Level 1 — Absolute Beginner
A neutron star is a very small, very heavy star. It is what is left after a big star dies in a huge explosion.
Most neutron stars are very dark. They are hard to see, even with the best telescopes we have today.
Now scientists have a new plan. They want to use a new space telescope called Roman to find these hidden stars.
The Roman telescope will look at how the light from far stars bends when it passes a neutron star. That bend will help us to count and weigh these dark, hidden stars.
- neutron star
- a very small but very heavy star, left behind after a big star explodes
- telescope
- a tool that helps us see things that are very far away in the sky
- space
- the area outside the Earth where the stars and planets are
- explosion
- a sudden, very loud event that throws out a lot of energy
- scientist
- a person whose job is to study the world or the sky and find new things
- light
- what comes from the sun, lamps and stars and lets us see
- bend
- to make something change direction
- weigh
- to find out how heavy something is
Level 2 — Elementary
Neutron stars are some of the strangest objects in space. When a very big star runs out of fuel, it explodes in what is called a supernova, and the core left behind can squeeze into a ball just 20 kilometres wide. That tiny ball still has more matter inside it than the Sun.
Scientists think the Milky Way, our galaxy, may hold tens to hundreds of millions of these neutron stars. But because most of them no longer send out radio pulses, only a few thousand have ever been spotted.
On May 15, 2026, researchers shared a new idea in the journal Astronomy and Astrophysics. They say NASA's new Nancy Grace Roman Space Telescope, which should launch in September, can use the bend in light from distant stars to find lonely neutron stars passing in front of them.
This trick is called astrometric microlensing. When a neutron star moves between us and a far star, its strong gravity bends the light a little, and the far star looks like it has moved sideways for a short time. By measuring this small shift, Roman should be able to find — and even weigh — neutron stars that no other telescope can see.
- supernova
- the huge explosion that ends the life of a very big star
- core
- the central, innermost part of an object
- matter
- the stuff that everything is made of, like rock, gas and water
- Milky Way
- the galaxy in which our Sun and Earth are found
- galaxy
- a huge group of stars, gas and dust held together by gravity
- pulse
- a short burst of radio waves or light, like a heart beat in space
- gravity
- the force that pulls objects with mass towards each other
- microlensing
- a small bending of light by gravity that makes a distant star seem to shift
Level 3 — Intermediate
A paper accepted by Astronomy and Astrophysics and circulated to the science press on May 15, 2026 argues that NASA's Nancy Grace Roman Space Telescope, now in final integration ahead of a launch window opening in early September, could become the first instrument capable of routinely detecting and weighing isolated neutron stars across the Milky Way. Theoretical models suggest the galaxy holds anywhere between fifty and several hundred million of these stellar remnants, yet existing surveys, dominated by radio pulsars and X-ray binaries, have catalogued only a few thousand.
The proposed technique is astrometric microlensing. When a neutron star drifts between an observer and a more distant background star, its compact mass deflects the background star's light, both brightening the source and shifting its apparent position by a tiny fraction of a milliarcsecond. Roman's 2.4-metre primary mirror and infrared focal plane are exquisitely sensitive to both the photometric brightening and that minute astrometric wobble.
Crucially, the joint measurement of the two signals breaks a long-standing degeneracy in microlensing analysis. Where ground-based surveys typically constrain only the product of the lens mass and its distance, Roman can measure that pair independently — yielding the mass of the lensing neutron star directly. The study estimates that during Roman's planned bulge time-domain survey, dozens of isolated neutron stars should be unambiguously detected and weighed over a five-year mission, with hundreds of further candidates flagged for follow-up.
If the prediction holds, Roman would for the first time deliver a population-scale mass function for solitary neutron stars — a measurement currently impossible because radio pulsars are observed mainly in binary systems. That distribution feeds directly into open questions about the equation of state of ultra-dense nuclear matter, the maximum mass before collapse to a black hole, and the supernova fallback physics that decides whether a dying star becomes a neutron star or a black hole at all.
- stellar remnant
- the dense object left behind after a star ends its life — typically a white dwarf, a neutron star or a black hole
- radio pulsar
- a rotating neutron star detected on Earth through its lighthouse-like beams of radio waves
- X-ray binary
- a system in which a neutron star or black hole pulls matter from a companion star, emitting X-rays
- milliarcsecond
- an angle of one thousandth of an arcsecond, the typical scale of high-precision astrometric measurements
- astrometry
- the branch of astronomy concerned with the precise positions and movements of stars
- photometric brightening
- a temporary rise in the apparent brightness of a star caused by gravitational lensing
- degeneracy
- a situation in which two physical quantities cannot be told apart from a single measurement
Level 4 — Advanced
A theoretical study accepted by Astronomy and Astrophysics on May 13 and released to the science press on May 15, 2026 argues that NASA's Nancy Grace Roman Space Telescope, now in final environmental testing at Goddard Space Flight Center ahead of a launch window opening on September 7, 2026, will become the first instrument capable of routinely identifying, distance-resolving and mass-measuring isolated stellar-mass remnants across the inner Milky Way. Synthetic population models — combining a Milky Way mass function, an initial mass function, supernova fallback prescriptions and a kinematic recipe for natal kicks — predict that Roman should detect dozens of unambiguous isolated-neutron-star microlensing events, plus a comparable number of isolated stellar-mass black holes, during its baseline five-year Galactic Bulge Time Domain Survey.
Roman's instrumental advantage is the simultaneous combination of a 2.4-metre infrared-optimised aperture, a 0.28-square-degree field of view at the focal plane, and astrometric precision at the few-tens-of-microarcsecond level — roughly two orders of magnitude better than any wide-field facility currently operating. When a compact lens transits in front of a more distant source, gravitational microlensing not only brightens the source by a magnification factor depending on dimensionless impact parameter, but also induces a centroid shift of the apparent source position; the amplitude of that shift scales linearly with the angular Einstein radius, breaking the lens-mass–distance degeneracy that has dogged ground-based microlensing surveys for three decades and yielding an absolute lens mass to within roughly ten percent.
The astrophysical payoff is substantial. The catalogue of well-determined neutron-star masses is currently dominated by pulsars in binary systems and is therefore biased towards stars whose evolution survived a close companion. A population-scale mass function of truly isolated neutron stars would constrain the high-density equation of state, calibrate the supernova fallback engine that governs the neutron-star-to-black-hole transition, and place independent limits on the maximum neutron-star mass — a parameter currently bracketed near roughly 2.2 to 2.5 solar masses by combined NICER, gravitational-wave and pulsar-timing measurements.
There are caveats. Crowding in the bulge complicates centroid measurement near galactic-plane extinction maxima, and the predicted yield is sensitive to the assumed natal-kick distribution; doubling the median kick velocity, for instance, roughly halves the number of detectable events as the lens population is sprayed out of the survey footprint. The paper's authors flag the importance of contemporaneous ground-based photometric coverage, both from the Vera C. Rubin Observatory's LSST and from the upgraded KMTNet/OGLE microlensing surveys, to disentangle alternative lens identifications. Even allowing for these systematics, the work makes the strongest theoretical case to date that Roman will, within months of first light, recover the first directly weighed isolated neutron stars in astronomical history.
