Integral Field Spectroscopy

Slides:

Advertisements

Similar presentations

GMOS Data Reduction Richard McDermid Gemini Data Reduction Workshop Tucson, July 2010.

Advertisements

GLAO instrument specifications and sensitivities

Echelle Spectroscopy Dr Ray Stathakis, AAO. What is it? n Echelle spectroscopy is used to observe single objects at high spectral detail. n The spectrum.

JWST IFUs and Data Tool Development Plans Tracy Beck JWST NIRSpec Instrument Scientist.

FMOS Observations and Data 14 January 2004 FMOS Science Workshop.

Integral field spectroscopy in the IR: Gemini-CIRPASS observations and the star-formation history in the nucleus of M83 While HST offers excellent spatial.

ELT Stellar Populations Science Near IR photometry and spectroscopy of resolved stars in nearby galaxies provides a way to extract their entire star formation.

AEOS Telescope + Image-Slicer/ Spectrograph Data Reduction and Results for June 8, 2006.

Astronomical Spectroscopy

1 High-z galaxy masses from spectroastrometry Alessio Gnerucci Department of Physics and Astronomy University of Florence 13/12/2009- Obergurgl Collaborators:

Memorandam of the discussion on FMOS observations and data kicked off by Ian Lewis Masayuki Akiyama 14 January 2004 FMOS Science Workshop.

JWST calibration requirements Harald Kuntschner. JWST - an overview NIRCam –0.6-5 microns –FoV: 2.16x4.4 arcmin (0.0317” for short band and ” for.

Distortion in the WFC Jay Anderson Rice University

NGC 2506 – a try for a spectroscopic study Ekaterina Atanasova Petr Kabath Christine Oppegaard Mª Carmen Sánchez Gil Tutor: Frédéric Royer 2nd NEON Archive.

Measuring the properties of QSO broad- line regions with the GMOS IFU. Randall Wayth with Matt O'Dowd & Rachel Webster.

3D meeting Tenerife July 2002 Ian Parry, Andrew Dean, Dave King, Andy Bunker, Steve Medlen, Jim Pritchard, Rachel Johnson, Anamparabu Ramaprakash, Rob.

14 October Observational Astronomy SPECTROSCOPY and spectrometers Kitchin, pp

Spectroscopic Observations (Massey & Hanson 2011, arXiv v2.pdf) Examples of Spectrographs Spectroscopy with CCDs Data Reduction and Calibration.

First results of the tests campaign in VISIBLE in VISIBLE for the demonstrator 12 October 2007 SNAP Collaboration Meeting Paris Marie-Hélène Aumeunier.

15 October Observational Astronomy Direct imaging Photometry Kitchin pp ,

INTEGRAL FIELD SPECTROSCOPY AT THE VLT STAR (CLUSTER) FORMATION IN 3D : INTEGRAL FIELD SPECTROSCOPY AT THE VLT Markus Kissler-Patig (Instrument Scientist.

18 October Observational Astronomy SPECTROSCOPY and spectrometers Kitchin, pp

Science with the new HST after SM4 WFC3 slitless spectroscopy Harald Kuntschner Martin Kümmel, Jeremy R. Walsh (ST-ECF) WFC3-team at STScI and NASA.

Integral Field Spectroscopy. David Lee, Anglo-Australian Observatory.

Detection of H-alpha emission from z>3.5 galaxies with AKARI-FUHYU NIR spectroscopy Chris Sedgwick Stephen Serjeant Chris Pearson The Open University on.

Fuerteventura, Spain – May 25, 2013 Physical parameters of a sample of M dwarfs from high- resolution near-infrared spectra Carlos del Burgo Collaborators:

Central Engine of AGN Xi’ian October 2006 Black Hole Mass Measurements with Adaptive Optic Assisted 3D-Spectroscopy Courtesy ESO Guia Pastorini Osservatorio.

The Study of IFU for the Li Jiang 2.4m Telescope ZHANG Jujia 张居甲 Yun Nan Astronomical Observatory. CAS Sino-French IFU Workshop Nov Li Jiang.

KMOS Instrument Overview & Data Processing Richard Davies Max Planck Institute for Extraterrestrial Physics  What does KMOS do?  When will it do it?

Data products of GuoShouJing telescope(LAMOST) pipeline and current problems LUO LAMOST Workshop.

Data Analysis Software Development Hisanori Furusawa ADC, NAOJ For HSC analysis software team 1.

MIRI Dither Patterns Christine H Chen. Dithering Goals 1.Mitigate the effect of bad pixels 2.Obtain sub-pixel sampling 3.Self-calibrate data if changing.

Exam2 : Oct 25, 2012 Exam2 : Lecture note #8 through #18.

MOS Data Reduction Michael Balogh University of Durham.

14 January Observational Astronomy SPECTROSCOPIC data reduction Piskunov & Valenti 2002, A&A 385, 1095.

THE STAR-FORMING DWARF GALAXY POPULATION IN THE LOCAL UNIVERSE AND BEYOND: The first 3D Spectroscopic study of a sample of nearby Star-Forming Dwarfs Luz.

DAO Observations and Instrumentation Jason Grunhut.

Goals for HETDEX Determine equation of state of Universe and evolutionary history for dark energy from 0

RAW DATA BIAS & DARK SUBTRACTION PIXEL-TO-PIXEL DQE CORR. LOCATE EXTR. WINDOW THROUGHPUT CORRECTION (incl. L-flat, blaze function, transmission of optics,

STScI Slitless Spectroscopy Workshop November 2010 aXe Advanced Topics – becoming more dextrous, using aXe with other instruments, making calibration.

Describing 3D Datasets Igor Chilingarian (CRAL Observatoire de Lyon/Sternberg Astronomical Institute of the Moscow State University) IVOA DM & DAL WG –

Raffaella Anna Marino UNIVERSIDAD COMPLUTENSE DE MADRID Grupo UCM de Astrofísica Instrumental y eXtragaláctica.

UNIVERSIDAD COMPLUTENSE DE MADRID Grupo UCM de Astrofísica Instrumental y eXtragaláctica PRESENTADO POR: Raffaella Anna Marino COLABORADORES: A. Gil de.

Competitive Science with the WHT for Nearby Unresolved Galaxies Reynier Peletier Kapteyn Astronomical Institute Groningen.

Sample expanded template for one theme: Physics of Galaxy Evolution Mark Dickinson.

Reducing IFU Data ITSO DR Workshop, Thursday 5th May Nic Scott.

Integral Field Spectroscopy

SINFONI data reduction using the ESO pipeline. Instrument design and its impact on the data (I) integral field spectrometer using mirrors brickwall pattern.

Galaxy Evolution and WFMOS

Single Object Slitless Spectroscopy Simulations

A.Zanichelli, B.Garilli, M.Scodeggio, D.Rizzo

JWST Pipeline Overview

Single Object & Time Series Spectroscopy with JWST NIRCam

NIRSpec pipeline concept Guido De Marchi, Tracy Beck, Torsten Böker

Extragalactic Archaeology

SN 1987A: The Formation & Evolution of Dust in a Supernova Explosion

JWST NIRCam Time Series Observations

Spectrophotometric calibration of the IFU spectrograph

Observing and Data Reduction

NIRSpec simulation data-package

Resolving the black hole - nuclear cluster - spheroid connection

ESAC 2017 JWST Workshop JWST User Documentation Hands on experience

Summary Single Object & Time Series Spectroscopy Jeff Valenti JWST Mission Scientist Space Telescope Science Institute.

A galaxy at redshift 10? Brigitta Eder Vera Könyves

The VIMOS IFU Pipeline Carlo Izzo.

NIR Spectroscopy at Gemini South

MIRI Observing Templates

Observational Astronomy

Validity of abundances derived from spaxel spectra of the MaNGA survey

Spectroscopic Observations (Massey & Hanson 2011, arXiv v2

Presentation transcript:

Integral Field Spectroscopy S.F.Sánchez (CAHA) Universidad de Almeria Viernes de Ciencia 14 January 2011

IFS or 3D Spectroscopy Is the spectroscopic technique that samples a quasi-continous area in the sky (FOV). The FOV is sampled by small aperture elements named spaxels, which correspond to pixels of an image. Light coming through each spaxel is transported to the entrance of an spectrograph. The image/plane and focal/plane are completely decoupled: Lot of software is required to reconstruct the orginal spatial shape at each wavelength.

Different kind of spaxels. Is the spectroscopic technique that samples a quasi-continous area in the sky (FOV). The FOV is sampled by small aperture elements named spaxels, which correspond to pixels of an image. Light coming through each spaxel is transported to the entrance of an spectrograph. The image/plane and focal/plane are completely decoupled: Lot of software is required to reconstruct the orginal spatial shape at each wavelength.

How to send the light to the Spectrograph? Image Slicers: Light is “sliced” in small continous pseudo-slits: SINFONI, MUSE... Lensarrays: Continous lensarray is focused in separated apertures: SAURON, TIGER... Fiber-Bundles (+lensarrays): Lights is conducted by fibers: PMAS/PPAK, VIMOS, GMOS...

Fiber Feed IFS technique

The Raw data of FF IFUs

The Raw data of FF IFUs

FF IFU: Data Reduction (I) Continuum exposure used to find and trace the location of the spectra in the CCD. The FWHM of the spectra projected in the cross-dispersion axis determined. Gaussian extraction performed. Comparison Arc used to determine the distorsion correction and wavelength solution, latter applied to the data.

FF IFU: Data Reduction (II) Sky-frames taken during the twilight used to correct for the differentical transmission fiber to fiber (wavelength dependent). Spectrophotometric calibration standard star exposure used to determine the flux calibration, applied to the science frames. Science (331), Sky (36) and calibration spectra (15) are separated in different frames, once reduced. Sky spectrum is derived for each frae (median+3sigma clipping of the 36 sky-spectra) and the subtracted to the data.

FF IFU: Data Reduction (III) Re-arrange the dithered pointings in a single row-stacked spectra frame, plus the complementary Position Table. Mask the spectral pixel strongly affected by the vignetting. Interpolate the final Mosaic into a common grid datacube of 1”/pixel. When available, perform a flux recalibration based on broad-band photometry.

The Raw data of FF IFUs

Tracing process (I)

Tracing process (II)

Extraction: How to Add flux?

Extraction: cross-talk?

Extraction: The final product

Distorsions: Shifting lines.

Dispersion:Which line are you?

Fiber-to-Fiber transmission

Sky subtraction... If possible.

Where my spectra comes from?.

PMAS/PPAK: Dithering. 3 position dither pattern per pointing. Complete spatial covering of the FOV. Increase of the spatial resolution. Fully implemented in R3D.

WF-IFS Mosaics Experiment

Matching the pointings. The pointings overlap, in at least 11 spectra. The change in transparency is critical Accuracy of the telescope offsets is also critical.

Results: Orion (Sánchez et al. 2006)

Results: M74 (Sánchez et al. 2010)

CALIFA: Introduction Survey of ~600 Galaxies in the Local Universe, using Integral Field Spectroscopy, with PPAK mounted at the 3.5m Telescope. Proposed by 53 researchers from 8 countries: PI:S.F.Sánchez. Board: R. Kennicutt (Chair), A. Gil de Paz (co-PI), J.M. Vilchez, L. Wisotzki, G. Van den Ven. 210 dark nights allocated in next 3 years. Started on July 1st 2010.

CALIFA: Science Goals Model the resolved stellar population in galaxies of any kind and trace the star formation history. Determine the nature of the ionized gas and its chemical abundance gradients. Determine the 2D kinematic structure of galaxies in the local Universe.

Results (I): Mother Sample Characterization of the Sample: How are the galaxies we are going to observe? Morphology, Spectral Type, Nuclear or Starformation activity… Do we have any possible Bias and how we can control/correct them?

Results (II): Reduced Data Pilot Studies: 43 objects observed in 2009: A) V300 (R~450); 1.5h Int.; 3700-7100 A. B) V600 (R~950); 1.5h Int.; 3800-6700 A. CALIFA First Runs (June-July 2009): 21 objects: A) V500 (R~890); 45m int: B) V1200 (R~1850); 1.5h int: 3500-4100A. R at 5000 A

Results (III): Science Diversity of the observed galaxies: Different colors, magnitudes, morphologies, gas content… a photograph of the Local Universe! Resolved properties of the stellar populations. Stellar Kinematics. Properties of the Ionized gas. All included in the First Article (in prep.)

3D Spectroscopy Summary IFS is a common user technique (40% of the observations done with the 3.5m at CAHA, 80% of one of the UT/VLT). Many of proposed or new generations instruments are IFUs (MUSE, MEGARA). JWST will include an IFU. There is science that can only be done with IFUs. Any future astronomer should be prepared to use it.