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Using adaptive mesh refinement, supercomputer simulation narrows axion mass range — ScienceDaily

Physicists looking — unsuccessfully — for as we speak’s most favored candidate for darkish matter, the axion, have been wanting within the fallacious place, based on a brand new supercomputer simulation of how axions had been produced shortly after the Large Bang 13.6 billion years in the past.

Utilizing new calculational methods and one of many world’s largest computer systems, Benjamin Safdi, assistant professor of physics on the College of California, Berkeley; Malte Buschmann, a postdoctoral analysis affiliate at Princeton College; and colleagues at MIT and Lawrence Berkeley Nationwide Laboratory simulated the period when axions would have been produced, roughly a billionth of a billionth of a billionth of a second after the universe got here into existence and after the epoch of cosmic inflation.

The simulation at Berkeley Lab’s Nationwide Analysis Scientific Computing Heart (NERSC) discovered the axion’s mass to be greater than twice as large as theorists and experimenters have thought: between 40 and 180 microelectron volts (micro-eV, or ?eV), or about one 10-billionth the mass of the electron. There are indications, Safdi stated, that the mass is near 65 ?eV. Since physicists started on the lookout for the axion 40 years in the past, estimates of the mass have ranged extensively, from a number of ?eV to 500 ?eV.

“We offer over a thousandfold enchancment within the dynamic vary of our axion simulations relative to prior work and clear up a 40-year previous query relating to the axion mass and axion cosmology,” Safdi stated.

The extra definitive mass implies that the most typical sort of experiment to detect these elusive particles — a microwave resonance chamber containing a robust magnetic area, through which scientists hope to snag the conversion of an axion right into a faint electromagnetic wave — will not be capable to detect them, regardless of how a lot the experiment is tweaked. The chamber must be smaller than a number of centimeters on a facet to detect the higher-frequency wave from a higher-mass axion, Safdi stated, and that quantity can be too small to seize sufficient axions for the sign to rise above the noise.

“Our work offers probably the most exact estimate thus far of the axion mass and factors to a selected vary of plenty that isn’t at present being explored within the laboratory,” he stated. “I actually do assume it is smart to focus experimental efforts on 40 to 180 ?eV axion plenty, however there’s a whole lot of work gearing as much as go after that mass vary.”

One newer sort of experiment, a plasma haloscope, which appears to be like for axion excitations in a metamaterial — a solid-state plasma — needs to be delicate to an axion particle of this mass, and will doubtlessly detect one.

“The essential research of those three-dimensional arrays of superb wires have labored out amazingly effectively, a lot better than we ever anticipated,” stated Karl van Bibber, a UC Berkeley professor of nuclear engineering who’s constructing a prototype of the plasma haloscope whereas additionally collaborating in a microwave cavity axion search referred to as the HAYSTAC experiment. “Ben’s newest end result could be very thrilling. If the post-inflation state of affairs is true, after 4 many years, discovery of the axion could possibly be vastly accelerated.”

If axions actually exist.

The work can be revealed Feb. 25 within the journal Nature Communications.

Axion high candidate for darkish matter

Darkish matter is a mysterious substance that astronomers know exists — it impacts the actions of each star and galaxy — however which interacts so weakly with the stuff of stars and galaxies that it has eluded detection. That does not imply darkish matter cannot be studied and even weighed. Astronomers know fairly exactly how a lot darkish matter exists within the Milky Method Galaxy and even in your entire universe: 85% of all matter within the cosmos.

To this point, darkish matter searches have targeted on huge compact objects within the halo of our galaxy (referred to as huge compact halo objects, or MACHOs), weakly interacting huge particles (WIMPs) and even unseen black holes. None turned up a probable candidate.

“Darkish matter is many of the matter within the universe, and we don’t know what it’s. One of the crucial excellent questions in all of science is, ‘What’s darkish matter?'” Safdi stated. “We suspect it’s a new particle we do not find out about, and the axion could possibly be that particle. It could possibly be created in abundance within the Large Bang and be floating on the market explaining observations which have been made in astrophysics.”

Although not strictly a WIMP, the axion additionally interacts weakly with regular matter. It passes simply via the earth with out disruption. It was proposed in 1978 as a brand new elementary particle that would clarify why the neutron’s spin doesn’t precess or wobble in an electrical area. The axion, based on principle, suppresses this precession within the neutron.

“Nonetheless to today, the axion is the perfect concept we’ve got about learn how to clarify these bizarre observations in regards to the neutron,” Safdi stated.

Within the Nineteen Eighties, the axion started to be seen additionally as a candidate for darkish matter, and the primary makes an attempt to detect axions had been launched. Utilizing the equations of the well-vetted principle of elementary particle interactions, the so-called Commonplace Mannequin, along with the idea of the Large Bang, the Commonplace Cosmological Mannequin, it’s attainable to calculate the axion’s exact mass, however the equations are so troublesome that thus far we’ve got solely estimates, which have different immensely. Because the mass is understood so imprecisely, searches using microwave cavities — primarily elaborate radio receivers — should tune via tens of millions of frequency channels to attempt to discover the one equivalent to the axion mass.

“With these axion experiments, they do not know what station they’re speculated to be tuning to, so that they should scan over many various prospects,” Safdi stated.

Safdi and his crew produced the newest, although incorrect, axion mass estimate that experimentalists are at present focusing on. However as they labored on improved simulations, they approached a crew from Berkeley Lab that had developed a specialised code for a greater simulation approach referred to as adaptive mesh refinement. Throughout simulations, a small a part of the increasing universe is represented by a three-dimensional grid over which the equations are solved. In adaptive mesh refinement, the grid is made extra detailed round areas of curiosity and fewer detailed round areas of house the place nothing a lot occurs. This concentrates computing energy on an important elements of the simulation.

The approach allowed Safdi’s simulation to see hundreds of occasions extra element across the areas the place axions are generated, permitting a extra exact dedication of the entire variety of axions produced and, given the entire mass of darkish matter within the universe, the axion mass. The simulation employed 69,632 bodily pc processing unit (CPU) cores of the Cori supercomputer with almost 100 terabytes of random entry reminiscence (RAM), making the simulation one of many largest darkish matter simulations of any type thus far.

The simulation confirmed that after the inflationary epoch, little tornadoes, or vortices, type like ropey strings within the early universe and throw off axions like riders bucked from a bronco.

“You may consider these strings as composed of axions hugging the vortices whereas these strings whip round forming loops, connecting, present process a whole lot of violent dynamical processes through the enlargement of our universe, and the axions hugging the edges of those strings are attempting to carry on for the trip,” Safdi stated. “However when one thing too violent occurs, they simply get thrown off and whip away from these strings. And people axions which get thrown off of the strings find yourself changing into the darkish matter a lot afterward.”

By holding monitor of the axions which are whipped off, researchers are capable of predict the quantity of darkish matter that was created.

Adaptive mesh refinement allowed the researchers to simulate the universe for much longer than earlier simulations and over a a lot greater patch of the universe than earlier simulations.

“We remedy for the axion mass each in a extra intelligent means and likewise by throwing simply as a lot computing energy as we may probably discover onto this drawback,” Safdi stated. “We may by no means simulate our complete universe as a result of it is too large. However we needn’t stimulate our complete universe. We simply must simulate a sufficiently big patch of the universe for an extended sufficient time period, such that we seize all the dynamics that we all know are contained inside that field.”

The crew is working with a brand new supercomputing cluster now being constructed at Berkeley Lab that may allow simulations that may present an much more exact mass. Known as Perlmutter, after Saul Perlmutter, a UC Berkeley and Berkeley Lab physicist who gained the 2011 Nobel Prize in Physics for locating the accelerating enlargement of the universe pushed by so-called darkish power, the next-generation supercomputer will quadruple the computing energy of NERSC.

“We need to make even greater simulations at even larger decision, which is able to enable us to shrink these error bars, hopefully all the way down to the ten% degree, so we are able to inform you a really exact quantity, like 65 plus or minus 2 micro-eV. That then actually adjustments the sport experimentally, as a result of then it will change into a neater experiment to confirm or exclude the axion in such a slender mass vary,” Safdi stated.

For van Bibber, who was not a member of Safdi’s simulation crew, the brand new mass estimate exams the boundaries of microwave cavities, which work much less effectively at excessive frequencies. So, whereas the decrease restrict of the mass vary remains to be inside the capacity of the HAYSTAC experiment to detect, he’s enthused in regards to the plasma haloscope.

“Through the years, new theoretical understanding has loosened the constraints on the axion mass; it may be anyplace inside 15 orders of magnitude, if you happen to take into account the chance that axions shaped earlier than inflation. It is change into an insane job for experimentalists,” stated van Bibber, who holds UC Berkeley’s Shankar Sastry Chair of Management and Innovation. “However a current paper by Frank Wilczek’s Stockholm principle group might have resolved the conundrum in making a resonator which could possibly be concurrently each very massive in quantity and really excessive in frequency. An precise resonator for an actual experiment remains to be some methods away, however this could possibly be the best way to go to get to Safdi’s predicted mass.”

As soon as simulations give an much more exact mass, the axion might, in reality, be straightforward to seek out.

“It was actually essential that we teamed up with this pc science crew at Berkeley Lab,” Safdi stated. “We actually expanded past the physics area and really made this a computing science drawback.”

Safdi’s colleagues embody Malte Buschmann of Princeton; MIT postdoctoral fellow Joshua Foster; Anson Hook of the College of Maryland; and Adam Peterson, Don Willcox and Weiqun Zhang of Berkeley Lab’s Heart for Computational Sciences and Engineering. The analysis was largely funded by the U.S. Division of Power via the Exascale Computing Mission (17-SC-20-SC) and thru the Early Profession program (DESC0019225).


Video on measuring an axion: