DOCSLIB.ORG

Eric Joseph Murphy

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Eric Joseph Murphy Eric Joseph Murphy First-Author 100. Murphy, Eric J. 2013, Astrophysical Journal, 777, 58 Refereed “The Role of Merger Stage on Galaxy Radio Spectra in Local Infrared-Bright Starburst Galaxies” Publications 99. Murphy, E.J., et al. 2013, Astrophysical Journal, 768, 2 “Radio and Mid-Infrared Properties of Compact Starbursts: Distancing Themselves from the Main Sequence” 98. Murphy, E.J., et al. 2012, Astrophysical Journal, 761, 97 “The Star Formation in Radio Survey: GBT 33 GHz Observations of Nearby Galaxy Nuclei and Extranuclear Star-Forming Regions” 97. Murphy, E.J., Porter, T.A., Moskalenko, I.V., Helou, G., and Strong, A.W., 2012, Astrophysical Journal, 750, 126 “Characterizing Cosmic-Ray Propagation in Massive Star-Forming Regions: The Case of 30Doradus and the Large Magellanic Cloud” 96. Murphy, E.J., et al. 2011, Astrophysical Journal, 737, 67 “Calibrating Extinction-Free Star Formation Rate Diagnostics with 33 GHz Free-Free Emission in NGC 6946” 95. Murphy, E.J., Chary, R-.R., Dickinson, M., Pope, A., Frayer, D.T., and Lin, L. 2011, Astrophysical Journal, 732, 126 “An Accounting of the Dust-Obscured Star Formation and Accretion Histories Over the Last ∼11 Billion Years” 94. Murphy, E.J., et al. 2010, Astrophysical Journal Letters, 709, L108 “The Detection of Anomalous Dust Emission in the Nearby Galaxy NGC 6946” 93. Murphy, Eric J. 2009, Astrophysical Journal, 706, 482 “The Far-Infrared–Radio Correlation at High Redshifts: Physical Considerations and Prospects for the Square Kilometer Array” 92. Murphy, E.J., Chary, R.-R., Alexander, D. M., Dickinson, M., Magnelli, B., Morrison, G., Pope, A., and Teplitz, H. I. 2009, Astrophysical Journal, 698, 1380 “Balancing the Energy Budget between Star-Formation and AGN in High Redshift Infrared Lumi- nous Galaxies” 91. Murphy, E.J., Kenney, J. D. P., Helou, G., Chung, A., and Howell, J. H. 2009, Astrophysical Journal, 694, 1435 “Environmental Effects in Clusters: Modified Far-Infrared–Radio Relations within Virgo Cluster Galaxies” 90. Murphy, E.J., Helou, G.., Kenney, J.D.P., Armus, L., and Braun, R 2008, Astrophysical Journal, 678, 828 “Connecting Far-Infrared and Radio Morphologies of Disk Galaxies: Cosmic-Ray Electron Diffusion After Star Formation Episodes” 89. Murphy, E.J., Helou, G., Braun, R., Kenney, J.D.P., Armus, L., et al., 2006, Astrophysical Journal Letters, 651, L111 “The Effect of Star Formation on the Far-Infrared–Radio Correlation within Galaxies” 88. Murphy, E.J.,Braun, R., Helou, G.,Armus, L.,Kenney, J.D.P., et al. 2006, Astrophysical Journal, 638, 157 “An Initial Look at the Far-Infrared-Radio Correlation within Nearby Star-forming Galaxies Using the Spitzer Space Telescope” 87. Murphy, E.J., Demarque, P., and Guenther, D.B. 2004, Astrophysical Journal, 605, 472 “A Preliminary Seismic Analysis of 51 Peg: Large and Small Spacings from Standard Models” Other 86. Bothwell, M.S., et al. 2013, Astrophysical Journal, in press (arXiv:1309.3257) Refereed “SPT 0538-50: Physical conditions in the ISM of a strongly lensed dusty star-forming galaxy at Publications z =2.8” 85. Irwin, J. et al. 2013, Astronomical Journal, 146, 164 “CHANG-ES III: UGC10288 – An Edge-on Galaxy with a Background Double-lobed Radio Source” 84. Haan, S., et al. 2013, Monthly Notices of the Royal Astronomical Society, 434, 1264 “The Build-up of Nuclear Stellar Cusps in Extreme Starburst Galaxies and Major Mergers” 83. Diaz-Santos, T., et al. 2013, Astrophysical Journal, 774, 68 “Explaining the [Cii]157.7 µm Deficit in Luminous Infrared GalaxiesFirst Results from a Herschel/PACS Study of the GOALS Sample” 82. Aravena, M., Murphy, E. J., et al. 2013, Monthly Notices of the Royal Astronomical Society, 433, 498 “Large Gas Reservoirs and Free-Free Emission in Two Lensed Star-Forming Galaxies at z =2.7” 81. Magnelli, B., et al. 2013, Astronomy and Astrophysics, 553, 132 “Release of the deepest Herschel-PACS far-infrared survey: number counts and infrared luminosity functions from combined PEP/GOODS-H observations” 80. Stierwalt, S., et al. 2013, Astrophysical Journal Supplements, 206, 1 “Mid-Infrared Properties of Nearby Luminous Infrared Galaxies I: Spitzer IRS Spectra for the GOALS Sample” 79. Riechers, D.A., et al. 2013, Nature, 496, 329 “A Dust-Obscured Massive Maximum-Starburst Galaxy at a Redshift of 6.34” 78. Li, Y., et al. 2013, Astrophysical Journal, 768, 180 “Star Formation Rates in Resolved Galaxies: Calibrations with Near and Far Infrared Data for NGC5055 and NGC6946” 77. Galmatz, M., et al. 2013, Monthly Notices of the Royal Astronomical Society, 431, 1956 “Calibration of the total infrared luminosity of nearby galaxies from Spitzer and Herschel bands” 76. Hanish, D.J., et al. 2013, Astrophysical Journal, 768, 13 “Far-infrared Properties of Type 1 Quasars” 75. Hezavey, Y. D., et al. 2013, Astrophysical Journal, 767, 132 “ALMA Observations of SPT-discovered, Strongly Lensed, Dusty, Star-forming Galaxies” 74. Weiß, A., et al. 2013, Astrophysical Journal, 767, 88 “ALMA Redshifts of Millimeter-selected Galaxies from the SPT Survey: The Redshift Distribution of Dusty Star-forming Galaxies” 73. Vieira, J.D., et al. 2013, Nature, 495, 344 “High-Redshift, Gravitationally Lensed, Dusty, Starburst Galaxies Revealed by the South Pole Tele- scope and ALMA” 72. Tabatabaei, F.S., Schinnerer, E., Murphy, E.J., et al. 2013, Astronomy and Astrophysics, 552, 19 “A detailed study of the radio-FIR correlation in NGC 6946 with Herschel-PACS/SPIRE from KINGFISH” 71. Norris, R.P., et al. 2013, Publications of the Astronomical Society of Australia, 30, 20 “Radio Continuum Surveys with Square Kilometre Array Pathfinders” 70. Lupu, R. E., et al. 2012, Astrophysical Journal, 757, 135 “Measurements of CO redshifts with Z-Spec for Lensed Submillimeter Galaxies Discovered in the H-ATLAS Survey” 69. Rovilos, E. et al. 2012, Astronomy and Astrophysics, 546, 58 “GOODS-Herschel: Ultra-Deep XMM-Newton Observations Reveal AGN/Star-Formation Connec- tion” 68. Aniano, G. et al. 2012, Astrophysical Journal, 756, 138 “Modeling Dust and Starlight in Galaxies Observed by Spitzer and Herschel: NGC 628 and NGC 6946” 67. Greve, T. R., et al. 2012, Astrophysical Journal, 756, 101 “Submillimeter Observations of Millimeter Bright Galaxies Discovered by the South Pole Telescope” 66. Hinz, J. L. et al. 2012, Astrophysical Journal, 756, 75 “Cool Dust in the Outer Ring of NGC 1291” 65. Buat, V. et al. 2012, Astronomy and Astrophysics, 545, 141 “GOODS-Herschel: dust attenuation properties of UV selected high redshift galaxies” 64. Irwin, J. et al. 2012, Astronomical Journal, 144, 44 “Continuum Halos in Nearby Galaxies: An EVLA Survey (CHANG-ES). II. First Results on NGC 4631” 63. Irwin, J. et al. 2012, Astronomical Journal, 144, 43 “Continuum Halos in Nearby Galaxies: An EVLA Survey (CHANG-ES). I. Introduction to the Survey” 62. Leroy, A.K., et al. 2011, Astronomical Journal, 144, 3 “Estimating the Star Formation Rate at 1 kpc Scales in Nearby Galaxies” 61. Beirao, P., et al., 2010, Astrophysical Journal, 751, 144 “A Study of Heating and Cooling of the ISM in NGC 1097 with Herschel-PACS and Spitzer-IRS” 60. Zemcov, M. et al. 2012, Astrophysical Journal, 749, 114 “High Spectral Resolution Measurement of the Sunyaev-Zel’dovich Effect Null with Z-Spec” 59. Croxall, K.V., et al. 2012, Astrophysical Journal, 747, 81 “Resolving the Far-IR Line Deficit: Photoelectric Heating and Far-IR Line Cooling in NGC 1097 and NGC 4559” 58. Dale, D.A., et al. 2012, Astrophysical Journal, 745, 95 “Herschel Far-Infrared and Sub-millimeter Photometry for the KINGFISH Sample of Nearby Galax- ies” 57. Kennicutt, R.C., Jr., et al. 2011, Publications of the Astronomical Society of the Pacific, 123, 1347 “KINGFISH – Key Insights on Nearby Galaxies: A Far-Infrared Survey with Herschel: Survey Description and Image Atlas” 56. Haan, S. et al. 2011, Astrophysical Journal Supplements, 197, 27 “Spitzer IRS Spectral Mapping of the Toomre Sequence: Spatial Variations of PAH, Gas, and Dust Properties in Nearby Major Mergers” 55. Reddy, N., et al. 2012, Astrophysical Journal, 744, 154 “GOODS-Herschel Measurements of the Dust Attenuation of Typical Star-Forming Galaxies at High Redshift: Observations of UV-Selected Galaxies at z ∼ 2” 54. Diaz-Santos, T., et al. 2011, Astrophysical Journal, 741, 32 “The Spatial Extent of (U)LIRGs in the Mid-Infrared. II. Feature Emission” 53. Bradford, C.M., et al. 2011, Astrophysical Journal Letters, 741, L37 “The Water Vapor Spectrum of APM 08279+5255: X-Ray Heating and Infrared Pumping over Hundreds of Parsecs” 52. Elbaz, D. et al. 2011, Astronomy and Astrophysics, 533, 119 “GOODS-Herschel: An Infrared Main Sequence for Star-Forming Galaxies” 51. Leroy, A.K., et al. 2011, Astrophysical Journal Letters, 739, 25 “Complex Radio Spectral Energy Distributions in Luminous and Ultraluminous Infrared Galaxies” 50. Skibba, R.A., et al. 2011, Astrophysical Journal, 738, 89 “The Emission by Dust and Stars of Nearby Galaxies in the Herschel KINGFISH Survey” 49. Gavazzi, R., et al. 2011, Astrophysical Journal, 738, 125 “Modeling of the HERMES J105751.1+573027 Submillimeter Source Lensed by a Dark Matter Dominated Foreground Group of Galaxies” 48. Krick. J. E., Bridge, C., Desai, V., Mihos, J. C., Murphy, E. J., Rudick, C., Surace, J., and Neill, J. 2011, Astrophysical Journal, 735, 76 “Spitzer IRAC Low Surface Brightness Observations of the Virgo Cluster” 47. Omont, A., et al. 2011, Astronomy and Astrophysics, 530, L3 “Observation of H2O in a strongly lensed Herschel-ATLAS source at z =2.3” 46. Scott, K. S., et al. 2011 Astrophysical Journal, 733, 29 “Redshift Determination and CO Line Excitation Modeling for the Multiply-Lensed Galaxy HLSW- 01” 45. Conley, A., et al. 2011, Astrophysical Journal Letters, 732, L35 “Discovery of a Multiply Lensed Submillimeter Galaxy in Early HerMES Herschel/SPIRE Data” 44. Smolˇci´c, V., et al. 2011, Astrophysical Journal Letters, 731, L27 “The Redshift and Nature of AzTEC/COSMOS 1: A Starburst Galaxy at z =4.6” 43.
Load more

Recommended publications
  • CO Multi-Line Imaging of Nearby Galaxies (COMING) IV. Overview Of
    Publ. Astron. Soc. Japan (2018) 00(0), 1–33 1 doi: 10.1093/pasj/xxx000 CO Multi-line Imaging of Nearby Galaxies (COMING) IV. Overview of the Project Kazuo SORAI1, 2, 3, 4, 5, Nario KUNO4, 5, Kazuyuki MURAOKA6, Yusuke MIYAMOTO7, 8, Hiroyuki KANEKO7, Hiroyuki NAKANISHI9 , Naomasa NAKAI4, 5, 10, Kazuki YANAGITANI6 , Takahiro TANAKA4, Yuya SATO4, Dragan SALAK10, Michiko UMEI2 , Kana MOROKUMA-MATSUI7, 8, 11, 12, Naoko MATSUMOTO13, 14, Saeko UENO9, Hsi-An PAN15, Yuto NOMA10, Tsutomu, T. TAKEUCHI16 , Moe YODA16, Mayu KURODA6, Atsushi YASUDA4 , Yoshiyuki YAJIMA2 , Nagisa OI17, Shugo SHIBATA2, Masumichi SETA10, Yoshimasa WATANABE4, 5, 18, Shoichiro KITA4, Ryusei KOMATSUZAKI4 , Ayumi KAJIKAWA2, 3, Yu YASHIMA2, 3, Suchetha COORAY16 , Hiroyuki BAJI6 , Yoko SEGAWA2 , Takami TASHIRO2 , Miho TAKEDA6, Nozomi KISHIDA2 , Takuya HATAKEYAMA4 , Yuto TOMIYASU4 and Chey SAITA9 1Department of Physics, Faculty of Science, Hokkaido University, Kita 10 Nishi 8, Kita-ku, Sapporo 060-0810, Japan 2Department of Cosmosciences, Graduate School of Science, Hokkaido University, Kita 10 Nishi 8, Kita-ku, Sapporo 060-0810, Japan 3Department of Physics, School of Science, Hokkaido University, Kita 10 Nishi 8, Kita-ku, Sapporo 060-0810, Japan 4Division of Physics, Faculty of Pure and Applied Sciences, University of Tsukuba, 1-1-1 Tennodai, Tsukuba, Ibaraki 305-8571, Japan 5Tomonaga Center for the History of the Universe (TCHoU), University of Tsukuba, 1-1-1 Tennodai, Tsukuba, Ibaraki 305-8571, Japan 6Department of Physical Science, Osaka Prefecture University, Gakuen 1-1,
    [Show full text]
  • Arxiv:Astro-Ph/0304318V1 16 Apr 2003
    The Globular Cluster Luminosity Function: New Progress in Understanding an Old Distance Indicator Tom Richtler Astronomy Group, Departamento de F´ısica, Universidad de Concepci´on, Casilla 160-C, Concepci´on, Chile Abstract. I review the Globular Cluster Luminosity Function (GCLF) with emphasis on recent observational data and theoretical progress. As is well known, the turn-over magnitude (TOM) is a good distance indicator for early-type galaxies within the limits set by data quality and sufficient number of objects. A comparison with distances derived from surface brightness fluctuations with the available TOMs in the V-band reveals, however, many discrepant cases. These cases often violate the condition that the TOM should only be used as a distance indicator in old globular cluster systems. The existence of intermediate age-populations in early-type galaxies likely is the cause of many of these discrepancies. The connection between the luminosity functions of young and old cluster systems is discussed on the basis of modelling the dynamical evolution of cluster systems. Finally, I briefly present the current ideas of why such a universal structure as the GCLF exists. 1 Introduction: What is the Globular Cluster Luminosity Function? Since the era of Shapley, who first explored the size of the Galaxy, the distances to globular clusters often set landmarks in establishing first the galactic, then the extragalactic distance scale. Among the methods which have been developed to determine the distances of early-type galaxies, the usage of globular clusters is one of the oldest, if not the oldest. Baum [5] first compared the brightness of the brightest globular clusters in M87 to those of M31.
    [Show full text]
  • 1. Introduction
    THE ASTROPHYSICAL JOURNAL SUPPLEMENT SERIES, 122:109È150, 1999 May ( 1999. The American Astronomical Society. All rights reserved. Printed in U.S.A. GALAXY STRUCTURAL PARAMETERS: STAR FORMATION RATE AND EVOLUTION WITH REDSHIFT M. TAKAMIYA1,2 Department of Astronomy and Astrophysics, University of Chicago, Chicago, IL 60637; and Gemini 8 m Telescopes Project, 670 North Aohoku Place, Hilo, HI 96720 Received 1998 August 4; accepted 1998 December 21 ABSTRACT The evolution of the structure of galaxies as a function of redshift is investigated using two param- eters: the metric radius of the galaxy(Rg) and the power at high spatial frequencies in the disk of the galaxy (s). A direct comparison is made between nearby (z D 0) and distant(0.2 [ z [ 1) galaxies by following a Ðxed range in rest frame wavelengths. The data of the nearby galaxies comprise 136 broad- band images at D4500A observed with the 0.9 m telescope at Kitt Peak National Observatory (23 galaxies) and selected from the catalog of digital images of Frei et al. (113 galaxies). The high-redshift sample comprises 94 galaxies selected from the Hubble Deep Field (HDF) observations with the Hubble Space Telescope using the Wide Field Planetary Camera 2 in four broad bands that range between D3000 and D9000A (Williams et al.). The radius is measured from the intensity proÐle of the galaxy using the formulation of Petrosian, and it is argued to be a metric radius that should not depend very strongly on the angular resolution and limiting surface brightness level of the imaging data. It is found that the metric radii of nearby and distant galaxies are comparable to each other.
    [Show full text]
  • The Centre of the Active Galaxy NGC 1097
    Figure 4: Relative map- References ping speed of SCOWL 1000000 versus the ALMA Com- The OWL Instrument Concept Studies have been pact Configuration. published as ESO internal reports. They can be ob- tained from the PI’s or ESO. 10000 (1) D’Odorico S., Moorwood A. F .M., Beckers, J. 1991, Journal of Optics 22, 85 (2) CODEX, Cosmic Dynamics Experiment, OWL–CSR-ESO-00000-0160, October 2005 100 (3) T-OWL, Thermal Infrared Imager and Spectrograph for OWL, OWL–CSR-ESO-00000-0161, October 2005 (4) QuantEYE, OWL–CSR-ESO-00000-0162, October 0 2005 (5) SCOWL, Submillimeter Camera for OWL; OWL–CSR-ESO-00000-0163, September 2005 (6) MOMFIS, Multi Object Multi Field IR Spectrograph, OWL–CSR-ESO-00000-0164, September 2005 0.01 (7) ONIRICA, OWL NIR Imaging Camera, OWL–CSR-ESO-00000-0165, October 2005 (8) EPICS, Earth-like Planet Imaging Camera and Spectrograph, OWL–CSR-ESO-00000-0166, 0.0001 October 2005 850 450 350 850 450 350 λ(µm) (9) HyTNIC, Hyper-Telescope Near Infrared Camera, ALMA Compact SCOWL OWL–CSR-ESO-00000-0167, October 2005 The Centre of the Active Galaxy NGC 1097 Near-infrared images of the active galaxy A colour-composite image of the cen- NGC 1097 have been obtained by a team of tral 5 500 light-years wide region of astronomers1 using NACO on the VLT. Located the spiral galaxy NGC 1097, obtained with NACO on the VLT. More than at a distance of about 45 million light years in 300 star-forming regions – white spots the southern constellation Fornax, NGC 1097 is in the image – are distributed along a relatively bright, barred spiral galaxy seen a ring of dust and gas in the image.
    [Show full text]
  • Arm Structure in Anemic Spiral Galaxies
    Arm Structure in Anemic Spiral Galaxies Debra Meloy Elmegreen1, Bruce G. Elmegreen2, Jay A. Frogel3,4, Paul B. Eskridge5, Richard W. Pogge3, Andrew Gallagher1, and Joel Iams1,6 ABSTRACT Anemic galaxies have less prominent star formation than normal galaxies of the same Hubble type. Previous studies showed they are deficient in total atomic hydrogen but not in molecular hydrogen. Here we compare the combined surface densities of HI and H2 at mid-disk radii with the Kennicutt threshold for star formation. The anemic galaxies are below threshold, which explains their lack of prominent star formation, but they are not much different than other early type galaxies, which also tend to be below threshold. The spiral wave amplitudes of anemic and normal galaxies were also compared, using images in B and J passbands from the OSU Bright Spiral Galaxy Survey. Anemic galaxies have normal spiral wave properties too, with the same amplitudes and radial dependencies as other galaxies of the same arm class. Because of the lack of gas, spiral waves in early type galaxies and anemics do not have a continuous supply of stars with low velocity dispersions to maintain a marginally stable disk. As a result, they are either short-lived, evolving toward lenticulars and S0 types in only a few rotations at mid-disk, or they are driven by the asymmetries associated with gas removal in the cluster environment. arXiv:astro-ph/0205105v1 7 May 2002 Subject headings: galaxies: clusters: individual (Virgo) — galaxies: evolution — galaxies: spiral — galaxies: structure 1Department of Physics and Astronomy, Vassar College, Poughkeepsie, NY 12604; e–mail: [email protected], [email protected] 2IBM T.
    [Show full text]
  • Astronomy Magazine Special Issue
    γ ι ζ γ δ α κ β κ ε γ β ρ ε ζ υ α φ ψ ω χ α π χ φ γ ω ο ι δ κ α ξ υ λ τ μ β α σ θ ε β σ δ γ ψ λ ω σ η ν θ Aι must-have for all stargazers η δ μ NEW EDITION! ζ λ β ε η κ NGC 6664 NGC 6539 ε τ μ NGC 6712 α υ δ ζ M26 ν NGC 6649 ψ Struve 2325 ζ ξ ATLAS χ α NGC 6604 ξ ο ν ν SCUTUM M16 of the γ SERP β NGC 6605 γ V450 ξ η υ η NGC 6645 M17 φ θ M18 ζ ρ ρ1 π Barnard 92 ο χ σ M25 M24 STARS M23 ν β κ All-in-one introduction ALL NEW MAPS WITH: to the night sky 42,000 more stars (87,000 plotted down to magnitude 8.5) AND 150+ more deep-sky objects (more than 1,200 total) The Eagle Nebula (M16) combines a dark nebula and a star cluster. In 100+ this intense region of star formation, “pillars” form at the boundaries spectacular between hot and cold gas. You’ll find this object on Map 14, a celestial portion of which lies above. photos PLUS: How to observe star clusters, nebulae, and galaxies AS2-CV0610.indd 1 6/10/10 4:17 PM NEW EDITION! AtlAs Tour the night sky of the The staff of Astronomy magazine decided to This atlas presents produce its first star atlas in 2006.
    [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]
  • SAC's 110 Best of the NGC
    SAC's 110 Best of the NGC by Paul Dickson Version: 1.4 | March 26, 1997 Copyright °c 1996, by Paul Dickson. All rights reserved If you purchased this book from Paul Dickson directly, please ignore this form. I already have most of this information. Why Should You Register This Book? Please register your copy of this book. I have done two book, SAC's 110 Best of the NGC and the Messier Logbook. In the works for late 1997 is a four volume set for the Herschel 400. q I am a beginner and I bought this book to get start with deep-sky observing. q I am an intermediate observer. I bought this book to observe these objects again. q I am an advance observer. I bought this book to add to my collect and/or re-observe these objects again. The book I'm registering is: q SAC's 110 Best of the NGC q Messier Logbook q I would like to purchase a copy of Herschel 400 book when it becomes available. Club Name: __________________________________________ Your Name: __________________________________________ Address: ____________________________________________ City: __________________ State: ____ Zip Code: _________ Mail this to: or E-mail it to: Paul Dickson 7714 N 36th Ave [email protected] Phoenix, AZ 85051-6401 After Observing the Messier Catalog, Try this Observing List: SAC's 110 Best of the NGC [email protected] http://www.seds.org/pub/info/newsletters/sacnews/html/sac.110.best.ngc.html SAC's 110 Best of the NGC is an observing list of some of the best objects after those in the Messier Catalog.
    [Show full text]
  • Dissecting the Origin of the Submillimetre Emission in Nearby Galaxies with Herschel and LABOCA
    MNRAS 439, 2542–2570 (2014) doi:10.1093/mnras/stu113 Advance Access publication 2014 February 17 Dissecting the origin of the submillimetre emission in nearby galaxies with Herschel and LABOCA M. Galametz,1,2‹ M. Albrecht,3 R. Kennicutt,1 G. Aniano,4 F. Bertoldi,3 D. Calzetti,5 K. V. Croxall,6 D. Dale,7 B. Draine,8 C. Engelbracht,9,10 K. Gordon,11 J. Hinz,9 Downloaded from https://academic.oup.com/mnras/article-abstract/439/3/2542/1092583 by Princeton University user on 02 May 2019 L. K. Hunt,12 A. Kirkpatrick,5 E. Murphy,13 H. Roussel,14 R. A. Skibba,15 F. Walter,16 A. Weiss17 andC.D.Wilson18 1Institute of Astronomy, University of Cambridge, Madingley Road, Cambridge CB3 0HA, UK 2European Southern Observatory, Karl-Schwarzschild-Str. 2, D-85748 Garching-bei-Munchen,¨ Germany 3Argelander-Institut fur¨ Astronomie, Abteilung Radioastronomie, Auf dem Hugel¨ 71, D-53121 Bonn, Germany 4Institut d’Astrophysique Spatiale, Orsay 5Department of Astronomy, University of Massachusetts, Amherst, MA 01003, USA 6Department of Astronomy, The Ohio State University, 4051 McPherson Laboratory, 140 W 18th Ave., Columbus, OH 43210, USA 7Department of Physics and Astronomy, University of Wyoming, Laramie, WY 82071, USA 8Department of Astrophysical Sciences, Princeton University, Princeton, NJ 08544, USA 9Steward Observatory, University of Arizona, Tucson, AZ 85721, USA 10Raytheon Company, 1151 East Hermans Road, Tucson, AZ 85756, USA 11Space Telescope Science Institute, 3700 San Martin Drive, Baltimore, MD 21218, USA 12INAF Osservatorio Astrofisico di Arcetri,
    [Show full text]
  • ASTRONOMY and ASTROPHYSICS Ultraviolet Spectral Properties of Magellanic and Non-Magellanic Irregulars, H II and Starburst Galaxies?
    Astron. Astrophys. 343, 100–110 (1999) ASTRONOMY AND ASTROPHYSICS Ultraviolet spectral properties of magellanic and non-magellanic irregulars, H II and starburst galaxies? C. Bonatto1, E. Bica1, M.G. Pastoriza1, and D. Alloin2;3 1 Universidade Federal do Rio Grande do Sul, IF, CP 15051, Porto Alegre 91501–970, RS, Brazil 2 SAp CE-Saclay, Orme des Merisiers Batˆ 709, F-91191 Gif-Sur-Yvette Cedex, France Received 5 October 1998 / Accepted 9 December 1998 Abstract. This paper presents the results of a stellar popula- we dedicate the present work to galaxy types with enhanced 1 1 tion analysis performed on nearby (VR 5 000 km s− ) star- star formation in the nearby Universe (VR 5 000 kms− ). We forming galaxies, comprising magellanic≤ and non-magellanic include low and moderate luminosity irregular≤ galaxies (magel- irregulars, H ii and starburst galaxies observed with the IUE lanic and non-magellanic irregulars, and H ii galaxies) and high- satellite. Before any comparison of galaxy spectra, we have luminosity ones (mergers, disrupting, etc.). The same method formed subsets according to absolute magnitude and morpho- used in the analyses of star clusters, early-type and spiral gala- logical classification. Subsequently, we have coadded the spec- xies (Bonatto et al. 1995, 1996 and 1998, hereafter referred to tra within each subset into groups of similar spectral proper- as Papers I, II and III, respectively), i.e. that of grouping objects ties in the UV. As a consequence, high signal-to-noise ratio with similar spectra into templates of high signal-to-noise (S/N) templates have been obtained, and information on spectral fea- ratio, is now applied to the sample of irregular and/or peculiar tures can now be extracted and analysed.
    [Show full text]
  • Caldwell Catalogue - Wikipedia, the Free Encyclopedia
    Caldwell catalogue - Wikipedia, the free encyclopedia Log in / create account Article Discussion Read Edit View history Caldwell catalogue From Wikipedia, the free encyclopedia Main page Contents The Caldwell Catalogue is an astronomical catalog of 109 bright star clusters, nebulae, and galaxies for observation by amateur astronomers. The list was compiled Featured content by Sir Patrick Caldwell-Moore, better known as Patrick Moore, as a complement to the Messier Catalogue. Current events The Messier Catalogue is used frequently by amateur astronomers as a list of interesting deep-sky objects for observations, but Moore noted that the list did not include Random article many of the sky's brightest deep-sky objects, including the Hyades, the Double Cluster (NGC 869 and NGC 884), and NGC 253. Moreover, Moore observed that the Donate to Wikipedia Messier Catalogue, which was compiled based on observations in the Northern Hemisphere, excluded bright deep-sky objects visible in the Southern Hemisphere such [1][2] Interaction as Omega Centauri, Centaurus A, the Jewel Box, and 47 Tucanae. He quickly compiled a list of 109 objects (to match the number of objects in the Messier [3] Help Catalogue) and published it in Sky & Telescope in December 1995. About Wikipedia Since its publication, the catalogue has grown in popularity and usage within the amateur astronomical community. Small compilation errors in the original 1995 version Community portal of the list have since been corrected. Unusually, Moore used one of his surnames to name the list, and the catalogue adopts "C" numbers to rename objects with more Recent changes common designations.[4] Contact Wikipedia As stated above, the list was compiled from objects already identified by professional astronomers and commonly observed by amateur astronomers.
    [Show full text]
  • The Caldwell Catalogue+Photos
    The Caldwell Catalogue was compiled in 1995 by Sir Patrick Moore. He has said he started it for fun because he had some spare time after finishing writing up his latest observations of Mars. He looked at some nebulae, including the ones Charles Messier had not listed in his catalogue. Messier was only interested in listing those objects which he thought could be confused for the comets, he also only listed objects viewable from where he observed from in the Northern hemisphere. Moore's catalogue extends into the Southern hemisphere. Having completed it in a few hours, he sent it off to the Sky & Telescope magazine thinking it would amuse them. They published it in December 1995. Since then, the list has grown in popularity and use throughout the amateur astronomy community. Obviously Moore couldn't use 'M' as a prefix for the objects, so seeing as his surname is actually Caldwell-Moore he used C, and thus also known as the Caldwell catalogue. http://www.12dstring.me.uk/caldwelllistform.php Caldwell NGC Type Distance Apparent Picture Number Number Magnitude C1 NGC 188 Open Cluster 4.8 kly +8.1 C2 NGC 40 Planetary Nebula 3.5 kly +11.4 C3 NGC 4236 Galaxy 7000 kly +9.7 C4 NGC 7023 Open Cluster 1.4 kly +7.0 C5 NGC 0 Galaxy 13000 kly +9.2 C6 NGC 6543 Planetary Nebula 3 kly +8.1 C7 NGC 2403 Galaxy 14000 kly +8.4 C8 NGC 559 Open Cluster 3.7 kly +9.5 C9 NGC 0 Nebula 2.8 kly +0.0 C10 NGC 663 Open Cluster 7.2 kly +7.1 C11 NGC 7635 Nebula 7.1 kly +11.0 C12 NGC 6946 Galaxy 18000 kly +8.9 C13 NGC 457 Open Cluster 9 kly +6.4 C14 NGC 869 Open Cluster
    [Show full text]