HOW MANY NEUTRON STARS ARE BORN RAPIDLY ROTATING? HOW MANY NEUTRON STARS ARE BORN RAPIDLY ROTATING? NIKOLAOS STERGIOULAS DEPARTMENT OF PHYSICS ARISTOTLE.

Slides:

Advertisements

Similar presentations

Stellar Structure Section 6: Introduction to Stellar Evolution Lecture 18 – Mass-radius relation for black dwarfs Chandrasekhar limiting mass Comparison.

Advertisements

Magnetars in Supernova Remnants & Magnetar Formation Jacco Vink Isolated NSs, London, April, 2006 Magnetars in Supernova Remnants & Magnetar Formation.

Neutron Stars: Insights into their Formation, Evolution & Structure from their Masses and Radii Feryal Ozel University of Arizona In collaboration with.

Upper-limit on Sco X-1 S2 preliminary results C Messenger, V Re and A Vecchio on behalf of PULG LSC General Meeting LHO, 10 th – 13 th November 2003.

White Dwarf Stars Low mass stars are unable to reach high enough temperatures to ignite elements heavier than carbon in their core become white dwarfs.

Stellar Evolution. Evolution on the Main Sequence Zero-Age Main Sequence (ZAMS) MS evolution Development of an isothermal core: dT/dr = (3/4ac) (  r/T.

Lecture 26: The Bizarre Stellar Graveyard: White Dwarfs and Neutron Stars.

1 Explaining extended emission Gamma-Ray Bursts using accretion onto a magnetar Paul O’Brien & Ben Gompertz University of Leicester (with thanks to Graham.

Accretion Processes in GRBs Andrew King Theoretical Astrophysics Group, University of Leicester, UK Venice 2006.

Compact remnant mass function: dependence on the explosion mechanism and metallicity Reporter: Chen Wang 06/03/2014 Fryer et al. 2012, ApJ, 749, 91.

Neutron Stars and Black Holes Please press “1” to test your transmitter.

Accretion in Binaries Two paths for accretion –Roche-lobe overflow –Wind-fed accretion Classes of X-ray binaries –Low-mass (BH and NS) –High-mass (BH and.

The evolution and collapse of BH forming stars Chris Fryer (LANL/UA)  Formation scenarios – If we form them, they will form BHs.  Stellar evolution:

Neutron Stars and Black Holes

The Lives of Stars Chapter 12. Life on Main-Sequence Zero-Age Main Sequence (ZAMS) –main sequence location where stars are born Bottom/left edge of main.

Life and Evolution of a Massive Star M ~ 25 M Sun.

Vicky Kalogera Jeremy Sepinsky with Krzysztof Belczynski X-Ray Binaries and and Super-Star Clusters Super-Star Clusters.

Magnetars origin and progenitors with enhanced rotation S.B. Popov, M.E. Prokhorov (Sternberg Astronomical Institute) (astro-ph/ )

Neutron Star Formation and the Supernova Engine Bounce Masses Mass at Explosion Fallback.

A Slow X-ray Pulsar in the Young, Massive Star Cluster Westerlund 1 M. MunoJ. S. ClarkP. Crowther S. DoughertyR. De GrijsC. Law S. McMillanM. MorrisI.

Black holes: Introduction. 2 Main general surveys astro-ph/ Neven Bilic BH phenomenology astro-ph/ Thomas W. Baumgarte BHs: from speculations.

1 Magnetars origin and progenitors with enhanced rotation S.B. Popov, M.E. Prokhorov (Sternberg Astronomical Institute) (astro-ph/ ) Poster N 21.

Two stories from the life of binaries: getting bigger and making magnetars Sergei Popov, Mikhail Prokhorov (SAI MSU) This week SAI celebrates its 175 anniversary.

Marc Pinsonneault (OSU).  New Era in Astronomy  Seismology  Large Surveys  We can now measure things which have been assumed in stellar modeling 

Gravitational-waves: Sources and detection

The birth-ultrafast-magnetic- field-decay model applied to isolated millisecond pulsars Ricardo Heras Preparatoria Abierta SEIEM Edo. Mexico.

He star evolutionary channel to intermediate-mass binary pulsars with a short-orbital-period Chen Wen-Cong School of Physics, Peking University Department.

Star Clusters and their stars Open clusters and globular clusters General characteristics of globular clusters Globular cluster stars in the H-R diagram.

ROTATING MASSIVE STARS as Long Gamma-Ray Burst progenitors Matteo Cantiello - Sterrekundig Instituut Utrecht as Long Gamma-Ray Burst progenitors Matteo.

Gravitational waves from neutron star instabilities: What do we actually know? Nils Andersson Department of Mathematics University of Southampton IAP Paris.

A few Challenges in massive star evolution ROTATIONMAGNETIC FIELD MULTIPLICITY How do these distributions vary with metallicity? How do these distributions.

Plasma universe Fluctuations in the primordial plasma are observed in the cosmic microwave background ESA Planck satellite to be launched in 2007 Data.

Merger of binary neutron stars in general relativity M. Shibata (U. Tokyo) Jan 19, 2007 at U. Tokyo.

A Neutron Star with a Massive Progenitor in the Star Cluster Westerlund 1 Michael Muno (UCLA/Hubble Fellow) J. S. Clark (Open U)R. de Grijs (U Sheffield)

Dec. 6, Review: >8Msun stars become Type II SNe As nuclear burning proceeds to, finally, burning Silicon (Si) into iron (Fe), catastrophe looms.

GW sources from a few Hz to a few kHz Cole Miller, University of Maryland 1.

Magnetic fields generation in the core of pulsars Luca Bonanno Bordeaux, 15/11/2010 Goethe Universität – Frankfurt am Main.

Do Old Neutron Stars Shiver to Keep Warm? Jeremy S. Heyl Harvard-Smithsonian CfA.

Compact Stars as Sources of Gravitational Waves Y. Kojima (Hiroshima Univ.) 小嶌康史 ( 広島大学理学研究科 ) 第 3 回 TAMA シンポジュウム（柏） 2003 年 2 月 6 － 7 日.

THE PECULIAR EVOLUTIONARY HISTORY OF IGR J IN TERZAN 5 A. Patruno Reporter: Long Jiang ( 姜龙 )

Expected Coalescence Rate of NS/NS Binaries for Ground Based Interferometers Tania Regimbau OCA/ARTEMIS on the behalf of J.A. de Freitas Pacheco, T. Regimbau,

GRAVITATIONAL WAVES FROM PULSATIONS OF COMPACT STARS GRAVITATIONAL WAVES FROM PULSATIONS OF COMPACT STARS NIKOLAOS STERGIOULAS DEPARTMENT OF PHYSICS ARISTOTLE.

Death of Stars II Physics 113 Goderya Chapter(s): 14

Supercritical Accretion in the Evolution of Neutron Star Binaries and Its Implications Chang-Hwan 1 Nuclear Physics A 928 (2014)

Evolutionary Sequences For Low- And-Intermediate-Mass X-Ray Binaries Ph. Podsiadlowski S. Rappaport E. D. Pfahl.

ADVANCED LIGO SCIENCE Kip S. Thorne CaRT, California Institute of Technology NSF Advanced R&D Panel - 29 January 2001.

Neutron Star Kicks Chris Fryer Aimee Hungerford Frank Timmes  Observational Evidence and constraints on kicks  Theoretical kick mechanisms.

Rates from binaries: current status Tomasz Bulik Warsaw University.

Oct. 30, 2002Source Simulation & Data Analysis1 Gravitational-Wave Observations of Galactic Populations of Compact Binaries M. Benacquista Montana State.

Binary Origin of Blue Stragglers Xuefei CHEN Yunnan Observatory, CHINA.

1 Gravitational waves from short Gamma-Ray Bursts Dafne Guetta (Rome Obs.) In collaboration with Luigi Stella.

Gravitational Waves What are they? How can they be detected?

Matteo Cantiello Astronomical Institute Utrecht Binary star progenitors of long GRBs M. Cantiello, S.-C. Yoon, N. Langer, and M. Livio A&A 465, L29-L33.

Gravitational wave sources

Searching for accreting neutron stars

Neutron Stars and Black Holes

Long GRB rate in the binary merger model

Progenitors of long GRBs

Probing Neutron Star interiors with ET ?

MERGING REVEALS Neutron Star INNARDS

Supernova Panel Discussion

Evolution of the Solar System

M. Benacquista Montana State University-Billings

Star Clusters and their stars

Evolution of X-ray Binaries and the Formation of Binary Pulsars

Delay time distribution of type Ia supernovae

Delay time distribution of type Ia supernovae

西华师范大学 China West Normal University

Stellar Evolution.

Evolutionary Link between X-ray Pulsars and Millisecond Radio Pulsars

Presentation transcript:

HOW MANY NEUTRON STARS ARE BORN RAPIDLY ROTATING? HOW MANY NEUTRON STARS ARE BORN RAPIDLY ROTATING? NIKOLAOS STERGIOULAS DEPARTMENT OF PHYSICS ARISTOTLE UNIVERSITY OF THESSALONIKI ENTAPP, 23/1/2006

WHY DO WE NEED RAPID ROTATION? 1.Core-bounce signal in axisymmetric collapse For slow rotation detectable only within Galaxy, but rapid rotation allows larger distances. Nonlinear couplings may enhance GW emission. 2.Dynamical bar-mode instability Need T/|W|>0.24. If bar persists for many periods, signal detectable out to the Virgo cluster. 3.Low T/|W| m=2 instability Need only T/|W|>0.01, but need a high degree of differential rotation. Has h eff ~ at 100Mpc(!) 4.Low T/|W| m=1 instability Need T/|W|>0.08 and a high degree of differential rotation. GWs through nonlinear m=2 mode excitation, only detectable in our Galaxy. 5.CFS f-mode instability Needs T/|W|>0.08 to operate. If T/|W|>0.25 and α~1, detectable to 100Mpc! 6.r-mode instability in young strange stars Needs millisecond initial periods. For α~10 -3 there may be several sources in our Galaxy at any time – detectable with a few weeks integration. Several GW emission mechanisms during NS formation rely on rapid rotation: But, are NS born rapidly rotating?

Typical Progenitors A large fraction of progenitor stars are initially rapidly rotating: Spruit & Phinney 1998, Spruit 2002, Heger, Woosley & Spruit 2004 The average rotation of OB type stars on the main sequence is 25% of break up speed. About 0.3% of B stars have Ω > 67% of breakup, e.g.of Regulus in Leo: 86% of breakup. When the progenitor passes through the Red Supergiant (RSG) phase it has a huge envelope of several hundred times the initial radius. The core’s differential rotation produces a magnetic field by dynamo action that couples the core to the outer layers, transferring away angular momentum. This leads to slowly rotating neutron stars at birth (~10-15ms). But: Magnetic Torques can Spin Down the Core! Is there a way out of this?

By-Passing the RSG Phase Massive Stars (M>25Msun) evolve very rapidly. Two advantages: a) There is not sufficient time to slow down the core effectively! b) A strong wind (WR phase) will expel the envelope, preventing slow down of core by magnetic torques. A strong wind (high mass-loss rate) allows NS to be formed instead of a BH, but could also carry away a lot of angular momentum. Mass-loss rate is lower if the star has low metallicity. In addition, rapidly rotating WR stars may lose mass mainly at the poles (temperature is higher there) => angular momentum loss is lower. Rapidly rotating cores produced by right mixture of high mass and low metallicity Observational evidence: 1) magnetar produced by 30-40Msun progenitor 2) magnetar with > 40Msun progenitor in star cluster Gaensler et al.2005 Muno et al.2005 Massive rapidly rotating cores => millisecond NS => magnetars. e.g. Wheeler et al.2000

Additional Paths to Rapid Rotation Additional Paths to Rapid Rotation 1) Rotational mixing in OB stars: If a binary companion strips the outer envelope of a massive star before core collapse, the RSG phase is avoided. (see Fryer & Kalogera 2001, Pfahl et al. 2002, Podsiadlowski et al. 2003, Ivanova & Podsiadlowski 2003) Rapid rotation in massive OB stars can induce deep rotational mixing, preventing the RSG phase (stars stay on main sequence). Woosley & Heger (2005) estimate that 1% of all stars with mass >10Msun will produce rapidly rotating cores. Woosley & Heger ) Loss of envelope in binary evolution: 3) Fall-back accretion (see e.g. Watts & Andersson, 2002) 4) Binary WD mergers (Middleditch 2003) Also, suggested as alternative magnetar formation mechanism, with event rate 0.3/year at ~ 40Mpc. Suggested as ms pulsar formation mechanism in globular clusters. (Levan et al. 2006)

CONCLUSIONS CONCLUSIONS Typical core collapse will lead to slowly rotating NSs - most GW mechanisms not operating/not detectable at good event rates. But, there are several ways to produce rapidly rotating NSs at birth, but only in ~1% of SN events. Still, the strongest GW mechanisms (those detectable beyond theVirgo cluster) may have good event rates for advanced LIGO/VIRGO type of detectors. Need to focus more on strongest GW mechanisms both theoretically and by narrow-banding/improving detectors in 1-3kHz range.