CRIRES - VLT High-Resolution IR Echelle Spectrometer

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CRIRES High-Resolution IR Echelle Spectrometer
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Table of Content

Instrument Status
Science Verification
Science Objectives
Instrument Concept

Instrument Name	CRIRES
ESO Responsible	H.U. Käufl
Instrument Scientist	R. Siebenmorgen
Location	Nasmyth UT1 (ANTU)
Status	Commissioning
Science Team	B. Gustafsson, C. de Bergh, A. Hatzes, K. Hinkle, E. van Dishoeck

Instrument Status

CRIRES first commissioning was successfully performed in June 2006.

First light images and spectra and more information is available : HERE

A second and third commissioning is scheduled in August and October 2006.

Our goal is to be able to release the instrument for the next call for proposals.

Science Verification

The science verification (SV) for CRIRES is carried out following the: VLT Science Verification Policy and Procedures .

SV runs are interleaved with commissioning and test activities, taking place between August 2006 and April 2007.

SV observer shall submit their proposals using the Science Verification proposal template Proposers are asked to provide at least a short summary of the science goal, coordinates and magnitudes of GS and science target, a finding chart, the observing wavelength ID, as specified in appendix A of the UM and DIT, NDIT settings of science detectors as computed with the exposure time calculator (see below).

Useful Links and manuals

CRIRES exposure time calculator
CRIRES User Manual (draft July 2006)

Science Objectives

A cryogenic high-resolution IR spectrograph has been conceived for the VLT in order to exploit the enormously enhanced sensitivity provided by a dispersive instrument with a large detector array at an 8 m telescope. The gain entails a quantitative and qualitative improvement of the observational capabilities. It can boost all scientific applications aiming at fainter objects, higher spatial (extended sources), spectral and temporal resolution.

The IR spectrograph will make previously inaccessible phenomena and objects available for spectroscopic studies. Table 1 presents a list of science objectives.

Table 1: Science Objectives

Extra-Solar Planets
Radial velocities studies
Direct spectroscopic detection and characterization: CO, CH4.

Solar System
Chemistry/phys. conditions/velocity fields/structure
Giant planets/Titan	H3+, CH4, NH3, CH3D, AsH3, H2O,C2H2,C2H6, PH3, CH3, NH3, HCN, C2H2, C2H6, PH3, CH3, NH3, HCN
Terrestrial planets	CO, HCL, HF, HDO, H2O, OCS Mars imaging (0.1"- 40 Km) spectr. of CO depletion.
Io	spatial/time mapping of volcanic activity (SO2)
Pluto/Charon/Triton	search tenous CO, CH4 atmos.
Comets	(resolve nuclei), H2O abundance, temperature, velocities, minor species.

Stars
Stellar evolution/nucleosynthesis (OB, AGB stars, cluster red giants, cool MS, C & S stars in galaxy, S/LMC, nearby glaxies), CNO isotopic abundances unique in IR.
Stellar mass:atom/mol. lines from secondaries
Stellar winds/mass loss, OB, WR, AGB stars in galaxy and S/LMC, CO,SiO,C2H2, HCN
Atmospheric structure & oscillations in cool stars
Magnetic fields

Star Formation Regions/ISM
Accretion/Outflow from embedded YSOs
ISM chemistry/ cloud structure, H3+, H2O, CH4, C2H2, NH3

Extragalactic
AGN	Velocity structure of BLR, NLR, CLR & molecular clouds, H recombination, [FeII], [SiIV], H2 lines suffering low dust extinction

Instrument Concept and Capabilities

The cryogenic echelle will provide for:

high-resolution spectroscopy in the 1-5 µm range
at the VLT. This instrument employs the largest available grating for a
spectral resolving power of >= 100,000
with a 0.2 arcsec slit. Simultaneous spectral coverage is maximized through one or several large (1024 x 1024 pixel) detector arrays in the focal plane. The second array dimension is exploited for
1-dimensional spectral imaging
along the ~ 50 arcsec slit
Adaptive Optics
to maximise SNR and spatial resolution.

Functionally, the instrument can be divided into four units. The fore-optics section provides for field de-rotation, cold pupil and field stops, curvature sensing adaptive optics, and slit viewing. The prism predisperser isolates one echelle order and minimizes the total amount of light entering into the high-resolution section. The high-resolution section comprises the collimator, the echelle which is tilt-tuned for wavelength selection, the camera providing the 0.1 arcsec/pixel plate scale, and the detector(s). The calibration unit outside the cryogenic environment contains light sources for flux/wavelength calibration and detector flatfielding.

Observational capabilities and predicted performance are given in Tables 2 and 3.

Table 2: Cryogenic Echelle Main Characteristics

Parameter	Value
Focus	Nasmyth
Configuration	stationary
Wavelenght range	1-5 µm
Slit width-res. power product	20,000-40,000 (Rmax = 100.000)
Echelle	40 cm length, 31.6 lines/mm
Optics	reflective
Detector	3 x 1024 x 1024 InSb arrays
Pixel size	0.1 arcsec
Spectral format	single order
Slit length	~ 50"
Operating temperature	60-80 °K
Detector temperature	~30 °K
background subtraction	nodding
Istantaneous wavelength coverage	lambda/70

Table 3: Performance Limits

Limiting magnitudes ( for S/N = 3 in 1 hr)
Wavelength (µm)	1.2	1.6	2.2	3.3	4.2	4.7
mag	17	16.5	16	13.5	12.5	11
Integration times (required for S/N=100 on a 5th mag. star)
Wavelength (µm)	1.2	1.6	2.2	3.3	4.2	4.7
T [sec], mag=5	< 5	5	10	10	15	30


	Send comments to Ralf Siebenmorgen Last update: 07/07/06

CRIRESHigh-Resolution IR Echelle Spectrometer

Table of Content

Instrument Status

Science Verification

Useful Links and manuals

Science Objectives

Table 1: Science Objectives

Instrument Concept and Capabilities

CRIRES
High-Resolution IR Echelle Spectrometer