Stephen White Space Vehicles Directorate Air Force Research Laboratory Solar Radio Bursts with LWA-1: DRX Observations.

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Presentation transcript:

Stephen White Space Vehicles Directorate Air Force Research Laboratory Solar Radio Bursts with LWA-1: DRX Observations

LW001: DRX data X5 flare at 01 UT on 2012 March 7

Post-flare loops: site of energy release(?) Locus of radio Type IV burst?

Bright radio emission

LW001 DRX setup: Beam 1 on Sun: filter 5, & MHz Beam 2 on Sun: filter 7, & MHz Beam 3 off Sun: filter 7, & MHz Beam 4 on Sun: filter 7, & MHz 3  2.2 TB TB (need 3 TB drives) Still learning …. but access time with LSL is fine

245 MHz light curve into LWA morning

Magnetic field distribution

Summary plot: MHz

Summary plot: MHz

Summary plot: MHz 45° above Sun

Summary plot: MHz on Sun

Summary plot: MHz off Sun

Summary plot: MHz on Sun

Summary plot: MHz

Summary plot: MHz

RFI at 15 UT off Sun

RFI at low elevation (solar beam)

RFI at 20 UT off Sun

RFI on Sun at local noon

Typical noise storm feature: Type I bursts

Low frequency emission: MHz

Unexpected fine structure above 60 MHz

“Zebra” patterns more common in flares

Issues at high frequencies: pointing?

Wrigglers and zebra alternating

“Wrigglers” at 10 millisecond resolution

Wrigglers, Type I, broadband modulation

Polarization properties: off Sun

Polarization properties: on Sun

Circular polarization spectrum

Science with LWA-1 TBN data TBN data provide basically rapid sampling of the waveform at a fixed frequency Big push by the Sydney group (Cairns, Robinson, Li) to interpret low-frequency plasma emission with “stochastic growth theory” (SGT): electron beams are not uniformly saturated but are dominated by density fluctuations in the medium, results in marginally unstable beams with very bursty emission. SGT predicts a log-normal distribution of intensities when averaged, power-law at high time resolution Complicated for coronal work by large sources and multi-path propagation

Science with LWA-1 TBW data TBW data provide snapshot spectra (60 msec) every minute: basically “luck” as to which portion of a burst you get What they do is confirm spectral structure that isn’t always “believable” in dynamic spectra Existing data already indicate interesting structure: need to interpret in terms of coronal inhomogeneity and electron beam properties.

The