A Solar FRB: Difference between revisions

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|first_author = Dale GARY  
|first_author = Dale GARY  
|second_author = Hugh HUDSON  
|second_author = Hugh HUDSON  
|publish_date = 15 February2021
|publish_date = 15 February 2021
|next_nugget = TBD
|next_nugget = NuSTAR
|previous_nugget = {{#ask: [[Category:Nugget]] [[RHESSI Nugget Index::399]]}}
|previous_nugget = {{#ask: [[Category:Nugget]] [[RHESSI Nugget Index::399]]}}
}}
}}
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([https://en.wikipedia.org/wiki/Fast_radio_burst FRB])  
([https://en.wikipedia.org/wiki/Fast_radio_burst FRB])  
burst upon the astronomical community only 15 years ago: these are
burst upon the astronomical community only 15 years ago: these are
remarkbly bright, remarkably fast transient sources.
remarkably bright, remarkably fast transient sources.
They last for only a few msec!
They last for only a few milliseconds!
Most of them, quite interestingly, have extragalactic origins, as can
Most of them, quite interestingly, have extragalactic origins, as can
be inferred from their frequency dispersion, typically hundreds of  
be inferred from their frequency dispersion, typically measured in hundreds of  
pc/cm<sup>3</sup>.
pc/cm<sup>3</sup>.
Here the unit pc is the parsec.
Here the unit pc is the
Many may be associated with  
[https://en.wikipedia.org/wiki/Parsec parsec], not normally involved in solar measurements.
Many FRBs may be associated with  
[https://sprg.ssl.berkeley.edu/~tohban/wiki/index.php/RHESSI_observes_a_magnetar magnetars],  
[https://sprg.ssl.berkeley.edu/~tohban/wiki/index.php/RHESSI_observes_a_magnetar magnetars],  
which links them to both RHESSI and to solar flares.
which links them to both RHESSI and to solar flares.


Recently a very sensitive FRB detector array detected a FRB-like event,
Recently a very sensitive FRB detector array detected a FRB-like event
but uniquely solar in origin (Ref. [1]).
that was uniquely solar in origin (Ref. [1]).
We'll call it the SFRB, for "solar FRB".
We'll call it the SFRB, for "solar FRB".
This event, observed at 1.6 GHz, lasted for only a few ms and thus
This event, observed at 1.4 GHz, lasted for only a few ms with a flux density
of 9.1 Mega-Janskys (910 solar flux units) and thus
seemed like a true FRB.
seemed like a true FRB.
Here the dispersion measure, still expressed in parsecs, was a  
Here the dispersion measure, still expressed in parsecs, was a  
minimal 5 pc/cm<sup>3</sup>, but consistent with zero (or the whole solar
minimal 5 pc/cm<sup>3</sup>, but consistent with zero (or the whole solar
corona, which has a scale height of about 1 nanoparsec.
corona, which has a scale height of about 1 nanoparsec).
Figure 1 shows the  
Figure 1 shows the  
[https://www.caltech.edu/about/news/magnificent-burst-within-our-galaxy STARE2 array]  
[https://www.caltech.edu/about/news/magnificent-burst-within-our-galaxy STARE2 array]  
detection by two instruments at the
detection by two of its receivers--one at the
[https://en.wikipedia.org/wiki/Owens_Valley_Radio_Observatory Owens Valley Radio Observatory].
[https://en.wikipedia.org/wiki/Owens_Valley_Radio_Observatory Owens Valley Radio Observatory] and one at the [https://en.wikipedia.org/wiki/Goldstone_Deep_Space_Communications_Complex Goldstone Deep Space Communications Complex].


[[File:400f1.png|600px|thumb|center|<b></b>
[[File:400f1.png|600px|thumb|center|<b></b>
The original detection of the FRB candidate ST 190506B, which we would have
The original detection of the FRB candidate ST 190506B, which we solar physicists would call by its solar designation SOL2019-05-06T17:47:35.
to call by a solar name like SOL2019-05-06T17:47:35.
Note its extreme brevity (19 ms) and the excellent SNR, as detected by two receivers.
Note its extreme brevity and excellent SNR, as detected by two instruments.
]]
]]


Line 48: Line 49:
Our [https://sprg.ssl.berkeley.edu/~tohban/wiki/index.php/A_New_Day_Dawns new solar radio observatory],  
Our [https://sprg.ssl.berkeley.edu/~tohban/wiki/index.php/A_New_Day_Dawns new solar radio observatory],  
[http://www.ovsa.njit.edu EOVSA], also at Owens Valley, detected something  
[http://www.ovsa.njit.edu EOVSA], also at Owens Valley, detected something  
remarkable at about the right time: Figure 2 shows the file EOVSA spectrogram,
remarkable at about the right time: Figure 2 shows the EOVSA quick-look spectrogram, with the GOES 1-8 A soft X-ray flux
with a fast broadband  
superimposed.  The C1-class event with a fast broadband radio response occurs just before 18:00 UT,
while others of similar strength show nothing obvious.


[[File:400f2.png|600px|thumb|center|<b></b>
[[File:400f2.png|600px|thumb|center|<b></b>
The EOVSA file graphic for the "solar FRB" event, marked by a red triangle
The EOVSA file graphic for the "solar FRB" event, whose time is marked by a red triangle
at the bottom.
at the bottom.  The yellow overlay is the GOES 1-8 A soft X-ray flux for reference.
]]
]]


RHESSI hard X-ray data were not available when this event happened, but
RHESSI hard X-ray data were not available when this event happened, but
[Fermi/GBM] data were, as shown in Figure 3 here.
Fermi/GBM captured the event, as shown in Figure 3 here.
During the SFRB there was hard X-ray emission with extremely hard spectra
During the time of the SFRB there was hard X-ray emission with extremely hard spectra
(index about -2.8), but no coincident spike.
(index about -2.8), but no coincident spike, so this non-coincidence likely just results from the
The EOVSA data show that the disturbance penetrated to the lower solar
relatively poor time resolution of the GRB data, 4 s rather than the 19 ms needed to resolve the event.
atmosphere, and so this non-coincidence likely just results from the
relatively poor time resolution of the GRB data, 4 s rather than 4 ms.


[[File:400f3.png|600px|thumb|center|<b></b>
[[File:400f3.png|600px|thumb|center|<b></b>
The hard X-ray time series (left) and spectrum (right, at the time of the  
The hard X-ray time series (left) and spectrum (right, at the time of the  
SFRB as marked by the dashed line). The dotted lines show GBM belatedly
SFRB as marked by the dashed line). The dotted lines show where GBM belatedly
increasing its temporal cadence in response to the detection.
increased its temporal cadence in response to the detection.
The spectrum extends to 100 keV, quite remarkable for a feeble
The spectrum extends to 100 keV above the estimated background (dotted line), quite remarkable for a feeble
[https://www.solarmonitor.org GOES] B2-class event
[https://www.solarmonitor.org GOES] C1-class event.
]]
]]


The EOVSA data provide the best possible solar radio observational
The EOVSA full time-resolution data provide a closer look, which we summarize in Figure 4 here.  
material, which we summarize in Figure 4 here.  
EOVSA's high time resolution (20 ms samples) would be enough to detect the event, except
EOVSA's high time resolution (20 ms samples) still do not resolve
that coverage of EOVSA's broad 1-18 GHz range is achieved by time-sharing, rather than  
the time scale of the STARE2 event (Figure 1), and are achieved by
continuous sampling. At the time of the STARE2 event (17:47:35.385, Figure 1), EOVSA was
time-sharing, rather than continuous sampling.
0.385 s into its sweep and was sampling another frequency band (8.25-8.55 GHz), at much higher  
In this case EOVSA scans were at either 8.25-8.55 GHz or 10.2-10.5 GHz,
frequencies than the 1.4 GHz of the STARE2 detection.
in any case at much higher frequencies than the 1.6 GHz of the STARE2
detection.


[[File:400f4.png|600px|thumb|center|<b></b>
[[File:400f4.png|600px|thumb|center|<b></b>
Upper, EOVSA time series at fixed frequencies; lower, the spectrogram
Upper, EOVSA 1-s time series at two fixed frequencies, topping out at less than 10 sfu.  The 910 sfu SFRB was not seen because of
its short lifetime and the fact that EOVSA was on another frequency at the time. Lower, the spectrogram
with an arrow pointing to the time of the SFRB.
with an arrow pointing to the time of the SFRB.
]]
]]


The morphology of the spectrogram in Figure 4 resembles that of type III  
Most of the emission in the spectrogram in Figure 4 is incoherent broadband emission
bursts, normally observed in the corona at much lower frequencies.
from high-energy electrons, but there are signs throughout the spectrum of spiky coherent
Here we are seeing source densities, on the plasma-frequency hypothesis,
emission, possibly type III bursts, normally observed in the corona at much lower frequencies.
Here we are seeing source electron densities, on the plasma-frequency hypothesis,
of 10<sup>10</sup> cm<sup>-3</sup>, which is typical of the chromosphere.
of 10<sup>10</sup> cm<sup>-3</sup>, which is typical of the chromosphere.
Such a high density at the base of an open-field flux tube could only
Such a high density at the base of an open-field flux tube could only

Latest revision as of 20:57, 10 March 2021


Nugget
Number: 400
1st Author: Dale GARY
2nd Author: Hugh HUDSON
Published: 15 February 2021
Next Nugget: NuSTAR
Previous Nugget: Richard Schwartz



Introduction

The idea of a "Fast Radio Burst" (FRB) burst upon the astronomical community only 15 years ago: these are remarkably bright, remarkably fast transient sources. They last for only a few milliseconds! Most of them, quite interestingly, have extragalactic origins, as can be inferred from their frequency dispersion, typically measured in hundreds of pc/cm3. Here the unit pc is the parsec, not normally involved in solar measurements. Many FRBs may be associated with magnetars, which links them to both RHESSI and to solar flares.

Recently a very sensitive FRB detector array detected a FRB-like event that was uniquely solar in origin (Ref. [1]). We'll call it the SFRB, for "solar FRB". This event, observed at 1.4 GHz, lasted for only a few ms with a flux density of 9.1 Mega-Janskys (910 solar flux units) and thus seemed like a true FRB. Here the dispersion measure, still expressed in parsecs, was a minimal 5 pc/cm3, but consistent with zero (or the whole solar corona, which has a scale height of about 1 nanoparsec). Figure 1 shows the STARE2 array detection by two of its receivers--one at the Owens Valley Radio Observatory and one at the Goldstone Deep Space Communications Complex.

The original detection of the FRB candidate ST 190506B, which we solar physicists would call by its solar designation SOL2019-05-06T17:47:35. Note its extreme brevity (19 ms) and the excellent SNR, as detected by two receivers.

The solar event

Our new solar radio observatory, EOVSA, also at Owens Valley, detected something remarkable at about the right time: Figure 2 shows the EOVSA quick-look spectrogram, with the GOES 1-8 A soft X-ray flux superimposed. The C1-class event with a fast broadband radio response occurs just before 18:00 UT, while others of similar strength show nothing obvious.

The EOVSA file graphic for the "solar FRB" event, whose time is marked by a red triangle at the bottom. The yellow overlay is the GOES 1-8 A soft X-ray flux for reference.

RHESSI hard X-ray data were not available when this event happened, but Fermi/GBM captured the event, as shown in Figure 3 here. During the time of the SFRB there was hard X-ray emission with extremely hard spectra (index about -2.8), but no coincident spike, so this non-coincidence likely just results from the relatively poor time resolution of the GRB data, 4 s rather than the 19 ms needed to resolve the event.

The hard X-ray time series (left) and spectrum (right, at the time of the SFRB as marked by the dashed line). The dotted lines show where GBM belatedly increased its temporal cadence in response to the detection. The spectrum extends to 100 keV above the estimated background (dotted line), quite remarkable for a feeble GOES C1-class event.

The EOVSA full time-resolution data provide a closer look, which we summarize in Figure 4 here. EOVSA's high time resolution (20 ms samples) would be enough to detect the event, except that coverage of EOVSA's broad 1-18 GHz range is achieved by time-sharing, rather than continuous sampling. At the time of the STARE2 event (17:47:35.385, Figure 1), EOVSA was 0.385 s into its sweep and was sampling another frequency band (8.25-8.55 GHz), at much higher frequencies than the 1.4 GHz of the STARE2 detection.

Upper, EOVSA 1-s time series at two fixed frequencies, topping out at less than 10 sfu. The 910 sfu SFRB was not seen because of its short lifetime and the fact that EOVSA was on another frequency at the time. Lower, the spectrogram with an arrow pointing to the time of the SFRB.

Most of the emission in the spectrogram in Figure 4 is incoherent broadband emission from high-energy electrons, but there are signs throughout the spectrum of spiky coherent emission, possibly type III bursts, normally observed in the corona at much lower frequencies. Here we are seeing source electron densities, on the plasma-frequency hypothesis, of 1010 cm-3, which is typical of the chromosphere. Such a high density at the base of an open-field flux tube could only be found in a transient, according to conventional wisdom.

What are the implications here?

Once again, we are indebted to non-solar astronomers for pointing out a potentially large unexplored parameter space. The presence of very short time scales also implies very small spatial scales, and current-day numerical simulations of solar atmospheric structure do not address these scales. They are important because they come closer to the microphysics involved in solar plasma dynamics, and this chance observation should really encourage observers to tackle this parameter range.


References

[1] "STARE2: Detecting Fast Radio Bursts in the Milky Way"

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