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Optics in Astronomy - Interferometry -

Optics in Astronomy - Interferometry -. Oskar von der Lühe Kiepenheuer-Institut für Sonnenphysik Freiburg, Germany. Contents. Fundamentals of interferometry Concepts of interferometry Practical interferometry. Fundamentals of interferometry Why interferometry? Diffraction-limited imaging

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Optics in Astronomy - Interferometry -

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  1. Optics in Astronomy- Interferometry - Oskar von der Lühe Kiepenheuer-Institut für Sonnenphysik Freiburg, Germany

  2. Contents • Fundamentals of interferometry • Concepts of interferometry • Practical interferometry • Fundamentals of interferometry • Why interferometry? • Diffraction-limited imaging • A Young‘s interference experiment • Propagation of light and coherence • Theorem of van Cittert - Zernike Optics in Astronomy

  3. What is interferometry? • superposition of electromagnetic waves • at (radio and) optical wavelengths • infrared:  = 20 µm ... 1µm • visible:  = 1 µm ... 0.38 µm • which emerge from a single source • and transverse different paths • to measure their spatio-temporal coherence properties • Why interferometry? • to increase the angular resolution in order to • compensate for atmospheric and instrumental aberrations • speckle interferometry • diluted pupil masks • overcome the diffraction limit of a single telescope by coherent combination of several separated telescopes • Topic of this lecture on interferometry? • to increase the angular resolution in order to • compensate for atmospheric and instrumental aberrations • speckle interferometry • diluted pupil masks • overcome the diffraction limit of a single telescope by coherent combination of several separated telescopes Optics in Astronomy

  4. Diffraction limited imaging D focal length F telescope aperture Optics in Astronomy

  5. diameter D baseline B focal length F A Young‘s interference experiment wavelength  Optics in Astronomy

  6. Two-way interferometer I Change of baseline Optics in Astronomy

  7. Two-way interferometer II Change of element diameter Optics in Astronomy

  8. Two-way interferometer IIa Change of element diameter Optics in Astronomy

  9. Two-way interferometer III Change of wavelength Optics in Astronomy

  10. Dependence on source position Optics in Astronomy

  11. Two-way interferometer IV Change of source position Optics in Astronomy

  12. delay  Dependence on internal delay Optics in Astronomy

  13. Two-way interferometer V Change of internal delay Optics in Astronomy

  14. C Monochromatic e. m. waves Time-dependent, monochromatic e.m. field: Time-independent e.m. field fulfils Helmholz equation: Optics in Astronomy

  15. r Propagation of field Kirchhoff-Fresnel integral, based on Huyghens‘ principle Optics in Astronomy

  16. Non-monochromatic waves Spectral decomposition: Propagation of a general e.m. wave: Condition of quasi-monochromatism: Propagation of a quasi-monochromatic wave: Optics in Astronomy

  17. Intensity at point of superposition The intensity distribution at the observing screen of the Young‘s interferometer is given by the sum of the intensities originating from the individual apertures plus the expected value of the cross product (correlation) of the fields. Optics in Astronomy

  18. Concepts of coherence I (terminology from J. W. Goodman, Statistical Optics) mutual intensity: temporally stationary conditions, with  = t2 - t1 complex degree of coherence: Optics in Astronomy

  19. Concepts of coherence II self coherence (temporal coherence): complex degree of self coherence: mutual intensity (spatial coherence): complex coherence factor: Optics in Astronomy

  20. Concepts of coherence III • Coherence is a property of the e.m. field vector! • It is important to consider the state of polarisation of the light as orthogonal states of polarisation do not interfere (laws of Fresnel-Arago). • Optical designs of interferometers which change the state of polarisaiton differently in different arms produce instrumental losses of coherence and therefore instrumental errors which need calibration. Optics in Astronomy

  21. S1 2R 2Z 1 2 S2 1 Temporal coherence coherence time: refined monochromatic condition: Optics in Astronomy

  22. Two-way interferometer VI Extended spectral distribution of a point source Optics in Astronomy

  23. Two-way interferometer VII Extended spectral distribution source and delay errors Optics in Astronomy

  24. Transport of coherence Optics in Astronomy

  25. Extended sources Optics in Astronomy

  26. Extended, incoherent sources Most astronomical sources of light have thermal origin. The processes emitting radiation are uncorrelated (incoherent) at the atomic level. Mutual intensity at the surface of an incoherent source: Transport of mutual intensity to the interferometer: Optics in Astronomy

  27. Celestial sources have large distances S compared to their dimensions. Differences in S can be expanded in first order to simplify the propagation equation. Inclination terms  are set to unity. Linear distances in the source surface are replaced by apparent angles . The transport equation can then be simplified: Theorem of van Cittert - Zernike Optics in Astronomy

  28. Intensity distribution in the Young‘s intererometer The complex coherence factor µ is often called the complex visibility. It fulfils the condition Optics in Astronomy

  29. Two-way interferometer VII Spatially extended source - double star Optics in Astronomy

  30. Two-way interferometer VII Spatially extended source - limb darkened stellar disk Optics in Astronomy

  31. Extended sources - not unique? Optics in Astronomy

  32. Source intensity Response to a point source in direction of  Observed Intensity Instrumental cosine term 2D Fourier transform of source intensity at angular frequency B/(visibility function) van Cittert - Zernike theorem Optics in Astronomy

  33. What does the vCZT mean? An interferometer projects a fringe onto the source‘s intensity distribution The magnitude of the fringe amplitude is given by the structural content of the source at scales of the fringe spacing The phase of the fringe is given by the position of the fringe which maximises the small scale signal Optics in Astronomy

  34. What have we learned? • An astronomical interferometer measures spatio-temporal coherene properties of the light emerging from a celestial source. • The spatial coherence properties encodes the small scale structural content of the intensity distribution in celestial coordinates. • The temporal coherence properties encodes the spectral content of the intensity distribution. • The measured interferometer signal depends on structural and spectral content. Optics in Astronomy

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