do stars launch deadly plasma bursts?
The detection was made during the LOw-Frequency ARray Two-metre Sky Survey, which monitored over 5,000 main-sequence stars at high sensitivity for extended periods. The observed TypeII burst was consistent with the highest velocity CMEs seen on the Sun, reaching around 2,400 kilometers per second. Such events were estimated to occur at a rate of approximately 0.84×10−3 per day per M dwarf, highlighting their rarity. While CMEs on younger and more magnetically active stars may be more frequent, the LOFAR findings indicate that detectable stellar coronal mass ejections remain uncommon. These results establish the first observational limits on stellar CME occurrence, providing a foundation for future studies using more advanced arrays such as the Square Kilometer Array, which will further refine detection rates and energy distributions of these bursts across the galaxy.
What a stellar radio burst tells us about plasma behavior
Analysis of the radio burst’s emission revealed both fundamental frequency characteristics and polarization patterns that matched theoretical expectations for solar TypeII bursts. The emitting region covered approximately 55 per cent of the star’s photospheric surface, producing a brightness temperature of around 1.5×1015 kelvin, a measurement consistent with flaring M dwarfs. While other radio emission mechanisms, such as the electron-cyclotron maser instability, could reproduce some observed features, they could not fully explain the frequency sweep. This alignment with the solar paradigm confirms that plasma was physically expelled into interplanetary space, offering a rare opportunity to measure the density and velocity of stellar ejecta and to model the potential consequences for orbiting exoplanets.Also Read | How was the first full-color photograph of Earth captured by NASA
