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Magnetars drag spacetime to power superluminous supernovae

March 14, 2026
Ars technica
Magnetars drag spacetime to power superluminous supernovae

Here's something that might blow your mind — magnetars, these ultra-magnetic neutron stars, might actually be the engines behind the universe's brightest explosions. According to Jacek Krywko writing in Technology, astrophysicists have long wondered what powers superluminous supernovae. Well, now it looks like magnetars are the key. These stars are born from collapsing massive cores of dead stars, and they spin incredibly fast, emitting energy through their magnetic fields. What’s fascinating is that as they slow down, they transfer their rotational energy into the surrounding debris, lighting up the explosion with mind-boggling brightness. Joseph Farah, an astrophysicist at UC Santa Barbara, points out that this process of dragging spacetime itself might be what makes these supernovae so absurdly luminous. So what does this mean for us? It’s a huge step toward understanding some of the universe’s most extreme events — and it’s pretty wild to think how these tiny, city-sized objects can have such a cosmic impact.

Some of the most extreme explosions in the universe are Type I superluminous supernovae. “They are one of the brightest explosions in the Universe,” says Joseph Farah, an astrophysicist at the University of California, Santa Barbara. For years, astrophysicists tried to understand what exactly makes superluminous supernovae so absurdly powerful. Now it seems like we may finally have some answers.

Farah and his colleagues have found that these events are most likely powered by magnetars, rapidly spinning neutron stars that warp the very space and time around them.

The power within

Magnetars have been a leading candidate for the engine behind superluminous supernovae. The theory says these insanely magnetized stars are born from the collapsing core of the original progenitor star and emit energy via magnetic dipole radiation. “This core is roughly a one solar mass object that gets crushed down to the size of a city,” Farah explains. As its spin slows down, a magnetar bleeds its rotational energy into the expanding material of the dead star, lighting it up.

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Audio Transcript

Some of the most extreme explosions in the universe are Type I superluminous supernovae. “They are one of the brightest explosions in the Universe,” says Joseph Farah, an astrophysicist at the University of California, Santa Barbara. For years, astrophysicists tried to understand what exactly makes superluminous supernovae so absurdly powerful. Now it seems like we may finally have some answers.

Farah and his colleagues have found that these events are most likely powered by magnetars, rapidly spinning neutron stars that warp the very space and time around them.

The power within

Magnetars have been a leading candidate for the engine behind superluminous supernovae. The theory says these insanely magnetized stars are born from the collapsing core of the original progenitor star and emit energy via magnetic dipole radiation. “This core is roughly a one solar mass object that gets crushed down to the size of a city,” Farah explains. As its spin slows down, a magnetar bleeds its rotational energy into the expanding material of the dead star, lighting it up.

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Magnetars drag spacetime to power superluminous supernovae | Speasy