DOCSLIB.ORG

Ionptumghrkwm ( { | }Y~Zxsl Qjvl {Gf) IB > XS < V OY Ej

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Ionptumghrkwm ( { | }Y~Zxsl Qjvl {Gf) IB > XS < V OY Ej x H Vol No PROGRESS IN ASTRONOMY Mar ionpt umg hrk wm y z U w X o D w G b S o s S Q w z C z QA U Bf w KD U A s M The th Draft for the Chinese Translation of Some Astronomical Terms The Astronomical Terminology Committee of the CAS x s l qjvl absorptionfree space by absorptionp o or space by aerobraking O D R alion creation N angular element k Bo omerang telescop e hG fi I B Ballo on Observations of Millimetri c Extragalactic Radiation and Geophysics telescop e CCD imaging CCD CDF Chandra Deep Field E QWJ h CDFi CDFN Chandra Deep Field North E Q WJ hCDFNi CDFS Chandra Deep Field South E QWJ hCDFS i celestial matter XS CLASS Cosmic Lens AllSky Survey X w hCLASSi closed fork mounting c Q cold atom clo ck V colo cational observation O Y cometary zone eJ comet HaleBopp C e comet Hyakutake e comet Sho emakerLevy c e cosmic catastrophe XA w G x s l qjvl cosmogoner wv l x cosmonaut cosmophysics X dark energy DASI Degree Angular Scale Interferometer NV hDASIi daylight meteor Y DENIS Deep NearInfrared Survey g W w h h i disk accretion r DLS Deep Lens Survey W w hDLSi doubleplanet g dust driven wind I earliest state t E p etheral ring m EVLA Expanded Very Large Array F PY w M hEVLAi exoplanet exoplanet system exoplanet transit exosolar wind o I exotic star B expansion lag TJ fewb o dy problem Tv t fountain clo ck KV FU Orionis ob ject j FU wv geo centric constant f Geo centric Co ordinate Time TCG c hTCGi GSMT Giant Segmented Mirror Telescop e c hGS MTi highenergy galaxy O Hubble Heritage Pro ject i vk hyp ernova imagingchip technology H Pue inb etween ob ject U wv innermost planet b International Celestial Reference System ICRS wwI hICRSi I hITRSi International Terrestrial Reference System ITRS w ISS International Space Station w y I hISSi KBO Kuip er Belt Ob ject wv Kozai resonance X D U L Kuip erEdgeworth b elt B i w z x s l qjvl lifeb earing planet Z LIGO Laser Interferometer Gravitational waveObservatory sZNV Y n hLIGOi LINEAR Lincoln NearEarth Ob ject Research wv hLINEARi LONEOS Lowell Observatory NearEarth Ob ject Search C wvj m hLONEOSi LSST Largeap erture Synoptic Survey Telescop e Lw a hLSSTi Lyman break galaxy Lyman break metho d FE magnetar G magnetic are magnetospheric accretion r Martian dust strom p Martian opp osition p Martian year p mass factor S minimo on mo died horsesho e mounting M uQ mo onlet multibre sp ectrometer BZ HZ multibre sp ectroscopy BZ HZ multiple ybys B W G nearcollisi on nebula NEAT NearEarth Asteroid Tracking R a hNEATi nulling interferometer N V nulling interferometry N V NVO National Virtual Observatory x w n hNVOi op en spiral dR optical clo ck Z V paragravity W PHA p otentially hazardous asteroid F D photop olarime ter L Zv plutino d PlutoKuip er Belt yby d G p ostcollisi on merger icwv primordial black hole o e Prosp ero w protostellar collapse f ql radio afterglow U n radio brown dwarf U d reionization era C w G x s l qjvl rubble pile structure V SAFIR SingleAp erture FarInfraRed Observatory g w n hSAFIRi satellite nebula Seteb os w shadow matter S SKA Square Kilometer Array FTwM hSKAi solvefor parameter Wf space wather oDh Spirograph Nebula IC y stargazer w aK starp o or region J Stephano w D stellarmass black hole f S e substellar system f sup erplanet sup errotation r surfacebrightness uctuation technique C LFE TCG Geo centric Co ordinate Time c hTCGi telescop e time Y y terraforming I l THEMIS Thermal Emission Imaging System M K U z hTHEMISi Thumbprint Nebula P TNO transNeptunian ob ject wv TT Terrestrial Time I hTTi Typ e quasar v Typ e quasar v ultradense neutron star U ultradense ob ject wv Vegalike ob ject N wv very lowmass star Y S f virial parameter f virtual observatory w n Vulcanlike asteroid Z O wv vulcanoid Z O wv X matter S Xray afterglow X U n X wind o I Yarkovsky eect C J h q MASS TwoMicro All Sky Survey Lw a h MASSi.
Load more

Recommended publications
  • Stellar Dynamics and Stellar Phenomena Near a Massive Black Hole
    Stellar Dynamics and Stellar Phenomena Near A Massive Black Hole Tal Alexander Department of Particle Physics and Astrophysics, Weizmann Institute of Science, 234 Herzl St, Rehovot, Israel 76100; email: [email protected] | Author's original version. To appear in Annual Review of Astronomy and Astrophysics. See final published version in ARA&A website: www.annualreviews.org/doi/10.1146/annurev-astro-091916-055306 Annu. Rev. Astron. Astrophys. 2017. Keywords 55:1{41 massive black holes, stellar kinematics, stellar dynamics, Galactic This article's doi: Center 10.1146/((please add article doi)) Copyright c 2017 by Annual Reviews. Abstract All rights reserved Most galactic nuclei harbor a massive black hole (MBH), whose birth and evolution are closely linked to those of its host galaxy. The unique conditions near the MBH: high velocity and density in the steep po- tential of a massive singular relativistic object, lead to unusual modes of stellar birth, evolution, dynamics and death. A complex network of dynamical mechanisms, operating on multiple timescales, deflect stars arXiv:1701.04762v1 [astro-ph.GA] 17 Jan 2017 to orbits that intercept the MBH. Such close encounters lead to ener- getic interactions with observable signatures and consequences for the evolution of the MBH and its stellar environment. Galactic nuclei are astrophysical laboratories that test and challenge our understanding of MBH formation, strong gravity, stellar dynamics, and stellar physics. I review from a theoretical perspective the wide range of stellar phe- nomena that occur near MBHs, focusing on the role of stellar dynamics near an isolated MBH in a relaxed stellar cusp.
    [Show full text]
  • Dark Mater Compact Stars in Pseudo-Complex General Relativity]{Dark Mater Compact Stars in Pseudo-Complex General Relativity
    Dark Mater Compact Stars in Pseudo-Complex General Relativity]{Dark Mater Compact Stars in Pseudo-Complex General Relativity César A. Zen Vasconcellos Instituto de Física Universidade Federal do Rio Grande do Sul (UFRGS) Porto Alegre, RS, Brazil E-mail: [email protected] Abstract: In the theory of pseudo-complex General Relativity (pc-GR), the field equations have an extra term, associated to the nature of spacetime, of repulsive character, which is believed to halt the gravitational attractive collapse of matter distributions in the evolution process of compact stars. According to Walter Greiner and Peter Hess, this additional term arises from micro-scale phenomena due to vacuum fluctuations which simulate the presence of dark energy in the Universe. In this contribution we explore the presence of this additional term and propose a toy model consisting of dark matter, represented by Standard Model gauge singlets having their origin in a portal model, held together by the presence of the gravitational interaction and superimposed to this (repulsive) background of dark energy forming a type of unconventional and non-luminous star. The combination of these two ingredients, gravitational attraction and dark energy repulsion, allows in thesis the hydrostatic equilibrium condition of the star to hold. Solving the corresponding field equations and the TOV equations, and assuming that the fluid components interact only gravitationally, we determine the hydrostatic equilibrium equations of the star composed only by dark matter and dark energy, a rare compact object formed solely by exotic content. We them analyze the corresponding results obtained for the equation of state and for the mass-radius relations and we them determine the maximum mass of the exotic star for different parameter configurations..
    [Show full text]
  • The Orbital Distribution of Near-Earth Objects Inside Earth’S Orbit
    Icarus 217 (2012) 355–366 Contents lists available at SciVerse ScienceDirect Icarus journal homepage: www.elsevier.com/locate/icarus The orbital distribution of Near-Earth Objects inside Earth’s orbit ⇑ Sarah Greenstreet a, , Henry Ngo a,b, Brett Gladman a a Department of Physics & Astronomy, 6224 Agricultural Road, University of British Columbia, Vancouver, British Columbia, Canada b Department of Physics, Engineering Physics, and Astronomy, 99 University Avenue, Queen’s University, Kingston, Ontario, Canada article info abstract Article history: Canada’s Near-Earth Object Surveillance Satellite (NEOSSat), set to launch in early 2012, will search for Received 17 August 2011 and track Near-Earth Objects (NEOs), tuning its search to best detect objects with a < 1.0 AU. In order Revised 8 November 2011 to construct an optimal pointing strategy for NEOSSat, we needed more detailed information in the Accepted 9 November 2011 a < 1.0 AU region than the best current model (Bottke, W.F., Morbidelli, A., Jedicke, R., Petit, J.M., Levison, Available online 28 November 2011 H.F., Michel, P., Metcalfe, T.S. [2002]. Icarus 156, 399–433) provides. We present here the NEOSSat-1.0 NEO orbital distribution model with larger statistics that permit finer resolution and less uncertainty, Keywords: especially in the a < 1.0 AU region. We find that Amors = 30.1 ± 0.8%, Apollos = 63.3 ± 0.4%, Atens = Near-Earth Objects 5.0 ± 0.3%, Atiras (0.718 < Q < 0.983 AU) = 1.38 ± 0.04%, and Vatiras (0.307 < Q < 0.718 AU) = 0.22 ± 0.03% Celestial mechanics Impact processes of the steady-state NEO population.
    [Show full text]
  • Planetary Science from a Next-Gen Suborbital Platform: Sleuthing the Long Sought After Vulcanoid Aster- Oids
    Next-Generation Suborbital Researchers Conference (2010) (2010) 4004.pdf Planetary Science from a Next-Gen Suborbital Platform: Sleuthing the Long Sought After Vulcanoid Aster- oids. S.A. Stern1 , D.D. Durda1, M. Davis1, and C.B. Olkin1. Southwest Research Institute, Suite 300, 1050 Walnut Street, Boulder, CO 80302, [email protected]. Introduction: We are on the verge of a revolution in pheric haze and turbulence are among the daunting scientific access to space. This revolution, fueled by challenges faced by ground-based observers searching billionaire investors like Richard Branson and Jeff for objects near the Sun at twilight. Consequently, only Bezos, is fielding no less than three human flight sub- a few visible-wavelength ground-based searches for orbital systems in the coming 24 months. This new Vulcanoids have been conducted. stable of vehicles, originally intended to open up a Experiment: We will conduct a large area search space tourism market, includes Virgin Galactic’s for Vulcanoids using our SWUIS imager developed for SpacesShip2, Blue Origin’s New Shepard, and Space Shuttle and high altitude F-18 flights. We will XCOR’s Lynx. Each offers the capability to fly multi- conduct our Vulcanoid search experiment at altitudes ple humans to altitudes of 70-140 km on a frequent of 100-140 km near twilight so that the Vulcanoid re- (daily to weekly) basis for per-seat launch costs of gion is seen above a dark Earth with the Sun below the $100K-$200K/launch. The total investment in these depressed horizon. In this way we will eliminate the systems is now approaching $1B, and test flights of scattered light problems that have dogged all ground- each are set to begin in 2010.
    [Show full text]
  • 1950 Da, 205, 269 1979 Va, 230 1991 Ry16, 183 1992 Kd, 61 1992
    Cambridge University Press 978-1-107-09684-4 — Asteroids Thomas H. Burbine Index More Information 356 Index 1950 DA, 205, 269 single scattering, 142, 143, 144, 145 1979 VA, 230 visual Bond, 7 1991 RY16, 183 visual geometric, 7, 27, 28, 163, 185, 189, 190, 1992 KD, 61 191, 192, 192, 253 1992 QB1, 233, 234 Alexandra, 59 1993 FW, 234 altitude, 49 1994 JR1, 239, 275 Alvarez, Luis, 258 1999 JU3, 61 Alvarez, Walter, 258 1999 RL95, 183 amino acid, 81 1999 RQ36, 61 ammonia, 223, 301 2000 DP107, 274, 304 amoeboid olivine aggregate, 83 2000 GD65, 205 Amor, 251 2001 QR322, 232 Amor group, 251 2003 EH1, 107 Anacostia, 179 2007 PA8, 207 Anand, Viswanathan, 62 2008 TC3, 264, 265 Angelina, 175 2010 JL88, 205 angrite, 87, 101, 110, 126, 168 2010 TK7, 231 Annefrank, 274, 275, 289 2011 QF99, 232 Antarctic Search for Meteorites (ANSMET), 71 2012 DA14, 108 Antarctica, 69–71 2012 VP113, 233, 244 aphelion, 30, 251 2013 TX68, 64 APL, 275, 292 2014 AA, 264, 265 Apohele group, 251 2014 RC, 205 Apollo, 179, 180, 251 Apollo group, 230, 251 absorption band, 135–6, 137–40, 145–50, Apollo mission, 129, 262, 299 163, 184 Apophis, 20, 269, 270 acapulcoite/ lodranite, 87, 90, 103, 110, 168, 285 Aquitania, 179 Achilles, 232 Arecibo Observatory, 206 achondrite, 84, 86, 116, 187 Aristarchus, 29 primitive, 84, 86, 103–4, 287 Asporina, 177 Adamcarolla, 62 asteroid chronology function, 262 Adeona family, 198 Asteroid Zoo, 54 Aeternitas, 177 Astraea, 53 Agnia family, 170, 198 Astronautica, 61 AKARI satellite, 192 Aten, 251 alabandite, 76, 101 Aten group, 251 Alauda family, 198 Atira, 251 albedo, 7, 21, 27, 185–6 Atira group, 251 Bond, 7, 8, 9, 28, 189 atmosphere, 1, 3, 8, 43, 66, 68, 265 geometric, 7 A- type, 163, 165, 167, 169, 170, 177–8, 192 356 © in this web service Cambridge University Press www.cambridge.org Cambridge University Press 978-1-107-09684-4 — Asteroids Thomas H.
    [Show full text]
  • The History of Enrichment of the Intergalactic Medium Using Cosmological Simulations
    The History of Enrichment of the Intergalactic Medium Using Cosmological Simulations Item Type text; Electronic Dissertation Authors Oppenheimer, Benjamin Darwin Publisher The University of Arizona. Rights Copyright © is held by the author. Digital access to this material is made possible by the University Libraries, University of Arizona. Further transmission, reproduction or presentation (such as public display or performance) of protected items is prohibited except with permission of the author. Download date 03/10/2021 02:22:25 Link to Item http://hdl.handle.net/10150/194237 THE HISTORY OF ENRICHMENT OF THE INTERGALACTIC MEDIUM USING COSMOLOGICAL SIMULATIONS by Benjamin Darwin Oppenheimer A Dissertation Submitted to the Faculty of the DEPARTMENT OF ASTRONOMY In Partial Fulfillment of the Requirements For the Degree of DOCTOR OF PHILOSOPHY In the Graduate College THE UNIVERSITY OF ARIZONA 2 0 0 8 2 THE UNIVERSITY OF ARIZONA GRADUATE COLLEGE As members of the Dissertation Committee, we certify that we have read the dissertation prepared by Benjamin Darwin Oppenheimer entitled “The History of Enrichment of the Intergalactic Medium Using Cosmological Simulations” and recommend that it be accepted as fulfilling the dissertation requirement for the Degree of Doctor of Philosophy. Date: August 6, 2008 Romeel Dave´ Date: August 6, 2008 Chris Impey Date: August 6, 2008 Jill Bechtold Date: August 6, 2008 Buell Jannuzi Date: August 6, 2008 John Bieging Final approval and acceptance of this dissertation is contingent upon the candi- date's submission of the final copies of the dissertation to the Graduate College. I hereby certify that I have read this dissertation prepared under my direction and recommend that it be accepted as fulfilling the dissertation requirement.
    [Show full text]
  • Newsletter Submillimeter Array Newsletter Number 20 | July 2015
    SMA Newsletter Submillimeter Array Newsletter Number 20 | July 2015 CONTENTS FROM THE DIRECTOR 1 From the Director SCIENCE HIGHLIGHTS: Dear SMA Newsletter readers, 2 Nuclear Ashes and Outflow in the Eruptive Star Nova I am pleased to congratulate Thomas Kaminski (ESO Chile and MPI Bonn), Hua-Bai Vul 1670 Li (The Chinese University of Hong Kong), Jean Turner (UCLA) and their colleagues 5 Magnetic Fields Shape for their recent publications in Nature, summarized in this Newsletter. Collectively Molecular Cloud Structures 7 A Cosmic Factory of Stars these publications highlight the relative ease and utility of the SMA to observe bright, and Soot – SMA Reveals a chemically rich, galactic sources, and nearby galaxies; and further demonstrate the SMA’s Super Star Cluster of Highly Efficient Star Formation in relatively unique polarization capability. NGC 5253 I would also like to thank members of the SMA correlator group for their continued efforts TECHNICAL HIGHLIGHTS: to provide additional wideband signal-processing capacity. We now regularly observe with bu A SWARM of ROACHs the first tranche of SWARM, albeit at 3/4 speed, in parallel with the aging ASIC correlator, Has Been Deployed for Submillimeter Array Science in service since 2002. While not yet perfect, the additional 2x1.5 GHz bands, coupled with bp Securing Service - Availability the original 2x2 GHz bands of the ASIC correlator and double sideband receiver operation in Hawaii Using Virtual Infrastructure result in an instantaneous bandwidth of 14 GHz. This provides additional flexibility OTHER NEWS during spectral line observations and improves the continuum sensitivity of the SMA by about 40%.
    [Show full text]
  • Gravity-Superconductor Interactions
    id2441218 pdfMachine by Broadgun Software - a great PDF writer! - a great PDF creator! - http://www.pdfmachine.com http://www.broadgun.com Mehtapress 2013 Print - ISSN : 2319–9814 Journal of Online - ISSN : 2319–9822 SpFauclle pEapxepr loration Full Paper WWW.MEHTAPRESS.COM P.A.Murad* An assessment concerning neutron stars and Morningstar Applied Physics, LLC, space propulsion implications Vienna, VA 22182, (USA) E-mail: [email protected] PACS: 04.50.Kd, 04.80.Cc, 06.30.Dr, Abstract 06.30. Gv, 97.10.-q, 97.10.Gz, 97.10.Xq, 97.60.Gb, 97.60.Jd, 97.60.Lf, 97.80.-d There are many uncertainties concerning stellar evolution of neutron stars. Neutron stars might possess multipolar architecture in lieu of a single dipole claimed by the conventional wisdom. The multipole issue cannot be resolved using a single observer reference point Received: April 30, 2013 such as the Earth, but would require an additional non-terrestrial observer location with a Accepted: June 24, 2013 significant offset. Without observing multiple beacons, we could not verify or deny the Published: July 29, 2013 existence of multiple poles from observing the sweeping lighthouse effect from Earth. Moreover, a neutron star’s magnetic field may be created by differences between the neutron core and a gas surface layer of protons and electrons. These differences between *Corresponding author’s Name & Add. the layers constitute charges and moving currents that result in a magnetic field supported by a fast moving rotating core. If electrons in Cooper pairs exist in a neutron star, then the amount of magnetism may increase by a similar order via superconductivity.
    [Show full text]
  • Phase Transitions in Neutron Stars and Their Links to Gravitational Waves
    Phase transitions in neutron stars and their links to gravitational waves Milva G. Orsaria 1;2, Germ´anMalfatti 1;2, Mauro Mariani 1;2, Ignacio F. Ranea-Sandoval 1;2, Federico Garc´ıa 4;5, William M. Spinella 6, Gustavo A. Contrera 1;3;8, Germ´anLugones 7, and Fridolin Weber 8;9 1Grupo de Gravitaci´on,Astrof´ısicay Cosmolog´ıa,Facultad de Ciencias Astron´omicasy Geof´ısicas,Univer- sidad Nacional de La Plata, Paseo del Bosque S/N, 1900, La Plata, Argentina. 2 CONICET, Godoy Cruz 2290, 1425, CABA, Argentina. 3 IFLP, UNLP, CONICET, Facultad de Ciencias Exactas, Diagonal 113 e/63 y 64, 1900, La Plata, Argentina. 4 AIM, CEA, CNRS, Universit´eParis-Saclay, Universit´eParis Diderot, Sorbonne Paris Cit´e,F-91191 Gif-sur- Yvette, France. 5 Instituto Argentino de Radioastronom´ıa(CCT-La Plata, CONICET; CICPBA), C.C. No. 5, 1894 Villa Elisa, Argentina. 6 Department of Sciences, Wentworth Institute of Technology, 550 Huntington Avenue, Boston, MA 02115, USA. 7 Universidade Federal do ABC, Centro de Ci^enciasNaturais e Humanas, Avenida dos Estados 5001- Bang´u, CEP 09210-580, Santo Andr´e,SP, Brazil. 8 Department of Physics, San Diego State University, San Diego, CA 92182, USA. 9 University of California at San Diego, La Jolla, CA 92093, USA. Abstract The recent direct observation of gravitational wave event GW 170817 and its GRB170817A signal has opened up a new window to study neutron stars and heralds a new era of Astronomy referred to as the Multimessenger Astronomy. Both gravitational and electromagnetic waves from a single astrophysical source have been detected for the first time.
    [Show full text]
  • Bursts of Gravitational Waves Due to Crustquake from Pulsars
    J. Astrophys. Astr. (0000) 000: #### DOI Bursts of Gravitational Waves due to Crustquake from Pulsars Biswanath Layek1,* and Pradeepkumar Yadav1 1Birla Institute of Technology and Science, Pilani Campus Pilani, Jhunjhunu 333031, Rajasthan, India *Corresponding author. E-mail: [email protected] Abstract. We revisit here a possibility of generation of gravitational wave (GW) bursts due to a very quick change in the quadrupole moment (QM) of a deformed spheroidal pulsar as a result of crustquake. Since it was originally proposed as a possible explanation for sudden spin-up (glitch) of pulsars, the occurrence of crustquake and it’s various consequences have been studied and discussed quite often in the literature. Encouraged by recent development in gravitational wave (GW) astronomy, we re-investigate the role of crustquake in the emission of GWs. Assuming exponential decay of excitation caused by crustquake, we have performed a Fourier analysis to estimate the GW strain amplitude h(t), characteristic signal amplitude hc( f ) and signal to noise ratio (SNR) of the burst for the Crab pulsar. For exotic quark stars, multifold enhancement of these quantities are expected, which might make quark star a potential source of gravitational waves. The absence of such bursts may put several constraints on pulsars and such hypothetical stars. Keywords. Neutron Star, Pulsar, Crustquake, Gravitational wave. 1. Introduction mal modes of a pulsar and hence may emit GWs. The timing glitch can be one of these sources, which has The remarkable first-ever direct detection of GWs in the potential to excite quasinormal modes in the parent 2015 by LIGO (Abbott & et al.
    [Show full text]
  • AM Herculis, June 2001 Variable Star of the Month Variable Star of the Month
    AAVSO: AM Herculis, June 2001 Variable Star Of The Month Variable Star Of The Month June, 2001: AM Herculis (1813+49) A man’s friends are his magnetisms. Emerson. Conduct of Life: Fate The exotic star AM Herculis is the namesake of the “AM Her stars” or “polars”, a unique class of cataclysmic variables in which the magnetic field of the primary star (white dwarf) completely dominates the accretion flow of the system. With the discovery of AM Her comes the discovery of “polars” and a lesson learned that even familiar objects will reveal exciting discoveries if they are approached in the correct way. AM Her was discovered in 1923 by M. Wolf in Heidelberg, Germany during a routine search for variable stars. It was then listed in the General Catalogue of Variable Stars as an irregular variable with a range from 12th to 14th magnitude. The listing remained as such until 1976, when the true complexities of AM Her were finally revealed. Berg & Duthie of the University of Rochester (1977) initially suggested that AM Her could be the optical Artistic impression of an AM Her system. The blue haze represents the counterpart of the weak X-ray source 3U 1809+50 which was white dwarf's magnetosphere. detected by Uhuru, the first Small Astronomy Satellite. They Image copyright Russell Kightley Media noted that the variable star lay just outside of the region of certainty where the weak X-ray source was believed to be. Subsequently, a better position for 3U 1809+50 was determined and the position of the X-ray source and the variable star were shown to be the same.
    [Show full text]
  • Secondary Component of Gravitational-Wave Signal GW190814 As an Anisotropic Neutron Star
    Secondary component of gravitational-wave signal GW190814 as an anisotropic neutron star Zacharias Roupas1 1Centre for Theoretical Physics, The British University in Egypt, Sherouk City 11837, Cairo, Egypt Abstract The gravitational-wave signal GW190814 involves a compact object with mass (2.50 − 2.67)M⊙ within the so-called low mass gap. As yet, a general consensus on its nature, being a black hole, a neutron star or an exotic star, has not been achieved. We investigate the possibility this compact object to be an anisotropic neutron star. Anisotropies in a neutron star core arise naturally by effects such as superfluidity, hyperons, strong magnetic fields and allow the maximum mass to exceed that of the ideally isotropic stars. We consider the Krori-Barua ansatz to model an anisotropic core and constrain the equation of state with LIGO/Virgo observations GW170817 and GW190814. We find that the GW190814 secondary component can be an anisotropic neutron star compatible with LIGO/Virgo constraints if the radius attains a value in the range (13.2 − 14.0) km with the anisotropic core’s boundary density in the range (3.5 − 4.0) · 1014g/cm3. 1 Introduction The LIGO/Virgo Collaboration announced recently the observation of a merger of a black hole with +1.1 +0.08 mass 23.2−1.0M⊙ with a compact object with mass 2.59−0.09M⊙ [1]. The mass of the secondary component lies within the so-called low mass gap [2–4]. Theoretical and observational evidence suggest that black holes of mass less than ∼ 5M⊙ may not be produced by stellar evolution [2,3,5].
    [Show full text]