Cloud Hosting

Until recently, gravitational waves could have been a figment of Einsteins imagination. Before they were detected, these ripples in spacetime existed only in the physicists general theory of relativity, as far as scientists knew.

Now, researchers have not one but two ways to detect the waves. And theyre on the hunt for more. The study of gravitational waves is booming, says astrophysicist Karan Jani of Vanderbilt University in Nashville. This is just remarkable. No field I can think of in fundamental physics has seen progress this fast.

Just as light comes in a spectrum, or a variety of wavelengths, so do gravitational waves. Different wavelengths point to different types of cosmic origins and require different flavors of detectors.

Gravitational waves with wavelengths of a few thousand kilometers like those detected by LIGO in the United States and its partners Virgo in Italy and KAGRA in Japan come mostly from merging pairs of black holes 10 or so times the mass of the sun, or from collisions of dense cosmic nuggets called neutron stars (SN: 2/11/16). These detectors could also spot waves from certain types of supernovas exploding stars and from rapidly rotating neutron stars called pulsars (SN: 5/6/19).

In contrast, immense ripples that span light-years are thought to be created by orbiting pairs of whopper black holes with masses billions of times that of the sun. In June, scientists reported the first strong evidence for these types of waves by turning the entire galaxy into a detector, watching how the waves tweaked the timing of regular blinks from pulsars scattered throughout the Milky Way (SN: 6/28/23).

With the equivalent of both small ripples and major tsunamis in hand, physicists now hope to plunge into a vast, cosmic ocean of gravitational waves of all sorts of sizes. These ripples could reveal new details about the secret lives of exotic objects such as black holes and unknown facets of the cosmos.

Theres still a lot of gaps in our coverage of the gravitational wave spectrum, says physicist Jason Hogan of Stanford University. But it makes sense to cover all the bases, he says. Who knows what else we might find?

This quest to capture the full complement of the universes gravitational waves could take observatories out into deep space or the moon, to the atomic realm and elsewhere.

Heres a sampling of some of the frontiers scientists are eyeing in search of new types of waves.

The Laser Interferometer Space Antenna, or LISA, sounds implausible at first. A trio of spacecraft, arranged in a triangle with 2.5-million-kilometer sides, would beam lasers to one another while cartwheeling in an orbit around the sun. But the European Space Agency mission, planned for the mid-2030s, is no mere fantasy (SN: 6/20/17). It is many scientists best hope for breaking into new realms of gravitational waves.

LISA is a mind-blowing experiment, says theoretical physicist Diego Blas Temio of Universitat Autnoma de Barcelona andInstitut de Fsica dAltes Energies.

As a gravitational wave passes by, LISA would detect the stretching and squeezing of the sides of the triangle, based on how the laser beams interfere with each other at the triangles corners. A proof-of-concept experiment with a single spacecraft, LISA Pathfinder, flew in 2015 and demonstrated the feasibility of the technique (SN: 6/7/16).

Generally, to catch longer wavelengths of gravitational waves, you need a bigger detector. LISA would let scientists see wavelengths millions of kilometers long. That means LISA could detect orbiting black holes that would be enormous, but moderately so millions of times the mass of the sun instead of billions.

Get great science journalism, from the most trusted source, delivered to your doorstep.

With NASAs Artemis program aiming at a return to the moon, scientists are looking to Earths neighbor for inspiration (SN: 11/16/22). A proposed experiment called the Laser Interferometer Lunar Antenna, or LILA, would put a gravitational wave detector on the moon.

Without the jostling of human activity and other earthly jitters, gravitational waves should be easier to pick out on the moon. Its almost like a spiritual quietness, Jani says. If you want to listen to the sounds of the universe, these is no place better in the solar system than our moon.

Like LISA, LILA would have three stations beaming lasers in a triangle, though the sides of this one would be about 10 kilometers long. It could catch wavelengths tens or hundreds of thousands of kilometers long. That would fill in a gap between the wavelengths measured by the space-based LISA and the Earth-based LIGO.

Because orbiting objects like black holes speed up as they get closer to merging, over time they emit gravitational waves with shorter and shorter wavelengths. That means LILA could watch black holes close in on one another during the weeks before they merge, giving scientists a heads-up that a collision is about to go down. Then, once the wavelengths get short enough, earthly observatories like LIGO would pick up the signal, catching the moment of impact.

A different moon-based option would use lunar laser ranging a technique by which scientists measure the distance from Earth to the moon with lasers, thanks to reflectors placed on the moons surface during previous moon landings.

The method could detect waves jostling the Earth and the moon, with wavelengths in between those seen by pulsar timing methods and LISA, Blas Temio and a colleague reported in Physical Review D in 2022. But that technique would require improved reflectors on the moon another reason to go back.

LISA, LIGO and other laser observatories measure the stretching and squeezing of gravitational waves by monitoring how laser beams interfere after traversing their detectors long arms. But a proposed technique goes a different route.

Rather than looking for slight changes in the lengths of detector arms as gravitational waves pass, this new technique keeps an eye on the distance between two clouds of atoms. The quantum properties of atoms mean that they act like waves that can interfere with themselves. If a gravitational wave passes through, it changes the distance between the atom clouds. Scientists can tease out that change in distance based on that quantum interference.

The technique could reveal gravitational waves with wavelengths between those detectable by LIGO and LISA, Hogan says. Hes part of an effort to build a prototype detector, called MAGIS-100, at Fermilab in Batavia, Ill.

Atom interferometers have never been used to measure gravitational waves, though they can sense Earths gravity and test fundamental physics rules (SN: 2/28/22; SN: 10/28/20). The idea is totally futuristic, Blas Temio says.

Another effort aims to pinpoint gravitational waves from the earliest moments of the universe. Such waves would have been produced during inflation, the moments after the Big Bang when the universe ballooned in size. These waves would have longer wavelengths than ever seen before as long as 1021 kilometers, or 1 sextillion kilometers.

But the hunt got off to a false start in 2014, when scientists with the BICEP2 experiment proclaimed the detection of gravitational waves imprinted in swirling patterns on the oldest light in the universe, the cosmic microwave background, or CMB. The claim was later overturned (SN: 1/30/15).

An effort called CMB-Stage 4 will continue the search, with plans for multiple new telescopes that would scour the universes oldest light for signs of the waves this time, hopefully, without any missteps.

For most types of gravitational waves that scientists have set their sights on, they know a bit about what to expect. Known objects like black holes or neutron stars can create those waves.

But for gravitational waves with the shortest wavelengths, perhaps just centimeters long, the story is different, says theoretical physicist Valerie Domcke of CERN near Geneva. We have no known source that would actually give us [these] gravitational waves of a large enough amplitude that we could realistically detect them.

Still, physicists want to check if the tiny waves are out there. These ripples could be produced by violent events early in the universes history such as phase transitions, in which the cosmos converts from one state to another, akin to water condensing from steam into liquid. Another possibility is tiny, primordial black holes, too small to be formed by standard means, which might have been born in the early universe. Physics in these regimes is so poorly understood, even looking for [gravitational waves] and not finding them would tell us something, Domcke says.

These gravitational waves are so mysterious that their detection techniques are also up in the air. But the wavelengths are small enough that they could be seen with high-precision, laboratory-scale experiments, rather than enormous detectors.

Scientists might even be able to repurpose data from experiments designed with other goals in mind. When gravitational waves encounter electromagnetic fields, the ripples can behave in ways similar to hypothetical subatomic particles called axions (SN: 3/17/22). So experiments searching for those particles might also reveal mini gravitational waves.

Gravitational waves come in a spectrum of shorter and longer wavelengths. Each wavelength range is generated by different sources. Pulsars and exploding stars, or supernovas, generate some short wavelength ripples. Other waves are produced by pairs of neutron stars, or by pairs of stellar mass black holes, with masses less than 100 times that of the sun. Still longer wavelengths are generated by pairs of supermassive black holes.

Different wavelengths can be spotted using different types of detectors, including ground-based detectors such as LIGO, space-based detectors such as LISA, and measurements of blips from dead stars called pulsars. Especially long wavelengths may be detected by studying the light released shortly after the Big Bang, the cosmic microwave background. Other detector types (not pictured) could fill in the gaps.

Source: NASAs Goddard Space Flight Center Conceptual Image Lab

Catching gravitational waves is like paddling against the tide: tough going, but worth it for the scenic views. Gravitational waves are really, really hard to detect, Hogan says. It took decades of work before LIGO spotted its first swells, and the same is true of the pulsar timing technique. But astronomers immediately began reaping the rewards. Its a whole new view of the universe, Hogan says.

Already, gravitational waves have helped confirm Einsteins general theory of relativity, discover a new class of black holes of moderately sized masses and unmask the fireworks that happen when two ultradense objects called neutron stars collide (SN: 2/11/16; SN: 9/2/20; SN: 10/16/17).

And its still early days for gravitational wave detection. Scientists can only guess at what future detectors will expose. Theres way more to discover, Hogan says. Its bound to be interesting.

Read the original:

Here are some of the new ways researchers might detect ... - Science News Magazine

ByRachel Wallach

Emanuele Berti and David Kaplan, both professors in the William H. Miller III Department of Physics and Astronomy, were named Simons Investigators in Physics by the Simons Foundation. Simons Investigators are outstanding theoretical scientists who receive a stable base of research support from the foundation, enabling them to undertake the long-term study of fundamental questions.

Image caption: David Kaplan and Emanuele Berti

Berti is a theoretical physicist who specializes in gravitational physics and gravitational-wave astronomy. His research interests include the structure, stability, dynamics, and formation of black holes and neutron stars; gravitational-wave signatures of modified theories of gravity and physics beyond the Standard Model; using gravitational waves to understand black hole binary astrophysics and cosmology; and preparing for the challenge of detecting gravitational waves in space with LISA (Laser Interferometer Space Antenna).

With the Simons funding, he plans to train Johns Hopkins students and postdocs in gravitational-wave physics and astronomy. "The models we use to detect gravitational waves from merging black holes and neutron stars are not perfect," Berti says. His group will work to improve these models, along with the ability to look for physics beyond general relativity. The group will use data from current gravitational-wave detectors to understand how astrophysical binaries of black holes and neutron stars form in the universe. The group will also explore the spectacular science enabled by future gravitational-wave detectors on the ground using the Cosmic Explorer and Einstein Telescope, and in space with LISA. These detectors will be much more sensitive, allowing researchers to use gravitational waves as messengers from the early universe.

Kaplan is also a theoretical physicist who discovers possible theoretical extensions to the standard models of particle physics and cosmology and finds novel ways to test them experimentally. He has discovered models of a naturally small cosmological constant and Higgs mass, classical solutions for firewalls in general relativity, and causal modifications of quantum mechanics. He has also found testable models of dark matter, dark energy, and dark radiation. He has proposed algorithms to discover both heavy and long-lived particles at colliders, as well as techniques for discovering dark matter and new elementary forces using new technologies in novel ways.The Simons funding will allow Kaplan to continue worldwide collaborations exploring some of the fundamentals of theoretical physics that could have dramatic physical consequences in cosmology. As Kaplan researches how gravity and quantum field theory interact, he has come to believe there may be deviations in quantum field theory itself. Discovering how general relativity emerges from a quantum theory has revealed the presence of an additional term in general relativity.

"In that sense, we're saying that there's a correction to Einstein's laws," Kaplan says. "And that correction, if it's there, would look like there is some dark matter in the universe that we can't interact with. That's what we're very excited and curious about and wanting to see if this is really true, and what the consequences of that are."

More:

Emanuele Berti and David Kaplan named Simons Investigators in ... - The Hub at Johns Hopkins

Physicists suspect the universe contains magnetic monopoles north or south poles without their counterpart. Theyve yet to find them, but new data from the worlds most powerful particle collider has allowed them to tighten the limits on where in energy-space they may lie.

Every magnet we know, from the Earth itself down to tiny versions we attach to our fridges, has both a north and a south pole. Who hasnt spent time attempting to push two poles of the same sort together? For almost a century, physicists have been on what some may consider an even more fruitless task; finding a north (or south) pole that exists in isolation, with no counterpart.

It sounds like the product of a mind on drugs Hey, what if there was only one magnetic pole? but it was the famously taciturn and workaholic physicist Paul Dirac who proposed the existence of what he called magnetic monopoles. Dirac showed their presence was consistent with quantum mechanics, and indeed a single magnetic monopole, somewhere in the universe could explain otherwise inexplicable features of charge. Dirac proposed the smallest possible magnetic charge, including for a single pole, was 68.5 times the charge on an electron. All larger monopoles should be multiples of that.

In the 70s, the idea moved from possibility to probability, as the existence of magnetic monopoles came to be a key test for theories to unite general relativity and quantum mechanics. Wacky as they sound to those outside the field, one physicist named Joseph Polchinski called their existence; One of the safest bets one could make about physics not yet seen. That was 21 years ago, and Polchinskis bet remains unfilled reports of the discovery of magnetic monopoles have occurred occasionally, but then been withdrawn or cases of misreporting.

The ATLAS collaboration at CERN suspects there are two ways high energy collisions between protons may create magnetic monopoles with masses up to 4 TeV. Each relies on the protons releasing virtual photons (an intermediary between particles that carries the electromagnetic force). In one a virtual photon creates a magnetic monopole on its own, while in the other two photons interact to create a monopole. Either of these would, the collaboration notes; Restore the broken electric-magnetic dual symmetry in Maxwells equations.

ATLAS hopes to find evidence for one of these by looking for charge deposits on their detector. Since a monopole would need to carry a charge so much greater than that of an electron, its deposits should stand out from those of more familiar subatomic particles.

Large Hadron Collider (LHC) data takes a long time to analyze. ATLAS has only now released a preprint of a paper still to pass peer review based on the second LHC run, from 2015-2018. Although they have not found evidence of magnetic monopoles, the team believes they have narrowed down the possible masses/energies for the smallest magnetic monopoles, and their rate of production, by a factor of three.

Quests like this can seem endless to outsiders, as particle physicists report over and over not finding what they are looking for. Telling the world they have narrowed the limits can sound like a justification of failure. However, the same pattern was seen with the search for the Higgs Boson, eventually ending in stunning success. As with the Higgs, finding magnetic monopoles is important, not only to prove theories that predict their existence right, but because the masses we find would differentiate between competing theories.

Certainly, the physics community believes in the quest. The list of the members of the ATLAS collaboration lists more than 3,000 scientists, making their names and affiliations considerably longer than the paper itself.

The paper has been submitted to the Journal of High Energy Physics, and a preprint is available on ArXiv.org

Go here to read the rest:

CERN Places New Limits In The Search For Magnetic Monopoles - IFLScience