{"id":62204,"date":"2024-07-31T12:00:33","date_gmt":"2024-07-31T12:00:33","guid":{"rendered":"http:\/\/3b75c68b-f619-49aa-8d52-93f641c5f9ca"},"modified":"2024-07-31T12:39:54","modified_gmt":"2024-07-31T12:39:54","slug":"the-summer-beehive-the-coathanger-and-dark-nebulae-6-binocular-night-sky-targets-for-august-2024","status":"publish","type":"rss_feed","link":"https:\/\/c01.purpledshub.com\/bbcskyatnight\/rss_feed\/the-summer-beehive-the-coathanger-and-dark-nebulae-6-binocular-night-sky-targets-for-august-2024\/","title":{"rendered":"The Summer Beehive, the Coathanger and dark nebulae: 6 binocular night-sky targets for August 2024"},"content":{"rendered":"

With binoculars you can see so much more in the night sky. Take our deep-sky tour and find out. <\/p>

By <\/p>

Published: Wednesday, 31 July 2024 at 12:00 PM<\/p>

\n\n

Whatever time of year you happen to be reading this, there are bound to be at least a few wonderful targets to see in the night sky tonight with binoculars.<\/p>

Indeed, there are hundreds of astronomical bodies that a pair of binoculars will bring into view for you.<\/p>

Not only will binoculars let you see many more objects than you can with the naked eye, but the detail and colour in those objects become a lot richer.<\/p>

With binoculars, the Coathanger asterism<\/a> in Vulpecula actually looks like a coathanger and the Orion Nebula<\/a> becomes a fantastically detailed painting of light.<\/p>

The Coathanger by Jos\u00e9 J. Chamb\u00f3, Hoya Redonda, Valencia, Spain. Equipment: GSO 8″ f\/3.8, Canon EOS-100D<\/figcaption><\/figure>
The Milky Way<\/a> is no longer a tenuous glowing band, but a knotted tangle of stars, interspersed with mysterious dark patches.<\/p>
Albireo<\/a> goes from being an ordinary-looking star that marks the head of Cygnus<\/a> to an exquisite binary juxtaposition of gold and sapphire.<\/p>
And you can easily see galaxies<\/a> by the light that left them millions of years ago, when our ancestors were thinking about leaving the trees.<\/p>
$\"Double$
Double star Albireo by Tony Moss, Downham Market, Norfolk<\/figcaption><\/figure>
Binoculars are still suitable even if you want to do \u2018serious\u2019 astronomy.<\/p>
There are variable star<\/a> observing programmes specifically for binoculars, and their portability makes them ideal for taking to the narrow track where a lunar graze or asteroid occultation<\/a> is visible.<\/p>
Alternatively, you could wrap up warm, lie back on your garden recliner and just enjoy the objects that the binoculars let you find as you cast your gaze among the stars.<\/p>
Before you even realise it, you have begun to learn the sky and you\u2019ll soon be able to navigate around it better than the entry-level Go-To telescope you nearly bought instead.<\/p>
Best of all, you can have this complete observing system for two eyesfor less than the price ofone reasonably good telescope eyepiece.<\/p>
$\"A$
A pair of binoculars may be all you need to get started in astronomy. Credit: VW Pics\/Contributor \/ Getty Images<\/figcaption><\/figure>
In this guide we’ll go through 6 wonderful targets that are visible in the night sky through binoculars.<\/p>
We’ll update the guide every month so you always have something new to observe, and as this archive grows you can scroll back through previous years of the current month and try and find those targets too.<\/p>
Each binocular tour is made all the easier by **downloading our PDF charts, the links for which you can find just at the top of each section below.<\/strong><\/p>**
**The tour charts are black on white, so you can read it under red light and avoid spoiling your night vision.<\/p>**
**For more advice, read our guide to** **stargazing with binoculars<\/a>, our pick of the best binoculars for astronomy<\/a> and the best budget binoculars<\/a>.<\/strong><\/em><\/p>**
**6 binocular night-sky targets for August 2024<\/strong><\/h2>** $\"The$
The Coathanger cluster. Credit: Jos\u00e9 J. Chamb\u00f3<\/figcaption><\/figure>
**Download our** **August 2024 binocular tour form (PDF)<\/a><\/strong><\/em><\/p>**
**1 – Poniatowski\u2019s Bull<\/strong><\/h3>**The uppercase V formed by the fourth- and fifth-magnitude stars 66, 67, 68, 70 and 73 Ophiuchi is reminiscent of the Hyades cluster<\/a> in Taurus. This led the 18th-century astronomer Marcin Odlanicki Poczobutt to propose it as a new constellation, Taurus Poniatovii, to honour Stanislaus Poniatowski, then king of Poland. Your binoculars will reveal many dozens more stars in this rich open cluster, more formally known as Melotte 186.<\/p>
**2 – The Summer Beehive\u00a0<\/strong><\/h3>**Locate mag. +2.7 Cebalrai (Beta (\u03b2) Ophiuchi) and you\u2019ll see IC 4665 in the same field of view, looking like a slightly smaller version of Praesepe (the Beehive Cluster<\/a>) just over 1\u00b0 northeast of the star. Your 10x50s should reveal curved chains of white stars forming the word \u2018HI\u2019, as this lovely cluster literally welcomes you to this beautiful region of sky. How many more stars can you count?<\/p>
3 – NGC 6633<\/strong><\/h3>
From IC 4665, turn 10\u00b0 east to NGC 6633. This lovely little cluster is often overlooked in lists of binocular objects because it can be tricky to find, but it\u2019s easily visible in a pair of 10x50s, with the four brightest stars shining against the 20-arcminute elongated glow of the unresolved fainter cluster stars. If you compare it to the Summer Beehive, you will see that its stars are yellower, and therefore older.<\/p>
4 – Graff\u2019s Cluster<\/strong><\/h3>
From NGC 6633, pan 3\u00b0 in the direction of mag. +4.6 Alya (Theta (\u03b8) Serpentis), where you will find a misty patch just over 1\u00b0 in diameter. This is Graff\u2019s Cluster, IC 4756. It\u2019s an enormous grouping of stars, over 20 lightyears across and approximately 1,300 lightyears away. You can hold it and NGC 6633 in the same field of view, as a simple demonstration of how different similarly-aged clusters can appear.<\/p>
5 – Barnard\u2019s E<\/strong><\/h3>
Find mag. +2.7 Tarazed (Gamma (\u03b3) Aquilae) and look 1\u00b0 west of it. Dark nebulae B142 and B143 are usually easy to identify because of the rich Milky Way starfield against which they lie. These accumulations of obscuring dust manifest as an uppercase \u2018E\u2019 or an underlined \u2018C\u2019, depending on sky transparency. If you can see only one sooty bar, you have the middle one; averted vision should reveal the others.<\/p>
6 – The Coathanger, Al Sufi\u2019s Cluster<\/strong><\/h3>
In his AD 964 Book of Fixed Stars<\/em>, Abd al-Rahman al-Sufi recorded the cluster that bears his name. It lies 5\u00b0 south of mag. +4.4 Anser (Alpha (\u03b1) Vulpeculae). In this relatively dark part of the Milky Way there\u2019s enough contrast for even quite small binoculars to reveal the 10 brightest stars whose pattern bestows its informal name, the Coathanger.<\/p>
**6 binocular night-sky targets for July 2024<\/strong><\/h2>** $\"M17,$
M17, The Swan Nebula by Ron Brecher, Guelph, Ontario, Canada.<\/figcaption><\/figure>
**Download our** **July 2024 binocular tour form (PDF)<\/a><\/strong><\/em><\/p>**
1 – The Scutum Star Cloud<\/strong><\/h3>
This fabulously rich star cloud is so easy to find that it has been mistaken for a real cloud on a clear night. Once you have it in your binoculars, look for the ripples of stars formed by the tenuous dark nebulae that weave among them. You will also see the densest of all open clusters, M11, the Wild Duck Cluster, which is an even richer condensation of nearly 3,000 hot blue stars.\u00a0<\/p>
**2 – The Swan Nebula, M17<\/strong><\/h3>**Use the chart to help you identify Gamma (\u03b3) Scuti, then pan 2.5\u00b0 to the southwest where you will find the misty patch that Charles Messier<\/a> described as \u201ca train of light without stars, in the shape of a spindle, of five or six minutes in extent\u201d. If you use averted vision, you may be able to make out a small hook-like extension extending south from the top right-hand side of the patch.<\/p>
3 – M22<\/strong><\/h3>
Next, the largest globular cluster visible from the UK. To find M22, put mag. +2.8 Kaus Borealis (Lambda (\u03bb) Sagittarii), the top of the \u2018lid\u2019 of the Teapot asterism in Sagittarius, at the south-west of the field of view. M22 should be obvious near the centre. It shows a bright core, very much like a comet, making it clear why Charles Messier compiled his catalogue of objects that were not to be mistaken for comets.<\/p>
4 – 52 and 53 Sagittarii<\/strong><\/h3>
We\u2019ll continue the tour with two easy line-of-sight (that is, not true binary) double stars. The first is a white pair, mag. +4.6 52 Sagittarii and mag +5.6 51 Sagittarii, which are 13 arcminutes apart. The 53 Sagittarii pair is fainter, closer and displays more of a colour contrast. 53 Sagittarii shines at mag.+6.3, a third of a magnitude fainter than its orange companion, 4 arcminutes to the east.<\/p>
5 – The Butterfly Cluster, M6<\/strong><\/h3>
This lovely open cluster is visible to the naked eye in a clear sky, but we are using binoculars because it is very low in the southern sky, so you\u2019ll need a pristine southern horizon if you are to see a hint of the wings and antennae that give it its common name. You\u2019ll find it in a sparse patch of the Milky Way, around 6\u00b0 west of mag. +3.0 Alnasl (Gamma^{2<\/sup> (\u03b3^{2<\/sup>) Sagittarii).<\/p>}}
6 – Ceres<\/strong><\/h3>
This apparition of asteroid Ceres is at its brightest (mag. +7.5) in early July, when you\u2019ll find it 1.5\u00b0 south of mag. +3.3 Tau (\u03c4) Sagittarii. It fades by a little more than half a magnitude during the month as it moves 6\u00b0 west into the lower part of Sagittarius\u2019s Teapot. Ceres was discovered on the first day of 1801 at the Palermo Observatory and named for the patron goddess of Sicily.<\/p>
**6 binocular night-sky targets for June 2024<\/strong><\/h2>** $\"Bode\u2019s$
Bode\u2019s Galaxy and the Cigar Galaxy, by Matt Baker, Ashbourne, 30 March 2019<\/figcaption><\/figure>
**Download our** **June 2024 binocular tour form (PDF)<\/a><\/strong><\/em><\/p>**
**1 – M81\/82 galaxy pair<\/strong><\/h3>**This month we\u2019ll tour the north polar region of the sky, starting with the galaxy pair M81 (Bode\u2019s Galaxy) and M82 (the Cigar Galaxy)<\/a>. Use the chart to identify mag. +4.6 24 Ursae Majoris and you should be able to get the galaxies in the same field of view. You can use them to demonstrate averted vision<\/a>: concentrate your gaze on one of them and the other will appear to brighten and grow.<\/p>
2 – Kappa Dra group<\/strong><\/h3>
We move on to a lovely little line of coloured stars. The brightest of these is the hot (14,000K) blue-whitemag. +3.9 Kappa (\u03ba) Draconis, shining with a luminosity 500 times greater than the Sun. North of it you\u2019ll see two orange stars, the brighter of which is mag. +4.9 6 Draconis. At the other end of this line of four you\u2019ll find the reddish 4 Draconis, a long-period pulsating variable (mag. +4.9 to +5.0).<\/p>
3 – Polaris \u2018Engagement Ring\u2019\u00a0<\/strong><\/h3>
Mag. + 2.0 Polaris (Alpha (\u03b1) Ursae Minoris) is a useful marker for the North Celestial Pole (NCP), but binoculars reveal that it\u2019s not alone, but part of a circlet of mostly eighth- and ninth- magnitude stars, like a solitaire diamond in an engagement ring. One star in the circlet is slightly displaced away from Polaris, which bisects the line joining it and the NCP, enabling a precise determination of the pole\u2019s location.<\/p>
**4 – The Guardians of the Pole\u00a0<\/strong><\/h3>**After Polaris, the next brightest stars in Ursa Minor are the southernmost stars of the Little Dipper: orange mag. +2.0 Kochab (Beta (\u03b2) Ursae Minoris) and brilliant-white mag. +3.0 Pherkad<\/a> (Gamma (\u03b3) Ursae Minoris). From our latitude, they\u2019re circumpolar and have traditionally been called the Guardians of the Pole. Pherkad is an easy double, with fifth-magnitude pale orange Gamma^{1<\/sup> (\u03b3^{1<\/sup>) Ursae Minoris17 arcminutes to the west.<\/p>}}
**5 – Kemble 2<\/strong>\u00a0<\/h3>**Find mag. +3.6 Chi (\u03c7) Draconis, then navigate 1\u00b0 east where you\u2019ll see a little equilateral triangle of seventh-magnitude stars. Look carefully to see a pair of fainter stars that complete a trapezium, of which the triangle is a part, forming a \u2018W\u2019 with the fainter stars at the tips. This similarity to the \u2018W\u2019 of Cassiopeia<\/a> gives the group it\u2019s common names, Mini-Cass or the Little Queen.<\/p>
**6 – The Iris Nebula<\/strong><\/h3>**Take a line from mag. +3.2 Errai (Gamma (\u03b3) Cephei) to the sapphire-blue mag. +3.2 Alfirk (Beta (\u03b2) Cephei) and extend it a further 3\u00b0, you will find a mag. +6.9 star. Half a degree west of this star is a mag. +7.4 star. Centre this star and use averted vision and patience. Surrounding the star, you should begin to notice the faint glow of NGC 7023, the Iris Nebula<\/a>, a few arcminutes across.<\/p>
**6 binocular night-sky targets for May 2024<\/strong><\/h2>** $\"Stars$
Stars Mizar and its fainter companion Alcor can be located in the Plough. Credit: Christophe Lehenaff \/ Getty Images<\/figcaption><\/figure>
**Download our** **May 2024 binocular tour form (PDF)<\/a><\/strong><\/em><\/p>**
1 – Mizar and Alcor<\/strong><\/h3>
In the days before Herman Snellen introduced his eponymous eye-test chart, mag. +2.2 Mizar (Zeta (\u03b6) Ursae Majoris) and mag. +4.0 Alcor (80 Ursae Majoris) were used as an eyesight test: if you couldn\u2019t see two stars, you knew you needed spectacles.<\/p>
They are, of course, easy to split in binoculars and these also reveal a fainter (mag. +7.6) companion that makes the southeast apex of a triangle with Alcor and Mizar<\/a>.<\/p>
2 – V Canum Venaticorum<\/strong><\/h3>
Half-way between mag. +1.9 Alkaid (Eta (\u03b7) Ursae Majoris) and mag. +2.9 Cor Caroli (Alpha (\u03b1) Canum Venaticorum) lies a pair of sixth-magnitude stars about 0.25\u00b0 apart.<\/p>
From there, pan 1.5\u00b0 towards 21 Canum Venaticorum where you should find, shining somewhere between mag. +8.5 and +6.5, V Canum Venaticorum. It\u2019s often described as a periodic variable, but both its range and period have fluctuated wildly in recent years.<\/p>
3 – La Superba<\/strong><\/h3>
Locate mag. +4.2 Chara (Beta (\u03b2) Canum Venaticorum) and pan 4.5\u00b0 towards Mizar to find a pale orange star (it looks a deeper orange in larger apertures). This is Y Canum Venaticorum, a cool carbon star whose magnitude varies from +6.3 to +4.7, with a period of about 160 days.<\/p>
Its common name, La Superba, was given on account of its unusual spectrum, in which absorption lines attenuate much of the short wavelength light.<\/p>
4 – 15 and 17 Canum Venaticorum<\/strong><\/h3>
Navigate a little more than 2.5\u00b0 east from Cor Caroli, where you\u2019ll find a widely separated (4.6 arcminutes) pair of stars, mag. +6.3 15 and mag. +5.9 17 Canum Venaticorum. This is not a binary star, but merely a line-of-sight pairing that shows how distance affects magnitude: although 17 appears to usas the brighter of the pair, 15 is six times as far and 25 times as bright as 17.<\/p>
5 – M106<\/strong><\/h3>
You\u2019ll need a dark, transparent sky for this galaxy. Find the orange star mag. +5.3 3 Canum Venaticorum, which makes the right angle of a triangle with Chara and mag. +3.7 Chi (\u03c7) Ursae Majoris. Slightly more than 1.5\u00b0 south of this is a small, faint glow.<\/p>
This is the 22-million-year-old light from the nucleus of M106. Try using averted vision to see it elongate from southeast to northwest.<\/p>
6 – M51, the Whirlpool Galaxy<\/strong><\/h3>
Our next galaxy is a bit brighter and is very easy to find. Imagine that a line from Mizar to Alkaid is the upright of a letter \u2018L\u2019. M51 lies at the \u2018toe\u2019 of this \u2018L\u2019, 3.5\u00b0 from Alkaid.<\/p>
You\u2019ll see the glow of the 25 billion suns that comprise the Whirlpool Galaxy, 20 million lightyears away. Any elongation you see is due to NGC 5195, the smaller galaxy with which the main face-on spiral is interacting.<\/p>
**6 binocular night-sky targets for April 2024<\/strong><\/h2>** $\"M13,$
M13, The Great Hercules Cluster, by Patrick Cosgrove<\/figcaption><\/figure>
**Download our April 2024 binocular tour form (PDF)<\/a><\/strong><\/em><\/p>**
**1 – M13, the Great Cluster in Hercules<\/strong><\/h3>**As we approach the season for trying a Messier marathon, M13 reminds us why Charles Messier created his famous catalogue of objects not to be mistaken for comets, known as the Messier Catalogue<\/a>.<\/p>
The great Hercules globular cluster<\/a> lies one-third of the way down the western side of the Keystone asterism. In binoculars, it looks just like a comet, brightening towards the core. You might even be able to see it with your naked eye in very transparent skies.<\/p>
2 – Nu Coronae Borealis<\/strong><\/h3>
Nu (\u03bd) Coronae Borealis appears as a double to your naked eye and is therefore easily split in small binoculars. The stars of this optical double (a chance line-of-sight pairing of stars that are not gravitationally bound) are both giants of about 2.5 solar masses.<\/p>
Although the brighter star, mag. +5.2 Nu^{1<\/sup> (\u03bd^{1<\/sup>), is more distant, it\u2019s at a later stage of evolution and therefore more luminous than mag. +5.4 Nu^{2<\/sup> (\u03bd^{2<\/sup>).<\/p>}}}}
3 – Tau Coronae Borealis group<\/strong><\/h3>
Navigate 4\u00b0 northwest from Nu (\u03bd) Coronae Borealis to find mag. +4.7 Tau (\u03c4) Coronae Borealis, the brightest star in a very pretty, straight chain of five stars running east\u2013west for 2.6\u00b0.<\/p>
All but the central star, a mag. +7.4 triple star resolvable in binoculars, shine brighter than magnitude +6, and binoculars reveal their colours. Notice that the mag. +5.6 stars at the ends of the chain are a deeper yellow than the others.<\/p>
4 – R Coronae Borealis<\/strong><\/h3>
Lying in the middle of the Northern Crown, R Coronae Borealis usually shines at mag. +5.9, but the brightness of this enigmatic variable star randomly plummets as low as mag. +15, like a reverse nova.<\/p>
It does this very quickly, so it\u2019s worth observing the star on every clear night. R Coronae Borealis periodically puffs out jets of carbon which, if they are in line of sight with us, obscure this \u2018sooty\u2019 carbon star.<\/p>
5 – Delta Bo\u00f6tis<\/strong><\/h3>
Mag. +3.5 Delta (\u03b4) Bo\u00f6tis is a very easy double. The primary is a deep-\u200byellow giant nearly 60 times more luminous than the Sun. Its mag. +7.8 companion, 105 arcseconds to the east, is slightly paler.<\/p>
At 117 lightyears distance from us, that 105 arcseconds translates to an enormous 0.6 lightyears apart. At that separation, the orbital period of this binary system is about 120,000 years.<\/p>
6 – RV Bo\u00f6tis<\/strong><\/h3>
The reddish variable (mag. +7.2 to +8.7) star RV Bo\u00f6tis is a little more than 2.5\u00b0 northeast of mag. +3.6 Rho (\u03c1) Bo\u00f6tis, in between two mag +6.3 stars, the brightest in the field of view.<\/p>
RV Bo\u00f6tis is a semi-regular variable with a period of 288 days. The Sun will eventually become like RV Bo\u00f6tis, with an inert core surrounded by helium- and hydrogen-burning shells within a hydrogen envelope.<\/p>
**6 binocular night-sky targets for March 2024<\/strong><\/h2>** $\"Close-up$
Close-up of globular cluster M3. Credit: Vitali Pelenjow<\/figcaption><\/figure>
**Download our March 2024 binocular tour form (PDF)<\/a><\/strong><\/em><\/p>**
1 – Melotte 111<\/strong><\/h3>
We\u2019ll start with a favourite \u2018made for binoculars\u2019 target. Look midway between mag. +2.9 Cor Caroli (Alpha (\u03b1) Canum Venaticorum) and mag. +2.1 Denebola (Beta (\u03b2) Leonis) and you should see a misty patch about 6\u00b0 across.<\/p>
Your 10x50s will resolve it into 30 or more stars, all of which are mag. +10.5 or brighter; any fainter ones have been gravitationally ejected from the cluster by a process called mass segregation.<\/p>
2 – M53<\/strong><\/h3>
A degree northeast of mag. +4.9 Diadem (Alpha (\u03b1) Comae Berenices), there\u2019s a small misty patch that appears to grow in size and brightness if you centre it in the field of view but look at Diadem.<\/p>
This is the globular cluster M53, and the trick you used to make it grow is averted vision, which puts the light from the object onto a more sensitive part of your retina. We\u2019ll use it later for galaxy hunting.<\/p>
3 – M3<\/strong><\/h3>
Our next target is one of the finest globular clusters in the northern sky, but there are no nearby bright stars to help you find it. However, if you look half-way between mag. \u20130.1 Arcturus (Alpha (\u03b1) Bo\u00f6tis) and Cor Caroli, you should find what looks like an out-of-focus star.<\/p>
Use averted vision and you will see more of the glow of the nearly half-million stars that comprise M3, discovered by Charles Messier in 1764.<\/p>
4 – M94<\/strong><\/h3>
Return to Cor Caroli and imagine a line between it and mag. +4.2 Chara (Beta (\u03b2) Canum Venaticorum). From half-way along this line, navigate 1.6\u00b0 to the northeast. Here, possibly needing averted vision at first, you should find the 13.6-million-year-old glow of light from the spiral galaxy M94.<\/p>
Like all galaxies, it benefits greatly from dark, transparent skies, but it is usually quite easy to see even in suburban skies.<\/p>
5 – M49<\/strong><\/h3>
Locate mag. +4.9 Rho (\u03c1) Virginis and place it on the northeast of your field of view. On the opposite side you\u2019ll see two sixth-magnitude stars, just over a degree apart and orientated southeast\u2013northwest.<\/p>
The 37-million-year-old fossil light from M49 is the small, oval patch between them. Using averted vision, see how many more galaxies you can find between M49 and Melotte 111.<\/p>
**6 – 86 Leonis star field\u00a0<\/strong><\/h3>**Let\u2019s finish with a colourful star field. Locate the orange-yellow mag +5.6 86 Leonis between Denebola and mag. +2.6 Zosma<\/a> (Delta (\u03b4) Leonis); compare it to brilliant-white mag. +6.3 90 Leonis, 2\u00b0 back towards Denebola.<\/p>
Find the curved string of multi\u00adcoloured seventh and eighth-magnitude stars that extends 3\u00b0 eastward from 86 Leo. Scan northeast of here too, if you like colourful stars.<\/p>
**6 binocular night-sky targets for February 2024<\/strong><\/h2>** $\"M48.$
M48. Credit: Michael Breite, Stefan Heutz, Wolfgang Ries, CCDGuide.com<\/figcaption><\/figure>
**Download our** **February 2024 binocular tour form (PDF)<\/a><\/strong><\/em><\/p>**
1 – The Hydra\u2019s Head<\/strong><\/h3>
The one immortal head of the Hydra, the longest constellation, is defined by six stars, but only the faintest, mag. +4.4 Sigma (\u03c3) Hydrae, retains a name \u2013 Minchir (the nostril) \u2013 that relates to Heracles\u2019s nine-headed nemesis.<\/p>
Binoculars enable you to enjoy the wide variation in colours, from the intense white of mag. +4.3 Eta (\u03b7) Hydrae to the yellow-orange of mag. +3.1 Zeta (\u03b6), the brightest of the six.<\/p>
2 – The Missing Messier, M48\u00a0<\/strong><\/h3>
It was 12 years after Charles Messier incorrectly catalogued the position of M48 that Caroline Herschel rediscovered it, but it took over a century and a half for astronomers to realise she\u2019d found the object that matched Messier\u2019s description.<\/p>
Find this open cluster 3\u00b0 southeast of mag. +4.4 Zeta (\u03b6) Monocerotis, as a condensed patch of stars of which you can resolve a few brighter members against a rich background glow.<\/p>
3 – M50<\/strong><\/h3>
Use the chart at the link above to locate M50, an obvious circular glow about half the apparent diameter of the Moon. This 78-million-year-old cluster lies 3,200 lightyears away and measures about 20 lightyears across.<\/p>
The glow comes from a little more than 100 stars, but don\u2019t expect to resolve more than four or five of them in 10×50 binoculars, the number depending on the darkness and transparency of your sky.<\/p>
4 – 14 CMi \u00a0<\/strong><\/h3>
Mag. +5.3 14 Canis Minoris is the middle star in a slightly curved line of three in the southeast of Canis Minor. This deserves a closer look, ideally using larger binoculars, which will show you that it\u2019s actually a triple star, with two very much fainter companions.<\/p>
The brighter one (mag. +9.4) lies 102 arcseconds to the east, and the other (mag. +9.8) is 137 arcseconds to the southeast of 14 CMi.<\/p>
5 – The Beehive Cluster (M44) and the Manger<\/strong><\/h3>
Named by the ancient Greeks as Nephelion, the Little Cloud, M44 is an ideal object for binoculars. It is framed by an asterism of four bright stars known as Praesepe (the Manger), and is visible to the naked eye as a misty patch just north-northeast of mag. +3.9 Asellus Australis (Delta (\u03b4) Cancri).<\/p>
It is one of the nearest open clusters and contains over 1,000 stars.<\/p>
6 – Iota Cancri<\/strong><\/h3>
You should be able to identify this month\u2019s tricky target, mag. +4.0 double star Iota (\u03b9) Cancri, with your naked eye. Its primary member is a yellow giant and its secondary is a mag. +6.0 white dwarf, 30 arcseconds to the northwest.<\/p>
The magnification of 15x70s will help you split this true binary star, which has an orbital period of 65,000 years.<\/p>
**6 binocular night-sky targets for January 2024<\/strong><\/h2>** $\"M79.$
Globular cluster M79. Credit: Harald Strau\u00df<\/figcaption><\/figure>
**Download our January 2024 binocular tour form (PDF)<\/a><\/strong><\/em><\/p>**
1 – The Stream<\/strong><\/h3>
Let\u2019s start the tour 6\u00b0 to the west of mag. +3.3Mu (\u00b5) Leporis, where you\u2019ll find the orange mag. +5.0 60 Eridani at the north of a 4.5\u00b0 chain of stars.<\/p>
Follow the chain through yellow 59 and 58 Eridani, via a white star, to the reddish mag. +4.3 54 Eridani, the brightest star in the group. On a transparent night, see how many fainter stars you can see, especially near the top of the chain.<\/p>
**2 – Iota and RX Leporis<\/strong><\/h3>**Nearly 4\u00b0 south of mag. +0.3 Rigel<\/a> (Beta (\u03b2) Orionis) lies mag. +4.5 Iota (\u03b9) Leporis, a brilliant-white star that contrasts beautifully with the fainter reddish star RX Leporis that lies 0.25\u00b0 to the west of it.<\/p>
RX Leporis is slightly variable, oscillating between magnitudes +5.1 and +6.7 over a period of 79.5 days, but this main period is overlaid by longer periods and it is classified as an \u2018unsolved\u2019 semi-regular variable.<\/p>
3 – Zibal<\/strong><\/h3>
The pure-white mag. +4.8 Zibal (Zeta (\u03b6) Eridani) should be just visible to your naked eye if your southern aspect is good. It\u2019s part of a wide pair, the other member being mag. +6.1 14 Eridani (mag. +6.1), 0.5\u00b0 to the south-east.<\/p>
Close examination will reveal another companion northwest of Zibal, a mere 5 arcminutes away, shining at mag. +6.6. Both of these companions are line-of-sight associations.<\/p>
4 – 62 Eridani\u00a0<\/strong><\/h3>
Use the chart to identify mag. +2.7 Cursa (Beta (\u03b2) Eridani). Linger for a while, taking time to appreciate its rich and colourful stellar environment, before heading 3\u00b0 due west to the brilliant blue-white magnitude +5.5 62 Eridani.<\/p>
This can be a tricky double star, not because of the separation, which is a substantial 66 arcseconds, but because the line of sight companion is so much fainter (mag. +8.9) than 62 Eridani.<\/p>
5 – CV Eridani<\/strong><\/h3>
In the northwest corner of Eridanus lies a little triangle of stars that covers about the same amount of sky as the Moon. The most easterly of these is mag. +6.1 7 Eridani, also designated CV Eridani.<\/p>
\u2018CV\u2019 indicates that it\u2019s a variable star, but the reason for its inclusion here is the beautiful contrast of its redness against the whiteness of the other two stars in the triangle.<\/p>
6 – M79<\/strong><\/h3>
Identify mag. +2.6 Arneb (Alpha (\u03b1) Leporis) and mag. +2.8 Nihal (Beta (\u03b2) Leporis) and mag. +3.6 Gamma (\u03b3) Leporis. Extend a line from Arneb to Nihal southwards for just over 4\u00b0, where you will find a mag. +5.4 star.<\/p>
Without looking away from this star, turn your attention to a spot about 0.5\u00b0 away in the direction of Gamma. What looks like a faint fuzzy star is the globular cluster<\/a> M79.<\/p>
**6 binocular night-sky targets for December 2023<\/strong><\/h2>** $\"hyades$
The Hyades open cluster. Credit: Pete Lawrence<\/figcaption><\/figure>
**Download our** **December 2023 binocular tour form (PDF)<\/a><\/strong><\/em><\/p>**
**1 – The Hyades<\/strong><\/h3>**The Hyades cluster is next to mag. +1.0 Aldebaran<\/a> (Alpha (\u03b1) Tauri), the reddish eye of the Bull, which is not part of the cluster but a foreground star. The cluster is only 153 lightyears away, making it the nearest open cluster to us.<\/p>
In mythology, the Hyades were the daughters of Atlas, and their weeping for their brother Hyas, who was slain by a lion, is the rain that is associated with their heliacal setting in spring.<\/p>
2 – NGC 1647<\/strong><\/h3>
About 3\u00b0 northeast of Aldebaran is a lovely little cluster, NGC 1647, often ignored because of the presence of its more prominent neighbour.<\/p>
With 10x50s you should be able to see eight or nine stars against a background glow about one and a half times the apparent size of the Moon. It\u2019s actually twice the size of the Hyades, but nearly 12 times the distance, which is why it seems so smallin comparison.<\/p>
3 – NGC 1662<\/strong><\/h3>
Switch to larger binoculars for our next target, 6.25\u00b0 from Aldebaran in the direction of mag. +0.3 Rigel (Beta (\u03b2) Orionis). In 15×70 binoculars, NGC 1662 appears as a complex winding string of stars against an elliptical background glow.<\/p>
With a core of about 10 lightyears diameter, it\u2019s approximately the same size as the Hyades, but is nearly 10 times as far away.<\/p>
**4 – Collinder 70<\/strong><\/h3>**Most amateur astronomers have seen Collinder 70 without realising it: it\u2019s the oval-shaped group of very young bluish-white stars that surrounds the Belt stars of Orion<\/a>.<\/p>
On a clear night, you should be able to see at least 70 stars in this magnificent cluster. They form some beautiful curved chains, in particular the S-shaped chain that weaves its way between mag. +1.8 Alnilam (Epsilon (\u03b5) Orionis) and mag. +2.4 Mintaka (Delta (\u03b4) Orionis).<\/p>
**5 – The Great Nebula in Orion<\/strong><\/h3>**The Orion Nebula<\/a>, M42, is a highlight of the winter skies and a superb object in binoculars of any size. It\u2019s the nearest stellar nursery to Earth and is visible to the naked eye as the fuzzy central \u2018star\u2019 of Orion\u2019s Sword.<\/p>
It is extremely sensitive to sky transparency and is best observed soon after rain has cleaned the sky of dust, revealing its exquisite, intricate detail.<\/p>
6 – M78<\/strong><\/h3>
This demands mounted binoculars, a very transparent sky and averted vision. Put mag. +1.9 Alnitak (Zeta (\u03b6) Orionis) just outside the south-southwest of the field of view and a small misty glow should appear near the centre.<\/p>
Brighter at the top than at the bottom, it looks like a comet, showing why Charles Messier put it in his catalogue of objects for comet-hunters to ignore, known as the Messier Catalogue.<\/p>
**6 binocular night-sky targets for November 2023<\/strong><\/h2>** $\"Chart$
Chart showing the location of asteroid 18 Melpomene in November 2023. Credit: Pete Lawrence<\/figcaption><\/figure>
**Download our** **November 2023 binocular tour form (PDF)<\/a><\/strong><\/em><\/p>**
The Cosmic Question Mark<\/strong><\/h3>
Use the chart at the link above to identify mag. +4.9 Nu (\u03bd) Ceti and hold it at the bottom half of the field of view. You\u2019ll see that it is the dot at the bottom of the 2.25\u00b0-long question mark asterism (an informal group of stars).<\/p>
This is a good star-party object, both because of its shape and the colours of the fainter stars that make up the rest of the asterism.<\/p>
The Pisces Parallelogram<\/strong><\/h3>
If you follow a line up from mag. +2.0 Deneb Kaitos (Beta (\u03b2) Ceti; also known as Diphda) through mag. +3.5 Iota (\u03b9) Ceti, you will find four stars of fifth magnitude (or so) that form a 3\u00b0 x 1\u00b0 parallelogram.<\/p>
The northeast corner is blue-white 29 Psc, and diagonally opposite is orange 30 Psc; the other two corners of the parallelogram appear yellowish. See how the parallelogram appears empty: it contains only one star brighter than eighth magnitude.<\/p>
T Ceti<\/strong><\/h3>
Return to Deneb Kaitos and find the mag. +4.4 star 7 Ceti, 7\u00b0 to the west. From there, go 2\u00b0 to the southeast to T Ceti, the most westerly star in an equilateral triangle of sixth(ish)-magnitude stars, with a side of 1.5\u00b0.<\/p>
T Ceti is a semi-regular variable star (mag. +5.0 to +6.9) with a period of 159.3 days. If you observe it every couple of weeks you should be able to notice this variation.<\/p>
37 Ceti\u00a0<\/strong><\/h3>
The double star 37 Ceti lies nearly 2.5\u00b0 west of mag. +3.6 Theta (\u03b8) Ceti. Its components are 49 arcseconds apart, which theoretically should be an easy split, even with lower magnifications.<\/p>
But the magnitude of the companion is only +7.9, which is 13 times less bright and can make splitting it a bit of a challenge. This is an optical double (a chance line-of-sight pairing), not a true binary star.\u00a0<\/p>
The Silver Coin Galaxy and NGC 288<\/strong><\/h3>
With a good clear southern horizon, find the right-angled triangle of fifth-magnitude stars 5\u00b0 south of Deneb Kaitos. Look below it for a rhombus of fainter stars. You\u2019ll see the Silver Coin Galaxy (NGC 253) as an elongated glow about 1\u00b0 beneath the rhombus.<\/p>
Next look slightly less than 2\u00b0 in the direction of Alpha (\u03b1) Sculptoris, where you should see the faint glow of the globular cluster NGC 288.<\/p>
**Melpomene<\/strong><\/h3>**Asteroid 18 Melpomene<\/a> has a very elliptical orbit with a period of 3.48 years, so approximately every seven years, when it\u2019s near its perihelion, it appears brighter than usual.<\/p>
It\u2019s at peak brightness (mag. +8.2) at the beginning of November. To identify it, observe its environs over several nights to determine which \u2018star\u2019 moves relative to the others.<\/p>
**6 binocular night-sky targets for October 2023<\/strong><\/h2>** $\"A$
A chart showing Cassiopeia’s position in the night sky, and its prominent stars. Credit: Pete Lawrence.<\/figcaption><\/figure>
**Download our** **October 2023 binocular tour form (PDF)<\/a><\/strong><\/em><\/p>**
**This month’s targets are all located in and around the constellation Cassiopeia<\/a>.<\/p>**
Kurhah star field<\/strong><\/h3>
The very white mag. +4.4 Kurhah (Xi (\u03be) Cephei) is the most northerly and brightest star of a lovely group that stretches southward for about 3\u00b0. There are some very red stars like mag. +5.2 18 Cephei and, at the other extreme, hot blue mag. +5.1 19 Cephei.<\/p>
Give yourself time to appreciate the sheer variety of what\u2019s on show and look around for the other, fainter groups of colourful stars that lurk nearby.<\/p>
**U Cephei<\/strong><\/h3>**Eclipsing variable star U Cephei lies midway between two white mag. +5.6 stars, 7.5\u00b0 from mag. +2.0 Polaris (Alpha (\u03b1) Ursae Minoris), the North Star<\/a>, in the direction of mag. +2.1 Gamma (\u03b3) Cassiopeiae.<\/p>
Its magnitude range is +6.8 to +9.2, a nine-fold variation in brightness over a period of 2.5 days which, coupled with it being circumpolar from the UK, makes it a suitable subject for newcomers to variable star observing.<\/p>
35 Cassiopeiae<\/strong><\/h3>
If you imagine that Segin (Epsilon (\u03b5) Cassiopeiae) and Ruchbah (Delta (\u03b4) Cassiopeiae) and Gamma (\u03b3) Cassiopeiae are the apexes of a rhombus, you\u2019ll see a triangle of stars near the fourth apex.<\/p>
The one nearest to Segin is mag. +6.3 35 Cassiopeiae, a very white star, but can you detect any colour in its mag. +8.4 companion 1 arcminute to the north? This is a line-of-sight pairing, not a true binary star<\/a>.<\/p>
Cassiopeia triple cluster (NGC 654, 659, 663)\u00a0<\/strong><\/h3>
Look 1\u00b0 to the east of the middle of an imaginary line joining Segin and Ruchbah and you\u2019ll easily find the largest and richest of these clusters, NGC 663. Slightly less than 1\u00b0 to the north-northwest is the brighter but smaller NGC 654.<\/p>
The poorest of the trio is NGC 659, a tiny ghostly glow which may need averted vision, just on the NGC 663 side of mag. +5.8 44 Cassiopeiae.<\/p>
The Owl Cluster, NGC 457<\/strong><\/h3>
Start at Ruchbah and navigate 2\u00b0 southwest to mag. +5.0 (Phi (\u03c6) Cassiopeiae) and its mag. +7.0 companion 2 arcminutes further on. These are the owl\u2019s eyes.<\/p>
The Owl Cluster<\/a>‘s body and wings are ninth and 10th-magnitude stars that span an area about 0.25\u00b0 in the direction of Gamma Cassiopeiae. The brighter eye is not actually part of NGC 457; it lies half-way between us and the 8,000-\u200blightyear-distant cluster.<\/p>
**The Muscleman Cluster<\/strong><\/h3>**Identify the Perseus Double Cluster<\/a> (NGC 884 and NGC 869) and from the part nearest to Cassiopeia follow a 2\u00b0 chain of eighth-magnitude stars north to Stock 2, the Muscleman Cluster.<\/p>
This gets its name from the brighter stars having the form of a stick-man in muscle-flexing body-builder pose, ripping this star-chain away from the Double Cluster.<\/p>
**6 binocular night-sky targets for September 2023<\/strong><\/h2>** $\"The$
The Saturn Nebula, NGC 7009 by Fernando Oliveira de Menezes<\/figcaption><\/figure>
**Download our** **September 2023 binocular tour form (PDF)<\/a><\/strong><\/em><\/p>**
**M2<\/strong><\/h3>**Charles Messier described the globular cluster M2 as \u201ca nebula<\/a> without stars\u201d. You\u2019ll find it due north of Sadalsuud (Beta (\u03b2) Aquarii) and due west of Sadalmelik (Alpha (\u03b1) Aquarii).<\/p>
It\u2019s obvious in a star-sparse region of sky; even in small binoculars you should be able to see this 38,000-lightyear-distant glow. If you use averted vision, it will appear to grow slightly and may appear very slightly oval in shape.<\/p>
\u03a32809<\/strong><\/h3>
From M2, head slightly more than a degree east-northeast to a mag. +6.2 star. This is the brighter component of a double-star system, Struve 2809.<\/p>
Seeing the fainter companion is a good test of both 10×50 binoculars and your observing technique, because it\u2019s a mere 31 arcseconds to the south-southeast and shines at only mag. +9.3. Don\u2019t expect to see it consistently; it may \u2018fade\u2019 in and out of visibility.<\/p>
Saturn and Titan<\/strong><\/h3>
Saturn is the brightest object in the area covered by the chart, so is easy to locate. You won\u2019t see the rings in 10×50 binoculars, but you can see the brightest moon, Titan, which shines at mag. +8.4.<\/p>
Its period of orbit around Saturn is nearly 16 days and its angular distance from the planet ranges between 0.5 and 3 arcminutes, so the second-largest moon in the Solar System is quite easy to spot. \u03bf <\/p>
The Saturn Nebula, NGC 7009<\/strong><\/h3>
If you want a good binocular observing challenge in British skies, this is a top candidate. Fortunately,it\u2019s very easy to locate, 1.3\u00b0 due west of mag. +4.5 Nu (\u03bd) Aquarii.<\/p>
It appears as a slightly defocused star but, because it\u2019s only about 0.4 arcminutes across, at this magnification you\u2019ll not be able to see the elongation that Lord Rosse detected when he gave it its common name.<\/p>
8 Flora<\/strong><\/h3>
Here\u2019s a rare opportunity to spot asteroid 8 Flora in binoculars. It starts the month at mag. +8.5, 6.7\u00b0 south of Saturn and fades by a bit more than half a magnitude as it tracks 5\u00b0 west-southwest during the month. It will be hard to identify against the background stars, so you\u2019ll need to observe on several occasions to detect which of these \u2018stars\u2019 moves in relation to the others.<\/p>
**6. M30<\/strong><\/p>**
If you plan to do a Messier Marathon (observing all 110 Messier objects between dusk and dawn) next spring, M30 is one you need to be confident of finding, being the difficult last object in a lightening dawn twilight sky. Autumn evenings are a very good time to start this practice. You\u2019ll find it half a degree from mag. +5.2 41 Capricorni in the direction of mag. +3.7 Zeta (\u03b6) Capricorni.<\/p>
**6 binocular night-sky targets for August 2023<\/strong><\/h2>** $\"M8$
M8 – Lagoon Nebula by Andreas Papp,<\/figcaption><\/figure>
Download our August 2023 binocular tour form (PDF)<\/a><\/strong><\/em><\/li><\/ul>
M11, the Wild Duck Cluster<\/b><\/h3>
Our tour of the southern portion of the Milky Way begins with one of the densest open clusters, M11, the Wild Duck Cluster. You\u2019ll find it 2\u00b0 southeast of mag. +4.2 Beta (\u03b2) Scuti, spanning about 0.25\u00b0 of sky.<\/p>
In 10×50 binoculars, the cluster appears as a bright, slightly wedge-shaped glow. Were it not so rich, you may have had trouble identifying it against the Scutum Star Cloud, the densest part of the Milky Way.<\/p>
M26<\/b><\/h3>
If you put mag. +3.8 Alpha (\u03b1) Scuti at the northwest of your field of view, open cluster M26, also known as NGC 6694, will be southeast of centre. Although it is only mag. +8.0, M26 is easy to find.<\/p>
Look for a glowing kite shape which has the unusual feature of being less bright in the middle, due to some intervening interstellar dust, so what you see is an open cluster with a tiny dark nebula in the middle.<\/p>
M24, the Sagittarius Star Cloud<\/b><\/h3>
M24 lies slightly more than half-way from mag. +4.7 Gamma (\u03b3) Scuti to mag. +3.8 Polis (Mu (\u00b5) Sagittarii). It is a bright patch of light that is easily visible to the naked eye and which has even been mistaken for a cloud just above the horizon.<\/p>
It is a remarkably good object in 10×50 binoculars, in which nearly 1,000 stars are resolved in a single field of view!<\/p>
M25 and U Sagittarii<\/b><\/h3>
If you navigate 4.5\u00b0 south from Gamma Scuti, you should easily find the bright (mag. +4.6) open cluster M25, showing distinctly against the background Milky Way, with eight or so stars resolved against a grainy background.<\/p>
It\u2019s easier to distinguish the cluster from the background Milky Way in small binoculars than in large ones. The brightest star in the cluster is the Cepheid variable, U Sagittarii (which varies from mag. +7.2 to +6.5).<\/p>
M23<\/b><\/h3>
M23 is just over half-way from mag. +3.5 Xi (\u03be) Serpentis to Polis, but may be difficult to distinguish from the rich background of the Milky Way.<\/p>
This bright, oval (15×27 arcminutes) open cluster is lovely in 70mm binoculars, which reveal about a dozen stars in the shape of a lower-case letter alpha (\u03b1) against the background glow of another 140 fainter stars.<\/p>
**M8, the Lagoon Nebula<\/b><\/h3>**Look for M8, the Lagoon Nebula<\/a>, 6\u00b0 west-northwest of mag. +3.0 Kaus Borealis (Lambda (\u03bb) Sagittarii). It is visible to the naked eye if it\u2019s high in a reasonably dark and transparent sky.<\/p>
With 10x50s you\u2019ll resolve more than half a dozen stars and reveal some of the surrounding nebulosity (NGC 6523) they illuminate, as well as the denser cluster of stars to the east of the main nebulosity.<\/p>
**6 binocular night-sky targets for July 2023<\/strong><\/h2>** $\"M27,$
M27, the Dumbbell Nebula. Credit: Patrick Cosgrove<\/figcaption><\/figure>
**Download our** July 2023 binocular tour form (PDF)<\/a><\/strong><\/em><\/li><\/ul>
**1 – Sadr, the Heart of Cygnus<\/b><\/h3>**The mag. +2.2 star Sadr<\/a> (Gamma (\u03b3) Cygni) is sometimes called \u2018the heart of Cygnus<\/a>\u2019, but it is really only part of the story. If you look carefully, you\u2019ll notice that Sadr is merely the point of inflexion in a cardioid-shaped asterism of 11 mostly 6th-magnitude stars.<\/p>
It has a diameter of a little less than 2\u00b0 and offers a wide variety of colours, from deep orange through yellow and white, to an intense blue-white.<\/p>
**2 – NGC 6940<\/b><\/h3>**The open star cluster<\/a> NGC 6940 deserves to be far better known. Use the chart to identify mag. +4.0 41 Cygni and mag. +4.9 30 Vulpeculae and you\u2019ll find NGC 6940 between them, appearing like an oval patch of light that extends to the same apparent diameter as the Moon.<\/p>
As you study the 2,700-year-old glow, you should be able to resolve eight or so stars of this very pretty cluster, depending on your sky conditions.<\/p>
**3 – The Dumbbell Nebula, M27<\/b><\/h3>**Our next stop is the easiest planetary nebula for binoculars, visible even in moderately light-polluted skies. If you place Gamma (\u03b3) Sagittae at the south of a 5\u00b0 field of view, the mag. +7.4 Dumbbell Nebula<\/a> will be just north of centre, looking like a tiny luminous cloud.<\/p>
Initially it will appear rectangular, but with patience you should make out the narrowing in the middle that gives it its common name.<\/p>
**4 – Barnard\u2019s E Nebula<\/b><\/h3>**In a dark, transparent sky, this pair of dark nebulae<\/a>, B142 and B143, which you will find 1\u00b0 west of mag. +2.7 Tarazed (Gamma (\u03b3) Aquilae) is easy to identify because of the rich Milky Way starfield against which it lies.<\/p>
These agglomerations of obscuring gas and dust will appear to you as an uppercase \u2018E\u2019 or an underlined \u2018C\u2019, depending on sky clarity. The easiest bit to see is the middle bar of the E.<\/p>
5 – Eta Aquilae<\/b><\/h3>
What was the first Cepheid variable star to be discovered? Answer: Eta (\u03b7) Aquilae (mag. +3.5 to +4.4) \u2013 *not<\/i> Delta (\u03b4) Cephei, the star that gave its name to this class of variables.<\/p>*
Edward Piggott found variability in the former a month before John Goodricke found it in the latter. In 1912, Henrietta Leavitt discovered their period-luminosity relationship \u2013 the \u2018standard candles\u2019 *Edwin Hubble<\/a> then used to measure galactic distances.<\/p>*
6 – M15<\/b><\/h3>
Easy globular cluster M15 is one 15×70 field of view northeast of Delta (\u03b4) Equulei. Don\u2019t expect it to look even half as wide (18 arcminutes) as the published data suggests.<\/p>
Most of its stars are in a core so dense that even the Hubble Space Telescope<\/a> can\u2019t resolve it, and only the central 7 arcminutes is visible in 70mm binoculars.<\/p>
**6 binocular night-sky targets for June 2023<\/strong><\/h2>** $\"M5.$
Globular cluster M5. Credit: Manfred Wasshuber \/ CCD Guide.com<\/figcaption><\/figure>
**Download our** June 2023 binocular tour form (PDF)<\/a><\/strong><\/em><\/li><\/ul>
1 – M5<\/b><\/h3>
Let\u2019s start with a fine globular cluster, M5, immediately north-northeast of mag. +5.0 5 Serpentis. It contains mostly Population II stars, which are among the oldest stars that we can see.<\/p>
They are thought to be more than 12 billion years old, which suggests that they formed very soon after our Galaxy did. In 10×50 binoculars, you should notice that M5 brightens towards the centre, exactly like a comet does.<\/p>
**2 – Zubenelgenubi<\/b><\/h3>**In antiquity, the stars of Libra, the only non-living zodiac constellation, represented the claws of Scorpius, and the common name of mag. +2.7 Alpha (\u03b1) Librae, Zubenelgenubi<\/a>, means \u2018southern claw\u2019 (the northern claw is mag. +2.6 Zubenelschamali (Beta (\u03b2) Librae).<\/p>
Zubenelgenubi is a nice easy binocular double star. Binoculars easily reveal the mag. +5.2 companion 3.5 arcminutes away.<\/p>
**3 – Delta Librae<\/b><\/h3>**You\u2019ll find the variable (mag. +5.8 to mag. +4.4) Delta (\u03b4) Librae 8\u00b0 north of Zubenelgenubi. It\u2019s an eclipsing binary star (a pair of stars orbiting their common centre of mass) in which the drop in brightness, which lasts for about six hours, occurs as the dimmer star occults<\/a> the brighter one.<\/p>
The orbital period is 2.3 days, so even during short summer nights you\u2019ll have several opportunities to notice the magnitude change.<\/p>
4 – Xi^{1<\/sup>\/Xi^{2<\/sup> and 17\/18 Librae<\/b><\/h3>Midway between Delta Librae and Zubenelgenubi lie two optical double stars (not gravitationally bound binaries). Mag. +5.8 Xi^{1<\/sup> (\u03be^{1<\/sup>) and mag. +5.4 Xi^{2<\/sup> (\u03be^{2<\/sup>) Librae are separated by 0.75\u00b0.<\/p>}}}}
Half a degree northeast of Xi^{2<\/sup> is the other pair, mag. +6.6 17 Librae and mag. +5.8 18 Librae, which are nearly 10 arcminutes apart. There is about 50 lightyears between 17 and 18, and more than four times that between Xi^{1<\/sup> and Xi^{2<\/sup>.<\/p>}}}}}**5 – M4<\/b><\/h3>**M4 is nearly 1.5\u00b0 west of bright orange mag. +1.0 Antares<\/a> (Alpha (\u03b1) Scorpii). It is only 7,000 lightyears away, making it appear rather loose, and is one of the few globular clusters in which you may be able to discern some structure with 15×70 binoculars.<\/p>
M4 lies on the edge of the Milky Way, within a beautifully rich, colourful star-field that is more pleasing in binoculars than in a scope.<\/p>
6 – Rho Ophiuchi<\/b><\/h3>
If you navigate 3\u00b0 north from M4, you\u2019ll find mag. +5.0 Rho (\u03c1) Ophiuchi. It is the bright component of a triple star, whose seventh-magnitude companions are 2.5 arcminutes to the north and west, respectively.<\/p>
If you have an exceptional southern horizon sky and fancy a challenge, see if averted vision enables you to detect a slight brightening surrounding the star.<\/p>
**6 binocular night-sky targets for May 2023<\/strong><\/h2>** $\"Markarian's$
Markarian’s Chain. Credit: Bob Franke.<\/figcaption><\/figure>
**Download our** May 2023 binocular tour form (PDF)<\/a><\/strong><\/em><\/li><\/ul>
**1 – M53<\/b><\/h3>**A degree northeast of mag. +4.3 Diadem<\/a> (Alpha (\u03b1) Comae Berenices), you\u2019ll find a small misty patch which appears to grow in size and brightness if you centre it in the field of view then avert your gaze back to Diadem.<\/p>
The apparent changes, which are typical of globular clusters, demonstrate the difference between direct and averted vision. Practice this technique; you\u2019ll need it later when we seek out the galaxies in Markarian\u2019s Chain<\/p>
2 – FS Comae<\/b><\/h3>
Navigate to a point half-way between Diadem and mag. +4.2 Beta (\u03b2) Comae Berenices, then another degree to the west to an orange star, FS Comae, shining somewhere around mag. +6. <\/p>
The magnitude of this semi-regular variable star<\/a> varies between mag. +6.1 and + 5.3, with a period of 55\u201358 days. Analysis of the star\u2019s spectrum reveals variations in radial velocity of the star\u2019s surface, which indicates that its variability is due to pulsations in size.<\/p>
**3 – 28 &29 Comae<\/b><\/h3>**Head 5\u00b0 northwest of mag. +2.8 Vindemiatrix<\/a> (Epsilon (\u03b5) Virginis) to a pair of white stars separated by half a degree and orientated roughly north\u2013south. The southerly one is mag. +6.4 28 Comae, brightest of a little parallelogram of stars.<\/p>
Mag. + 5.7 29 Comae is the brightest of a triple star group. The brighter (mag. +8.6) companion is 5 arcminutes back towards 28 Comae, and the fainter (mag. +9.9) one is an arcminute closer.<\/p>
**4 – Ceres<\/b><\/h3>**Ceres<\/a> was discovered by Guiseppe Piazzi on the first day of the 19th century and is the only dwarf planet visible in standard binoculars.<\/p>
It fades from mag. +7.8 to mag. +8.4 during the month, but should be easiest to detect around mid-month when the Moon is out of the way and it is 2.2\u00b0 east of mag. +2.1 Denebola (Beta (\u03b2) Leonis).<\/p>
5 – M49<\/b><\/h3>
Locate mag. +4.9 Rho (\u03c1) Virginis and place it on the northeast of your field of view. On the opposite side you should find a pair of sixth-magnitude stars, a little more than a degree apart and orientated southeast\u2013northwest.<\/p>
M49 is the small, slightly oval patch of light between these two. Use averted vision to see how many more galaxies you can detect in this region of sky.<\/p>
**6 – Markarian\u2019s Chain<\/b><\/h3>**TTheis chain of galaxies known as Markarian’s Chain<\/a>, which you may already have detected north of M49, lies almost exactly half way between Vindemiatrix and Denebola.<\/p>
Starting with M84 and M86, you should be able to identify at least the seven brightest galaxies in the chain.<\/p>
**6 binocular night-sky targets for April 2023<\/strong><\/h2>** $\"NGC869$
The Double Cluster. Credit: Raoul van Eijndhoven<\/figcaption><\/figure>
**Download our** April 2023 binocular tour form (PDF)<\/a><\/strong><\/em><\/li><\/ul>
1 – The Double Cluster<\/b><\/h3>
Half way between mag. 2.6 Ruchbah (Delta (\u03b4) Cassiopeiae) and mag. +2.9 Gamma (\u03b3) Cassiopeiae you will find a close pair of open clusters. These are known as the Double Cluster.<\/p>
In a rural sky, you can see them with your naked eye as a distinctly elongated smudge of light, but binoculars will reveal two little concentrations of stars. Those stars are intrinsically extremely bright: if the Sun was there, it would be too faint for you to see it in binoculars!<\/p>
2 – Melotte 15<\/b><\/h3>
If you imagine that mag. +3.3 Segin (Epsilon (\u03b5) Cassiopeiae) and mag. +4.6 Iota (\u03b9) Cassiopeiae are two corners of an equilateral triangle, Melotte 15 is the third corner.<\/p>
In 10×50 binoculars, you\u2019ll see a large (20-arcminute) glow with a handful of brighter stars forming a V shape. If you have a UHC filter to hold over an eyepiece, you might see the nebulosity (IC1805, the Heart Nebula) that surrounds, and gave birth to, the cluster.<\/p>
3 – Markarian 6<\/b><\/h3>
Markarian 6 lies slightly less than 1\u00b0 to the south-southwest of Mel 15. It\u2019s quite easy to miss, so we use larger binoculars. What you should see is an arrow of half a dozen ninth-magnitude stars pointing southwards.<\/p>
Owing to its faintness compared to Mel 15, you might assume it is much further away, but at 1,600 lightyears it is actually just under a quarter of the distance.<\/p>
4 – Pazmino\u2019s Cluster <\/b><\/h3>
If you pan slightly more than 1.5\u00b0 due west from mag. +4.3 CS Camelopardalis, you will find an unremarkable little trapezium of seventh and eigth-magnitude stars. This is Stock 23, also known as Pazmino\u2019s Cluster.<\/p>
Your binoculars should reveal that this is much more than a trapezium and you may be able to resolve about half a dozen stars against a faintly glowing patch of sky about 10 arcminutes in diameter.<\/p>
**5 – Kemble\u2019s Cascade<\/b><\/h3>**On spring evenings, Kemble\u2019s Cascade<\/a> is near-horizontal in the sky, so this line of eighth-magnitude stars, with a brighter fifth-magnitude one in the middle, looks more like a wristwatch or bracelet opened out against the sky than a tumbling cascade.<\/p>
To find it, extend a line from mag. +2.3 Caph (Beta (\u03b2) Cassiopeiae) to Segin the same distance to the central bright star.<\/p>
6 – Beta Cam<\/b><\/h3>
You can see mag. +4.0 Beta (\u03b2) Camelopardalis with the naked eye, and its mag. +7.4 companion, which lies 84 arcseconds southwest is easy to distinguish, even in small binoculars.<\/p>
Beta Cam is a yellow supergiant in transition between being a hot new blue star and a much cooler red supergiant. It sometimes flashes, probably due to the equivalent of huge solar flares.<\/p> <\/body><\/html>\n
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