Home page:ISSI Call for Proposals 2011 for International Teams in Space Science (incl. Geosciences)

18 Jan 2011

Announcement

The International Space Science Institute (ISSI) in Bern, Switzerland, invites proposals for establishing International Teams to conduct on its premises research activities in Space Sciences, based on the interdisciplinary analysis and evaluation of data from spacecraft and possible integration with ground data and theoretical models. For the purpose of this Call, Space Sciences include the Solar and Heliospheric Physics, Solar-Terrestrial Sciences, Space Plasma and Magnetospheric Physics, Planetary Sciences, Astrobiology, Cosmology, Astrophysics, Fundamental Physics, and Earth Sciences.

The Call for International Teams proposals is available on the ISSI web site: http://www.issibern.ch/spotlight/annualcall2011.pdf

Bern, 18 January 2011

Dr. Maurizio Falanga
Science Program Manager
International Space Science Institute (ISSI)
Hallerstrasse 6
CH-3012 Bern, Switzerland
Tel:  +41 31 6314893
Fax: +41 31 6314897
E-mail: mfalangaissibern.ch

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Last Update: 18 Jan 2011  

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Director's Desk:Cosmic Vision L-class missions presentation event 2011

Cosmic Vision 2015-2025 Plan
L-class missions presentation

Thursday, 3 February 2011

Institut Océanographique de Paris
195 rue Saint-Jacques
75005 Paris, France

 
L-class candidate missions

Meeting homepage: http://sci.esa.int/Lmissions2011

A special event was held in Paris on 3 February 2011, to present the three L-class mission concepts, EJSM-Laplace, IXO and LISA. These are the three candidates for a launch opportunity in 2020 within the frame of the Cosmic Vision 2015-2025 Plan for the ESA Science Programme.

Materials from the meeting, and reports from the assessment studies of the three L-class mission concepts, are posted on these pages. The following material has been uploaded and is available from the links below and from the right-hand menu:

Photos from the meeting

Audio recording and presentations
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Last Update: 21 Feb 2011

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Hubble:Flocculent spiral NGC 2841 [heic1104]

17 Feb 2011

The galaxy NGC 2841 - shown here in this NASA/ESA Hubble Space Telescope image, taken with the space observatory's newest instrument, the Wide Field Camera 3 - currently has a relatively low star formation rate compared to other spirals. It is one of several nearby galaxies that have been specifically chosen for a new study in which a pick 'n' mix of different stellar nursery environments and birth rates are being observed.

Star formation is one of the most important processes in shaping the Universe; it plays a pivotal role in the evolution of galaxies and it is also in the earliest stages of star formation that planetary systems first appear.

Yet there is still much that astronomers don't understand, such as how do the properties of stellar nurseries vary according to the composition and density of the gas present, and what triggers star formation in the first place? The driving force behind star formation is particularly unclear for a type of galaxy called a flocculent spiral, such as NGC 2841 shown here, which features short spiral arms rather than prominent and well-defined galactic limbs.

In an attempt to answer some of these questions, an international team of astronomers is using the new Wide Field Camera 3 (WFC3) installed on the NASA/ESA Hubble Space Telescope to study a sample of nearby, but wildly differing, locations where stars are forming. The observational targets include both star clusters and galaxies, and star formation rates range from the baby-booming starburst galaxy Messier 82 to the much more sedate star producer NGC 2841.

WFC3 was installed on Hubble in May 2009 during Servicing Mission 4, and replaces the Wide Field and Planetary Camera 2. It is particularly well-suited to this new study, as the camera is optimised to observe the ultraviolet radiation emitted by newborn stars (shown by the bright blue clumps in this image of NGC 2841) and infrared wavelengths, so that it can peer behind the veil of dust that would otherwise hide them from view.

While the image shows lots of hot, young stars in the disc of NGC 2841, there are just a few sites of current star formation where hydrogen gas is collapsing into new stars. It is likely that these fiery youngsters destroyed the star-forming regions in which they were formed.

Notes

The Hubble Space Telescope is a project of international cooperation between ESA and NASA.

Image credit: NASA, ESA and the Hubble Heritage (STScI/AURA)-ESA/Hubble Collaboration Acknowledgment: M. Crockett and S. Kaviraj (Oxford University, UK), R. O'Connell (University of Virginia), B. Whitmore (STScI) and the WFC3 Scientific Oversight Committee.

Oli Usher
Hubble/ESA
Garching, Germany
Tel: +49-89-3200-6855
Email: oushereso.org

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Last Update: 17 Feb 2011

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INTEGRAL:The Prompt Activity of Gamma-ray Bursts: their Progenitors, Engines, and Radiation Mechanisms[Sat, 05 Mar 2011]

 ESA    HOME   SCIENCE OUTREACH   RESEARCH   EDUCATIONAL SUPPORT   DIRECTOR'S DESK   PRODEX  Sorry, I could not read the content fromt this page.

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Robotic Exploration:Announcement of Opportunity for ExoMars EDM science

30 Nov 2010 11:38

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Last Update: 30 Nov 2010

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Cluster:First results of Cluster's auroral acceleration campaign

01 Feb 2011

Auroras, more commonly known as the northern and southern lights, are one of the most beautiful and awe-inspiring natural phenomena. New insights into the processes that generate Earth's auroras (and those of other planets) are now being provided by a flotilla of ESA satellites, known as the Cluster mission, as they sweep through the region of space where these colourful curtains of light are created. As they fly in formation above the planet's poles, the Cluster spacecraft are gathering the first multi-point observations of auroral nurseries.

The aurora, or northern lights. Credit: J. Curtis

The red and green emissions are most commonly created by beams of electrons that are boosted to high velocities by quasi-static parallel electric fields in the auroral acceleration region (AAR), located between 4000 and 12 000 km above the poles. The downward-moving particles collide with the upper atmosphere at altitudes of around 100 km, producing shimmering patterns in the night sky.

"The AAR is a particle accelerator in space, similar to an electron gun in an old TV," said Arnaud Masson, ESA's deputy project scientist for Cluster. "It is fed by electrically charged particles that originate in the magnetotail, an elongated region of the magnetosphere located on the nightside of Earth."

"The AAR is not permanent – it comes and goes," continued Masson. "In the absence of the AAR and Alfvén waves, the aurora is diffuse or spread out, and not always noticeable to the naked eye. When the AAR is present, bright, discrete arcs can be seen, sometimes with 'black auroras' embedded."

The existence of the AAR has been known for decades. However, there are still many open questions about auroras, including the altitude distribution and stability of the electric fields which accelerate the particles inside these regions. Now, by analysing the new data from Cluster, these open issues can be tackled for the first time.

Since 2006, the Cluster satellites have slowly drifted away from their initial polar orbits. Meanwhile, the perigees (lowest points) of their orbits have decreased from 19 000 km to just a few hundred kilometres, giving Cluster access to new regions of near-Earth space. For the first time, in Spring 2009, scientists could make use of this natural orbital drift to obtain simultaneous measurements of the AAR with more than one satellite.

Two Cluster spacecraft crossed the auroral acceleration region on 5 June 2009. Credit: ESA

Some of the first results from the AAR data campaign are published by a team of European and American scientists in the 1 February 2011 issue of the prestigious journal Physical Review Letters. Their paper details the observations made by the Cluster C3 and C1 satellites on 5 June 2009, when they made an oblique crossing of the dusk-side auroral oval between 16:55 and 17:15 UT.

At that time, C1 was flying at an altitude of 9000 km, some 2600 km above its sister craft but lagging about 5 minutes behind. Subsequent analysis of data from the EFW electric field and waves, FGM magnetic field, PEACE electron and CIS ion instruments enabled the team to conduct a unique study of the physical state of the AAR during the flybys.

The dual observations revealed spatial and temporal variations in the electric fields and associated particle signatures For the first time it was possible to constrain the size and longevity of these regions. The data showed that the electric field structures measured at least 800 km across and remained stable for at least 5 minutes.

Measurements obtained with two of the Cluster spacecraft provided new insight into the auroral acceleration region. Credit: ESA

The measurements also revealed the 2-D morphology and altitude distribution of the acceleration (electric) potential. They showed that two broad, U-shaped potentials at higher altitude formed a single, combined structure with a narrow, S-shaped potential at lower level.

Using measurements made by the Cluster C3 and C1 spacecraft it has been possible, for the first time, to constrain the size and longevity of the electric fields in the acceleration regions. Credit: ESA (For larger versions of this video click here)

"The data from this and other events are revealing how the acceleration region and the associated electric potential pattern evolve in time and space, and the time scales over which they can be regarded as stable," said Professor Göran Marklund from the Royal Institute of Technology, Stockholm, Sweden, who is lead author of the paper.

"These new results do not yet provide a complete explanation of the dynamics of the aurora, since the Cluster instruments are not optimised for measuring this region, but they provide important constraints on how these structures are created. They also provide inputs for simulations and for future multi-point missions that will explore near-Earth space. Similar space plasma processes occur throughout the Solar System, so a greater understanding of Earth's auroras has implications far beyond our own planet," he added.

Reference paper

Marklund, G.T. et al., Altitude distribution of the auroral acceleration potential determined from Cluster satellite data at different heights, published on 1 February 2011 in Phys. Rev. Lett., 2011

Co-authors of the paper are: Soheil Sadeghi, Tomas Karlsson and Per-Arne Lindqvist (Space and Plasma Physics Department, School of Electrical Engineering, Stockholm), Hans Nilsson (Swedish Institute of Space Physics), Colin Forsyth and Andrew Fazakerley (Mullard Space Science Laboratory, University College, UK), Elizabeth Lucek (Space and Atmospheric Physics Group, Imperial College, London) and Jolene Pickett (Department of Physics and Astronomy, University of Iowa, USA)

Professor Göran Marklund
KTH - Royal Institute of Technology
Sweden
Phone: +46 8 790 7695
Email: goran.marklundee.kth.se

Arnaud Masson
Cluster Deputy Project Scientist
Directorate of Science and Robotic Exploration
ESA, The Netherlands
Phone: +31 71 565 5634
Email: Arnaud.Massonesa.int

Matt Taylor
Cluster Project Scientist
Directorate of Science and Robotic Exploration
ESA, The Netherlands
Phone: +31 71 565 8009
Email: Matthew.Tayloresa.int

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Last Update: 02 Feb 2011

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Herschel:Herschel Open Time Cycle 1 Data Processing Workshop[Mon, 14 Mar 2011]

Villafranca del Castillo
Madrid

14 - 16 March 2011 - PACS Instrument
16 - 18 March 2011 - SPIRE and HIFI Instrument

This workshop is targeted to new HIPE users involved in successful OT1 programmes who want to get familiar with the interactive processing of Herschel data in time for the analysis of the OT1 observations that will start to be collected in Spring 2011 for most of these programmes.

The workshop will include overview talks about the Herschel Interactive Processing Environment (HIPE) and demos, including some hands-on sessions in which the participants will run pipelines scripts on test data provided. For information about logistics, and registration instructions, you can visit the workshop website.

Please note that room capacity is limited, and thus preference will be given to members of OT1 programmes who are new to Herschel data processing.

Registration will close on: Thursday 24 February 2011

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Last Update: 22 Feb 2011

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Herschel:Herschel quantifies the dark matter threshold for starburst galaxies

16 Feb 2011

How much dark matter is needed to trigger a starburst in the cosmic cribs where galaxies are born? A new study, based on data from ESA's Herschel Space Observatory, has revealed that dark matter halos with a mass larger than 300 billion times the Sun's are particularly efficient at igniting massive starbursts, as they house the most active star-forming galaxies in the Universe. Astronomers have discovered this key threshold by measuring small fluctuations in the Cosmic Infrared Background, the integrated diffuse emission produced by the dust from every galaxy that ever existed. These fluctuations trace the distribution of otherwise mostly unresolved star-forming galaxies and of the dark matter halos that enshroud them. These results are reported in the 24 February 2011 issue of Nature and are published online today.

Herschel's deep infrared view of the Lockman Hole.
Credit: ESA & SPIRE consortium & HerMES consortium

Modern astronomers have established that there is much more to galaxies than meets the eye, as the stars, gas and dust - perceivable by telescopes across the entire electromagnetic spectrum - make up only about 10 per cent of their total mass; the rest is believed to reside in a considerably larger assembly, or halo, of invisible dark matter. These halos are, according to the most commonly accepted theory for the formation of cosmic structure the sites where galaxies take shape. In this scenario, tiny fluctuations in the early Universe grew, under the attractive effect of gravity, into a complex network of dark matter sheets and filaments - the so-called cosmic web; later, gas accumulating in the densest knots of the cosmic web began to cool, giving rise to clumps where the first stars formed and which would later assemble into galaxies.

Since the cosmic web constitutes the skeleton supporting the later emergence of stars and galaxies, the distribution of galaxies is expected to follow, and thus trace, that of the dark matter. Whereas the growth of dark matter structures is only regulated by gravity, a number of additional phenomena affect star and galaxy formation, resulting in two different clustering trends. Astronomers refer to this by saying that galaxies are biased tracers of the dark matter distribution.

An interesting feature in this context is that all galaxies are to be found within dark matter halos, with one or more galaxies inhabiting a halo, but not all halos are expected to harbour a galaxy. "The formation of a galaxy is simply not efficient enough in halos with masses that are either too large or too small," explains Asantha Cooray from the University of California, Irvine, USA, who directed the study based on Herschel data that has revealed new details about the most efficient sites for galaxy formation.

Distribution of dark matter, obtained from a numerical simulation, at a redshift z~2; showing the continuous distribution (left panel), a simplified view of the complex network of dark matter structure (central panel) and the most massive dark matter halos - shown in yellow (right panel).
Credit: From Amblard, Cooray, Serra et al., Nature, 2011

The study focussed on starburst galaxies, the most prolific stellar factories in the history of the Universe, which give birth to hundreds or even thousands of stars per year - as a comparison, our Galaxy produces, on average, only one star per year. It is during these intense bursts, lasting from tens to a few hundred million years, that certain types of galaxies are believed to acquire most of their stars. "Our analysis has led to the first observational estimate of the minimum mass of a halo in which a large number of stars could ignite suddenly, creating a starbursting galaxy. This is a key ingredient to improve our current understanding of galaxy formation and evolution," adds Cooray.

The distribution of the dark matter, obtained from a numerical simulation, at a redshift z~2, or when the Universe was about 3 billion years old.
Credit: From Amblard, Cooray, Serra et al., Nature, 2011

The team addressed the issue by studying the maps in the Herschel Multi-tiered Extra-galactic Survey (HerMES). The galaxies in these maps shine brightly in the far-infrared and submillimetre portion of the spectrum, as their dust component absorbs a significant fraction of starlight and radiates it again at these longer wavelengths. As the Universe expands, this emission is shifted to longer wavelengths and, for the very distant galaxies, it peaks in the longer wavelength channels of the SPIRE instrument aboard Herschel. Corresponding to redshifts of about z~2–3, these galaxies thus appear as they were when the Universe was only a few billion years old.

Extreme star-forming galaxies like these in the distant Universe have been a real puzzle for over a decade. They are rather challenging to detect individually, as source confusion effects arise because of the relatively poor angular resolution achievable at the wavelengths at which they radiate the bulk of their light. "As previous results obtained with early Herschel data show, even with deep observations it is possible to directly resolve only about 15 per cent of them," notes co-author Seb Oliver from the University of Sussex, United Kingdom, who coordinates the HerMES Key Programme together with Jamie Bock from Caltech, USA. "But this is not the end of the story: with the large maps of HerMES and the sensitivity and resolution of Herschel, we have finally been able to trace them," adds Oliver.

The infrared light radiated collectively by all faint, star-forming galaxies creates a diffuse background, known as the Cosmic Infrared Background (CIB). "The CIB exhibits fluctuations which closely reflect the clustering pattern of the galaxies responsible for it," says Alexandre Amblard from UC Irvine and currently at NASA Ames, first author of the Nature paper. Observing these fluctuations, which span a wide range of angular scales, is one of the very few methods available to explore the properties of the unresolved population of galaxies contributing to the CIB. "Thanks to Herschel's extraordinary data, we have been able, for the first time, to pin the fluctuations down to very small scales - about 1 arc minute," he adds.

Clustering of faint, star-forming galaxies as a funtion of angular scale on the sky.
Credit: From Amblard, Cooray, Serra et al., Nature, 2011

The team of astronomers used HerMES observations of two fields, the Lockman Hole and the GOODS North. "With its large telescope and its unprecedented resolution and sensitivity at these far-infrared wavelengths, Herschel is a unique facility that has now made it possible to scrutinise the CIB fluctuations down to scales that reveal really interesting information about the emergence of starburst galaxies around the peak of the star formation history of the Universe," comments Göran Pilbratt, Herschel Project Scientist at ESA.

In order to extract information about these galaxies and how they formed, the data need to be properly modelled. "The tool we employed for this is known as the halo model," says co-author Paolo Serra, also from UC Irvine and currently at NASA Ames. The halo model is a statistical approach to describe the dark matter distribution, which is viewed as an ensemble of discrete objects - the halos. Within this framework, galaxies and their clustering properties can be studied in relation to the dark matter halos to which they belong. "By applying the halo model to the fluctuations of the CIB measured by Herschel on both large and small scales, it was possible to characterise correlations in the distribution not only of galaxies that reside in different halos, but also of galaxies occupying the same halo," adds Serra.

The latter effect is the key to constraining differences in the way galaxies and dark matter halos tend to be grouped: it is, in fact, at the small scales that the two distributions deviate the most from each other, as the least massive amongst dark matter halos do not host galaxies. "This analysis has demonstrated that the starbursting galaxies we targeted tend to reside in halos with a mass greater than 3×1011 times that of the Sun, thus leading to a firm estimate of the minimum mass needed by a halo for a starburst galaxy to form within it," notes Amblard. "This value singles out the halos where star formation takes place at its highest efficiency, and is ten times lower than the one predicted by semi-analytical models for galaxy formation," adds Serra.

Theory suggests that star formation may set in even within dark matter halos with masses smaller than this value, but it is expected to be promptly suppressed by supernova explosions of the most massive amongst these first stars: these would blow away the surrounding gas which, in the absence of the strong gravitational potential of a massive dark matter halo, would leave the halo barren. At the other end of the scale, if the dark matter halo is too massive, the cooling of gas is inefficient and cannot happen rapidly enough to produce a starburst.

"From a theoretical perspective, the interplay between these two mechanisms, and possibly with other processes as well, is not yet fully understood," notes Cooray. "In this context, our measurements provide strong evidence for a mass scale where these effects are balanced, resulting in a very powerful star formation activity. This value will now have to be taken into account by all theoretical efforts trying to model the properties of starbursting galaxies, and will certainly shed new light on some still nebulous details about galaxy formation," concludes Cooray.

Notes for editors

The study relies on data from the Herschel Multi-tiered Extra-galactic Survey (HerMES), a Guaranteed Time Key Programme probing galaxy evolution at high redshift. The observations have been performed with the SPIRE instrument aboard Herschel during the Science Demonstration Phase at the end of 2009. The data consist of a wide area in the Lockman Hole, measuring 218 × 218 square arc minutes, complemented by a narrow and deep map of the GOODS North field, covering 30 × 30 square arc minutes, which have been observed at wavelengths of 250, 350 and 500 µm.

Herschel is an ESA space observatory with science instruments provided by European-led Principal Investigator consortia and with important participation from NASA. The SPIRE instrument contains an imaging photometer (camera) and an imaging spectrometer. The camera operates in three wavelength bands centred on 250, 350 and 500 µm, and so can make images of the sky simultaneously in three sub-millimetre colours. SPIRE was designed and built by an international collaboration, led by Professor Matt Griffin of Cardiff University, UK.

HerMES is the largest Herschel Key Programme in terms of observing time and aims at studying the evolution of galaxies in the distant Universe. The project is carried out by a large international collaboration, including many institutes from across the world, and in particular the team who built the SPIRE instrument on board Herschel.

Related publications

Amblard, A., Cooray, A., Serra, P., et al., "Sub-millimetre galaxies reside in dark matter halos with masses greater than 3×1011 MSun", Nature, DOI: 10.1038/nature09771

Cooray, A., & Sheth, R., "Halo Models of Large Scale Structure", Physics Reports, Vol 372, pp. 1-129, 2002
DOI: 10.1016/S0370-1573(02)00276-4

Alexandre Amblard
University of California, Irvine
and NASA Ames Research Center
USA
Email: alexandre.amblardnasa.gov
Phone: +1-415-294-1882

Asantha Cooray
University of California, Irvine
USA
Email: acoorayuci.edu
Phone: +1-949 824-6832

Paolo Serra
University of California, Irvine
and NASA Ames Research Center
USA
Email: paolo.serranasa.gov
Phone: +1-714-463-8249

Seb Oliver
Principal Investigator of the HerMES Key Programme
University of Sussex, United Kingdom
Email: S.Oliversussex.ac.uk
Phone: +44-1273-678852

Göran Pilbratt
Herschel Project Scientist
Research and Scientific Support Department
Science and Robotic Exploration Directorate
ESA, The Netherlands
Email: gpilbrattrssd.esa.int
Phone: +31 71 565 3621

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Last Update: 16 Feb 2011

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Cosmic Vision:Four candidates selected for the next medium-class mission in ESA's Cosmic Vision

25 Feb 2011

Looking ahead to the next decade of scientific exploration, ESA has today (25 February) selected four candidates for a medium-class mission that will launch in the period 2020-22. The candidates cover very different areas of scientific research, ranging from investigations of black holes and general relativity to near-Earth asteroid sample return and studies of planets orbiting distant stars.

"There was huge interest in this flight opportunity from right across the scientific community," said Fabio Favata, Head of ESA's Science Planning and Community Coordination Office. "The competition for this launch opportunity is the strongest to date for the ESA Science Programme."

ESA issued a call to the scientific community on 29 July 2010, soliciting proposals for a third medium-class mission (M3) within the long-term science plan known as Cosmic Vision 2015-2025. A total of 47 proposals was submitted and then peer reviewed by the Advisory Structure to the Science Programme.

As a result of this review process, recommendations based on the scientific excellence of the missions were forwarded by the Space Science Advisory Committee to David Southwood, ESA's Director of Science and Robotic Exploration.

The Director has now selected four missions to undergo an initial Assessment Phase. Once this is completed, a further down-selection will be performed, leading to a decision on which mission will be finally implemented.

"This selection of medium-class mission candidates is a major milestone in the definition of ESA's future science programme," said Professor Southwood.

"All of the missions selected for the Assessment Phase promise exciting scientific breakthroughs and choosing the mission that will be implemented will be a difficult process."

The four proposals chosen to proceed for assessment are EChO, LOFT, MarcoPolo-R and STE-QUEST.

The Exoplanet Characterisation Observatory (EChO) would be the first dedicated mission to investigate exoplanetary atmospheres, addressing the suitability of those planets for life and placing our Solar System in context.
Orbiting around the L2 Lagrange point, 1.5 million km from Earth in the anti-sunward direction, EChO would provide high resolution, multi-wavelength spectroscopic observations. It would measure the atmospheric composition, temperature and albedo of a representative sample of known exoplanets, constrain models of their internal structure and improve our understanding of how planets form and evolve.
The Large Observatory For X-ray Timing (LOFT) is intended to answer fundamental questions about the motion of matter orbiting close to the event horizon of a black hole, and the state of matter in neutron stars, by detecting their very rapid X-ray flux and spectral variability.
LOFT would carry two instruments: a Large Area Detector with an effective area far larger than current spaceborne X-ray detectors, and a Wide Field Monitor that would monitor a large fraction of the sky. With its high spectral resolution, LOFT would revolutionise studies of collapsed objects in our Galaxy and of the brightest supermassive black holes in active galactic nuclei.
MarcoPolo-R is a mission to return a sample of material from a primitive near-Earth asteroid (NEA) for detailed analysis in ground-based laboratories. The scientific data would help to answer key questions about the processes that occurred during planet formation and the evolution of the rocks which were the building blocks of terrestrial planets.
The mission would also reveal whether NEAs contain pre-solar material not yet found in meteorite samples, determine the nature and origin of the organic compounds they contain, and possibly shed light on the origin of molecules necessary for life.
The Space-Time Explorer and Quantum Equivalence Principle Space Test (STE-QUEST) is devoted to precise measurement of the effects of gravity on time and matter. Its main objective would be to test the Principle of Equivalence, a fundamental assumption of Einstein's Theory of General Relativity. STE-QUEST would measure space-time curvature by comparing the tick rate of an atomic clock on the spacecraft with other clocks on the ground.
A second primary goal is a quantum test of the Universality of Free Fall – the theory that gravitational acceleration is universal, independent of the type of body.

The missions flown as part of ESA's Cosmic Vision 2015-2025 plan will tackle some of the major outstanding scientific questions about the Universe and our place in it:

What are the conditions for planet formation and the emergence of life?How does the Solar System work?What are the fundamental physical laws of the Universe?How did the Universe originate and what is it made of?

There are currently three missions - Euclid, PLATO and Solar Orbiter - which are undergoing competitive assessment for selection as the first and second medium class missions under Cosmic Vision. The final selection for M1 and M2 will be made later this year, with launches expected in 2017-18.

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Last Update: 25 Feb 2011

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IXO:IXO science meeting: Present status and future prospects of X-ray Astronomy[Mon, 14 Mar 2011]

CNR Headquarter
P.le Aldo Moro; 7
Rome

The purpose of this three-day conference is to gather together the worldwide X-ray astronomical community to discuss the key science topics of IXO and to review the discovery space opened by science and technological developments. Major parts of the meeting will be devoted to IXO, its science objectives and instruments, but a session for discussing other future missions will also be available.

It is planned to have both invited/review and contributed talks, as well as a poster session.

Science Topics:

Co-evolution of galaxies and their supermassive black holesLarge scale structure and the creation of chemical elementsMatter under extreme conditionsLife cycles of matter and energy in the Universe
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Last Update: 26 Jan 2011

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