Dark matter is strange, mysterious stuff. It might make up as much as 85 percent of the mass of the universe, and its gravity affects everything around it. But we canât see it with our naked eyes. Weâve never directly observed it with any of our instruments, on Earth or zooming through space on some probe.
Now a Swiss team has drawn up an intriguing planâa possible way to get a much more precise read on dark matter. It involves shooting probes toward the most distant planets in our solar system, Uranus and Neptune, and carefully logging every force tugging on their trajectories. If we subtract the known forcesâthe gravitational pull of every nearby planet, moon and asteroidâwhatâs left should be the effect of dark matter.
Itâs a âunique opportunityâ to âimprove measurements of the standard gravitational parameters in the solar system,â Lorenz Zwick and his team from the Center for Theoretical Astrophysics and Cosmology at the University of Zurich wrote in a new peer-reviewed study that appeared online on April 22.
The Swiss plan looks great on paper. In practice, however, it might not be possible to separate the force of dark matter acting on a probe from, say, the force from some unmapped asteroidâor even a loose connector in the probe venting radiation into space. In other words, we might not know enough about the matter we can see to start inferring things about the matter we canât see.
The going theory is that dark matter doesnât interact with electromagnetic fields the same way visible matter does. It neither absorbs light nor reflects it. But weâre pretty sure itâs there. Without it, the universe doesnât make sense. Planets and star systems and whole galaxies behave as though they weigh nearly twice as their visible mass seems to imply. Thereâs a lot more gravitational force than we can account for just by adding up the mass of objects in space.
The gap between what we can see and what we think is there first became evident in the early 20th century. The gap got bigger as our instruments got better. In the late 1960s, Seth Shostak, an astronomer now most famous for his work on SETIâthe search for extraterrestrial intelligenceâused a radio telescope array in California to determine that some galaxies were spinning faster than their visible stars indicated they would. Shostak later surmised the galaxies had mass we couldnât directly observe.
Today, dark matter is integral to astronomy. But that doesnât mean we understand it very well. For one, we donât know how evenly itâs spread. Itâs possible that dark matter is denser inside a star system than it is in the vast distances between systems. Itâs also possible dark matter has contours inside a star system.
Zwickâs close survey of our own system could help us answer that question, with possible knock-on effects across the space sciences. âPursuing new avenues like what is proposed here looks very exciting,â Priyamvada Natarajan, a Yale astronomer who specializes in mapping dark matter and wasnât involved in the University of Zurich study, told The Daily Beast.
We might even be able to settle whether our solar system, or even just our corner of the solar system, is special. âOur current expectations for the [dark matter] density at Earth are based on observations of stars around the galaxy, combined with the assumption that Earth is in a fairly typical part of the galaxy for its distance from the galactic center,â Tracy Slatyer, an associate professor with the Center for Theoretical Physics at Massachusetts Institute of Technology who wasnât involved in the study, told The Daily Beast. âIt would be fantastic if we could test that assumption.â
Zwickâs idea is to launch a probeâor a couple of probesâtoward the farthest big objects in the solar system: the icy planets Uranus and Neptune.
âOnly Uranus and Neptune are sensible targets since the measurement is sensitive to the total enclosed mass of dark matter between the sun and the spacecraft,â Zwick explained to The Daily Beast. In other words, the farther away the targets of your probes, the more dark matter the probes have to travel throughâand the more data they can help gather.
Controllers on the ground would carefully track the probes, noting every tiny change in course and velocity. Logging those changes is the whole point, actually. Each one hints at the influence of gravityâfrom a planet or moon or asteroid or something.
Or maybe even from dark matter. âThe presence of [dark matter] would produce a radial force proportional to the enclosed mass within the spacecraftâs orbit,â the University of Zurich team wrote.
If Zwickâs team or other scientists could send probes to the outer edges of our system and keep track of them for a decade or soâand yes, Zwick has particular probes in mind that could launch in the next 15 yearsâthey might have enough data to start weeding out the obvious influences on the probesâ journeys. Whatâs left might be evidence of dark matter.
Some dark matter experts are skeptical of the planâbut maybe not for the obvious reasons. Cost and technology, the usual obstacles to a new space mission, arenât really the issues. After all, Zwickâs survey wouldnât actually require its own spacecraft. Since all the dark matter scientists need to do is track a probe or two and build a model of gravitational forces on them, any probes will do as long as theyâre traveling far enough.
So it makes the most sense to piggyback on existing spacecraft. Just tweak the radio link for the better telemetry data, and youâre ready to go investigate local dark matter. âIn a sense, we are only hitchhikers,â Zwick said.
Perhaps the best candidates are a pair of probes that NASA wants to send to Uranus and Neptune in the late 2030s. The space agency hasnât fully committed to the probes yet, so thereâs no clear sense of what instruments they might carry or exactly when they might launch. Mark Hofstadter, a planetary scientist at NASA's Jet Propulsion Laboratory in California, stressed the âimportance of exploring at least one of these planets and its entire environment, which includes surprisingly dynamic icy moons, rings and bizarre magnetic fields.â
Zwick and company are already making overtures to NASA. âIf we can make a strong enough case and convince enough people, we hope that the idea will snowball, and that improving the radio link will become a priority in mission planning,â Zwick said.
But even if NASA signs on without delay, other complications could doom Zwickâs dark matter mission.
For starters, itâs possible that dark matterâs influence on a probe, even a far-flying one, would be really, really subtle. Perhaps too subtle to differentiate from a rounding error in our calculations of known gravitational influences. âThere is no way that I know of to get the sensitivity needed to measure dark matter in the solar system purely through its gravitational effects unless the density [of dark matter] is far higher than we expect,â Slatyer warned.
Then thereâs the prospect of unknown gravitational forces that arenât dark matter. As much as Zwickâs proposed project is a matter of subtraction, itâs absolutely critical that we understand all the numbers. A previously unknown force, even a minuscule one, could throw off the whole project. âThe precision one needs to achieve in the determination of motions of test objects in the gravitational field is⌠very high,â Francisco-Shu Kitaura, an astrophysicist at the Institute for Astrophysics in the Canary Islands and the University of La Laguna who wasnât involved in the study, told The Daily Beast. Even Zwick and his team conceded that their proposal would only work âif all the forces acting on the real spacecraft are fully modeled.â
Incomplete modeling was behind one of the earliest dark matter disappointments. In 1972, NASAâs Pioneer probe launched on a mission to Jupiter. Controllers detected a small, unplanned acceleration. For a heady moment, some scientists believed it was evidence of dark matter tugging on the craft. They were wrong. âIn the end, people realized that the spacecraft was emitting thermal radiation⌠which caused it to deviate slightly from its trajectory,â Zwick recalled.
Of course, itâs not 1972 any more. Our tech is better. And when it comes to dark matter, we have a clearer sense of what weâre looking for. Maybe Zwickâs mission to map invisible stuff, assuming it goes forward, will fail because we havenât accounted for all the visible stuff⌠yet.
But itâd still be a probe or two in the right direction.
