PRESS RELEASE          Embargoed until April 15, 2004 17:00 GMT

April 2004

"Distant Planet Found by Gravitational Microlensing"

The most distant giant planet to orbit an ordinary star in the Milky Way
has been discovered by an international team of astronomers. This is the
first unequivocal planet discovery to be made by the gravitational
microlensing technique, which has the potential to extend our knowledge
of extra-solar planets to lower mass planets like Neptune and Earth.
Microlensing can also detect planets in the central region of our
Galaxy. This discovery is reported in a paper by jointly authored by the
MOA and OGLE collaborations, to appear in the May 10 issue of The
Astrophysical Journal Letters.

Gravitational microlensing is the newest concept for detecting planets,
having been first proposed by Bohdan Paczynski of Princeton University
and his student, Shude Mao, in 1991. This was two years before the first
reported microlensing events due to stellar mass objects by three
different groups, known as the OGLE, MACHO, and EROS collaborations.
Now, just over a decade later, the first discovery of an extra-solar
planet with the microlensing technique has been announced. Paczynski is
"thrilled as a theoretician to see the prediction come true: the first
definite detection of a planet through gravitational microlensing".

"The real strength of the microlensing technique is its ability to
detect low mass planets", said Ian Bond of the MOA Collaboration. The
MOA and OGLE groups expect that observations over the next few years
lead to the discovery of Neptune-mass planets in Jupiter-like orbits
around distant stars. The improved sensitivity required for such
discoveries is being made possible by the new large field-of-view
OGLE-III camera, the MOA-II 1.8m telescope which is now being built, and
improved cooperation between the different groups that observe
microlensing events. Earth-like planets are also detectable by
microlensing under favorable conditions. But to do a systematic study of
their abundance requires a space-based telescope, such as the proposed
Microlensing Planet Finder (MPF). "MPF would have the sensitivity to
detect planets like those in our own solar system with the exception of
Mercury and Pluto," said David Bennett (Notre Dame), the leader of the
MPF team. MPF could complete the census of Earth-like planets begun by
Kepler, a NASA mission in development, which can find Earth-like planets
at star-planet separations as large as the Earth-Sun distance.

This discovery was made possible only through the cooperation and
sharing of data between the competing MOA and OGLE groups. While such
cooperation among competitors is rare in many other fields, it is
becoming the norm among groups that observe microlensing events.
"Observations of microlensing events can be so time-critical that the
science would really suffer if we don't make our data available as
quickly as possible", said OGLE team-leader Andrzej Udalski of the
Warsaw University Observatory. The OGLE team has been the leader in this
cooperative mode of science, being the first to announce microlensing
events and release their measurements while the events are in progress.

The gravitational microlensing technique is able to detect a planet
through the effect of the planet's gravitational field on the light we
see from a more distant background star. The simple effect of
gravitational lensing of one star by another has now been detected more
than thousand times. When two stars are nearly perfectly aligned as seen
from Earth, the gravitational field of the foreground star acts as a
lens to magnify the background star. The magnified image is very small,
and can only be resolved with a telescope that produces images 1000
times sharper than the Hubble Space Telescope. Hence the term
"microlensing". Even so, the effect can be observed by the increased
brightness of the magnified star. It is only a temporary effect. The
orbital motion of the stars in the Galaxy will occasionally bring pairs
of stars into alignment as seen from Earth. Their continued motion will
then bring them out of alignment again and the microlensing effect
ceases.

Most of the one thousand microlensing events that have been observed
have followed a brightening pattern or "light curve" characteristic of a
lens composed of a single star. However, some have followed a very
different light curve caused by a lens composed of a double star. The
planetary microlensing event observed by the OGLE and MOA Collaborations
resembles the single lens light curve for most of its four-month
duration. But for a period of about a week, the gravitational field of
the planet causes the light curve to resemble that of a double star
lens.

The precise shape of the light curve reveals that the lighter mass of
the double lens has only 0.4% of the mass of the heavier component,
which implies that the lighter component must be a planet. Analysis of
the light curve revealed that it was most likely a red dwarf star and a
planet of about 1.5 times the mass of Jupiter at a separation of about 3
AU. (An Astronomical Unit, or AU, is the mean distance between the Earth
and Sun.) It was located about 17,000 light years away toward the
central part of the Galactic disk, in the constellation Sagittarius.

OGLE is a Polish/American OGLE project led by Udalski in Poland and
Paczynski in the US. It has operated continuously since 1992 at the Las
Campanas Observatory in Chile, which is operated by the Carnegie
Institution of Washington. They currently run the largest microlensing
survey in the world on the 1.3 meter Warsaw Telescope which enables them
to observe more than 150 million stars in the Galactic center every
night. The OGLE Project operation is funded by NASA and NSF grants in
the United States, and the Polish State Committee for Scientific
Research and Foundation for Polish Science grants.

The MOA Project is primarily a New Zealand/Japanese group led by Phil
Yock in New Zealand and Yasushi Muraki in Japan with collaborators in
the UK and US. It has a MOA member in Scotland, Ian Bond, who first
noticed the planetary feature in the light curve of the present event
and is the first author of the Astrophysical Journal Letters paper. A
quick response from Nagoya University graduate student, Tomohiro
Sekiguchi, who was on telescope duty at the time, enabled a critical
feature of the light curve to be observed. The MOA Project is supported
by the Marsden Fund in New Zealand, NASA and the NSF in the US, and the 
Ministry of Education, Culture, Sports, Science, and Technology (MEXT)
of Japan, and the Japan Society for the Promotion of Science (JSPS).

The gravitational microlensing technique is, in one sense, the easiest
way to detect extrasolar planets because the signal of the planet can be
quite large. For the present event, the maximum effect due to the planet
was more than a factor of two increase in the apparent brightness of the
background source star. In contrast, the radial velocity technique
requires the detection of Doppler shifts of one part in ten million.
Moreover, the critical data for the present event were obtained over a
period of only a couple of months. By contrast, many years of data by
the radial velocity technique would be required to detect a similar
planet.

The difficulty with the gravitational microlensing technique is that the
necessary alignment between pairs of stars is rare, so that many
millions of stars must be monitored to detect planets. Recent
developments in image analysis techniques have, however, made this task
quite manageable. 

The only other method that has been used to detect extrasolar planets
orbiting ordinary stars (besides radial velocities and microlensing) is
the transit technique which requires detection of a 1% variation in
brightness. The first planet discovery by the transit method was
initiated by photometry from the OGLE Collaboration, but follow-up
spectroscopic observations were needed to prove that the transit was due
to a planet.

The paper by the OGLE/MOA collaboration is available on the Internet at
arXiv.org/abs/astro-ph/XXXXXXX.

The OGLE Collaboration consists of: A. Udalski, B. Paczynski, M. Kubiak,
M. Szymanski, M. Jaroszynski, G. Pietrzynski, I. Soszynski, K. Zebrun,
O. Szewczyk and L. Wyrzykowski.

The MOA Collaboration consists of: F. Abe, D.P. Bennett, I.A. Bond, S.
Eguchi, Y. Furuta, J.B. Hearnshaw, K. Kamiya, P.M. Kilmartin, Y. Kurata,
K. Masuda, Y. Matsubara, Y. Muraki, S. Noda, K. Okajima, N.J.
Rattenbury, T. Sako, T. Sekiguchi, D.J. Sullivan, T. Sumi, P.J.
Tristram, T. Yanagisawa and P.C.M. Yock.

Contacts:

Japan:   Dr. Yasushi  Muraki

Solar-Terrestrial Environment  Laboratory

             Nagoya University

             Nagoya, 464-8601 Japan

             phone: 81 52 789 4314;

             email: muraki@stelab.nagoya-u.ac.jp

New Zealand: 

             Dr. Philip Yock

             Department of Physics

             University of Auckland

             Auckland, New Zealand

             phone: 64 9 3737599 ext 86838

             email: p.yock@auckland.ac.nz

Poland: Dr. Andrzej Udalski

             Warsaw University Observatory

             Al.  Ujazdowskie 4

             00-478 Warszawa, Poland

             phone: 48 22 6294011 ext. 116 

             email: udalski@astrouw.edu.pl

UK:      Dr. Ian Bond

             Institute for Astronomy

             University of Edinburgh

             Royal Observatory

             Edinburgh, Scotland 

             phone: 44 131 668 8329

             email: iab@roe.ac.uk

USA:    Dr. David Bennett

             Department of Physics

             University of Notre Dame

             225 Nieuwland Science Hall

             Notre Dame, IN 46556, USA

             phone: 1 574 631 8298

             email: bennett@nd.edu

             Dr. Bohdan Paczynski

             Department of Astrophysics

             Princeton University

             124 Peyton Hall

             Princeton, NJ 08544-1001

             phone: 609 258 3807

             email: bp@astro.princeton.edu

Figure 1: This Figure shows the geometry of a microlensing event in
which the almost perfect alignment between a background source star, a
lens star, and our observatory allow us to discover a planet that orbits
the lens star. Each panel represents a different time in the history of
the event, and time can be taken to run from either left to right or
right to left depending on the motion of the lens and source stars.  The
left and right panels show the usual case in which the alignment is not
good enough for the lens star or its planet to affect the light rays
that we see. The third and fourth panels (from the left) show the case
of lensing by a star: the light rays from the background source star are
bent so that two distorted images of star are visible. These images
cannot be resolved without a telescope with much sharper images than
HST, but the overall magnification of the images is visible as an
apparent brightening of the source star. The second panel shows the
configuration for a planet detection. One of the light rays that is bent
by the lens star's gravity comes close enough to the planet that it
feels the gravity of  the planet, too. This causes additional distortion
of the images, and in some cases, additional images can be created which
result in dramatic changes in brightness (the spikes seen in the
magnification curve).