Matthias Tecza

Testing the limit of AO for ELTs: Diffraction limited astronomy in the red optical

AO for ELT 2011 - 2nd International Conference on Adaptive Optics for Extremely Large Telescopes (2011)

Authors:

M Tecza, J Magorrian, N Thatte, F Clarke

Abstract:

Many of the proposed science cases for extremely large telescopes (ELT) are only possible because of the unprecedented sensitivity and spatial resolution due to advanced, e.g. tomographic and multi conjugate, adaptive optic (AO) systems. Current AO systems on 8-10 m telescopes work best at wavelengths longward of 1 μm with Strehl ratios ≥ 15%. At red-optical wavelengths, e.g. in the I band (0.8 μm), the Strehl ratio is at best a few percent. The AO point spread function (PSF) typically has a diffraction-limited core superimposed on the seeing halo, however, for a 5% Strehl ratio the core has a very low intensity above the seeing halo. At an ELT, due to a 3-4 times higher angular resolution, the diffraction limited PSF core of only 5% Strehl ratio stands more prominently atop the shallow seeing halo leading to almost diffraction limited image quality even at low Strehl ratios. Prominent ELT science cases that use the Calcium triplet can exploit this gain in spatial resolution in the red-optical: stellar populations in dense environments or crowded fields; and the case of intermediate mass black holes in nuclear and globular stellar clusters, as well as (super-) massive black holes in galaxies.

SWIFT observations of the Arp 147 ring galaxy system

Monthly Notices of the Royal Astronomical Society (2011)

Authors:

L Fogarty, N Thatte, M Tecza, F Clarke, T Goodsall, R Houghton, G Salter, RL Davies, SA Kassin

An image slicer-based integral-field spectrograph for EPICS

Proceedings of SPIE - The International Society for Optical Engineering 7735:PART 1 (2010)

Authors:

M Tecza, N Thatte, G Salter, F Clarke

Abstract:

We present the results of a design study for an integral field spectrograph as the "back-end" instrument for spectroscopy of exoplanets carried out in the context of the EPICS Phase A study. EPICS is the planet finder imager and spectrograph for the E-ELT. In our study we investigated the feasibility of an image slicer based integral field spectrograph and developed an optical design for the image slicer and the necessary pre-optics, as well as the spectrograph optics. We present a detailed analysis of the optical performance of the design. © 2010 Copyright SPIE - The International Society for Optical Engineering.

Coronagraphic capability for HARMONI at the E-ELT

Proceedings of SPIE - The International Society for Optical Engineering 7735:PART 1 (2010)

Authors:

S Gladysz, NA Thatte, F Clarke, M Tecza, GS Salter

Abstract:

HARMONI is a proposed visible and near-infrared integral field spectrograph for the European Extremely Large Telescope. We are exploring the merits of adding a coronagraphic capability to HARMONI, specifically targeted at enabling observations of faint, nearby companions (primarily extra-solar planets) that require high contrast. Although HARMONI is not fed by extreme adaptive optics, we show that substantial contrasts can be achieved by post-processing of the hyperspectral data cube using spectral deconvolution. We make predictions of achievable contrast as a function of coronagraph design, based on realistic models of the telescope's aberrations. © 2010 Copyright SPIE - The International Society for Optical Engineering.

EPICS: Direct imaging of exoplanets with the E-ELT

Proceedings of SPIE - The International Society for Optical Engineering 7735:PART 1 (2010)

Authors:

M Kasper, JL Beuzit, C Verinaud, RG Gratton, F Kerber, N Yaitskova, A Boccaletti, N Thatte, HM Schmid, C Keller, P Baudoz, L Abe, E Aller-Carpentier, J Antichi, M Bonavita, K Dohlen, E Fedrigo, H Hanenburg, N Hubin, R Jager, V Korkiakoski, P Martinez, D Mesa, O Preis, P Rabou, R Roelfsema, G Salter, M Tecza, L Venema

Abstract:

Presently, dedicated instruments at large telescopes (SPHERE for the VLT, GPI for Gemini) are about to discover and explore self-luminous giant planets by direct imaging and spectroscopy. The next generation of 30m-40m ground-based telescopes, the Extremely Large Telescopes (ELTs), have the potential to dramatically enlarge the discovery space towards older giant planets seen in reflected light and ultimately even a small number of rocky planets. EPICS is a proposed instrument for the European ELT, dedicated to the detection and characterization of Exoplanets by direct imaging, spectroscopy and polarimetry. ESO completed a phase-A study for EPICS with a large European consortium which - by simulations and demonstration experiments - investigated state-of-the-art diffraction and speckle suppression techniques to deliver highest contrasts. The paper presents the instrument concept and analysis as well as its main innovations and science capabilities. EPICS is capable of discovering hundreds of giant planets, and dozens of lower mass planets down to the rocky planets domain. © 2010 Copyright SPIE - The International Society for Optical Engineering.