HARMONI: A single-field wide-band integral-field spectrograph for the European ELT

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

Authors:

N Thatte, M Tecza, F Clarke, RL Davies, A Remillieux, R Bacon, D Lunney, S Arribas, E Mediavilla, F Gago, N Bezawada, P Ferruit, A Fragoso, D Freeman, J Fuentes, T Fusco, A Gallie, A Garcia, T Goodsall, F Gracia, A Jarno, J Kosmalski, J Lynn, S McLay, D Montgomery, A Pecontal, H Schnetler, H Smith, D Sosa, G Battaglia, N Bowles, L Colina, E Emsellem, A Garcia-Perez, S Gladysz, I Hook, P Irwin, M Jarvis, R Kennicutt, A Levan, A Longmore, J Magorrian, M McCaughrean, L Origlia, R Rebolo, D Rigopoulou, S Ryan, M Swinbank, N Tanvir, E Tolstoy, A Verma

Abstract:

We describe the results of a Phase A study for a single field, wide band, near-infrared integral field spectrograph for the European Extremely Large Telescope (E-ELT). HARMONI, the High Angular Resolution Monolithic Optical & Nearinfrared Integral field spectrograph, provides the E-ELT's core spectroscopic requirement. It is a work-horse instrument, with four different spatial scales, ranging from seeing to diffraction-limited, and spectral resolving powers of 4000, 10000 & 20000 covering the 0.47 to 2.45 μm wavelength range. It is optimally suited to carry out a wide range of observing programs, focusing on detailed, spatially resolved studies of extended objects to unravel their morphology, kinematics and chemical composition, whilst also enabling ultra-sensitive observations of point sources. We present a synopsis of the key science cases motivating the instrument, the top level specifications, a description of the opto-mechanical concept, operation and calibration plan, and image quality and throughput budgets. Issues of expected performance, complementarity and synergies, as well as simulated observations are presented elsewhere in these proceedings[1]. © 2010 Copyright SPIE - The International Society for Optical Engineering.

High-contrast observations with slicer-based integral field spectrographs 1: Simulations

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

Authors:

GS Salter, NA Thatte, M Tecza, F Clarke, C Verinaud, ME Kasper

Abstract:

As part of the Phase A study for the EPICS instrument, we investigate if there are any contrast limitations imposed by the choice of the integral field spectrograph (IFS) technology, and if so, to determine the contrast limits applicable to each technology. In this document we investigate (through simulations) the contrast limitations inherent in a slicer based IFS. Current results show the achievable contrast with the slicer to be promising when taking into consideration the fact that the central region of the apodized PSF has not been masked. Limiting the maximum intensity by a factor of 100-1000 using an obscuring focal plane mask should also reduce the intensity of the secondary speckles by an equivalent factor. Furthermore, the secondary speckles created in the slicer spectrograph only influence the few slices where the bright central core is imaged. By orienting these slices to lie along the spider arms of the E-ELT secondary, the fraction of the field of view affected can be minimized. © 2010 Copyright SPIE - The International Society for Optical Engineering.

The Oxford SWIFT spectrograph: First commissioning and on-sky results

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

Authors:

N Thatte, M Tecza, F Clarke, T Goodsall, L Fogarty, R Houghton, G Salter, N Scott, RL Davies, A Bouchez, R Dekany

Abstract:

The Oxford SWIFT spectrograph, an I & z band (6500-10500 A) integral field spectrograph, is designed to operate as a facility instrument at the 200 inch Hale Telescope on Palomar Mountain, in conjunction with the Palomar laser guide star adaptive optics system PALAO (and its upgrade to PALM3000). SWIFT provides spectra at R(≡λ/Δλ)∼4000 of a contiguous two-dimensional field, 44 x 89 spatial pixels (spaxels) in size, at spatial scales of 0.235″;, 0.16″, and 0.08″ per spaxel. It employs two 250μm thick, fully depleted, extremely red sensitive 4k X 2k CCD detector arrays (manufactured by LBNL) that provide excellent quantum efficiency out to 1000 nm. We describe the commissioning observations and present the measured values of a number of instrument parameters. We also present some first science results that give a taste of the range of science programs where SWIFT can have a substantial impact. © 2010 Copyright SPIE - The International Society for Optical Engineering.

Diviner lunar radiometer observations of cold traps in the moon's south polar region

Science 330:6003 (2010) 479-482

Authors:

DA Paige, MA Siegler, JA Zhang, PO Hayne, EJ Foote, KA Bennett, AR Vasavada, BT Greenhagen, JT Schofield, DJ McCleese, MC Foote, E DeJong, BG Bills, W Hartford, BC Murray, CC Allen, K Snook, LA Soderblom, S Calcutt, FW Taylor, NE Bowles, JL Bandfield, R Elphic, R Ghent, TD Glotch, MB Wyatt, PG Lucey

Abstract:

Diviner Lunar Radiometer Experiment surface-temperature maps reveal the existence of widespread surface and near-surface cryogenic regions that extend beyond the boundaries of persistent shadow. The Lunar Crater Observation and Sensing Satellite (LCROSS) struck one of the coldest of these regions, where subsurface temperatures are estimated to be 38 kelvin. Large areas of the lunar polar regions are currently cold enough to cold-trap water ice as well as a range of both more volatile and less volatile species. The diverse mixture of water and high-volatility compounds detected in the LCROSS ejecta plume is strong evidence for the impact delivery and cold-trapping of volatiles derived from primitive outer solar system bodies.

Adaptive optics systems for HARMONI: A visible and near-infrared integral field spectrograph for the E-ELT

Proceedings of SPIE - The International Society for Optical Engineering 7736:PART 1 (2010)

Authors:

T Fusco, N Thatte, S Meimon, M Tecza, F Clarke, M Swinbank

Abstract:

HARMONI is a visible and near-infrared integral field spectrograph for the E-ELT. It needs to work at diffraction limited scales. This will be possible thanks to two adaptive optics systems, complementary to each other. Both systems will make use of the telescope's adaptive M4 and M5 mirrors. The first one is a simple but efficient Single Conjugate AO system (good performance, low sky coverage), fully integrated in HARMONI itself. The second one is a Laser Tomographic AO system (medium performance, very good sky coverage). We present the overall design of the SCAO system and discuss the complementary between SCAO and LTAO for HARMONI. © 2010 SPIE.