DOCSLIB.ORG

Messier 31 – the Andromeda Galaxy

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Messier 31 – the Andromeda Galaxy Messier 31 – The Andromeda Galaxy Article Updated: 9 Jan , 2017 by Tammy Plotner Welcome back to Messier Monday! In our ongoing tribute to the great Tammy Plotner, we take a look at the Andromeda Galaxy, also known as Messier 31. Enjoy! During the 18th century, famed French astronomer Charles Messier noted the presence of several “nebulous objects” in the night sky. Having originally mistaken them for comets, he began compiling a list of them so that others would not make the same mistake he did. In time, this list (known as the Messier Catalog) would come to include 100 of the most fabulous objects in the night sky. One of these objects is the famed Andromeda Galaxy, the closest spiral galaxy to the Milky Way which is named for the area of the sky it appears in (in the vicinity of the Andromeda constellation). It is the largest galaxy in the Local Group, and has the distinction of being one of the few objects that is actually getting closer to the Milky Way (and is expected to merge with us in a few billion years!). Description: Approaching us at roughly 300 kilometers per second, our massive galactic neighbor has been the object of studies of spiral structure, globular and open clusters, interstellar matter, planetary nebulae, supernova remnants, galactic nucleus, companion galaxies, and more for as long as we’ve been peering its way with a telescope. It’s part of our Local Group of galaxies and its two easily visible companions are only part of the eleven others that swarm around it. One day, this galaxy will collide with our own, much as it is now consuming its neighbor – M32. However, this won’t come to pass for several billions years, so don’t go worrying about the immense gravitational disturbances just yet! And not surprisingly, a giant galaxy like Andromeda doesn’t get to be so big by keeping to itself. How many times now has the Great Andromeda Galaxy consumed another? More than once! In 1993, the Hubble Space Telescope revealed that M31 has a double nucleus – a ‘leftover’ from another meal! As NASA and the ESA stated about the discovery at the time: “Each of the two light-peaks contains a few million densely packed stars. The brighter object is the “classic” nucleus as studied from the ground. However, HST reveals that the true center of the galaxy is really the dimmer component. One possible explanation is that the brighter cluster is the leftover remnant of a galaxy cannibalized by M31. Another idea is that the true center of the galaxy has been divided in two by deep dust absorption across the middle, creating the illusion of two peaks. This green-light image was taken with HST’s Wide Field and Planetary Camera (WF/PC), in high resolution mode, on July 6, 1991. The two peaks are separated by 5 light-years. The Hubble image is 40 light-years across.” Perhaps one of the most fascinating discovery recent years in Messier 31 was made by the orbiting Chandra X-Ray Observatory. The X-ray image below, made with the Chandra X-Ray Astronomy Center’s Advanced CCD Imaging Spectrometer (ACIS), shows the central portion of the Andromeda Galaxy. The Chandra X-ray Observatory is part of NASA’s fleet of “Great Observatories” along with the Hubble Space Telescope. The Andromeda galaxy as seen in optical light, and Chandra’s X-ray vision of the changing supermassive black hole in Andromeda’s heart. Credit: X-Ray NASA/CXC/SAO/Li et al.), Optical (DSS) The blue dot in the center of the image is a “cool” million degree X-ray source where Andromeda’s massive central object, with the mass of 30 million suns, is located, which many astronomers consider to be a supermassive black hole. Most of these are probably due to X-ray binary systems, in which a neutron star (or perhaps a stellar black hole) is in a close orbit around a normal star.” Over the years our studies have advanced even more with the discovery of an eclipsing binary star in Messier 31. As Ignasi Ribas (et al) put it in a 2005: “We present the first detailed spectroscopic and photometric analysis of an eclipsing binary in the Andromeda Galaxy (M31). This is a 19.3 mag semidetached system with late O and early B spectral type components. From the light and radial velocity curves we have carried out an accurate determination of the masses and radii of the components. Their effective temperatures have been estimated by modeling the absorption-line spectra. The analysis yields an essentially complete picture of the properties of the system, and hence an accurate distance determination to M31.” In 2005, we discovered more. At that time, Scott Chapman of Caltech, Rodrigo Ibata of the Observatoire de Strasbourg, and their colleagues conducted detailed studies on the motions and metals of nearly 10,000 stars in Andromeda, which that the galaxy’s stellar halo is “metal-poor.” Essentially, this indicated that the stars lying in the outer bounds of the galaxy are lacking in elements heavier than hydrogen. Image of the Andromeda Galaxy, showing Messier 32 to the lower left, which is currently merging with Andromeda. Credit: Wikipedia Commons/Torben Hansen According to Chapman, this was surprising since one of the key differences thought to exist between Andromeda and the Milky Way was that the former’s stellar halo was metal-rich and the latter’s was metal-poor. If both galaxies are metal-poor, then they must have had very similar evolutions. As Chapman explained: “Probably, both galaxies got started within a half billion years of the Big Bang, and over the next three to four billion years, both were building up in the same way by protogalactic fragments containing smaller groups of stars falling into the two dark-matter haloes.” While no one yet knows what dark matter is made of, its existence is well established because of the mass that must exist in galaxies for their stars to orbit the galactic centers. In fact, current theories of galactic evolution assume that dark-matter wells acted as a sort of “seed” for today’s galaxies, with the dark matter pulling in smaller groups of stars as they passed nearby. What’s more, galaxies like Andromeda and the Milky Way have each probably gobbled up about 200 smaller galaxies and protogalactic fragments over the last 12 billion years. Chapman and his colleagues arrived at the conclusion about the metal-poor Andromeda halo by obtaining careful measurements of the speed at which individual stars are coming directly toward or moving directly away from Earth. The Andromeda Galaxy, viewed using conventional optics and IR. Credit: Kitt Peak National Observatory This measure is called the radial velocity, and can be determined very accurately with the spectrographs of major instruments such as the 10-meter Keck-II telescope, which was used in the study. Of the approximately 10,000 Andromeda stars for which the researchers have obtained radial velocities, about 1,000 turned out to be stars in the giant stellar halo that extends outward by more than 500,000 light- years. These stars, because of their lack of metals, are thought to have formed quite early, at a time when the massive dark-matter halo had captured its first protogalactic fragments. The stars that dominate closer to the center of the galaxy, by contrast, are those that formed and merged later, and contain heavier elements due to stellar evolution processes.In addition to being metal-poor, the stars of the halo follow random orbits and are not in rotation. By contrast, the stars of Andromeda’s visible disk are rotating at speeds upwards of 200 kilometers per second.According to Ibata, the study could lead to new insights on the nature of dark matter. “This is the first time we’ve been able to obtain a panoramic view of the motions of stars in the halo of a galaxy,” says Ibata. “These stars allow us to weigh the dark matter, and determine how it decreases with distance.” History of Observation: Andromeda was known as the “Little Cloud” to Persian astronomer Abd-al-Rahman Al-Sufi, who described and depicted it in 964 AD in his Book of Fixed Stars. This wonderful galaxy was also cataloged by Giovanni Batista Hodierna in 1654, Edmund Halley in 1716, by Bullialdus 1664, and again by Charles Messier in 1764. The Andromeda Galaxy is a spiral galaxy approximately 2.5 million light-years away in the constellation Andromeda. Credit: Wikipedia Commons/Adam Evans Like most of the objects he added to the Messier Catalog, he mistook the galaxy initially for a nebulous object. As he wrote of the object in his notes: “The sky has been very good in the night of August 3 to 4, 1764; and the constellation Andromeda was near the Meridian, I have examined with attention the beautiful nebula in the girdle of Andromeda, which was discovered in 1612 by Simon Marius, and which has been observed since with great care by different astronomers, and at last by M. le Gentil who has given a very ample and detailed description in the volume of the Memoirs of the Academy for 1759, page 453, with a drawing of its appearance. I will not report here what I have written in my Journal: I have employed different instruments for examining that nebula, and above all an excellent Gregorian telescope of 30 pouces focal length, the large mirror having 6 pouces in diameter, and magnifying 104 times these objects: the middle of that nebula appeared rather bright with this instrument, without any appearance of stars; the light went diminishing up to extinguishing; it resembles two cones or pyramids of light, opposed at their bases, of which the axis was in the direction form North-West to South- East; the two points of light or the two summits are about 40 minutes of arc apart; I say about, because of the difficulty to recognize these two extremities.
Load more

Recommended publications
  • Winter Messier List Observing Club
    Winter Messier List Observing Club Raleigh Astronomy Club Version 1.1 24 November 2012 Introduction Welcome to the Winter Messier List Observing Club. The objects on this list represent many of the most prominent deep sky objects (Globular Clusters, Open Clusters, Nebula, Galaxies) visible from mid-northern latitudes. The Messier list of objects was compiled in the 1700’s by the French comet hunter Charles Messier and his associates as a list of objects to not confuse with their primary goal of discovering new comets. What they really produced, was a list of many of the best deep sky objects for astronomers to enjoy. Observing the Messier List is an excellent way for beginning astronomers to learn the night sky. This club is intended for those who wish to tour the Messier objects while adding more structure to their observing activities. Club members who wish to work their way through the Messier objects, a season at a time, will find this list to be a helpful guide. Two certificate levels are offered, Silver and Gold. The Silver certificate is earned by viewing and logging all objects on the list while using Go-To or Digital Setting Circles to help locate the Messier objects. The Gold certificate is earned by those who view and log all the objects while only using charts and star hopping to locate them. Anyone who intends to use their RAC list results as a stepping-stone to the Astronomlcal League Messier certificate, MUST work to the Gold certificate rules. Rules To earn the Winter Messier List certificate, you must: 1.
    [Show full text]
  • Messier Objects
    Messier Objects From the Stocker Astroscience Center at Florida International University Miami Florida The Messier Project Main contributors: • Daniel Puentes • Steven Revesz • Bobby Martinez Charles Messier • Gabriel Salazar • Riya Gandhi • Dr. James Webb – Director, Stocker Astroscience center • All images reduced and combined using MIRA image processing software. (Mirametrics) What are Messier Objects? • Messier objects are a list of astronomical sources compiled by Charles Messier, an 18th and early 19th century astronomer. He created a list of distracting objects to avoid while comet hunting. This list now contains over 110 objects, many of which are the most famous astronomical bodies known. The list contains planetary nebula, star clusters, and other galaxies. - Bobby Martinez The Telescope The telescope used to take these images is an Astronomical Consultants and Equipment (ACE) 24- inch (0.61-meter) Ritchey-Chretien reflecting telescope. It has a focal ratio of F6.2 and is supported on a structure independent of the building that houses it. It is equipped with a Finger Lakes 1kx1k CCD camera cooled to -30o C at the Cassegrain focus. It is equipped with dual filter wheels, the first containing UBVRI scientific filters and the second RGBL color filters. Messier 1 Found 6,500 light years away in the constellation of Taurus, the Crab Nebula (known as M1) is a supernova remnant. The original supernova that formed the crab nebula was observed by Chinese, Japanese and Arab astronomers in 1054 AD as an incredibly bright “Guest star” which was visible for over twenty-two months. The supernova that produced the Crab Nebula is thought to have been an evolved star roughly ten times more massive than the Sun.
    [Show full text]
  • Spatial Distribution of Galactic Globular Clusters: Distance Uncertainties and Dynamical Effects
    Juliana Crestani Ribeiro de Souza Spatial Distribution of Galactic Globular Clusters: Distance Uncertainties and Dynamical Effects Porto Alegre 2017 Juliana Crestani Ribeiro de Souza Spatial Distribution of Galactic Globular Clusters: Distance Uncertainties and Dynamical Effects Dissertação elaborada sob orientação do Prof. Dr. Eduardo Luis Damiani Bica, co- orientação do Prof. Dr. Charles José Bon- ato e apresentada ao Instituto de Física da Universidade Federal do Rio Grande do Sul em preenchimento do requisito par- cial para obtenção do título de Mestre em Física. Porto Alegre 2017 Acknowledgements To my parents, who supported me and made this possible, in a time and place where being in a university was just a distant dream. To my dearest friends Elisabeth, Robert, Augusto, and Natália - who so many times helped me go from "I give up" to "I’ll try once more". To my cats Kira, Fen, and Demi - who lazily join me in bed at the end of the day, and make everything worthwhile. "But, first of all, it will be necessary to explain what is our idea of a cluster of stars, and by what means we have obtained it. For an instance, I shall take the phenomenon which presents itself in many clusters: It is that of a number of lucid spots, of equal lustre, scattered over a circular space, in such a manner as to appear gradually more compressed towards the middle; and which compression, in the clusters to which I allude, is generally carried so far, as, by imperceptible degrees, to end in a luminous center, of a resolvable blaze of light." William Herschel, 1789 Abstract We provide a sample of 170 Galactic Globular Clusters (GCs) and analyse its spatial distribution properties.
    [Show full text]
  • And Ecclesiastical Cosmology
    GSJ: VOLUME 6, ISSUE 3, MARCH 2018 101 GSJ: Volume 6, Issue 3, March 2018, Online: ISSN 2320-9186 www.globalscientificjournal.com DEMOLITION HUBBLE'S LAW, BIG BANG THE BASIS OF "MODERN" AND ECCLESIASTICAL COSMOLOGY Author: Weitter Duckss (Slavko Sedic) Zadar Croatia Pусскй Croatian „If two objects are represented by ball bearings and space-time by the stretching of a rubber sheet, the Doppler effect is caused by the rolling of ball bearings over the rubber sheet in order to achieve a particular motion. A cosmological red shift occurs when ball bearings get stuck on the sheet, which is stretched.“ Wikipedia OK, let's check that on our local group of galaxies (the table from my article „Where did the blue spectral shift inside the universe come from?“) galaxies, local groups Redshift km/s Blueshift km/s Sextans B (4.44 ± 0.23 Mly) 300 ± 0 Sextans A 324 ± 2 NGC 3109 403 ± 1 Tucana Dwarf 130 ± ? Leo I 285 ± 2 NGC 6822 -57 ± 2 Andromeda Galaxy -301 ± 1 Leo II (about 690,000 ly) 79 ± 1 Phoenix Dwarf 60 ± 30 SagDIG -79 ± 1 Aquarius Dwarf -141 ± 2 Wolf–Lundmark–Melotte -122 ± 2 Pisces Dwarf -287 ± 0 Antlia Dwarf 362 ± 0 Leo A 0.000067 (z) Pegasus Dwarf Spheroidal -354 ± 3 IC 10 -348 ± 1 NGC 185 -202 ± 3 Canes Venatici I ~ 31 GSJ© 2018 www.globalscientificjournal.com GSJ: VOLUME 6, ISSUE 3, MARCH 2018 102 Andromeda III -351 ± 9 Andromeda II -188 ± 3 Triangulum Galaxy -179 ± 3 Messier 110 -241 ± 3 NGC 147 (2.53 ± 0.11 Mly) -193 ± 3 Small Magellanic Cloud 0.000527 Large Magellanic Cloud - - M32 -200 ± 6 NGC 205 -241 ± 3 IC 1613 -234 ± 1 Carina Dwarf 230 ± 60 Sextans Dwarf 224 ± 2 Ursa Minor Dwarf (200 ± 30 kly) -247 ± 1 Draco Dwarf -292 ± 21 Cassiopeia Dwarf -307 ± 2 Ursa Major II Dwarf - 116 Leo IV 130 Leo V ( 585 kly) 173 Leo T -60 Bootes II -120 Pegasus Dwarf -183 ± 0 Sculptor Dwarf 110 ± 1 Etc.
    [Show full text]
  • The Messier Catalog
    The Messier Catalog Messier 1 Messier 2 Messier 3 Messier 4 Messier 5 Crab Nebula globular cluster globular cluster globular cluster globular cluster Messier 6 Messier 7 Messier 8 Messier 9 Messier 10 open cluster open cluster Lagoon Nebula globular cluster globular cluster Butterfly Cluster Ptolemy's Cluster Messier 11 Messier 12 Messier 13 Messier 14 Messier 15 Wild Duck Cluster globular cluster Hercules glob luster globular cluster globular cluster Messier 16 Messier 17 Messier 18 Messier 19 Messier 20 Eagle Nebula The Omega, Swan, open cluster globular cluster Trifid Nebula or Horseshoe Nebula Messier 21 Messier 22 Messier 23 Messier 24 Messier 25 open cluster globular cluster open cluster Milky Way Patch open cluster Messier 26 Messier 27 Messier 28 Messier 29 Messier 30 open cluster Dumbbell Nebula globular cluster open cluster globular cluster Messier 31 Messier 32 Messier 33 Messier 34 Messier 35 Andromeda dwarf Andromeda Galaxy Triangulum Galaxy open cluster open cluster elliptical galaxy Messier 36 Messier 37 Messier 38 Messier 39 Messier 40 open cluster open cluster open cluster open cluster double star Winecke 4 Messier 41 Messier 42/43 Messier 44 Messier 45 Messier 46 open cluster Orion Nebula Praesepe Pleiades open cluster Beehive Cluster Suburu Messier 47 Messier 48 Messier 49 Messier 50 Messier 51 open cluster open cluster elliptical galaxy open cluster Whirlpool Galaxy Messier 52 Messier 53 Messier 54 Messier 55 Messier 56 open cluster globular cluster globular cluster globular cluster globular cluster Messier 57 Messier
    [Show full text]
  • The Messier Objects
    WHAT’S IN The Messier Objects THE NIGHT SKY? Bonus Material The Messier objects are a list of 110 deep-sky objects that were catalogued by a French astronomer called Charles Messier. He created this list in the 1700’s when he was looking for comets. He wanted to keep track of the things he could see in the night sky, so he wouldn’t confuse them for comets. The Messier objects all have names that start with the letter M (for Messier), followed by a number. For example, M13 is a Messier object which can be found in the Hercules constellation. Types of Messier objects Globular Clusters – These are spherical Supernova Remnants – When a very large (round) systems of ancient stars held together star (more than 5 times the size of our Sun) by gravity. They are dense systems, which uses up all its fuel, it collapses. The collapse contain thousands or millions of stars. From happens so quickly that the outer layers of Earth, they look like small, blurry blobs in the star explode! A supernova remnant is the the night sky. The globular cluster in the hot, expanding cloud of gas that is given off in picture is M13, which is found in the Hercules this explosion. The supernova remnant in the constellation. picture is M1, which is more commonly named the Crab Nebula. Types of Messier objects continued... Galaxies – A huge collection of dust, gas, Open Cluster – An open cluster is a loose billons of stars and their solar systems group of hundreds or thousands of stars.
    [Show full text]
  • Messier Objects
    Messier Objects by Ken Graun he Messier Object catalogue represents the cream-of-the-crop his most notable life-long achievements was discovering about 20 deep sky objects that can be seen from the mid-latitudes of the comets, which lead to his induction into almost every European science T northern hemisphere. It was compiled at the end of the 1700s academy. by Charles Messier from Paris, France, using telescopes around 3 to Messier never would have believed that his namesake would be 4-inches in diameter. This catalogue is historically significant because it defined by his little catalogue—he would have thought it would have is the very first catalogue ever compiled of deep sky objects. And, since been his comet discoveries. He catalogued deep sky objects because he it lists the biggest and brightest objects in the sky, it realized that such a catalogue was missing in the field has become a logical “next step” for amateurs want - of astronomy (astronomy and most sciences were ing to go beyond observing the Moon and Planets. just starting to get organized during this time in his - An interesting point about this catalogue is that tory). To start the catalogue, he used a few short lists it has at least one example of every type of deep sky of deep sky objects complied by other astronomers object that exists, so it represents a good sample of and quickly added objects he found exploring the the objects that can be found in the heavens. night sky. Three editions of his catalogue were pub - There is a quirk of nature that allows viewing all lished, each growing in size, with the last published of the Messier objects in one night.
    [Show full text]
  • SSAS Marmesmad Doc
    The South Shore Astronomical Society and Unistellar Optics present An Initiative to Engage in Astronomical Observing Welcome to the month of March, a time of the year when astronomy enthusiasts can view every object in Charles Messier’s venerable catalog of ‘non-comets’ in the course of just one overnight, should they choose to do so. But seeing every Messier object in one night, also known as a Messier Marathon, is a daunting prospect indeed. The observer needs to be blessed with not only dark enough skies and low enough horizons to see the very first and very last objects on the list, but he also has to get lucky with the weather and have clear skies for a nearly twelve hour stretch throughout the night. The first two requirements can be met by carefully choosing your observing site. The third, unfortunately, cannot. For these reasons and perhaps others, most observers tend to shy away from Messier Marathon participation, especially when the group you’re affiliated with insists on sticking to a purist’s approach – the one where only star hopping to every object and only visual sighting through the eyepiece is considered the right way to do it. While there is something to be said for completing the challenge in that manner, it also has a tendency to push many would-be observers to the sidelines. So what if the rules were changed? And what if a variety of approaches to observing Messier’s during the month of March were considered not only acceptable, but were encouraged? Enter Unistellar Optics, a French company that markets a unique telescope, the Unistellar eVscope.
    [Show full text]
  • Messier Certificate Log
    A B C D E F 1 CENTRAL FLORIDA ASTRONOMICAL SOCIETY, INC. 2 MESSIER CERTIFICATE OBSERVING LOG 3 FOR: (Your name) 4 CONSTELLATION Messier Object Date Time Instrument Remarks 5 Andromeda 6 M31 The Andromeda Galaxy spiral galaxy (type Sb) 7 M32 Satellite galaxy of M31 elliptical galaxy (type E2 8 M110 Satellite galaxy of M31 elliptical galaxy (type E6pec) 9 10 Aquarius 11 M2 globular cluster 12 M72 globular cluster 13 M73 system or asterism of 4 stars 14 15 Auriga 16 M36 open cluster 17 M37 open cluster 18 M38 open cluster 19 20 Cancer 21 22 M44 Praesepe, the Beehive Cluster open cluster 23 M67 open cluster 24 25 Canes Venatici 26 M3 globular cluster 27 M51 The Whirlpool Galaxy spiral galaxy 28 M63 Sunflower galaxy spiral galaxy 29 M94 spiral galaxy 30 M106 spiral galaxy 31 32 Canis Major 33 M41 open cluster 34 Capricornus 35 M30 globular cluster 36 37 Cassiopeia 38 M52 open cluster A B C D E F 1 CENTRAL FLORIDA ASTRONOMICAL SOCIETY, INC. 2 MESSIER CERTIFICATE OBSERVING LOG 3 FOR: (Your name) 4 CONSTELLATION Messier Object Date Time Instrument Remarks 39 M103 open cluster 40 41 Cetus 42 M77 spiral galaxy 43 44 Coma Berenices 45 M53 globular cluster 46 M64 Blackeye galaxy spiral galaxy 47 M85 elliptical galaxy 48 M88 spiral galaxy 49 M91 spiral galaxy 50 M98 spiral galaxy 51 M99 spiral galaxy 52 M100 spiral galaxy 53 54 Cygnus 55 M29 open cluster 56 M39 open cluster 57 58 Draco 59 M102 may be NGC 5866 Spindle Galaxy , a lenticular galaxy (type S0_3) 60 Gemini 61 M35 open cluster 62 Hercules 63 M13 Great Hercules Globular Cluster globular cluster 64 M92 globular cluster 65 66 Hydra 67 M48 open cluster 68 M68 globular cluster 69 M83 spiral galaxy 70 71 72 A B C D E F 1 CENTRAL FLORIDA ASTRONOMICAL SOCIETY, INC.
    [Show full text]
  • Messier Object Mapping System
    Messier Object Mapping System Messier Object Constellation Map# Messier Object Constellation Map# M1 Taurus 1-6 M56 Lyra 3 M2 Aquarius 8 M57 Lyra 3 M3 Canes Venatici 4-10 M58 Virgo IN2-5 M4 Scorpius 2 M59 Virgo IN2 M5 Scorpius 10 M60 Virgo IN2-5-9-10 M6 Scorpius 2 M61 Virgo IN2-5-8 M7 Scorpius 2 M62 Ophiuchus 2 M8 Sagittarius 2-IN1 M63 Canes Venatici 4 M9 Ophiuchus 2 M64 Coma Berenices 4-5 M10 Ophiuchus 2 M65 Leo 5 M11 Scutum 2 M66 Leo 5 M12 Ophiuchus 2 M67 Cancer 6 M13 Hercules 3 M68 Hydra 9 M14 Ophiuchus 2 M69 Sagittarius 2-IN1-8 M15 Pegasus 8 M70 Sagittarius 2-IN1-8 M16 Serpens 2-IN1 M71 Sagittarius 2 M17 Sagittarius 2-IN1 M72 Aquarius 8 M18 Sagittarius 2-IN1 M73 Aquarius 8 M19 Ophiuchus 2 M74 Pisces 11 M20 Sagittarius 2-IN1-8 M75 Sagittarius 8 M21 Sagittarius 2-IN1-8 M76 Perseus 7 M22 Sagittarius 2-IN1-8 M77 Cetus 11 M23 Sagittarius 2-IN1 M78 Orion 1 M24 Sagittarius 2-IN1 M79 Lepus 1 M25 Sagittarius 2-IN1-8 M80 Scorpius 2 M26 Scutum 2 M81 Ursa Major 4 M27 Vupecula 3 M82 Ursa Major 4 M28 Sagittarius 2-IN1-8 M83 Hydra 9 M29 Cygnus 3 M84 Virgo IN2-5 M30 Capricornus 8 M85 Coma Berenices 4-5 M31 Andromeda 7-11 M86 Virgo IN2-5 M32 Andromeda 7-11 M87 Virgo IN2-5 M33 Triangulum 7-11 M88 Coma Berenices IN2-5 M34 Perseus 7-11 M89 Virgo IN2 M35 Gemini 1-6 M90 Virgo IN2-5 M36 Auriga 1-6 M91 Virgo IN2-5 M37 Auriga 1-6 M92 Hercules 3 M38 Auriga 1 M93 Puppis 1-6 M39 Cygnus 3-7 M94 Canes Venatici 4-5 M40 Ursa Major 4 M95 Leo 5 M41 Canis Major 1 M96 Leo 5 M42 Orion 1 M97 Ursa Major 4 M43 Orion 1 M98 Coma Berenices IN2-4-5 M44 Sagittarius 6 M99 Coma Berenices IN2-4-5 M45 Taurus 1-11 M100 Coma Berenices IN2-4-5 M46 Puppis 1-6 M101 Ursa Major 4 M47 Puppis 1-6 M102 Draco 4 M48 Hydra 6 M103 Cassiopeia 7 M49 Virgo 2-IN1-8 M104 Virgo 5-9-10 M50 Monoceros 1-6 M105 Leo 5 M51 Canes Venatici 4-10 M106 Canes Venatici 4-5 M52 Cassiopeia 7 M107 Ophiuchus 2 M53 Coma Berenices 4-5-10 M108 Ursa Major 4 M54 Sagittarius 2-IN1-8 M109 Ursa Major 4-5 M55 Sagittarius 2-8 M110 Andromeda 7-11 Messier Object List # NGC# Constellation Type Name, If Any Mag.
    [Show full text]
  • Santa Fe, New Mexico, USA May 31 – June 5, 2009
    Santa Fe, New Mexico, USA May 31 – June 5, 2009 Stellar Pulsation: Challenges for Theory and Observation 2 Scientific Organizing Committee Conny Aerts (Leuven) Giuseppe Bono (Rome) Michel Breger (Vienna) Joergen Christensen- Arthur Cox Merieme Chadid (Nice) Dalsgaard (Aarhus) (Los Alamos) Wojciech Dziembowski Wolfgang Gieren Joyce Guzik (Warsaw) (Concepcion) (Los Alamos) Jaymie Matthews Joanna Molenda- Hiromoto Shibahashi (Vancouver) Zakowicz (Wroclaw) (Tokyo) Peter Wood (Canberra) Stellar Pulsation: Challenges for Theory and Observation 3 Local Organizing Committee Thomas Beach Stephen Becker Kunegunda Belle Paul Bradley Michelle Creech-Eakman Joyce Guzik John Keady Evan Sanchez Kim Simmons Meeting Sponsors Los Alamos National Laboratory: Applied Physics Division Center for Space Science and Exploration Institute of Geophysics and Planetary Physics TAE Photo and Design La Fonda on the Plaza Stellar Pulsation: Challenges for Theory and Observation 4 Local Information La Fonda on the Plaza 100 E. San Francisco St. Santa Fe, NM 87501 505-982-5511 Stellar Pulsation: Challenges for Theory and Observation 5 Restaurants within 0.25 miles of La Fonda Stellar Pulsation: Challenges for Theory and Observation 6 Stellar Pulsation Meeting Program Sunday, May 31 16:00-18:00 Put up posters 18:00-20:00 Reception and Registration (La Terraza at the La Fonda Hotel) Monday, June 1 8:00-8:45 Put up posters 8:45-9:00 Welcome Session I. Cepheids and the Distance Scale, Chair: Wolfgang Gieren 9:00-9:30 Thomas Barnes, Cepheid Distance Scale (Invited) 9:30-9:45
    [Show full text]
  • Deep Sky Companion
    June 5th–December 18th Hours: 9am-5pm and by appointment For images of this body of work and others, please visit: WWW.LIAHALLORAN.COM CATALOG NOTES. The front and back cover of this catalog will glow in the dark. Just leave it open so it can charge with any light source. Then turn off the lights! You can also enjoy two posters of Messier in positive and negative versions included inside. Cahill Center for Astronomy and Astrophysics 1216 East California Boulevard, Pasadena, CA 91125 Contact: Ann Rho at [email protected] or (626) 395-4223 WWW.CALTECH.EDU DEEP SKY COMPANION When I first read about French Lia Halloran’s work often uses science astronomer Charles Messier’s initially as a conceptual bounding point frustrated attempts at comet hunting, to explore how perception, time which instead led to a blurry nebulae and scale inform a constant desire (M1), I related the account to my own to understand our physical and challenging first stabs at observing the have come to know what we know are the origins of the psychological relationship to the night sky. In college, I was given a small Deep Sky Companion series. world we inhabit. Solo exhibitions Celestron telescope for Christmas and When he came across fuzzy objects, or heard of her work have been held at eagerly and faithfully observed planets, about them from others, Messier would take note ‘of venues in New York, Miami, Boston, Jupiter’s moons (wow!) and Saturn’s rings objects to be avoided while hunting for comets’ so he Los Angeles, London, Vienna and (double wow!).
    [Show full text]