DOCSLIB.ORG

An Improved Geometric Test for Optical Surfaces

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
An Improved Geometric Test for Optical Surfaces An Improved Geometric Test for Optical Surfaces A Thesis Submitted for the Degree of Doctor of Philosophy of the University of London by Young-Soo Kim Department of Physics and Astronomy University College University of London 1998 ProQuest Number: U642131 All rights reserved INFORMATION TO ALL USERS The quality of this reproduction is dependent upon the quality of the copy submitted. In the unlikely event that the author did not send a complete manuscript and there are missing pages, these will be noted. Also, if material had to be removed, a note will indicate the deletion. uest. ProQuest U642131 Published by ProQuest LLC(2015). Copyright of the Dissertation is held by the Author. All rights reserved. This work is protected against unauthorized copying under Title 17, United States Code. Microform Edition © ProQuest LLC. ProQuest LLC 789 East Eisenhower Parkway P.O. Box 1346 Ann Arbor, Ml 48106-1346 An Improved Geometric Test for Optical Surfaces Abstract As the quality of large optics are required to be more accurate, even to the diffraction limit, more accurate testing methods are needed. For example, large telescope optics consist of aspheric concave and convex mirrors with significant aspheric departures. Testing these optics using classical methods usually requires the use of a null lens or mirror. However, the null corrector itself can be wrong and thus lead to incorrect test results. One example is the primary mirror of Hubble Space Telescope. In order to avoid such a mistake, at least two independent test methods should be applied. A new test method - a quantitative knife-edge test (AQuaKET) - has been developed by revolutionizing one of the oldest testing method, the Foucault test. One of the advantages of the Foucault test is that it does not need any additional optical components which can introduce errors, whereas a disadvantage is that it does not give a quantitative result. Whilst maintaining the merits of the Foucault test, AQuaKET embodies novel ideas for acquiring quantitative results. The thesis describes the application of opto-electronic, data acquisition, and data processing techniques including refined simplex method to the Foucault test. Test results of three mirrors are presented which validate the reliability of the method for testing optics with high accuracy, including aspheric mirrors. Several potential improvements are discussed and future work is suggested. Finally, the overall methodology developed is compared with other approaches currently available. Glossary and symbols A AT Anglo-Australian Telescope ADASS Astronomical Data Analysis Software and Systems AQuaKET A Quantitative Knife-Edge Test ASP Astronomical Society of the Pacific °C temperature in Celsius CC conic constant CCD Charge-Coupled Device CFHT Canada-France-Hawaii Telescope CGH Computer-Generated Hologram CoC Centre of Curvature CORI COaxial Reference Interferometer, HST COSTAR Corrective Optics Space Telescope Axial Replacement, HST DOS Disk Operating System ESO European Southern Observatory exp exponential F Focal ratio FWHM Full Width Half Maximum HET Hobby-Eberly telescope HST Hubble Space Telescope INT Isaac Newton Telescope IR Infrared LET Large Binocular Telescope MAI Multiple Annular Interferograms MMT Multiple Mirror Telescope MPIA Max-Planck-Institut für Astronomie Nt Refractive index at a temperature t OPD Optical Path Difference OS Operating System PC Personal Computer P-V Peak-to-Valley RC Ritchey-Chrétien RMS Root Mean Square RNC Reflective Null Corrector ROC Radius Of Curvature SNI Sub-Nyquist Interferometry SPI Scatter-plate interferometry STD Standard deviation UCL University College London, London, U.K. U.K. United Kingdom UKIRT United Kingdom Infrared Telescope U.S.A. United States of America UV Ultraviolet VLT Very Large Telescope, ESO WHT William Herschel Telescope Zi Coefficient of Zemike polynomials Ô standard deviation X wavelength variance V frequency Z angle between two lines Contents Abstract 2 Glossary and symbols ................................................................................. 3 Contents 5 List of Tables 10 List of Figures 13 1. Introduction 17 1.1 Optical telescopes .................................................................... 18 1.1.1 History of optical telescopes 18 1.1.2 Large telescopes and their optics ..................... 20 1.1.3 A problem in Hubble Space Telescope: primary mirror .. 25 1.1.4 Accuracy requirements: the Gemini telescopes as an example 26 1.1.5 Probable height error estimation from slope error ....... 29 1.2 Optical testing ................................................................................. 32 1.2.1 General categorization of test methods 32 1.2.2 Test methods for large aspheric optics 33 1.2.3 Test methods for large convex mirror 37 1.3 Foucault test .................................................................................... 39 1.3.1 Principle of the Foucault test 40 1.3.2 Advantages and disadvantages of the Foucault test ..... 42 1.3.3 Accuracy of the Foucault test: survey of papers ..... 43 1.4 A Quantitative Knife-Edge Test (AQuaKET) 44 1.4.1 Previous works 44 1.4.2 Goals of AQuaKET 45 1.4.3 Principle of AQuaKET 46 1.5 Description of following chapters ................................................. 49 2. Equipment .................................................................................................... 51 2.1 Light source and accessories 54 2.1.1 Accuracy estimation on intensity variation .................. 54 2.1.2 Halogen lamp 57 2.1.3 He-Ne laser 58 2.2 Two knife-edges and supports ..................................................... 63 2.2.1 Set-up errors of the stages ................................................ 63 2.2.2 Micropositioner ............................................................... 68 2.3 CCD camera and frame grabber 69 2.4 Parallax .................................................................... 71 3. Data Acquisition ........................................................................................... 76 3.1 Mirror image size 78 3.2 Alignment 80 3.2.1 Multi-axes measurement ........................................... 81 3.2.2 Multi-areas measurement ........................................... 91 3.2.3 Accuracy and diffraction effect ............................... 97 3.3 Mirror image capture 99 3.3.1 Knife movements 99 3.3.2 Binning and data size 100 3.3.3 Step size 103 3.3.4 Saving data and measuring time ............................... 104 4. Data Processing ............................................................................................ 107 4.1 Finding knife position 109 4.1.1 Intensity subtraction method .......................................... 110 4.1.2 Finding peak step ........................................................ 115 4.1.3 Intensity difference area .................................................. 118 4.1.4 Blade angle correction 119 4.2 Direct slope calculation method .................................................... 121 4.3 Local focus sensing method .......................................................... 125 4.3.1 Local focus calculation 125 4.3.2 Slope calculation 127 4.3.3 Accuracy estimation 131 4.4 Height calculation .............................................................................. 132 4.4.1 Height calculation method 133 4.4.2 Numerical integration methods 134 4.4.3 Height error calculation 137 4.5 Zemike polynomials .......................................................................... 139 4.5.1 Zemike polynomials in Cartesian coordinates ................. 139 4.5.2 Zemike polynomials fitting ............................................... 140 4.5.3 Derivation of Seidel coefficients ...................................... 143 5. Refined Simplex Method ............................................................................... 145 5.1 General features of the simplex method 146 5.1.1 History 146 5.1.2 Basic idea of minimization 147 5.1.3 Principle of the simplex method .................................. 147 5.1.4 Advantages and disadvantages 153 5.1.5 Test mn of the simplex method .................................. 154 5.2 Initial condition 155 5.2.1 Basic idea 156 5.2.2 Test results 157 5.3 Shrinkage 162 6. Results and Discussion .................................................................................. 164 6.1 The big mirror test ............................................................................. 165 6.1.1 AQuaKET result 165 6.1.2 Scatter-plate interferometry 175 6.1.3 Test result by scatter-plate interferometer ..................... 177 6.1.4 Discussions on the test results 179 6.2 The small mirror test ......................................................................... 180 6.2.1 AQuaKET result 181 6.2.2 Aspherics test 188 6.3 The metal mirror test ..................................................................... 197 6.3.1 AQuaKET result 198 6.3.2 Test result of scatter-plate interferometry .................. 201 6.4 Discussion ...................................................................................... 202 6.4.1 Test limit on asphericity .................................................. 202 6.4.2 Environmental effects ..................................................... 204 6.4.3 User-friendly software .................................................... 207 6.4.3 Testing time .................................................................... 209 7. Conclusions ................................................................................................
Load more

Recommended publications
  • Nova Report 2006-2007
    NOVA REPORTNOVA 2006 - 2007 NOVA REPORT 2006-2007 Illustration on the front cover The cover image shows a composite image of the supernova remnant Cassiopeia A (Cas A). This object is the brightest radio source in the sky, and has been created by a supernova explosion about 330 year ago. The star itself had a mass of around 20 times the mass of the sun, but by the time it exploded it must have lost most of the outer layers. The red and green colors in the image are obtained from a million second observation of Cas A with the Chandra X-ray Observatory. The blue image is obtained with the Very Large Array at a wavelength of 21.7 cm. The emission is caused by very high energy electrons swirling around in a magnetic field. The red image is based on the ratio of line emission of Si XIII over Mg XI, which brings out the bi-polar, jet-like, structure. The green image is the Si XIII line emission itself, showing that most X-ray emission comes from a shell of stellar debris. Faintly visible in green in the center is a point-like source, which is presumably the neutron star, created just prior to the supernova explosion. Image credits: Creation/compilation: Jacco Vink. The data were obtained from: NASA Chandra X-ray observatory and Very Large Array (downloaded from Astronomy Digital Image Library http://adil.ncsa.uiuc. edu). Related scientific publications: Hwang, Vink, et al., 2004, Astrophys. J. 615, L117; Helder and Vink, 2008, Astrophys. J. in press.
    [Show full text]
  • Large Telescopes and Why We Need Them Transcript
    Large telescopes and why we need them Transcript Date: Wednesday, 9 May 2012 - 1:00PM Location: Museum of London 9 May 2012 Large Telescopes And Why we Need Them Professor Carolin Crawford Astronomy is a comparatively passive science, in that we can’t engage in laboratory experiments to investigate how the Universe works. To study any cosmic object outside of our Solar System, we can only work with the light it emits that happens to fall on Earth. How much we can interpret and understand about the Universe around us depends on how well we can collect and analyse that light. This talk is about the first part of that problem: how we improve the collection of light. The key problem for astronomers is that all stars, nebulae and galaxies are so very far away that they appear both very small, and very faint - some so much so that they can’t be seen without the help of a telescope. Its role is simply to collect more light than the unaided eye can, making astronomical sources appear both bigger and brighter, or even just to make most of them visible in the first place. A new generation of electronic detectors have made observations with the eye redundant. We now have cameras to record the images directly, or once it has been split into its constituent wavelengths by spectrographs. Even though there are a whole host of ingenious and complex instruments that enable us to record and analyse the light, they are still only able to work with the light they receive in the first place.
    [Show full text]
  • The GLENDAMA Database
    Technical Report & User's Guide The GLENDAMA Database Luis J. Goicoechea, Vyacheslav N. Shalyapin? and Rodrigo Gil-Merino Universidad de Cantabria, Santander, Spain ABSTRACT This is the first version (v1) of the Gravitational LENses and DArk MAtter (GLENDAMA) database accessible at http://grupos.unican.es/glendama/database The new database contains more than 6000 ready-to-use (processed) astronomical frames corresponding to 15 objects that fall into three classes: (1) lensed QSO (8 objects), (2) binary QSO (3 objects), and (3) accretion-dominated radio-loud QSO (4 objects). Data are also divided into two categories: freely available and available upon request. The second category includes observations related to our yet unpublished analyses. Although this v1 of the GLENDAMA archive incorporates an X-ray monitoring campaign for a lensed QSO in 2010, the rest of frames (imaging, polarimetry and spectroscopy) were taken with NUV, visible and NIR facilities over the period 1999−2014. The monitorings and follow-up observations of lensed QSOs are key tools for discussing the accretion flow in distant QSOs, the redshift and structure of intervening (lensing) galaxies, and the physical properties of the Universe as a whole. Subject headings: astronomical databases | gravitational lensing: strong and micro | quasars: general | quasars: supermassive black holes | quasars: ac- cretion | galaxies: general | galaxies: distances and redshifts | galaxies: halos arXiv:1505.04317v2 [astro-ph.IM] 19 May 2015 | cosmological parameters ?permanent address: Institute for Radiophysics and Electronics, Kharkov, Ukraine { 2 { 1. Target objects and facilities At present, the Gravitational LENses and DArk MAtter (GLENDAMA) project at the Universidad de Cantabria (UC) is conducting a programme of observation of eight lensed QSOs with facilities at the European Northern Observatory (ENO).
    [Show full text]
  • 9. Instruments and Techniques (Instruments Et Techniques)
    9. INSTRUMENTS AND TECHNIQUES (INSTRUMENTS ET TECHNIQUES) PRESIDENT: E.H. Richardson VICE-PRESIDENT: W. C. Livingston ORGANIZING COMMITTEE: T. Bolton, W. B. Burton, P. Connes, J. Davis, J. L. Heudier, I. M. Kopylov, A. Labeyrie, D. McMullan, A. B. Meinel, N. N. Mikhel'son, J. Ring, J. Rosch, N. Steshenko, G.A.H. Walker, M. F. Walker. I. MEETING AT THE 6 METRE TELESCOPE The major activity organized by Commission 9 was IAU Colloquium 67, Instrumentation for Large Telescopes, held 8-10 Sept., 1981, on a portion of the observing floor of the 6 metre telescope of the Special Astrophysical Observatory, USSR. The cooling coils in the floor were turned off and a rug laid. The enormous BTA (Bolshoi Altazimuth Telescope) provided a spectacular back drop to the 88 participants. Between sessions, the particpants were shown every detail of the telescope by its Chief Designer, Dr. B. K. Ioannisiani, and SAO staff. Night observations continued: speckle interferometry. The Proceedings, edited by C. M. Humphries, and consisting of some 40 titles and three photographs at the BTA, will be published by Reidel as "Instrumentation for Astronomy with Large Optical Telescopes." There are four sections. 1) Telescopes (existing, e.g. 6 metre, MMT and CFHT; under construction, e.g. 4.2 metre Herschel and Iraqi 3.5 metre; and planned, e.g. 7.6 metre Texas and USSR 6 metre polar); 2) Spectrographs (including multi-object, wide field, and with and without slit); 3) Interferometers; and 4) Detectors. The smallest telescope described, 5 cm, is located at the most extreme site, the South Pole, and is used to measure solar oscillations by the Observatoire de Nice.
    [Show full text]
  • (68346) 2001 KZ66 from Combined Radar and Optical Observations
    MNRAS 000,1–13 (2021) Preprint 1 September 2021 Compiled using MNRAS LATEX style file v3.0 Detection of the YORP Effect on the contact-binary (68346) 2001 KZ66 from combined radar and optical observations Tarik J. Zegmott,1¢ S. C. Lowry,1 A. Rożek,1,2 B. Rozitis,3 M. C. Nolan,4 E. S. Howell,4 S. F. Green,3 C. Snodgrass,2,3 A. Fitzsimmons,5 and P. R. Weissman6 1Centre for Astrophysics and Planetary Science, University of Kent, Canterbury, CT2 7NH, UK 2Institute for Astronomy, University of Edinburgh, Royal Observatory, Edinburgh, EH9 3HJ, UK 3Planetary and Space Sciences, School of Physical Sciences, The Open University, Milton Keynes, MK7 6AA, UK 4Lunar and Planetary Laboratory, University of Arizona, Tucson, AZ 85721, USA 5Astrophysics Research Centre, Queens University Belfast, Belfast, BT7 1NN, UK 6Planetary Sciences Institute, Tucson, AZ 85719, USA Accepted XXX. Received YYY; in original form ZZZ ABSTRACT The YORP effect is a small thermal-radiation torque experienced by small asteroids, and is considered to be crucial in their physical and dynamical evolution. It is important to understand this effect by providing measurements of YORP for a range of asteroid types to facilitate the development of a theoretical framework. We are conducting a long-term observational study on a selection of near-Earth asteroids to support this. We focus here on (68346) 2001 KZ66, for which we obtained both optical and radar observations spanning a decade. This allowed us to perform a comprehensive analysis of the asteroid’s rotational evolution. Furthermore, radar observations from the Arecibo Observatory enabled us to generate a detailed shape model.
    [Show full text]
  • Curriculum Vitæ
    Curriculum vitæ Robert Andrew Ernest Fosbury as of: June 2012 Date of birth: 2nd April 1948 Place: Farnham, Surrey, England Nationality: British Present address: Michael-Huber-Weg 12 81667 München Germany Tel:+49 89 609 96 50 [domiciled in Germany] Email: [email protected] ; [email protected] Married to: Patricia Susan Fosbury (née Major-Allen) Children: Emma Louise – 1974, England Thomas Benjamin – 1977, Australia Andrew Daniel – 1977, Australia Present employer: European Southern Observatory Karl Schwarzschild Straße 2 85748 Garching bei München Germany Tel: +49 89 320 06 235 Societies: Fellow of the Royal Astronomical Society, Council service 1983, 1984 Member of the International Astronomical Union Fluorescent Mineral Society: member of Research Chapter Present job 2011–> European Southern Observatory (ESO) Astronomer Emeritus. I am also employed part-time by ESO to perform certain functions for them including editing the ESO Annual Report (http://www.eso.org/public/products/annualreports/ann-report2010/ ) and representing ESO (as an observer) at the United Nations Committee on the Peaceful Uses of Outer Space. As part of this UN work, I am a member of Action Team 14 which is tasked to make recommendations to the General Assembly and the Security Council for the mitigation of the threat of Earth impact of potentially hazardous Near Earth Asteroids (NEO). Also, I currently serve on the European Research Council panel for the evaluation of Advanced Grant proposals in Universe Sciences. Previous jobs and appointments 2003–2006 Visiting Professor at the University of Sheffield 1985–2010 Staff member (ESA) of the (Hubble) Space Telescope – European Coordinating Facility (ST-ECF): co-funded by the European Space Agency (ESA) and the European Southern Observatory and hosted by the latter organization at its headquarters near Munich.
    [Show full text]
  • Photometric Distances to Six Bright Resolved Galaxies?
    ASTRONOMY & ASTROPHYSICS MARCH II 2000, PAGE 425 SUPPLEMENT SERIES Astron. Astrophys. Suppl. Ser. 142, 425–432 (2000) Photometric distances to six bright resolved galaxies? I.O. Drozdovsky1 and I.D. Karachentsev2 1 Astronomical Institute, St.-Petersburg State University, Petrodvoretz 198904, Russia 2 Special Astrophysical Observatory, N. Arkhyz, KChR 357147, Russia Received September 27; accepted October 18, 1999 Abstract. We present photometry of the brightest stars in et al. 1994; Georgiev et al. 1997; Makarova et al. 1997; six nearby spiral and irregular galaxies with corrected ra- Karachentsev et al. 1997; Makarova & Karachentsev dial velocities from 340 to 460 km s−1. Three of them are 1998; Karachentsev & Drozdovsky 1998; Tikhonov & resolved into stars for the first time. Based on luminosity Karachentsev 1998). Besides several early type objects of the brightest blue stars we estimate the following dis- (NGC 404, NGC 4150, NGC 4736, NGC 4826, and Maffei tances to the galaxies: 5.0 Mpc for NGC 784, 9.2 Mpc for 1) all of the galaxies are resolved into stars, moreover NGC 2683, 8.9 Mpc for NGC 2903, 4.1 Mpc for NGC 5204, most of them for the first time. 6.8 Mpc for NGC 5474, and 8.7 Mpc for NGC 5585. Here we present large-scale images of three previously unobserved galaxies: NGC 784, NGC 2683, NGC 2903, Key words: galaxies: distances — galaxies: general as well as of three galaxies, NGC 5204, NGC 5474, and NGC 5585, from the M 101 group imaged with a higher angular resolution. 1. Introduction 2. Observations and photometry This paper completes a series of publications devoted The first four galaxies were observed in February 1995 to photometry of the brightest stars in nearby late type at the 2.5-m Nordic telescope with a subarcsec seeing.
    [Show full text]
  • User-Support Models at the Isaac Newton Group
    Chris Benn, ING, La Palma La Palma • 4.5 hours flight from UK, NL. • Observatory at 2300 m, 1 hour drive from Santa Cruz. Residencia close to telescopes. • Visitor-mode observing at most of the telescopes. Isaac Newton Group ING = 4.2-m WHT (left), 2.5-m INT (right), 1.0-m JKT (right). Funding for ING is NL/ES/UK. ING employs ~ 40 staff, all on La Palma. Sea-level office • Until the mid-1990s, most staff worked on the mountain. • Currently, the sea-level office accommodates: 2/3 of staff; meeting rooms; library; remote- observing facility. • No base in partner countries (UK, NL, ES). 4.2-m William Herschel Telescope • Flexible operation: • Broad range of common- user instruments: ISIS, LIRIS, ACAM, PF imager, AF2, AO. • ACAM permanently at folded-Cass focus. • ~ 6 visiting instruments per semester e.g. CANARY, EXPO, FASTCAM, GHaFaS, PNS, SAURON, Ultracam. • Service programme, ~ 20 nights per year. Daytime operations • ~ 10 ING staff on the mountain, for: • Instrument changes; • Maintenance, e.g. aluminising; • Fault fixing, aided by searchable fault database (> 20000 entries to date): User support - why? • The WHT has long been one of the most scientifically-productive 4-m telescopes, probably due to (1) a strong user community, (2) a good site, and (3) first-class telescopes and instrumentation. • User support is key to efficient exploitation of the latter. • Aim of user support is to facilitate every step of observing process, from proposal preparation to data acquisition. Support model at WHT • Staff astronomers provide pre-observing and first-night (afternoon + evening) support of each run (~ 80 runs per year).
    [Show full text]
  • Arxiv:2004.11764V1 [Astro-Ph.SR] 24 Apr 2020 * Yclrcaatrsisi Esfeun.Too Hmae T T and Telescope[5] Are: Newton Them Isaac of the Two Using Conducted Frequent
    Possibilities of Using Middle-Band Filters to Search for Polar Candidates M. M. Gabdeev,1, * T. A. Fatkhullin,1 and N.V. Borisov1 1Special Astrophysical Observatory, Russian Academy of Sciences, Nizhnii Arkhyz, 369167 Russia We present a method for searching for polar candidates using mid-band filters. One of the spectral singularities of polars is the HeIIλ4686A˚ strong emission line. We selected the Edmund Optics filters with central wavelengths of 470, 540, and 656 nm and a transmission bandwidth of 10 nm. These filters cover the regions of the HeIIλ4686A˚ line, continuum, and the Hα line respectively. We constructed a color diagram based on the available spectra of polars and objects with a zero redshift from the SDSS archive. We show that most polars make a group with unique color indices. In practice, the method is implemented in SAO RAS at the Zeiss-1000 telescope with a new multi-mode photometer-polarimeter (MMPP). Approbation of the method with the known polars allowed us to develop two criteria to select candidates with an efficiency of up to 75%. 1. INTRODUCTION Polars are close magnetic cataclysmic systems consisting of a white dwarf whose magnetic field intensity exceeds 10 MG and a red dwarf of a late spectral type. Evolving, the red dwarf fills its Roche lobe and begins to lose matter through the inner Lagrange point L1. If the magnetic field intensity of the white dwarf does not exceed 10 MG, the matter under the gravitational influence of the white dwarf falls on it in Keplerian orbits and forms an accretion disk.
    [Show full text]
  • A Tale of Two Grbsne at a Common Redshift of Z0.54
    Mon. Not. R. Astron. Soc. 413, 669–685 (2011) doi:10.1111/j.1365-2966.2010.18164.x A tale of two GRB-SNe at a common redshift of z = 0.54 Z. Cano,1† D. Bersier,1 C. Guidorzi,1,2 R. Margutti,3 K. M. Svensson,4 S. Kobayashi,1 A. Melandri,1,3 K. Wiersema,5 A. Pozanenko,6 A. J. van der Horst,7,8 G. G. Pooley,9 A. Fernandez-Soto,10 A. J. Castro-Tirado,11 A. de Ugarte Postigo,12 M. Im,13 A. P. Kamble,14 D. Sahu,15 J. Alonso-Lorite,16 G. Anupama,15 J. L. Bibby,1,17 M. J. Burgdorf,18,19 N. Clay,1 P. A. Curran,20 T. A. Fatkhullin,21 A. S. Fruchter,22 P. Garnavich,23 A. Gomboc,24,25 J. Gorosabel,11 J. F. Graham,22 U. Gurugubelli,15 J. Haislip,26 K. Huang,27 A. Huxor,28 M. Ibrahimov,29 Y. Jeon,13 Y.-B. Jeon,30 K. Ivarsen,26 D. Kasen,31‡ E. Klunko,32 C. Kouveliotou,33 A. LaCluyze,26 A. J. Levan,4 V. Loznikov,6 P. A. Mazzali,34,35,36 A. S. Moskvitin,21 C. Mottram,1 C. G. Mundell,1 P. E. Nugent,37 M. Nysewander,22 P. T. O’Brien,5 W.-K. Park,13 V. Peris, 16 E. Pian,35,38 D. Reichart,26 J. E. Rhoads,39 E. Rol,14 V. Rumyantsev,40 V. Scowcroft, 41 D. Shakhovskoy,40 E. Small,1 R. J. Smith,1 V. V. Sokolov, 21 R. L. C.
    [Show full text]
  • HPS: Annual Report 2007-2008
    Contents The Department Introduction.................................................................................................................................... 2 Staff and affiliates .......................................................................................................................... 3 Visitors and students ...................................................................................................................... 4 Comings and goings....................................................................................................................... 5 Roles and responsibilities .............................................................................................................. 6 Prizes, projects and honours........................................................................................................... 8 Seminars and special lectures ...................................................................................................... 10 Students Student statistics........................................................................................................................... 11 Part II essay and dissertation titles............................................................................................... 12 MPhil essay and dissertation titles............................................................................................... 14 PhD theses...................................................................................................................................
    [Show full text]
  • Isaac Newton Institute of Chile in Eastern Europe and Eurasia Casilla
    1 Isaac Newton Institute of Chile in Eastern Europe and Eurasia Casilla 8-9, Correo 9, Santiago, Chile e-Mail: [email protected] Web-address: www.ini.cl ͓S0002-7537͑95͒03301-4͔ The Isaac Newton Institute, ͑INI͒ for astronomical re- and luminosity functions ͑LFs͒ of the cluster Main Sequence search was founded in 1978 by the undersigned. The main ͑MS͒ for two fields extending from a region near the center office is located in the eastern outskirts of Santiago. Since of the cluster out to Ӎ 10 arcmin. The photometry of these 1992, it has expanded into several countries of the former fields produces a narrow MS extending down to VӍ27, Soviet Union in Eastern Europe and Eurasia. much deeper than any previous ground based study on this As of the year 2003, the Institute is composed of fifteen system and comparable to previous HST photometry. The V, Branches in nine countries ͑see figure on following page͒. V-I CMD also shows a deep white dwarf cooling sequence These are: Armenia ͑19͒, Bulgaria ͑28͒, Crimea ͑35͒, Kaza- locus, contaminated by many field stars and spurious objects. khstan ͑18͒, Kazan ͑12͒, Kiev ͑11͒, Moscow ͑23͒, Odessa We concentrate the present work on the analysis of the ͑35͒, Petersburg ͑33͒, Poland ͑13͒, Pushchino ͑23͒, Special MSLFs derived for two annuli at different radial distance Astrophysical Observatory, ‘‘SAO’’ ͑49͒, Tajikistan ͑9͒, from the center of the cluster. Evidence of a clear-cut corre- Uzbekistan ͑24͒ and Yugoslavia ͑23͒. The quantities in pa- lation between the slope of the observed LFs before reaching rentheses give the number of scientific staff, the grand total the turn-over, and the radial position of the observed fields of which is 355 members.
    [Show full text]