The multi-unit spectroscopic explorer (MUSE) is an

integral field spectrograph Integral Field Spectrographs (IFS) combine spectrographic and imaging capabilities in the optical or infrared wavelength domains -from 0.32 μm to 24 μm- to get from a single exposure spatially resolved spectra in a bi-dimensional region. Develop ...

installed at the

Very Large Telescope The Very Large Telescope (VLT) is a telescope facility operated by the European Southern Observatory on Cerro Paranal in the Atacama Desert of northern Chile. It consists of four individual telescopes, each with a primary mirror 8.2 m acro ...

(VLT) of the European Southern Observatory (ESO).MUSE instrument development page at ESO.
/ref> It operates in the visible wavelength range, and combines a wide

field of view The field of view (FoV) is the extent of the observable world that is seen at any given moment. In the case of optical instruments or sensors it is a solid angle through which a detector is sensitive to electromagnetic radiation. Human ...

with a fine spatial sampling and a large simultaneous spectral range. It is designed to take advantage of the improved spatial resolution provided by

adaptive optics Adaptive optics (AO) is a technology used to improve the performance of optical systems by reducing the effect of incoming wavefront distortions by deforming a mirror in order to compensate for the distortion. It is used in astronomical tele ...

. MUSE had first light on the VLT on 31 January 2014.MUSE blog entry for first light

Background

A celebration of MUSE at the Observatoire de Lyon

Traditionally astronomical observations in the optical region have been separated into imaging and spectroscopy. The former can cover a wide field of view, but at the cost of a very coarse resolution in the wavelength direction. The latter has tended to either lose spatial resolution - completely in the case of fibre spectrographs, and partially in the case of long-slit spectrographs - or to have only coarse spatial resolving power in the case of recent

s. MUSE was devised to improve on this situation by providing both high spatial resolution as well as a good spectral coverage. The principal investigator of the instrument is Roland Bacon at the Lyon Centre for Astrophysics Research (CRAL) in charge of a consortium consisting of six major European institutes: CRAL at

Lyon Observatory Lyon Observatory is located in Saint-Genis-Laval, a commune in the Rhône department in eastern France, near Lyon. Founded in 1878, the entire facility was listed as a historical site on May 9, 2007. In 1867, Paris astronomer Charles André reque ...

is the PI institute and led the construction of the majority of the instrument. Other involved institutes include the German ''Institut für Astrophysik Göttingen'' (IAG) and the Leibniz Institute for Astrophysics Potsdam (AIP), the '' Netherlands Research School for Astronomy'' (NOVA), the ''Institut de Recherche en Astrophysique et Planétologie'' (IRAP), France,

ETH Zürich (colloquially) , former_name = eidgenössische polytechnische Schule , image = ETHZ.JPG , image_size = , established = , type = Public , budget = CHF 1.896 billion (2021) , rector = Günther Dissertori , president = Joël Mesot , a ...

, Switzerland as well as the European Southern Observatory (ESO). The kick-off for the project was January 18, 2005 with the final design review in March 2009. The instrument passed its final acceptance in Europe on September 10, 2013 MUSE was mounted on the Nasmyth platform of the fourth VLT Unit telescope on January 19, 2014, and saw first light on January 31, 2014.

Scientific goals

Stars and resolved stellar populations

MUSE has a field of view that is well-matched to a number of fascinating objects in the Milky Way, such as

globular clusters A globular cluster is a spheroidal conglomeration of stars. Globular clusters are bound together by gravity, with a higher concentration of stars towards their centers. They can contain anywhere from tens of thousands to many millions of membe ...

and

planetary nebula A planetary nebula (PN, plural PNe) is a type of emission nebula consisting of an expanding, glowing shell of ionized gas ejected from red giant stars late in their lives. The term "planetary nebula" is a misnomer because they are unrelate ...

e. The high spatial resolution and sampling will enable MUSE to simultaneously observe the spectra of thousands of stars in one shot in dense regions such as globular clusters. In star-forming regions, with a mixture of ionised gas and stars, MUSE will provide information both on the stellar and nebular content across this region.

Lyman-alpha emitters

A key goal of the design of MUSE was to be able to study the progenitors of normal nearby galaxies out to redshifts z > 6. These sources can be extremely faint, in which case they can only be detected using through the emission in the Lyman-alpha emission line, such galaxies are frequently referred to as

Lyman-alpha emitter A Lyman-alpha emitter (LAE) is a type of distant galaxy that emits Lyman-alpha radiation from neutral hydrogen. Most known LAEs are extremely distant, and because of the finite travel time of light they provide glimpses into the history of the un ...

s. A common way to study such sources is to use narrow-band imaging, but this technique can only survey a very narrow redshift range at a time – set by the width of the filter. In addition this method is not as sensitive as direct spectroscopic studies because the width of the filter is wider than the typical width of an emission line. Since MUSE is a spectrograph with a 1'x1' field of view, it can be used to search for emission line sources over a wide range in redshift (z = 2.9–6.65 for Lyman-alpha) at the same time. It is expected that the instrument will be used for exposures of up to 100 hours, in which case it should reach a limiting flux of 3x10⁻¹⁹ erg/s/cm² which is an order of magnitude fainter than current narrow-band imaging surveys. MUSE views the strange galaxy NGC 4650A

Galaxy evolution

MUSE will be a powerful instrument for studying the dynamical properties of galaxies from the nearby Universe out to at least a redshift of 1.4, after which the IIforbidden emission line at 372.7 nm disappears off the red end of the spectrograph. At low redshift MUSE will provide two-dimensional maps of the kinematics and the stellar populations in all types of galaxies. It will build on and expand the science done with the SAURON instrument on the

William Herschel Telescope The William Herschel Telescope (WHT) is a optical/near-infrared reflecting telescope located at the Roque de los Muchachos Observatory on the island of La Palma in the Canary Islands, Spain. The telescope, which is named after William Hersc ...

, extending it to both larger radii and to more distant galaxies. With the narrow-field mode, MUSE will be able to zoom in on the region around the super-massive black hole at the centre of massive galaxies. It is hoped that this will help astronomers understand the process by which these giants formed - likely through a merging process whereby two black holes coalesce to form a more massive end product and at the same time perturbing the stellar orbits in the centre of the galaxy. At higher redshift MUSE will provide the power to construct maps of the distribution of metals in galaxies and at the same time provide constraints on the dynamical structure of these objects. Combining this with environmental information due to the wide field of view (1 arcminute corresponds to 430 kilo-parsec at a redshift of 0.7) it will be possible to study how the properties of galaxies are affected by the environment they find themselves in a very powerful, and mostly new, way.

Science with the narrow field mode

MUSE will also have a high spatial resolution mode with a field of view of 7.5x7.5 arcsec and a spatial resolution of 0.042 arcsec at 750 nm. The main scientific use of this mode is for studying in detail more nearby systems such as the environment around

supermassive black hole A supermassive black hole (SMBH or sometimes SBH) is the largest type of black hole, with its mass being on the order of hundreds of thousands, or millions to billions of times the mass of the Sun (). Black holes are a class of astronomical ob ...

s in nearby galaxies. In particular it will be possible to resolve the sphere of influence of the black holes in most massive galaxies out to the

Virgo cluster The Virgo Cluster is a large cluster of galaxies whose center is 53.8 ± 0.3 Mly (16.5 ± 0.1 Mpc) away in the constellation Virgo. Comprising approximately 1,300 (and possibly up to 2,000) member galaxies, the cluster forms the heart of the la ...

and for the most massive galaxies also in the

Coma cluster of galaxies The Coma Cluster (Abell 1656) is a large cluster of galaxies that contains over 1,000 identified galaxies. Along with the Leo Cluster (Abell 1367), it is one of the two major clusters comprising the Coma Supercluster. It is located in and tak ...

. Closer to home, MUSE will be able to study jets in nearby star forming regions and the surfaces of a range of solar system objects. This could for instance be used to carry out spectroscopic monitoring studies of volcanic activity on Io and spectroscopic studies of the atmosphere of Titan.

Technical

To meet the scientific aims of the instrument, MUSE has had to fulfill a number of requirements: * The instrument should have high throughput. * The ability to carry out very long integrations, thus the instrument has to be very stable. * In combination with adaptive optics the instrument should achieve allow a boost in spatial resolution relative to seeing limited observations across the field of view across the celestial sphere. * A wide field of view, allowing survey operation * Efficient production to reduce cost, and efficient design to fit within the volume and mass constraints. To achieve the latter two points, the spectrograph consists of 24 identical integral field units (IFU), hence reducing cost by replication. These have each excellent image quality and light in the instrument plan is slice up and sent to individual IFUs using an image slicer. The spectrograph design has achieved an excellent image quality across the spectral bandwidth of MUSE with the tilt of the detector compensating for axial chromaticism. With such a design, expensive optical materials such as CaF₂ are not needed, thus reducing the overall cost. The throughput is kept high by using high quantum efficiency CCDs. There is also only one grating, a high transmission volume phase holographic grating. This has given a throughput that peaks above 50% around 700-800 nm and exceeds 40% across almost the entire wavelength range of the instrument. The full instrument weighs close to eight metric tons and essentially fills the Nasmyth platform's volume of 50 m³. But due to the modular design, each of the 24 IFUs can be removed for maintenance or repair - in order to do this a special cradle was designed to safely remove and insert an IFU.

Adaptive optics interface

In order to achieve the required boost in spatial resolution across the celestial sphere, MUSE makes use of the GALACSI interface which is part of the ''Adaptive Optics Facility'' on UT4 at VLT. All the adaptive optics (AO) components are all mounted in the Nasmyth derotator and a metrology system is used to ensure alignment of the AO system with MUSE. This is needed since MUSE is located on the Nasmyth platform. Armed with the AO system, it is expected that MUSE will achieve a median spatial resolution of 0.46 arcseconds, or ~3 kpc at a redshift >3, across the 1'x1' field-of-view of the wide-field mode. In the narrow-field mode, the spatial resolution should reach 0.042 arcseconds at 750 nm, corresponding to ~3 pc resolution at the distance of

Virgo Cluster The Virgo Cluster is a large cluster of galaxies whose center is 53.8 ± 0.3 Mly (16.5 ± 0.1 Mpc) away in the constellation Virgo. Comprising approximately 1,300 (and possibly up to 2,000) member galaxies, the cluster forms the heart of the la ...

of galaxies.

Data rates and management

Each exposure with MUSE will return a datafile with data from the 24 IFUs at 35 MB each - thus the total size of the raw datafile is 0.84 GB. After data reduction this will expand to a total of 3.2 GB per exposure as the data are translated into floating point values and an error estimate cube is produced. This means that observations that rely on many short exposures can produce very large datasets - easily producing 100 GB per night of fairly complex data.

Operation and results

Gallery

File:MUSE video of the transit of Europa across the disc of Jupiter.ogg, This video sequence was created from many separate MUSE observations of the planet Jupiter during a transit of the moon Europa and its shadow. File:MUSE views the Orion Nebula.ogg, This view shows how the instrument gives a three-dimensional view of the Orion Nebula. File:MUSE views the unusual galaxy NGC 4650A.ogg, This view shows how the instrument gives a three-dimensional view of a distant galaxy. File:MUSE — Close up of the H-alpha line in the strange galaxy NGC 4650A.ogg, This view shows how the instrument gives a three-dimensional view of NGC 4650A. File:MUSE — Running through the 3D data of NGC 4650A.ogg, Another view of how the instrument gives a three-dimensional view of NGC 4650A. File:MUSE shows ESO 137-001 in three dimensions.ogg, This view shows how MUSE gives a three-dimensional depiction of the galaxy ESO 137-001 as it falls into the vast Norma Galaxy Cluster and is stripped of its gas.

References

External links

MUSE page in Lyon

The MUSE commissioning blog
{{European Southern Observatory Spectrometers Telescope instruments European Southern Observatory Articles containing video clips