 Pulsars are just a kind of neutron stars so it’s essential to get a grip of these first.  The stars that come into being at the end of a massive.

Slides:

Advertisements

Similar presentations

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.

Advertisements

1 Stellar Remnants White Dwarfs, Neutron Stars & Black Holes These objects normally emit light only due to their very high temperatures. Normally nuclear.

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

Chapter 12 The Deaths of Stars. What do you think? Will the Sun explode? If so, what is the explosion called? Where did carbon, silicon, oxygen, iron,

Chapter 13 The Bizarre Stellar Graveyard

Copyright © 2009 Pearson Education, Inc. Chapter 13 The Bizarre Stellar Graveyard.

The Stellar Graveyard AST 112. Review: Stellar Evolution (Low Mass)

Copyright © 2010 Pearson Education, Inc. Chapter 13 Neutron Stars.

Stellar Deaths II Neutron Stars and Black Holes 17.

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

Chapter 13 The Bizarre Stellar Graveyard White Dwarfs... n...are stellar remnants for low-mass stars. n...are found in the centers of planetary nebula.

The Discovery of the Neutron Star The Neutron Predicted by Ernest Rutherford in 1920 Experimentally discovered by James Chadwick in 1932.

Neutron Stars and Black Holes

 When found in stars between 8 and 25x M sun, what happens to the core?  Cores are stopped by the outer layers of the star  Cores recontract and remain.

Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display 1 Announcements Homework #10: Chp.14: Prob 1, 3 Chp. 15: Thought.

Neutron Stars and Pulsars Marcus Shinbo Melissa Onishi Astronomy Pd. 3 18, April, 2011.

White Dwarfs and Neutron Stars White dwarfs –Degenerate gases –Mass versus radius relation Neutron stars –Mass versus radius relation –Pulsars, magnetars,

Supernova and Neutron Stars

Earth Science 25.2B : Stellar Evolution

10 Black Holes and Neutron Stars Dead Stars Copyright – A. Hobart.

Neutron stars - Chapter Neutron stars The remains of cores of some massive stars that have become supernovae. Cores are a degenerate gas of mostly.

This set of slides This set of slides covers the supernova of white dwarf stars and the late-in-life evolution and death of massive stars, stars > 8 solar.

Question The pressure that prevents the gravitational collapse of white dwarfs is a result of ______.  A) Conservation of energy  B) Conservation of.

Nebulas are made up of gas left behind by stars forming or exploding There are different classes of Nebulas The classes are: Reflection Nebulae, Emission.

25 Facts about Parkes, Pulsars and

Neutron Stars and Black Holes Chapter 14. Formation of Neutron Stars Compact objects more massive than the Chandrasekhar Limit (1.4 M sun ) collapse beyond.

Conversations with the Earth Tom Burbine

High mass endings. Answers from you folks on yesterday’s quiz. Differences between a dying low mass vs. a dying high mass star: No He flash in a high.

1 Stellar Remnants White Dwarfs, Neutron Stars & Black Holes These objects normally emit light only due to their very high temperatures. Normally nuclear.

Neutron Stars Pulsars. Neutron Stars In 1967, it was believed (by some) that the first intelligent signal from outer space had been discovered. A graduate.

Remnant of a Type II supernova explosion Iron core collapses until neutrons are squeezed tightly together During the explosion core remains intact, outer.

JP ©1 2 3 Stars are born, grow up, mature, and die. A star’s mass determines its lifepath. Let M S = mass of the Sun = ONE SOLAR MASS Stellar Evolution.

Exotic Stars. White Dwarfs White dwarfs form after the helium flash, where the helium ash at the core of the star ignites. This usually leads to enough.

Who discovered the first pulsar? Jocelyn Bell Pulsars spin fast due to what physics concept?

Astronomy 1020-H Stellar Astronomy Spring_2015 Day-36.

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

Goal: To understand special stars. Objectives: 1)To learn about Neutron Stars 2)To learn about Pulsars 3)To understand Stars that erupt.

Life Cycle of Stars Mr. Weaver.

Chapter 13: Neutron Stars and Black Holes. When a massive star begins its core collapse, the electrons get compressed into the protons to form neutrons.

White dwarfs cool off and grow dimmer with time. The White Dwarf Limit A white dwarf cannot be more massive than 1.4M Sun, the white dwarf limit (or Chandrasekhar.

Chapter 13 Neutron Stars and Black Holes. Optical, Infrared and X-ray Image of Cassiopeia A.

The Star Cycle. Birth Stars begin in a DARK NEBULA (cloud of gas and dust)… aka the STELLAR NURSERY The nebula begins to contract due to gravity in.

Neutron Stars & Black Holes. Neutron Stars and Black Holes I. Neutron Stars A. Remnant from the collapse of a _________. B. During the core collapse of.

Chapter 10 The Bizarre Stellar Graveyard. The Products of Star Death White Dwarfs Neutron Stars Black Holes.

© 2010 Pearson Education, Inc. The Bizarre Stellar Graveyard.

Deep Space Objects Variable stars Caused by pulsations in the stars – expansions make them cooler and dimmer – Contractions make them hotter and brighter.

Unit 12: Stellar Remnants: White Dwarfs, Neutron Stars, and Black Holes Mr. Ross Brown Brooklyn School for Law and Technology.

Death of sun-like Massive star death Elemental my dear Watson Novas Neutron Stars Black holes $ 200 $ 200$200 $ 200 $ 200 $400 $ 400$400 $ 400$400.

Stellar Evolution Continued…. White Dwarfs Most of the fuel for fusion is used up Giant collapses because core can’t support weight of outer layers any.

 When we look at the scale of the universe we have to start looking at some big numbers. For example –  The age of the universe – seconds  Mass.

A pulsar is a supernova remnant which is a super dense, rapidly spinning neutron star which emits dipole electromagnetic radiation and features a strong.

Black holes, neutron stars and binary star systems

The Fate of High-Mass Stars

Ch Exploding Stars & Black Holes

The Legacy of Supernovae

The lifecycles of stars

Neutron Stars In a type II supernova the shock wave does not start at the very center of the collapsing core. After the explosion, the inner ball of neutrons.

You can often predict how a baby will look as an adult by looking at other family members. Astronomers observe stars of different ages to infer how stars.

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.

Evolution of the Solar System

Take out 2 sheets of paper for notes

The Death of a Star.

THE LIFE CYCLE OF STARS Chapter 15-2 Part 3.

Section 3 – pg 608 Lives of Stars

THE LIFE CYCLE OF STARS Chapter 15-2 Part 3.

THE LIFE CYCLE OF STARS Chapter 15-2 Part 3.

The lifecycles of stars

The Death of a Star.

THE LIFE CYCLE OF STARS Chapter 15-2 Part 3.

Goals Explain how neutron stars form Explain what pulsars are Explain what gamma ray bursts are Explain how Einstein’s theories apply to these objects.

Presentation transcript:

 Pulsars are just a kind of neutron stars so it’s essential to get a grip of these first.  The stars that come into being at the end of a massive star’s lifetime are called neutron stars.  When these massive stars have finished burning their nuclear fuel, they undergo a supernova explosion.  The event of formation of neutron stars is called core-collapse supernova’.  The central region of the star collapses so much that even electron, proton combine to form neutron and hence the name neutron star.

+  Small diameter + High mass=Super High Density.  Density of an average neutron star would be around 5 x kg/m 3.  Rotates about 40,000 times a minute.  Crust is about 1 km thick but 100 billion times stronger than steel.  Has a very tiny atmosphere(made mostly of iron 56 and lighter elements).  The surface is about 1 million degrees Celsius.  They have an escape velocity of about 33% the speed of light.

 Discovered by Jocelyn Bell in  She observed a pulsar whose pulsations lasted for about 0.04 seconds and were seconds apart, called pulsar period.  It was initially named LGM-1, for Little Green Men.  Bell and her instructor assumed it as a sign of extraterrestrial life.  Later Thomas Gold recognized that pulsars were rotating neutron stars.  So pulsar is a kind of neutron star that emits beams of radiation that sweep through Earth’s line of sight.  A special phenomenon called lighthouse effect is observed.  All pulsars are neutron stars, not all neutron stars are pulsars!

WWhen normal stars collapse into pulsars(neutron stars) their magnetic fields also compress and become enormously intense as much as a trillion times Earth’s magnetic field. PPulsars spin fast for the same reason ice skaters pull in their arms to spin, following conservation of angular momentum.

IIn Map reading. AAs precise clocks. AAs gravitational wave detectors. Relative position of the Sun to the centre of the galaxy and 14 pulsars

REFERENCES