Feature NASA’S GODDARD SPACE FLIGHT CENTER SPACE GODDARD NASA’S Powerful magnetic and electric fields whip charged particles around, in a computer simulation of a spinning neutron star. THE STRANGE HEARTS OF NEUTRON STARS Space observations are poised to reveal more about the centre of one of the Universe’s most enigmatic objects. By Adam Mann hen a massive star dies in a cores, remains a mystery. Some researchers team plans to release results about more stars supernova, the explosion is theorize that neutrons might dominate all the in the next few months. Other data are com- only the beginning of the end. way down to the centre. Others hypothesize ing in from gravitational-wave observatories, Most of the stellar matter is that the incredible pressure compacts the which can watch neutron stars contort as they thrown far and wide, but the material into more exotic particles or states crash together. With these combined observa- star’s iron-filled heart remains that squish and deform in unusual ways. tions, researchers are poised to zero in on what behind. This core packs as Now, after decades of speculation, research- fills the innards of a neutron star. much mass as two Suns and ers are getting closer to solving the enigma, For many in the field, these results mark Wquickly shrinks to a sphere that would span in part thanks to an instrument on the Inter- a turning point in the study of some of the the length of Manhattan. Crushing internal national Space Station called the Neutron Star Universe’s most bewildering objects. “This is pressure — enough to squeeze Mount Everest Interior Composition Explorer (NICER). beginning to be a golden age of neutron-star to the size of a sugar cube — fuses subatomic Last December, this NASA space observatory physics,” says Jürgen Schaffner-Bielich, a protons and electrons into neutrons. provided astronomers with some of the most theoretical physicist at Goethe University in Astronomers know that much about how precise measurements ever made of a neutron Frankfurt, Germany. neutron stars are born. Yet exactly what hap- star’s mass and radius1,2, as well as unexpected Launched in 2017 aboard a SpaceX Falcon pens afterwards, inside these ultra-dense findings about its magnetic field1,3. The NICER 9 rocket, the US$62-million NICER telescope 20 | Nature | Vol 579 | 5 March 2020 ©2020 Spri nger Nature Li mited. All ri ghts reserved. ©2020 Spri nger Nature Li mited. All ri ghts reserved. sits outside the space station and collects to the creation of particles called hyperons. relates mass to radius or, equivalently, internal X-rays coming from pulsars — spinning neu- Like neutrons, these particles contain three pressure to density. tron stars that radiate charged particles and quarks. But whereas neutrons contain the If scientists are particularly lucky and nature energy in enormous columns that sweep most basic and lowest-energy quarks, known happens to serve up especially good data, around like beams from a lighthouse. The as up and down quarks, a hyperon has at least NICER might help eliminate certain versions X-rays originate from million-degree hot- one of those replaced with an exotic ‘strange’ of this equation. But most physicists think spots on a pulsar’s surface, where a power- quark. Another possibility is that the centre that, on its own, the observatory will proba- ful magnetic field rips charged particles off of a neutron star is a Bose–Einstein conden- bly narrow down rather than completely rule the exterior and slams them back down at the sate, a state of matter in which all subatomic out models of what happens in the mysterious opposing magnetic pole. particles act as a single quantum-mechanical objects’ cores. NICER detects these X-rays using 56 gold- entity. And theorists have dreamt up even “This would still be a huge advance on where coated telescopes, and time-stamps their more outlandish prospects, too. we are now,” says Watts. arrival to within 100 nanoseconds. With this capability, researchers can precisely track “It’s one thing to know Field lines hotspots as a neutron star whips around at NICER’s first target was J0030+0451, an up to 1,000 times per second. Hotspots are the ingredients. It’s isolated pulsar that spins roughly 200 times visible as they swing across the object. But neu- another to understand per second and is 337 parsecs (1,100 light tron stars warp space-time so strongly that the recipe.” years) from Earth, in the constellation Pisces. NICER also detects light from hotspots facing Two groups — one based primarily at the away from Earth. Einstein’s general theory of University of Amsterdam1 and another led relativity provides a way to calculate a star’s Crucially, each possibility would push back by researchers at the University of Maryland mass-to-radius ratio through the amount of in a characteristic way against a neutron star’s in College Park2 — separately sifted through light-bending. That and other observations colossal gravity. They would generate differ- 850 hours of observations, serving as checks allow astrophysicists to pin down the masses ent internal pressures and therefore a larger on one another. and radii of the deceased stars. Those two or smaller radius for a given mass. A neutron Because the hotspot light curves are so com- properties could help in determining what is star with a Bose–Einstein condensate centre, plex, the groups needed supercomputers to happening down in the cores. for instance, is likely to have a smaller radius model various configurations and work out than one made from ordinary material such which ones best fit the data. But both came up Deep, dark mystery as neutrons. One with a core made of pliable with similar results, finding that J0030 has a Neutron stars get more complicated the hyperon matter could have a smaller radius still. mass that is 1.3 or 1.4 times that of the Sun, and deeper one goes. Beneath a thin atmosphere “The types of particles and the forces a radius of roughly 13 kilometres. made mostly of hydrogen and helium, the between them affect how soft or squashy the Those results are not definitive: they could stellar remnants are thought to boast an material is,” says Anna Watts, a NICER team be used to support either the mundane or the outer crust just a centimetre or two thick member at the University of Amsterdam. other worldly predictions for what’s inside the that contains atomic nuclei and free-roaming Differentiating between the models will guts of neutron stars. “There’s no requirement electrons. Researchers think that the ionized require precise measurements of the size for anything funky or crazy or exotic yet,” says elements become packed together in the next and mass of neutron stars, but researchers Andrew Steiner, a nuclear astrophysicist at the layer, creating a lattice in the inner crust. Even haven’t yet been able to push their techniques University of Tennessee, Knoxville. further down, the pressure is so intense that to fine-enough levels to say which possibility Researchers got a bigger surprise with almost all the protons combine with electrons is most likely. They typically estimate masses findings about the shape and position of to turn into neutrons, but what occurs beyond by observing neutron stars in binary pairs. As the hotspots. The canonical view of neutron that is murky at best (see ‘Dense matter’). the objects orbit one another, they tug gravi- stars has their magnetic field lines looking like “It’s one thing to know the ingredients,” says tationally on each other, and astronomers can those surrounding a bar magnet, with north Jocelyn Read, an astrophysicist at California use this to determine their masses. Roughly and south sides emerging from circular spots State University, Fullerton. “It’s another to 35 stars have had their masses measured in at opposing ends of the star. By contrast, the understand the recipe, and how those ingre- this way, although the figures can contain Dutch supercomputer simulations implied dients are going to interact with each other.” error bars of up to one solar mass. A mere that both of J0030’s hotspots are in its south- Physicists have some idea of what happens, dozen or so have also had their radii calcu- ern hemisphere, and that one of them is long thanks to particle accelerators on Earth. At lated, but in many cases, the techniques can’t and crescent-shaped1. The Maryland team also facilities such as Brookhaven National Labo- determine this value to better than a few kilo- came up with the possibility of a three-hotspot ratory in Upton, New York, and CERN’s Large metres — as much as one-fifth of the size of a solution: two southerly oval-shaped ones and Hadron Collider near Geneva, Switzerland, neutron star. a final circle near the rotational south pole3. researchers have smashed together heavy NICER’s hotspot method has been used by “It looks like they might have made the first ions, such as those of lead and gold, to cre- the European Space Agency’s XMM-Newton real detection of a pulsar where the beams are ate brief collections of monumentally dense X-ray observatory, which launched in 1999 and not 180 degrees separated,” says Natalie Webb, mat erial. But these kinetic experiments gen- is still in operation. NICER is four times more an astrophysicist at the Institute for Research erate billion- or even trillion-degree flashes, sensitive and has hundreds of times better in Astrophysics and Planetology in Toulouse, in which protons and neutrons dissolve into a time resolution than the XMM-Newton.