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Newly discovered Fast Radio Burst 190520 prompts more questions due to strange behavior

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Newly discovered fast radio burst (FRB) 190520 shows unique behavior compared to other FRBs discovered so far.  This deviant cosmic burst was observed by an international team, co-led by researchers at West Virginia University and the Center for Gravitational Waves and Cosmology.

Sarah Burke-SpolaorProfessor Sarah Burke Spolaor along with then Graduate Assistant Kshitij Aggarwal, both of the WVU Department of Physics and Astronomy and the Center for Gravitational Waves and Cosmology, published their findings in Nature.  In the paper, they describe observing the unique behavior of the fast radio burst called FRB 190520.




Additionally, West Virginia University Graduate Assistants Jessica Sydnor and Reshma Thomas both played critical roles in the discovery.


Reshma Thomas
Reshma (left) worked closely with Burke Spolaor to obtain follow-up data on the FRB to better understand some of the interesting properties found by the initial discovery.

Jessica (below, right) aided Burke Spolaor in imaging and image interpretation to cross check results seen by the FAST collaborators.

Jessica Sydnor








The odd one

FRBs are transient radio pulses caused by astrophysical sources located well beyond our galaxy, the Milky Way. While the origins of these millisecond duration, bright, extragalactic flashes are still not fully understood, researchers are closing in on the mystery with each new discovery. This FRB, FRB 190520, proved to be unique enough to be considered an outlier among all known FRBs. First, it was classified as a repeater. A repeater is an FRB that repeats its pulses randomly. Typically, FRBs are unpredictable, but repeaters are more reliable but are also rare.  With repeating behaviors, researchers can better focus and observe the data with relative precision and map out repeating bursts which assists in future observations.  FRB 190520 is one of the most active repeating FRBs to ever be observed. 

Furthermore, this is only the second localized FRB, out of over 20 localized FRBs, with a persistent radio source associated with it. Localization is when an FRB location is pinpointed to a very small area in space, connecting the FRB to a host galaxy near that location. Observations of host galaxy of FRB 190520 showed that it is much closer than expected. Overall, it was behaving very differently than other FRBs, prompting more questions from the team.  Why was this one different?  What was making it behave differently?  Is the behavior due to the actual FRB itself, or its host galaxy?  Could this host galaxy give astronomers more clues which could fill in more pieces of the cosmology puzzle?

Let’s begin to understand how the discovery unfolded. 

The first FRB was discovered in 2007 by West Virginia University Professor Duncan Lorimer, Professor Maura McLaughlin, and an undergraduate student working with Lorimer, D. Narkevic, while analyzing archival data recorded by the Parkes Observatory. This burst was originally dubbed the Lorimer Burst. This discovery opened the doors for a whole field of study around FRBs.

Fast forward fourteen years, FRB 190520 sparks a host of new questions.

FRB 190520 was discovered by researchers using the FAST (Five-hundred-meter Aperture Spherical radio Telescope) in 2019. In 2020, a team of researchers observed FRB 190520 using the VLA (Karl G. Jansky Very Large Array) observatory and found remarkable characteristics, very unique to this particular FRB.

Kshitij Argawal Kshitij Aggarwal, Center for Gravitational Waves and Cosmology, West Virginia University (WVU)

How do you know the location of an FRB?

Quite like the Doppler effect, astronomers use what is called redshift, or the wavelength of the light that is stretched as sound waves move through space. Much like the sound an ambulance makes; it changes and peaks in pitch as it moves towards you and then drops in pitch as it moves away from you. Light waves move similarly. The light drifts towards the red side of the spectrum for objects that are far away and moving away from us and allows astronomers to measure and calculate the speed of a galaxy relative to Earth.

If you count up all the stars, gas and other luminous things we can see, based on cosmological observations, there should be more missing matter accounted for, but we don't fully have those direct measurements. Sarah Burke spolaor

Combining all that they knew about the FRB, the team used the Realfast observing system at VLA to observe and collect data where they detected a persistent radio source (PRS) colocated with FRB 190520.  Using the position of the FRB with realfast, the team searched for the host galaxy and identified the host galaxy, a dwarf galaxy, at distance of ~0.2.  The team isn’t sure whether the PRS is related to the FRB, or something near the FRB in its environment.  Many theories around both scenarios exist. This is the beginning of a better understanding of repeaters that are also co-localized.

Trip Calculations using Dispersion Measure

Plasma occupying the “empty” space between stars and galaxies actually cause light to slow down, and this effect becomes more extreme at lower radio frequencies. This causes high-radio-frequency signals to arrive first and low-radio-frequency signals to arrive later, causing FRBs to demonstrate a descending “whistle” in the data. The duration of that descending tone can be used to calculate the amount of gas and matter it has passed through, giving them an idea of how far it originated from.The Dispersion Measure (DM) gives us a lot of information about our universe because it tells us about the electron distribution out in space. As the pulses from an FRB far away move through matter, like gas and plasma within the universe, the sounds of the pulses are bouncing off of electrons within the intergalactic medium (outside our own galaxy) causing changes in the pulse.  Astronomers can calculate the dispersion within the Milky Way, our own Galaxy.  Beyond the Milky Way, dispersion in the intergalactic medium is unknown, so researchers need to fill in the blanks with calculated estimates.  There may be lots of matter hiding within the intergalactic medium; another puzzle for another day.

DM of FRB 190520

When calculating its dispersion measure, the team discovered it was very large.  The dispersion measure (DM) is used to estimate how far the FRB could be, and based on the DM alone, it should have been very far away, but combined with the redshift, it wasn’t at all far away; just the opposite. It was very close.  Based on existing observations using the redshift/DM relationship, characteristics of this FRB proved to be vastly unique, even an outlier. This breakthrough calculation now challenges the DM-redshift relations that are routinely used in FRB analysis to determine the distances to FRBs.

The Outlier

FRB 190520 again had to prove its uniqueness.  Its DM was very large, which is typically used to estimate how far the FRB could be located.  Based on the DM alone, it should've been very far, but the redshift proved otherwise. It was actually very close to Earth.

If all FRBs behave the same way, then we can use them to serve as an average point. But if we have deviant FRBs, like FRB 190520, the averages aren’t as evenly presented.  In other words, it could cause the known average to be wider due to the obvious outliers in the mix.

According to Aggarwal, FRB 190520 could throw initial estimates and assumptions out the window.

FRB 190520 is proving to be a portal of continuous unknowns.  This outlier and its host galaxy has now opened more questions around the cosmic world of FRBs, intriguing researchers with more scientific curiosity.  Researchers have used these FRBs to draw important conclusions around other areas of research pertaining to the universe, like its evolution. “If you count up all the stars, gas, and other luminous things we can see, based on cosmological observations, there should be more missing matter accounted for, but we don’t fully have those direct measurements,” Burke Spolaor explains.  FRBs can probe the space between galaxies, helping to fill in those unknown details about the intergalactic medium including the hidden matter. 

Something is going on with FRB 190520, and we want to know more!  The host galaxy, or the environment around this FRB has something unique going on, which could contribute to such a high dispersion. Localization is the key to better understanding outliers like FRB 190520, by pinpointing the FRB to its parent galaxy and estimating its exact distance.

With every discovery, the puzzle becomes more complex, offering more answers to questions pertaining to the evolution of the universe and beyond.

While currently an anomaly, it's quite possible that in five or ten years, it could be considered normal as more details around repeating FRBs, like FRB 190520, are uncovered.


The original Nature article can be found here: https://www.nature.com/articles/s41586-022-04755-5#Abs1

More Press here:

The Conversation: https://theconversation.com/newly-discovered-fast-radio-burst-challenges-what-astronomers-know-about-these-powerful-astronomical-phenomena-184634

CNN: 

https://www.cnn.com/2022/06/08/world/repeating-fast-radio-burst-detection-scn/index.html

Science Alert:

https://www.sciencealert.com/a-new-mystery-signal-is-repeating-from-a-distant-galaxy-and-it-s-a-weird-un

Space.com:

https://www.space.com/second-fast-radio-burst-discovered




hal/06/08/22

 

Media contact: Holly Legleiter

Public Relation Coordinator

Center for Gravitational Waves and Cosmology

West Virginia University

hlegleiter@mail.wvu.edu

304-685-5301