The Night Sky February 2007
Compiled by Ian Morison
This page, updated monthly, will let you know some of the things that you can look out for in the night sky. It lists the phases of the Moon, where you will see the naked-eye planets and describes some of the prominent constellations in the night sky during the month.
Image of the Month
Open Cluster NGC602 - click on image to download a full resolution version
Image: Hubble Heritage, NASA-ESA Collaboration
NGC602 - An open cluster in the Small Magellanic Cloud
This beautiful image from the Hubble Space Telescope shows an open cluster on the outskirts of the Small Magellanic Cloud (SMC)which is a daughter galaxy of our own Milky Way galaxy The image spans about 200 light-years across at the distance of the SMC of ~200 thousand light-years. Also visible in the image are a stunning array of galaxies - hundreds of millions of light years further away from us
The Moon
Third Quarter Moon - by Ian Morison using a 6" Maksutov-newtonian and Canon G6 camera.
| new | first quarter | full moon | last quarter |
|---|---|---|---|
| Feb 17th | Feb 24th | Feb 1st | Feb 7th |
Some Lunar Images by Ian Morison, Jodrell Bank Observatory: Lunar Images
Highlights of the Month
February 10th: 18:20 onwards:- See Saturn's rings increase in brightness.
Saturn imaged from Earth with an 11 inch telescope.
Image copyright: Damian Peach
To see more of Damian Peache's Images: Damian Peache's website
[This image is stunning and one of the best ever obtained from Earth. In my view it is better than those taken by the Hubble Space Telescope and the Very Large Telescope in Chile. Damian is almost certainly one of the best planetary imagers in the world today.]
Saturn is now rising in the eastern sky during the evening lying in the constellation of Leo It is at magnitude 0.0, so stands out amongst the stars - over to the left of Orion and below and to the left of Gemini.
As Saturn passes through opposition during the evening of February 10th you might like to try to observe the Seeliger Effect. This is a relative brightening of the rings relative to the disk when to Sun is directly behind the observer as happens at opposition. At this time each particle in the ring system presents a fully illuminated face to the observer with its shadow away from us and the particles, and hence the rings - will appear as bright as they can be. When the sunlight is from the side, then particles will drop shadows on others so the overall brightness is not as great.
February 8th - 11th Sunset - A great chance to spot Mercury
Sunset Venus and Mercury
The evenings from the 8th to the 11th of February will provide a good chance to see Mercury as it will lie between Venus, shining brightly in the West, and the point where the Sun has set. You will need to observe from a location with a good low western horizon. Get there before sunset which will be at about 5pm. Soon after you should be able to spot Venus up and to the south (left) of where the Sun has set. As the sky light gets darker Mercury should appear between Venus and the point where the Sun has set. Binoculars will initially help pick it up, but it should soon become visible to the unaided eye. Not visible to the eye, but just possibly in binoculars, Uranus lies halfway between the two.
Observe a White Dwarf
Eridanus
This is a good month to try to observe a White Dwarf star - the end state of a star like our own Sun. They are about the size of the Earth, but are very hot so can still appear reasonably bright. Omicron-2 is an orange star of magnitude 4.4 in the constellation Eridanus that lies to the right of Rigel. You will be able to pick this up with a pair of binoculars. However if you can use a small telescope with medium power you should spot a faint white 9th magnitude companion - a white dwarf. White dwarfs are very dense and a teaspoon full might weigh as much as a ton! Near the White Dwarf is an 11th magnitude "Red Dwarf" that might be spotted as well.
The Planets
A montage of the Solar System. JPL / Nasa
Jupiter
A Cassini image of Jupiter . Nasa
Jupiter, lying in the constellation Scorpius, passed behind the Sun during the early part of November but, at the beginning of February, rises at 4:22 am low in the south-east about 4 hours before the Sun. Jupiter will be a morning object for several months yet. Sadly, Jupiter now lies along the most southerly part of the ecliptic, and will never reach the high elevations in the sky that we have enjoyed in recent years so our views will be hindered by the atmosphere, but a small telescope will easily show the four Galilean moons as they weave from side to side. A trip to Hawaii would be just the ticket!
Saturn
The planet Saturn. Cassini - Nasa
Saturn is in the constellation Leo and about 7.5 degrees up and to the right of its brightest star Regulus at the start of February. It reaches "opposition" on the 10th February so will be due south around midnight and closest to us - so its angular size will be its maximum making it a great month during which to observe Saturn. It rises in the east north-east at ~ 5:45 pm as February starts and is due south and highest in the sky at ~ midnight. Its magnitude is ~ +0.0 and its globe subtends an angle of ~20 arc seconds. The rings are closing and are now about 13 degrees from edge-on, so Saturn is shining less brightly than during the previous few years whilst the rings have been more open. Saturn is still, however, a beautiful sight in a small telescope. A 4 to 6 inch telescope will also easily show Saturn's largest moon, Titan, and an 8 inch three or four more.
The image was taken as the Cassini spacecraft neared Saturn at the start of its exploration of the planet and its moons - particularly Titan.
Mercury
Mariner 10 composite image of Mercury. Nasa
Mercury passed behind the Sun on January 7th and was thus lost in the Sun's glare until the end of January. At the start of February it may be glimpsed in the western sky just after Sunset down to the lower right of Venus. It will increase in brightness from magnitude -0.9 on the first to 0.0 on the 11th (compared to that of Venus of -3.9) and binoculars will help to pick it out in the twilight. It will lie down to the lower right of Venus which will act as a great marker for it. It will pass in front of the Sun towards the end of February so will become very difficult to see after the 18th February. See highlight above
Note that the blank region in the image above is simply because this part of Mercury's surface has not yet been imaged in detail.
Mars
A Hubble Space Telescope image of Mars.
Jim Bell et al. AURA / STScI / Nasa
Mars reappeared in the pre-dawn sky at the very end of November and during December and January it gradually rose earlier than the Sun so became easier to see. At February's start it lies about two thirds of the way between The Sun and Jupiter and rises about 1 hour before the Sun. It will be at magnitude +1.4, but its disk will be just ~5 arc seconds across so no details will be seen on the salmon pink surface.
Venus
Venus showing some cloud structure
Venus is now beyond and on the eastern side of the Sun, becoming visible after sunset and setting an hour or so after the Sun. With a magnitude of -3.9 (brightening to -4 during the month) it can hardly be missed! At the beginning of February, Venus is 23 degrees away from the Sun but this increases during February so Venus sets later as the month progresses. As it is on the far side of the Sun from us we see it with a phase of 92 degrees at the state of February - not far from full - but with an angular size of only 11 arc seconds. As the months progress, the phase will reduce and the angular size will increase. This has the interesting consequence that the "apparent reflecting area" stays almost constant and hence the magnitude stays very close to -4 for quite a few months. It was the fact that Venus could show almost full phases that showed Galileo that Venus must orbit the Sun and hence the Copernican theory of ther Solar system must be correct.
Radar image showing surface features
Find more planetary images and details about the Solar System: The Solar System
The Stars
The Mid Evening February Sky
The February Sky in the south - mid evening.
This map shows the constellations seen in the south during the evening. The brilliant constellation of Orion is seen in the south. Moving up and to the right - following the line of the three stars of Orion's belt - brings one to Taurus; the head of the bull being outlined by the V-shaped cluster called the Hyades with its eye delineated by the orange red star Aldebaran. Further up to the right lies the Pleaides Cluster. Towards the zenith from Taurus lies the constellation Auriga, whose brightest star Capella will be nearly overhead. To the upper left of Orion lie the heavenly twins, or Gemini, their heads indicated by the two bright stars Castor and Pollux. Down to the lower left of Orion lies the brightest star in the northern sky, Sirius, in the consteallation Canis Major. Up and to the left of Sirius is Procyon in Canis Minor. Rising in the East is the constellation of Leo, the Lion, with the planet Saturn up and to the right of Regulus its brightest star. Continuing in this direction towards Gemini is the faint constellation of Cancer with its open cluster Praesepe (also called the Beehive Cluster),the 44th object in Messier's catalogue. On a dark night it is a nice object to observe with binoculars. There is also information about the constellation Ursa Major,seen in the north, in the constellation details below.
The constellation Taurus
Taurus
Taurus is one of the most beautiful constellations and you can almost imagine the Bull charging down to the left towards Orion. His face is delineated by the "V" shaped cluster of stars called the Hyades, his eye is the red giant star Aldebaran and the tips of his horns are shown by the stars beta and zeta Tauri. Although alpha Tauri, Aldebaran, appears to lie amongst the stars of the Hyades cluster it is, in fact, less than half their distance lying 68 light years away from us. It is around 40 times the diameter of our Sun and 100 times as bright.
AAO Image of the Pleiades, M45, by David Malin
To the upper right of Taurus lies the open cluster, M45, the Pleiades. Often called the Seven Sisters, it is one of the brightest and closest open clusters. The Pleiades cluster lies at a distance of 400 light years and contains over 3000 stars. The cluster, which is about 13 light years across, is moving towards the star Betelgeuse in Orion. Surrounding the brightest stars are seen blue reflection nebulae caused by reflected light from many small carbon grains. These relfection nebulae look blue as the dust grains scatter blue light more efficiently than red. The grains form part of a molecular cloud through which the cluster is currently passing. (Or, to be more precise, did 400 years ago!)
VLT image of the Crab Nebula
Close to the tip of the left hand horn lies the Crab Nebula, also called M1 as it is the first entry of Charles Messier's catalogue of nebulous objects. Lying 6500 light years from the Sun, it is the remains of a giant star that was seen to explode as a supernova in the year 1056. It may just be glimpsed with binoculars on a very clear dark night and a telescope will show it as a misty blur of light.
Lord Rosse's drawing of M1
Its name "The Crab Nebula" was given to it by the Third Earl of Rosse who observed it with the 72 inch reflector at Birr Castle in County Offaly in central Ireland. As shown in the drawing above, it appeared to him rather lile a spider crab. The 72 inch was the world's largest telelescope for many years. At the heart of the Crab Nebula is a neutron star, the result of the collapse of the original star's core. Although only around 20 km in diameter it weighs more than our Sun and is spinning 30 times a second. Its rotating magnetic field generate beams of light and radio waves which sweep across the sky. As a result, a radio telescope will pick up very regular pulses of radiation and the object is thus also known a Pulsar. Its pulses are monitored each day at Jodrell Bank with a 13m radio telescope.
The constellation Orion
Orion
Orion, perhaps the most beautiful of constellations, will be seen in the south at around 11 - 12 pm during January. Orion is the hunter holding up a club and shield against the charge of Taurus, the Bull up and to his right. Alpha Orionis, or Betelgeuse, is a read supergiant star varying in size between three and four hundred times that of our Sun. The result is that its brightness varies somewhat. Beta Orionis, or Rigel, is a blue supergiant which, at around 1000 light years distance is about twice as far away as Betelgeuse. It has a 7th magnitude companion. The three stars of Orion's belt lie at a distance of around 1500 light years. Just below the lower left hand star lies a strip of nebulosity against which can be seen a pillar of dust in the shape of the chess-board knight. It is thus called the Horsehead Nebula. It shows up very well photographically but is exceedingly difficult to see visually - even with relativly large telescope.
The Horsehead Nebula: Anglo Australian Observatory
Beneath the central star of the belt lies Orion's sword containing one of the most beautiful sights in the heavens - The Orion Nebula. It is a region of star formation and the reddish colour seen in photographs comes from Hydrogen excited by ultraviolet emitted from the very hot young stars that make up the Trapesium which is at its heart. The nebula, cradling the trapesium stars, is a beautiful sight in binoculars or, better still, a telescope. To the eye it appears greenish, not red, as the eye is much more sensitive to the green light emitted by ionized oxygen than the reddish glow from the hydrogen atoms.
The Orion Nebula: David Malin
The constellation Ursa Major
Ursa Major
The stars of the Plough, shown linked by the thicker lines in the chart above, form one of the most recognised star patterns in the sky. Also called the Big Dipper, after the soup ladles used by farmer's wives in America to serve soup to the farm workers at lunchtime, it forms part of the Great Bear constellation - not quite so easy to make out! The stars Merak and Dubhe form the pointers which will lead you to the Pole Star, and hence find North. The stars Alcor and Mizar form a naked eye double which repays observation in a small telescope as Mizar is then shown to be an easily resolved double star. A fainter reddish star forms a triangle with Alcor and Mizar.
Ursa Major contains many interesting "deep sky" objects. The brightest, listed in Messier's Catalogue, are shown on the chart, but there are many fainter galaxies in the region too. In the upper right of the constellation are a pair of interacting galaxies M81 and M82 shown in the image below. M82 is undergoing a major burst of star formation and hence called a "starburst galaxy". They can be seen together using a low power eyepiece on a small telescope.
M81 and M82
Another, and very beautiful, galaxy is M101 which looks rather like a pinwheel firework, hence its other name the Pinwheel Galaxy. It was discovered in1781 and was a late entry to Messier's calalogue of nebulous objects. It is a type Sc spiral galaxy seen face on which is at a distance of about 24 million light years. Type Sc galaxies have a relativly small nucleus and open spiral arms. With an overall diameter of 170,000 light it is one of the largest spirals known (the Milky Way has a diameter of ~ 130,000 light years).
M101 - The Ursa Major Pinwheel Galaxy
Though just outside the constellation boundary, M51 lies close to Alkaid, the leftmost star of the Plough. Also called the Whirlpool Galaxy it is being deformed by the passage of the smaller galaxy on the left. This is now gravitationally captured by M51 and the two will eventually merge. M51 lies at a distance of about 37 million light years and was the first galaxy in which spiral arms were seen. It was discovered by Charles Messier in 1773 and the spiral structure was observed by Lord Rosse in 1845 using the 72" reflector at Birr Castle in Ireland - for many years the largest telescope in the world.
M51 - The Whirlpool Galaxy
Lying close to Merak is the planetary nebula M97 which is usually called the Owl Nebula due to its resemblance to an owl's face with two large eyes. It was first called this by Lord Rosse who drew it in 1848 - as shown in the image below right. Planetary nebulae ar the remnants of stars similar in size to our Sun. When all possible nuclear fusion processes are complete, the central core collpses down into a "white dwarf" star and the the outer parts of the star are blown off to form the surrounding nebula.
M97 - The Owl Planetary Nebula Lord Rosse's 1848 drawing of the Owl Nebula
