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Interstellar Holography at Low Frequencies

Interstellar Holography at Low Frequencies. Dan Stinebring, Willem van Straten, Leon Koopmans. Mark Walker (Manly Astrophysics). Overview. Background Technique Results and current directions Issues at low frequency Applications Interstellar medium Pulsar timing. Background.

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Interstellar Holography at Low Frequencies

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  1. Interstellar Holographyat Low Frequencies Dan Stinebring, Willem van Straten, Leon Koopmans • Mark Walker • (Manly Astrophysics)

  2. Overview • Background • Technique • Results and current directions • Issues at low frequency • Applications • Interstellar medium • Pulsar timing

  3. Background • Patterns in dynamic spectra • DRS: Lots of high quality data • emphasis on Fourier Plane • Discovery of Parabolic Arcs • Spectrum is FT{U} A FT{U*} • Sparse power in Fourier Domain • Model FT{U} by “CLEANing” • Holographic Image of ISM

  4. Iterative modelling Delay Doppler Shift *

  5. Noise-limited performance

  6. Current Directions • Mitigate propagation-induced timing delays • B1937+21 test case (430 MHz baseband data) - UCB • Virtual phase conjugation • PD: dynamic cyclic spectra supercede dynamic spectra • Migrating to physical representations • Parametric descriptions of DM(x) and B(x) • Predict fields at any frequency / epoch / location • Determine all geometric / kinematic parameters ? • Continuum frequencies - slow transforms • Stationary Phase Points { DMk , DMk’ , DMk’’ }

  7. Low frequency issues • Small scintillation bandwidths & timescales • Sampling limits are delay: Tobs / 2, Doppler: 2 / P • Low signal / noise per scintle • Use a compact representation of the wave field • Degeneracies in complicated environments • Extended media ? Complex velocity fields ? • Systematics in phased arrays ?

  8. Imaging the ionised ISM • Lots of potential in regular monitoring of many L.O.S. • B0834+06 holographic imaging tells us: • Linear image (aspect ratio > 50) tens of AU long • Strong magnetic field most likely cause • Propagation anomalies show us high-stress regions - this and size scale common to ESEs, IDVs and Arcs - probable physical association • Such regions are common

  9. Physical context of anomalies Self-Gravitating “Bullets” of Neutral Gas Shock Heating of ISM to T ~ 1 MK Dark Matter Filamentary Magnetotail Field Stretched to B ~ 10-4 G

  10. Timing • Understanding propagation delays will be critical • Characterise ISM at “low” frequencies, because • Get most detailed picture of ISM structure • Get widest field image of ISM • Minimise the chance of missing features • Stitch together images of ISM with large overlap • Wide-angle multi-beaming - regular monitoring • Best spatial resolution at edge of FOV • Time at high or low frequencies ??

  11. Imaging through the ISM • Know Phi(x) - determine source visibility vs. baseline • Just like terrestrial interferometric imaging • Highest resolution at lowest frequency • Resolution limit ~ FMHz km or better • Pulse-phase resolved images in any polarisation state • Image emission regions - new insights • Differential astrometry at ~ 100 pico-arcsecond level • Image reflex motions of PSRs with companions • Refraction & broadening in winds • Refraction in gravitational potential

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