* Astronomy

Members Login
Username 
 
Password 
    Remember Me  
Post Info
TOPIC: Extrasolar Planets


L

Posts: 131433
Date:
RE: extra-solar planets
Permalink  
 


Star formation, brown dwarfs and planets
At the Centre for Astrophysics Research (CAR), our work on star formations is wide-ranging. We play a key role in several large international surveys, and are investigating the 'failed' stars known as brown dwarfs.
Our astronomers are also involved in a variety of programmes in one of the newest fields of research: to detect and characterise extrasolar planets.

Planets around other stars (exoplanets) were discovered just over a decade ago and have rapidly become one of the most high-profile topics for research. The ultimate goal is to detect planets in the habitable zone of stars and then detect biomarkers which could signal the presence of life.
A team led by Professor Hugh Jones is one of the few groups worldwide to discover nearby extrasolar planets. Over the last decade they have found around forty extrasolar planets from the radial velocities of nearby stars, using the Anglo-Australian Telescope, and from imaging and spectroscopy in Orion.
Radial velocity observations measure the slight change in the speed of a star towards and away from us resulting from the motion of a planet around the star. Such observations are biased towards detecting larger mass planets as these have the biggest effect on the star.
An alternative way of detecting planets is to observe the reduction in the brightness of a star as a planet transits across the stellar disc. Again, this technique is biased towards larger planets as these will produce the largest reduction in the star's brightness and be more easily detected.
Dr David Pinfield is leading a Transit Survey which has the best prospects for finding the smaller earth-like extrasolar planets in the habitable zone, via transits of planets across cooler, smaller stars. Such stars are only bright in the infrared and his survey is being carried out at the United Kingdom Infrared Telescope, Hawaii.

Read more

__________________


L

Posts: 131433
Date:
Permalink  
 

A team of University of Hertfordshire astronomers led by Dr David Pinfield of the Centre for Astrophysics Research is leading a major new European collaboration to search for and study planets around other stars (extra-solar planets).
Funded with £2.75 million from the European Commission, this research and technology network will focus on the search for rocky planets around cool stars and the development of future space-based technology to study extra-solar planets.
Cool stars are much fainter than the Sun and are thus challenging to study, but they play a major role in astrophysics; they are the most common type of star in our Galaxy.

"This fast moving field is at the forefront of modern astrophysics, and is moving towards a goal of discovering terrestrial planets like the Earth around stars other than the Sun. Learning about the diverse range of planetary systems that exist around other stars allows us to better understand our own place in the universe, and will reveal the extent of possible habitats for life elsewhere" - Dr David Pinfield.

The project is built on the team's international collaboration with leading research institutes in the UK (UH and Cambridge), Spain (Canary Islands and Madrid), Germany (Munich) and Ukraine (Kiev), and the space engineering company Astrium (based in Stevenage).
Over its four year life-time (Dec 2008 - Nov 2012) the project will employ fifteen young doctoral and postdoctoral researchers to carry out new research, work with industry on technology development, and receive training through a range of science and technology activities.
The network will specifically pursue extra-solar planets that transit (pass in-front of their host star during their orbit) - currently an extremely active area of astronomy. For cool stars this technique is sensitive to smaller planets that could be warm rocky worlds.
By exploiting new survey facilities that are being led by Dr Pinfield and his network, they aim to improve their understanding of the broad nature of extra-solar planet populations, and explore new extra-solar planet territory around the coolest stars in our galaxy. Intersectorial activities will be carried out jointly at UH and Astrium, and will centre on the European Space Agency's Cosmic Vision 2015-2025 programme to implement the next generation of space-based observatories.

"The project will thus be looking to the future as well as focussing on the ongoing search for and study of planets around other stars" - Dr David Pinfield.

Source: University of Hertfordshire

__________________


L

Posts: 131433
Date:
RE: Extrasolar Planets
Permalink  
 


We might soon get our first glimpse of a moon orbiting a planet in another solar system.
Little effort has so far been made to find such an 'exomoon'. Spotting other planets is hard enough; finding their moons is even harder.
But astronomer David Kipping of University College London has devised a way to spot the effects of a moon on the path of the planet it orbits.
The effect can be seen when the planet passes between us and its star. This is called a transit, and it is a common way of spotting exoplanets. If a planet has a moon, each transit has a slightly different position and velocity, creating a wobble in the planet's orbit.


Read more

__________________


L

Posts: 131433
Date:
Exomoons
Permalink  
 


Title: Transit timing effects due to an exomoon
Authors: David M. Kipping
(Version v2)

As the number of known exoplanets continues to grow, the question as to whether such bodies harbour satellite systems has become one of increasing interest. In this paper, we explore the transit timing effects that should be detectable due to an exomoon and predict a new observable. We first consider transit time variation (TTV), where we update the model to include the effects of orbital eccentricity. We draw two key conclusions: 1) In order to maintain Hill stability, the orbital frequency of the exomoon will always be higher than the sampling frequency. Therefore, the period of the exomoon cannot be reliably determined from TTV, only a set of harmonic frequencies. 2) The TTV amplitude is proportional to M_S a_S where M_S is the exomoon mass and a_S is the semi-major axis of the moon's orbit. Therefore, M_S and a_S cannot be separately determined. We go on to predict a new observable due to exomoons - transit duration variation (TDV). We derive the TDV amplitude and conclude that its amplitude is not only detectable, but the TDV signal will provide two robust advantages: 1) The TDV amplitude is proportional to M_S a_S^{-½} and therefore the ratio of TTV and TDV allows for a separate determination of M_S and a_S. 2) TDV has a 90 degrees phase difference to the TTV signal, making it an excellent complementary technique.

Read more (552kb,PDF )

__________________


L

Posts: 131433
Date:
RE: Extrasolar Planets
Permalink  
 


Four types of habitable planets proposed
The origin of life and the habitability of worlds other than Earth are two of the biggest mysteries facing science today. Much research has been dedicated to these topics, but there is still a lack of definite answers.
Jan Hendrik Bredehöft from the UK's Open University has been considering habitability on other worlds.

"I'm one of those guys who takes a piece of meteorite, grinds it up and finds out what the organic chemistry is in there" - Jan Hendrik Bredehöft.

Based on these types of studies, he has come to believe that habitable worlds can be split into four categories, each with varying likelihoods of being home to extraterrestrial organisms.

Read more

__________________


L

Posts: 131433
Date:
Hot Jupiters
Permalink  
 




This artist's animation shows first what a fiery hot star and its close-knit planetary companion might look like close up in visible light, then switches to infrared views. In visible light, a star shines brilliantly, overwhelming the little light that is reflected by its planet. In infrared, a star is less blinding, and its planet perks up with a fiery glow.
Astronomers using NASA's Spitzer Space Telescope took advantage of this fact to directly capture the infrared light of two previously detected planets orbiting stars outside our solar system. Their findings revealed the temperatures and orbits of the planets. Upcoming Spitzer observations using a variety of infrared wavelengths may provide more information about the planets' winds and atmospheric compositions.
In this animation, the colours represent real differences between the visible and infrared views of the system. The initial visible view shows what our eyes would see if we could witness the system close up. The hot star is yellow, because like our Sun, it is brightest in yellow wavelengths. The warm planet, on the other hand, is brightest in infrared light, which we can't see. Instead, we would see the glimmer of star light that the planet reflects.
In the second half of the animation, the colours reflect what our eyes might see if we could retune them to the invisible, infrared portion of the light spectrum. The hot star is less bright in infrared light than in visible and appears fainter. The warm planet peaks in infrared light, so is shown brighter. Their hues represent relative differences in temperature. Because the star is hotter than the planet, and because hotter objects give off more blue light than red, the star is depicted in blue, and the planet, red.
The overall look of the planet is inspired by theoretical models of hot, gas giant planets. These "hot Jupiters" are similar to Jupiter in composition and mass, but are expected to look quite different at such high temperatures. The models are courtesy of Drs. Curtis Cooper and Adam Showman of the University of Arizona, Tucson.

Credit: NASA/JPL-Caltech/R. Hurt (SSC)

__________________


L

Posts: 131433
Date:
Exomoons
Permalink  
 


Planetary wobbles could reveal alien moons
With over 300 exoplanets now known, the question as to whether such planets harbour moons as become increasingly asked. At the University College London, astronomers have now developed a new method for finding moons by watching the wobble of the host planet.
When an exoplanet transits, astronomers are afforded a brief snapshot of the planet's position and velocity. The presence of a moon around such a planet should cause the planet to wobble, resulting in both position and velocity varying over time. By watching multiple transits David Kipping, of the Dept. of Physics and Astronomy, has shown that these variations can be measured, producing a unique exomoon signature. Furthermore, this signal can be analysed to determine both the mass and distance of the moon from the planet. The UCL-based work also finds that current telescopes could find Earth-mass moons today and Titan-mass moons in the next few years.

The paper has been accepted for publication in the Monthly Notices of the Royal Astronomical Society.

Read more

__________________


L

Posts: 131433
Date:
Exoplanet moons
Permalink  
 


Moons outside our Solar System with the potential to support life have just become much easier to detect, thanks to research by an astronomer at University College London (UCL).
David Kipping has found that such moons can be revealed by looking at wobbles in the velocity of the planets they orbit. His calculations, which appear in the Monthly Notices of the Royal Astronomical Society today, not only allow us to confirm if a planet has a satellite but to calculate its mass and distance from its host planet ­ factors that determine the likely habitability of a moon.

Read more

__________________


L

Posts: 131433
Date:
HD189733b
Permalink  
 


Astronomers have detected water, and possibly even the first signs of weather, on a planet outside our Solar System. The gas giant, which orbits a star 63 light years from Earth, also has carbon dioxide and methane in its atmosphere, according to recent reports.
The planet, HD 189733b, is a 'hot Jupiter' - a gas giant that is in a closer orbit to its star than Jupiter is to the Sun, and so is hotter. To study the atmosphere of HD189733b, Carl Grillmair of the Spitzer Science Center in Pasadena, California, and his colleagues used the 'secondary eclipse' method to exclude light from the planet's star and record light from the planet alone.

Read more

__________________


L

Posts: 131433
Date:
RE: Extrasolar Planets
Permalink  
 


Title: The HARPS search for southern extra-solar planets. XVII. Super-Earth and Neptune-mass planets in multiple planet systems HD47186 and HD181433
Authors: F. Bouchy, M. Mayor, C. Lovis, S. Udry, W. Benz, J-L Bertaux, X. Delfosse, C. Mordasini, F. Pepe, D. Queloz, D. Segransan

This paper reports on the detection of two new multiple planet systems around solar-like stars HD47186 and HD181433. The first system includes a hot Neptune of 22.78 M_Earth at 4.08-days period and a Saturn of 0.35 M_Jup at 3.7-years period. The second system includes a Super-Earth of 7.5 M_Earth at 9.4-days period, a 0.64 M_Jup at 2.6-years period as well as a third companion of 0.54 M_Jup with a period of about 6 years. These detections increase to 20 the number of close-in low-mass exoplanets (below 0.1 M_Jup) and strengthen the fact that 80% of these planets are in a multiple planetary systems.

Read more (240kb, PDF)

__________________
«First  <  113 14 15 16 1745  >  Last»  | Page of 45  sorted by
Quick Reply

Please log in to post quick replies.



Create your own FREE Forum
Report Abuse
Powered by ActiveBoard