New simulations performed on a NASA supercomputer are providing scientists with the most comprehensive look yet into the maelstrom of interacting magnetic structures around city-sized neutron stars in the moments before they crash. The team identified potential signals emitted during the stars’ final moments that may be detectable by future observatories.
“Just before neutron stars crash, the
highly magnetized, plasma-filled regions around them, called magnetospheres,
start to interact strongly. We studied the last several orbits before the
merger, when the entwined magnetic fields undergo rapid and dramatic changes,
and modeled potentially observable high-energy signals,” said lead scientist
Dimitrios Skiathas, a graduate student at the University
of Patras, Greece, who is conducting research for
the Southeastern Universities Research
Association in Washington at NASA’s
Goddard Space Flight Center in Greenbelt,
Maryland.
New supercomputer simulations explore the tangled magnetic structures
around merging neutron stars. Called magnetospheres, the highly magnetized,
plasma-filled regions start to interact as the city-sized stars close on each
other toward their final orbits. Magnetic field lines can connect both stars,
break, and reconnect, while currents surge through surrounding plasma moving at
nearly the speed of light. The simulations show that as these systems merge to
produce one kind of gamma-ray burst — the universe’s most powerful class of
explosions — they emit tell-tale X-rays and gamma rays that future
observatories should be able to detect. NASA’s
Goddard Space Flight Center
A paper describing
the findings published Nov. 20, 2025, in the The Astrophysical Journal.
Neutron star mergers produce a
particular type of GRB (gamma-ray burst), the most powerful class of explosions
in the cosmos.
Most investigations have naturally
concentrated on the spectacular mergers and their aftermaths, which produce
near-light-speed jets that emit gamma rays, ripples in space-time called
gravitational waves, and a so-called kilonova explosion that forges heavy
elements like gold and platinum. A merger observed in 2017 dramatically confirmed the long-predicted connections between
these phenomena — and remains the only event seen so far to exhibit all three.
Neutron stars pack more mass than our
Sun into a ball about 15 miles (24 kilometers) across, roughly the length of
Manhattan Island in New York City. They form when the core of a massive star
runs out of fuel and collapses, crushing the core and triggering a supernova
explosion that blasts away the rest of the star. The collapse also revs up the
core’s rotation and amplifies its magnetic field.
“In our simulations, the magnetosphere behaves like a magnetic circuit that
continually rewires itself as the stars orbit.
Newborn neutron stars can spin dozens of
times a second and wield some of the strongest magnetic fields known, up to 10
trillion times stronger than a refrigerator magnet. That’s strong enough to
directly transform gamma-rays into electrons and positrons and rapidly
accelerate them to energies far beyond anything achievable in particle
accelerators on Earth.
“In our simulations, the magnetosphere
behaves like a magnetic circuit that continually rewires itself as the stars
orbit. Field lines connect, break, and reconnect while currents surge through
plasma moving at nearly the speed of light, and the rapidly varying fields can
accelerate particles,” said co-author Constantinos Kalapotharakos at NASA
Goddard. “Following that nonlinear evolution at high resolution is exactly why
we need a supercomputer!”
Using the Pleiades supercomputer at
NASA’s Ames Research Center in California’s Silicon Valley, the team ran more
than 100 simulations of a system of two orbiting neutron stars, each with 1.4
solar masses. The goal was to explore how different magnetic field
configurations affected the way electromagnetic energy — light in all of its
forms — left the binary system. Most of the simulations describe the last 7.7
milliseconds before the merger, enabling a detailed study of the final orbits.
“Our work shows that the light emitted
by these systems varies greatly in brightness and is not distributed evenly, so
a far-away observer’s perspective on the merger matters a great deal,” said
co-author Zorawar Wadiasingh at the University of Maryland, College Park and
NASA Goddard. “The signals also get much stronger as the stars get closer and
closer in a way that depends on the relative magnetic orientations of the
neutron stars.”
Magnetic field lines anchored to the
surfaces of each star sweep behind them as the stars orbit. Field lines may
directly connect one star to the other as the orbits shrink, while lines
already linking the stars may break and reconfigure.
“One value of studies like this is to help us figure out what future
observatories might be able to see and should be looking for in both
gravitational waves and light.
Demosthenes Kazanas
Using the simulations, the team also
computed electromagnetic forces acting on the stars’ surfaces. While the
effects of gravity dominate, these magnetic stresses could accumulate in
strongly magnetized systems. Future models may help reveal how magnetic
interactions influence the last moments of the merger.
“Such behavior could be imprinted on
gravitational wave signals that would be detectable in next-generation
facilities. One value of studies like this is to help us figure out what future
observatories might be able to see and should be looking for in both
gravitational waves and light,” said Goddard’s Demosthenes Kazanas.
The team, which includes Alice Harding at the Los Alamos National Laboratory in New Mexico and Paul Kolbeck at the University of Washington in Seattle, then used the simulated fields to identify where the highest-energy emission would be produced and how it would propagate.
This view of a
supercomputer simulation of merging, magnetized neutron stars highlights
regions producing the highest-energy light. Brighter colors indicate stronger
emission. These regions produce gamma rays with energies trillions of times
greater than that of visible light, but likely none of it could escape. That’s
because the highest-energy gamma rays quickly convert to particles in the
presence of the stars' powerful magnetic fields. However, gamma rays at lower
energies, with millions of times the energy of visible light, can exit the
merging system, and the resulting particles may also radiate at still lower
energies, including X-rays. The emission varies rapidly and is highly
directional, but it could potentially be detected by future facilities.
NASA’s Goddard Space
Flight Center/D. Skiathas et al. 2025
In the chaotic plasma
surrounding the neutron stars, particles transform into radiation and vice
versa. Speedy electrons emit gamma rays, the highest-energy form of light,
through a process called curvature radiation. A gamma-ray photon can interact
with a strong magnetic field in a way that transforms it into a pair of
particles, an electron and a positron.
The study found regions producing gamma
rays with energies trillions of times greater than that of visible light, but
likely none of it could escape. The highest-energy gamma rays quickly converted
to particles in the presence of powerful magnetic fields. However, gamma rays
at lower energies, with millions of times the energy of visible light, can exit
the merging system, and the resulting particles may also radiate at still lower
energies, including X-rays.
The finding suggests that future
medium-energy gamma-ray space telescopes, especially those with wide fields of
view, may detect signals originating in the runup to the merger if
gravitational-wave observatories can provide timely alerts and sky localization.
Today, ground-based gravitational-wave observatories, such as LIGO (Laser Interferometer Gravitational-Wave Observatory) in Louisiana
and Washington, and Virgo in Italy, detect neutron star
mergers with frequencies between 10 and 1,000 hertz and can enable rapid
electromagnetic follow-up.
ESA (European
Space Agency) and NASA are collaborating on a space-based gravitational-wave
observatory named LISA (Laser Interferometer Space
Antenna), planned for launch in the 2030s. LISA will observe neutron-star
binaries much earlier in their evolution at far lower gravitational-wave
frequencies than ground-based observatories, typically long before they merge.
Future gravitational-wave observatories
will be able to alert astronomers to systems on the verge of merging. Once such
systems are found, wide-field gamma-ray and X-ray observatories could begin
searching for the pre-merger emission highlighted by these simulations.
Routine observation of events like these
using two different “messengers” — light and gravitational waves — will provide
a major leap forward in understanding this class of GRBs, and NASA researchers
are helping to lead the way.
By Francis Reddy
NASA’s
Goddard Space Flight Center,
Greenbelt, Md.
Source: NASA Researchers Probe Tangled Magnetospheres of Merging Neutron Stars - NASA Science
