High Energy meets Low Energy an introduction to radio interferometry

1. High Energy meets Low Energyan introduction to radio interferometry Ignasi Reichardt IFAE Thursday meeting, March 19th 2009

2. Radioastronomy “Exploring the sky at wavelengths from 10m to 0.4mm (30MHz – 800GHz)”

3. Radiative processes and sources Pulsars Synchrotron Spectral lines Free-Free Thermal

4. Detection Principle

5. Detection Principle Johnson noise Antenna Temperature Noise voltage

6. Detection Principle OFF ON S = g(TAON– TAOFF)

7. Detection Principle Local Oscillator: VL ~ cos(2πνLt + φL) VI ~ cos(2π(νS-νL )t + φL + φS) Noise voltage: VS ~ cos(2πνRt + φR) <Vi2> = <(VS+VL)2> = <VS2> + < VL2>

8. Nice pictures? Cas-A (SNR) Cyg-A (AGN)

9. Interferometry <V1·V2> = <VS2>eiφ ~ Seiφ <V1·V2> = <VS2> ~ S V1 = VA + VS V2 = VB + VS

10. Interferometry S S Interferometer output: S·exp[2πiLsinθ(νS-νL)/c] Extra phase: 2πsinθL/λ Interferometer output: S·exp(2πisinθL/λ) θ L

11. Interferometry S2 S2 Uncompensated path for S2 : Δφ = 2π(L/λ)cosθΔθ S1 S1 g: Angular Resolution! Δθ θ L

12. DEC y θ = (x2 + y2)1/2 x RA Interferometry Two sources: STOT = S1 + S2e2πigΔθ Many sources: STOT = S1 + S2e2πigΔθ2+ ... + SNe2πigΔθN Extended source: STOT = ∫b(θ)e2πigθ dθ 2D sky: STOT = ∫b(x, y)e2πi(ux +vy)dxdy

13. v g(t) u v g = (u2 + v2)1/2 u Filling the (u, v) plane

14. Filling the (u, v) plane

15. Very Long Baseline Interferometry

16. Extremely Long Baselines?

17. Provided by Daniel Mazin PRELIMINARY! VLA – 90cm M87: γ-rays meet radio waves