Relativistic Stars: White Dwarfs
|
|
- Betty Carroll
- 5 years ago
- Views:
Transcription
1 Relativistic Stars: White Dwarfs
2 Late Stages of Stellar Evolution The star enters the Asymptotic Giant Branch with an active helium shell burning and an almost dormant hydrogen shell Again the stars size and luminosity increase, leading to a deepening of the convective zone (dredge-up) The hydrogen shell reignites, possibly several times, leading to pulsation of the star Eventually the helium burning stops and the core collapses Outer layers will be blown off and a planetary nebula forms in a Nova
3 Planetary Nebulae The glow of planetary nebula shells is caused by ultra-violet light emitted by the dwarf star Abell 78 NGC 39 Eskimo
4 White Dwarf Sirius B In 1844, Friedrich Wilhelm Bessel concluded from observations of Sirius that it was a binary star system Sirius is the brightest star in the sky, mostly because of its proximity of 8.6 ly In 186, Alvan Graham Clark discovered Sirius B with the new 18.5 Lick refractor Sirius A is ~1,000 times brighter than Sirius B Friedrich Wilhelm Bessel ( ) White dwarf Sirius B at the five o clock position
5 White Dwarf Sirius B Some parameters for Sirius B M = 1 M " L = 0.03 L T e = 7,000 K R = R ρ = kg m 3 g = m s
6 Spectral Classes of White Dwarfs White dwarfs have their own spectral class D DA display on pressure-broadened hydrogen absorption lines (about two thirds of white dwarfs) DB display only helium absorption lines (8% of white dwarfs) DC display no lines (14% of white dwarfs) DQ display some carbon absorption lines DZ display some metal lines
7 Cores of White Dwarfs We derived the period-density relation using P ( r ) = π G ρ ( R r ) 3 At the central core of the white dwarf we have P ( 0 ) π G ρ R N m Sirius B
8 Cores of White Dwarfs Estimate the core temperature using d T dr = 3 4 a c κ ρ T 3 L r 4 π r Radiation T T c R 0 = 3 4 a c κ ρ T c 3 L 4 π R T c 3 4 a c κ ρ L 4 π R ¼ T c T K Sirius B
9 Cores of White Dwarfs Sirius is a class DA white dwarf with hydrogen lines in the spectrum Given the core temperature the energy production rate due to hydrogen fusion in the core should lead to much higher luminosity than observed Therefore, hydrogen is present only at the dwarf s surface Most white dwarfs consist of ionized carbon and oxygen cores which cannot undergo fusion at the given temperatures What acts against the gravitational force inside a white dwarf?
10 Electron Degeneracy Pressure Answer: Pauli exclusion principle at work Any particle or wave in an ensemble occupies a quantum state identified by a set of quantum numbers In case of fermions with spin ½, each fermion has to have a different set of quantum numbers As an ensemble of fermions cools down, more and more of the lower energy states are being filled At zero temperature, all of the lower energy states are occupied and the fermion gas is completely degenerate The maximum energy of an electron in a completely degenerate gas is called Fermi energy ε F
11 Electron Degeneracy Pressure Consider electrons as standing waves in a box of sides L The momentum is given by p x ( y, z ) = h N x ( y, z ) L N x ( y, z ) integer quantum numbers Which yields for the total kinetic energy ε = h N 8 m L N = N x + N y + N z
12 Electron Degeneracy Pressure Total number of electrons in gas corresponds to total number of unique quantum numbers times two (for two spins states) N e = 1 4 π N 3 for positive N 8 3 x ( y, z ) Solving for N = 3 N e π ⅓ yields ε F = ħ m ( 3 π n e ) ⅔ with n e = N e / L 3
13 Electron Degeneracy Pressure Write for the number density of electrons # electrons # nucleons Z n e = = nucleon volume A ρ m H And obtain for the Fermi energy ε F = ħ 3 π m Z ρ A m H ⅔ This gives for the condition for a degenerate electron gas 3 k T < ħ 3 π m Z ρ A m H ⅔
14 Electron Degeneracy Pressure This gives for the condition for a degenerate electron gas With the definition T ħ < 3 π Z ⅔ ρ ⅔ = D 3 m k m H A D = 161 K m kg - ⅔
15 Electron Degeneracy Pressure The calculation of the degeneracy pressure makes use of Pauli exclusion principle Heisenberg s uncertainty principle Δx Δp x ħ Without derivation, we obtain for the pressure due to a completely degenerate, non-relativistic electron gas P = ( 3 π ) ⅔ ħ Z ρ 5 m A m H 5/3 Using Z / A = 0.5 for a carbon-oxygen white dwarf gives P N m Sirius B
Late Stages of Stellar Evolution. Late Stages of Stellar Evolution
Late Stages of Stellar Evolution The star enters the Asymptotic Giant Branch with an active helium shell burning and an almost dormant hydrogen shell Again the stars size and luminosity increase, leading
More informationStellar Evolution Stars spend most of their lives on the main sequence. Evidence: 90% of observable stars are main-sequence stars.
Stellar Evolution Stars spend most of their lives on the main sequence. Evidence: 90% of observable stars are main-sequence stars. Stellar evolution during the main-sequence life-time, and during the post-main-sequence
More information(2) low-mass stars: ideal-gas law, Kramer s opacity law, i.e. T THE STRUCTURE OF MAIN-SEQUENCE STARS (ZG: 16.2; CO 10.6, 13.
6.1 THE STUCTUE OF MAIN-SEQUENCE STAS (ZG: 16.2; CO 10.6, 13.1) main-sequence phase: hydrogen core burning phase zero-age main sequence (ZAMS): homogeneous composition Scaling relations for main-sequence
More informationGuiding Questions. The Deaths of Stars. Pathways of Stellar Evolution GOOD TO KNOW. Low-mass stars go through two distinct red-giant stages
The Deaths of Stars 1 Guiding Questions 1. What kinds of nuclear reactions occur within a star like the Sun as it ages? 2. Where did the carbon atoms in our bodies come from? 3. What is a planetary nebula,
More informationThe Deaths of Stars 1
The Deaths of Stars 1 Guiding Questions 1. What kinds of nuclear reactions occur within a star like the Sun as it ages? 2. Where did the carbon atoms in our bodies come from? 3. What is a planetary nebula,
More informationStellar Evolution: The Deaths of Stars. Guiding Questions. Pathways of Stellar Evolution. Chapter Twenty-Two
Stellar Evolution: The Deaths of Stars Chapter Twenty-Two Guiding Questions 1. What kinds of nuclear reactions occur within a star like the Sun as it ages? 2. Where did the carbon atoms in our bodies come
More informationGuiding Questions. The Deaths of Stars. Pathways of Stellar Evolution GOOD TO KNOW. Low-mass stars go through two distinct red-giant stages
The Deaths of Stars Guiding Questions 1. What kinds of nuclear reactions occur within a star like the Sun as it ages? 2. Where did the carbon atoms in our bodies come from? 3. What is a planetary nebula,
More informationLife and Death of a Star. Chapters 20 and 21
Life and Death of a Star Chapters 20 and 21 90 % of a stars life Most stars spend most of their lives on the main sequence. A star like the Sun, for example, after spending a few tens of millions of years
More informationStellar Evolution. Eta Carinae
Stellar Evolution Eta Carinae Evolution of Main Sequence Stars solar mass star: from: Markus Bottcher lecture notes, Ohio University Evolution off the Main Sequence: Expansion into a Red Giant Inner core
More informationStellar Deaths and Compact Objects
Stellar Deaths and Compact Objects White Dwarf Stars: Surface temperatures range from 5,000 to 80,000 K. They are the exposed stellar cores containing the products of nuclear fusion. They are composed
More informationAST 101 Introduction to Astronomy: Stars & Galaxies
AST 101 Introduction to Astronomy: Stars & Galaxies Summary: When a Low-Mass Star runs out of Hydrogen in its Core 1. With fusion no longer occurring in the core, gravity causes core collapse 2. Hydrogen
More informationComparing a Supergiant to the Sun
The Lifetime of Stars Once a star has reached the main sequence stage of it life, it derives its energy from the fusion of hydrogen to helium Stars remain on the main sequence for a long time and most
More informationLow mass stars. Sequence Star Giant. Red. Planetary Nebula. White Dwarf. Interstellar Cloud. White Dwarf. Interstellar Cloud. Planetary Nebula.
Low mass stars Interstellar Cloud Main Sequence Star Red Giant Planetary Nebula White Dwarf Interstellar Cloud Main Sequence Star Red Giant Planetary Nebula White Dwarf Low mass stars Interstellar Cloud
More informationAST101 Lecture 13. The Lives of the Stars
AST101 Lecture 13 The Lives of the Stars A Tale of Two Forces: Pressure vs Gravity I. The Formation of Stars Stars form in molecular clouds (part of the interstellar medium) Molecular clouds Cold: temperatures
More informationIntroductory Astrophysics A113. Death of Stars. Relation between the mass of a star and its death White dwarfs and supernovae Enrichment of the ISM
Goals: Death of Stars Relation between the mass of a star and its death White dwarfs and supernovae Enrichment of the ISM Low Mass Stars (M
More informationEvolution of Stars Population III: Population II: Population I:
Evolution of Stars 1. Formed from gas/dust cloud collapse from gravity 2. Fuse H to He on the Main Sequence. Then evolve off Main-sequence as they burn He and successive elements. 3. When nuclear fusion
More informationLecture 16: The life of a low-mass star. Astronomy 111 Monday October 23, 2017
Lecture 16: The life of a low-mass star Astronomy 111 Monday October 23, 2017 Reminders Online homework #8 due Monday at 3pm Exam #2: Monday, 6 November 2017 The Main Sequence ASTR111 Lecture 16 Main sequence
More informationAstronomy. Stellar Evolution
Astronomy A. Dayle Hancock adhancock@wm.edu Small 239 Office hours: MTWR 10-11am Stellar Evolution Main Sequence star changes during nuclear fusion What happens when the fuel runs out Old stars and second
More informationStages of the Sun's life:
Stellar Evolution Stages of the Sun's life: 1) initial collapse from interstellar gas (5 million yrs) 2) onset of nuclear reactions to start of main sequence phase (30 million yrs) 3) main sequence (10
More informationWhite Dwarfs - Degenerate Stellar Configurations
White Dwarfs - Degenerate Stellar Configurations Austen Groener Department of Physics - Drexel University, Philadelphia, Pennsylvania 904, USA Quantum Mechanics II May 7, 200 I Abstract The end product
More informationFirst: Some Physics. Tides on the Earth. Lecture 11: Stellar Remnants: White Dwarfs, Neutron Stars, and Black Holes A2020 Prof. Tom Megeath. 1.
Lecture 11: Stellar Remnants: White Dwarfs, Neutron Stars, and Black Holes A2020 Prof. Tom Megeath First: Some Physics 1. Tides 2. Degeneracy Pressure Concept 1: How does gravity cause tides? R F tides
More informationPre Main-Sequence Evolution
Stellar Astrophysics: Stellar Evolution Pre Main-Sequence Evolution The free-fall time scale is describing the collapse of the (spherical) cloud to a protostar 1/2 3 π t ff = 32 G ρ With the formation
More informationThe life of a low-mass star. Astronomy 111
Lecture 16: The life of a low-mass star Astronomy 111 Main sequence membership For a star to be located on the Main Sequence in the H-R diagram: must fuse Hydrogen into Helium in its core. must be in a
More informationA Star Becomes a Star
A Star Becomes a Star October 28, 2002 1) Stellar lifetime 2) Red Giant 3) White Dwarf 4) Supernova 5) More massive stars Review Solar winds/sunspots Gases and Dust Molecular clouds Protostars/Birth of
More informationStars with Mⵙ go through two Red Giant Stages
Astronomy A. Dayle Hancock adhancock@wm.edu Small 239 Office hours: MTWR 10-11am Death of Stars Nuclear reactions in small stars How stars disperse carbon How low mass stars die The nature of white dwarfs
More informationStellar Astrophysics: The Classification of Stellar Spectra
Stellar Astrophysics: The Classification of Stellar Spectra Temperature and Color The intensity of light emitted by three hypothetical stars is plotted against wavelength The range of visible wavelengths
More informationLecture Outlines. Chapter 20. Astronomy Today 8th Edition Chaisson/McMillan Pearson Education, Inc.
Lecture Outlines Chapter 20 Astronomy Today 8th Edition Chaisson/McMillan Chapter 20 Stellar Evolution Units of Chapter 20 20.1 Leaving the Main Sequence 20.2 Evolution of a Sun-Like Star 20.3 The Death
More informationDegenerate Matter and White Dwarfs
Degenerate Matter and White Dwarfs Summary of Post-Main-Sequence Evolution of Sun-Like Stars Formation of a Planetary Nebula Fusion stops at formation of C,O core. Core collapses; outer shells bounce off
More informationAs the central pressure decreases due to the increase of μ, the stellar core contracts and the central temperature increases. This increases the
Stellar Evolu,on Stars spend most of their lives on the main sequence. Evidence for this is provided by the fact that 90% of stars observable from Earth are main- sequence stars. Stellar evolu,on during
More informationMass-Volume Relation. ( 3 π 2 ) ⅔ ħ 2 Z ρ. π G ρ 2 R 2 = ( 18 π ) ⅔ ħ 2 Z
Mass-Volume Relation Chandrasekhar realized, that there has to be a maximum mass for a white dwarf Equating the central pressure estimate with the electron degeneracy pressure yields 2 3 π G ρ 2 R 2 =
More informationPrinciples of Astrophysics and Cosmology
Principles of Astrophysics and Cosmology Welcome Back to PHYS 3368 Friedrich Wilhelm Bessel July 22, 1784 March 17, 1846 Announcements - Reading Assignments: Chapter 4.1-4.3. - Problem Set 6 is due Wednesday,
More information10/26/ Star Birth. Chapter 13: Star Stuff. How do stars form? Star-Forming Clouds. Mass of a Star-Forming Cloud. Gravity Versus Pressure
10/26/16 Lecture Outline 13.1 Star Birth Chapter 13: Star Stuff How do stars form? Our goals for learning: How do stars form? How massive are newborn stars? Star-Forming Clouds Stars form in dark clouds
More informationVisit for more fantastic resources. OCR. A Level. A Level Physics. Astrophysics 1 (Answers) Name: Total Marks: /30
Visit http://www.mathsmadeeasy.co.uk/ for more fantastic resources. OCR A Level A Level Physics Astrophysics 1 (Answers) Name: Total Marks: /30 Maths Made Easy Complete Tuition Ltd 2017 1. Amongst all
More informationReading and Announcements. Read Chapter 14.1, 14.2 Homework #6 due Tuesday, March 26 Exam #2, Thursday, March 28
Reading and Announcements Read Chapter 14.1, 14.2 Homework #6 due Tuesday, March 26 Exam #2, Thursday, March 28 The life of the Sun The Sun started as a cloud of gas. Gravity caused the cloud to collapse.
More informationChapter 14: The Bizarre Stellar Graveyard. Copyright 2010 Pearson Education, Inc.
Chapter 14: The Bizarre Stellar Graveyard Assignments 2 nd Mid-term to be held Friday Nov. 3 same basic format as MT1 40 mult. choice= 80 pts. 4 short answer = 20 pts. Sample problems on web page Origin
More informationAge of M13: 14 billion years. Mass of stars leaving the main-sequence ~0.8 solar masses
Age of M13: 14 billion years. Mass of stars leaving the main-sequence ~0.8 solar masses Helium coreburning stars Giants Subgiants Main Sequence Here is a way to think about it. Outside of star Plenty of
More informationAstro 1050 Fri. Apr. 10, 2015
Astro 1050 Fri. Apr. 10, 2015 Today: Continue Ch. 13: Star Stuff Reading in Bennett: For Monday: Finish Chapter 13 Star Stuff Reminders: Ch. 12 HW now on Mastering Astronomy, due Monday. Ch. 13 will be
More informationWhat is a star? A body of gases that gives off tremendous amounts of energy in the form of light & heat. What star is closest to the earth?
Stars What is a star? A body of gases that gives off tremendous amounts of energy in the form of light & heat. What star is closest to the earth? Answer: The SUN It s about 150,000,000 km from earth =
More information17.1 Lives in the Balance. Our goals for learning: How does a star's mass affect nuclear fusion?
Stellar Evolution 17.1 Lives in the Balance Our goals for learning: How does a star's mass affect nuclear fusion? How does a star's mass affect nuclear fusion? Stellar Mass and Fusion The mass of a main-sequence
More informationAstronomy Ch. 20 Stellar Evolution. MULTIPLE CHOICE. Choose the one alternative that best completes the statement or answers the question.
Name: Period: Date: Astronomy Ch. 20 Stellar Evolution MULTIPLE CHOICE. Choose the one alternative that best completes the statement or answers the question. 1) A star (no matter what its mass) spends
More informationAstronomy Ch. 20 Stellar Evolution. MULTIPLE CHOICE. Choose the one alternative that best completes the statement or answers the question.
Name: Period: Date: Astronomy Ch. 20 Stellar Evolution MULTIPLE CHOICE. Choose the one alternative that best completes the statement or answers the question. 1) A star (no matter what its mass) spends
More informationSunday, May 1, AGB Stars and Massive Star Evolution
AGB Stars and Massive Star Evolution Iben The Helium Flash (< 2 Msun) The central core becomes dense enough, that degeneracy pressure dominates over thermal pressure. Still, the core radiates energy and
More informationThe Evolution of Low Mass Stars
The Evolution of Low Mass Stars Key Ideas: Low Mass = M < 4 M sun Stages of Evolution of a Low Mass star: Main Sequence star star star Asymptotic Giant Branch star Planetary Nebula phase White Dwarf star
More informationHR Diagram, Star Clusters, and Stellar Evolution
Ay 1 Lecture 9 M7 ESO HR Diagram, Star Clusters, and Stellar Evolution 9.1 The HR Diagram Stellar Spectral Types Temperature L T Y The Hertzsprung-Russel (HR) Diagram It is a plot of stellar luminosity
More informationStellar Death. Final Phases
Stellar Death Final Phases After the post-agb phase, the death of the star is close at hand. Function of Mass (For stars < ~ 4 solar masses) 1. Lowest mass stars will never have sufficient pressure and
More informationThe Life and Death of Stars
The Life and Death of Stars What is a Star? A star is a sphere of plasma gas that fuses atomic nuclei in its core and so emits light The name star can also be tagged onto a body that is somewhere on the
More informationTA feedback forms are online!
1 Announcements TA feedback forms are online! find the link at the class website. Please take 5 minutes to tell your TAs your opinion. In case you did not notice, the Final is set for 03/21 from 12:00-3:00
More informationAST 101 Introduction to Astronomy: Stars & Galaxies
AST 101 Introduction to Astronomy: Stars & Galaxies The H-R Diagram review So far: Stars on Main Sequence (MS) Next: - Pre MS (Star Birth) - Post MS: Giants, Super Giants, White dwarfs Star Birth We start
More informationWhy Do Stars Leave the Main Sequence? Running out of fuel
Star Deaths Why Do Stars Leave the Main Sequence? Running out of fuel Observing Stellar Evolution by studying Globular Cluster HR diagrams Plot stars in globular clusters in Hertzsprung-Russell diagram
More informationVisit for more fantastic resources. Edexcel. A Level. A Level Physics. Astrophysics 1 (Answers) Name: Total Marks: /30
Visit http://www.mathsmadeeasy.co.uk/ for more fantastic resources. Edexcel A Level A Level Physics Astrophysics 1 (Answers) Name: Total Marks: /30 Maths Made Easy Complete Tuition Ltd 2017 1. Amongst
More informationAstronomy 1144 Exam 3 Review
Stars and Stellar Classification Astronomy 1144 Exam 3 Review Prof. Pradhan 1. What is a star s energy source, or how do stars shine? Stars shine by fusing light elements into heavier ones. During fusion,
More informationLecture 15: Electron Degeneracy Pressure
Lecture 15: Electron Degeneracy Pressure As the core contracts during shell H-burning we reach densities where the equation of state becomes significantly modified from that of the ideal gas law. The reason
More information20. Stellar Death. Interior of Old Low-Mass AGB Stars
20. Stellar Death Low-mass stars undergo three red-giant stages Dredge-ups bring material to the surface Low -mass stars die gently as planetary nebulae Low -mass stars end up as white dwarfs High-mass
More informationWhite Dwarfs. We'll follow our text closely for most parts Prialnik's book is also excellent here
White Dwarfs We'll follow our text closely for most parts Prialnik's book is also excellent here Observational Properties The Helix Nebula is one of brightest and closest examples of a planetary nebula,
More informationclass 21 Astro 16: Astrophysics: Stars, ISM, Galaxies November 20, 2018
Topics: Post-main-sequence stellar evolution, degeneracy pressure, and white dwarfs Summary of reading: Review section 2 of Ch. 17. Read the beginning and first section of Ch. 18 (up through the middle
More informationAST 101 Introduction to Astronomy: Stars & Galaxies
The H-R Diagram review So far: AST 101 Introduction to Astronomy: Stars & Galaxies - Stars on Main Sequence (MS) - Pre MS (Star Birth) Next: - Post MS: Giants, Super Giants, White dwarfs Evolution of Low
More informationHeading for death. q q
Hubble Photos Credit: NASA, The Hubble Heritage Team (STScI/AURA) Heading for death. q q q q q q Leaving the main sequence End of the Sunlike star The helium core The Red-Giant Branch Helium Fusion Helium
More informationChapters 12 and 13 Review: The Life Cycle and Death of Stars. How are stars born, and how do they die? 4/1/2009 Habbal Astro Lecture 27 1
Chapters 12 and 13 Review: The Life Cycle and Death of Stars How are stars born, and how do they die? 4/1/2009 Habbal Astro 110-01 Lecture 27 1 Stars are born in molecular clouds Clouds are very cold:
More informationReview: HR Diagram. Label A, B, C respectively
Stellar Evolution Review: HR Diagram Label A, B, C respectively A C B a) A: White dwarfs, B: Giants, C: Main sequence b) A: Main sequence, B: Giants, C: White dwarfs c) A: Main sequence, B: White Dwarfs,
More informationAstronomy 110: SURVEY OF ASTRONOMY. 11. Dead Stars. 1. White Dwarfs and Supernovae. 2. Neutron Stars & Black Holes
Astronomy 110: SURVEY OF ASTRONOMY 11. Dead Stars 1. White Dwarfs and Supernovae 2. Neutron Stars & Black Holes Low-mass stars fight gravity to a standstill by becoming white dwarfs degenerate spheres
More informationLow-mass Stellar Evolution
Low-mass Stellar Evolution The lives of low-mass stars And the lives of massive stars The Structure of the Sun Let s review: The Sun is held together by? The inward force is balanced by? Thinking about
More informationAstronomy 210. Outline. Stellar Properties. The Mosquito Dilemma. Solar Observing & HW9 due April 15 th Stardial 2 is available.
Astronomy 210 Outline This Class (Lecture 31): Stars: Spectra and the H-R Diagram Next Class: Life and Death of the Sun Solar Observing & HW9 due April 15 th Stardial 2 is available. The Mosquito dilemma
More informationStellar Astronomy Sample Questions for Exam 4
Stellar Astronomy Sample Questions for Exam 4 Chapter 15 1. Emission nebulas emit light because a) they absorb high energy radiation (mostly UV) from nearby bright hot stars and re-emit it in visible wavelengths.
More informationGuiding Questions. Stellar Evolution. Stars Evolve. Interstellar Medium and Nebulae
Guiding Questions Stellar Evolution 1. Why do astronomers think that stars evolve? 2. What kind of matter exists in the spaces between the stars? 3. What steps are involved in forming a star like the Sun?
More informationStellar Evolution. The lives of low-mass stars. And the lives of massive stars
Stellar Evolution The lives of low-mass stars And the lives of massive stars The Structure of the Sun Let s review: The Sun is held together by what force? The inward force is balanced by what other force?
More informationAnnouncements. L! m 3.5 BRIGHT FAINT. Mass Luminosity Relation: Why? Homework#3 will be handed out at the end of this lecture.
Announcements BRIGHT Homework#3 will be handed out at the end of this lecture. Due October 14 (next Thursday) Review of Mid-term exam will be handed out Tuesday. Mid-term exam will be variants (if not
More informationChapter 19: The Evolution of Stars
Chapter 19: The Evolution of Stars Why do stars evolve? (change from one state to another) Energy Generation fusion requires fuel, fuel is depleted [fig 19.2] at higher temperatures, other nuclear process
More informationPlanetary Nebulae evolve to White Dwarf Stars
Planetary Nebulae evolve to White Dwarf Stars Planetary Nebulae When Red Giant exhausts its He fuel the C core contracts Low & medium-mass stars don t have enough gravitational energy to heat to core 6
More informationNames: Team: Team Number:
Astronomy C Michigan Region 8 March 11, 2017 Names: Team: Team Number: Directions 1. There is a separate answer sheet. Answers written elsewhere (e.g. on the test) will not be considered. 2. You may take
More informationAstronomy 102: Stars and Galaxies Examination 3 April 11, 2003
Name: Seat Number: Astronomy 102: Stars and Galaxies Examination 3 April 11, 2003 Do not open the test until instructed to begin. Instructions: Write your answers in the space provided. If you need additional
More informationPhys 100 Astronomy (Dr. Ilias Fernini) Review Questions for Chapter 9
Phys 0 Astronomy (Dr. Ilias Fernini) Review Questions for Chapter 9 MULTIPLE CHOICE 1. We know that giant stars are larger in diameter than the sun because * a. they are more luminous but have about the
More informationIntroduction to Astronomy. Lecture 8: The Death of Stars White Dwarfs, Neutron Stars, and Black Holes
Introduction to Astronomy Lecture 8: The Death of Stars White Dwarfs, Neutron Stars, and Black Holes Continued from Last Week Lecture 7 Observing Stars Clusters of stars Some clouds start breaking into
More informationChapter 17 Lecture. The Cosmic Perspective Seventh Edition. Star Stuff Pearson Education, Inc.
Chapter 17 Lecture The Cosmic Perspective Seventh Edition Star Stuff Star Stuff 17.1 Lives in the Balance Our goals for learning: How does a star's mass affect nuclear fusion? How does a star's mass affect
More informationScience Olympiad Astronomy C Regional Event February 11, 2017 Maryland
Science Olympiad Astronomy C Regional Event February 11, 2017 Maryland TEAM NUMBER: TEAM NAME: INSTRUCTIONS: 1) Please turn in ALL MATERIALS at the end of this event. 2) Do not forget to put your TEAM
More informationCh. 16 & 17: Stellar Evolution and Death
Ch. 16 & 17: Stellar Evolution and Death Stars have lives: born, evolve, die Mass determines stellar evolution: Really Low Mass (0.08 to 0.4 M sun ) Low Mass: (0.4 to 4 M sun ) Long lives High Mass (4
More informationStellar Remnants. White Dwarfs Neutron Stars Black Holes
Stellar Remnants White Dwarfs Neutron Stars Black Holes 1 Announcements q Homework # 5 is due today. q Homework # 6 starts today, Nov 15th. Due on Tuesday, Nov 22nd. 2 Assigned Reading Chapters: 64.4,
More informationLifespan on the main sequence. Lecture 9: Post-main sequence evolution of stars. Evolution on the main sequence. Evolution after the main sequence
Lecture 9: Post-main sequence evolution of stars Lifetime on the main sequence Shell burning and the red giant phase Helium burning - the horizontal branch and the asymptotic giant branch The death of
More informationStars: Their Life and Afterlife
The 68 th Compton Lecture Series Stars: Their Life and Afterlife Lecture 3: The Life and Times of Low Mass Stars Brian Humensky, lecturer http://kicp.uchicago.edu/~humensky/comptonlectures.htm October
More informationTeacher of the Week DEVIL PHYSICS THE BADDEST CLASS ON CAMPUS IB PHYSICS
Teacher of the Week DEVIL PHYSICS THE BADDEST CLASS ON CAMPUS IB PHYSICS TSOKOS LESSON E-2 STELLAR RADIATION IB Assessment Statements Topic E-2, Stellar Radiation and Stellar Types Energy Source E.2.1.
More informationChapter 12 Review. 2) About 90% of the star's total life is spent on the main sequence. 2)
Chapter 12 Review TRUE/FALSE. Write 'T' if the statement is true and 'F' if the statement is false. 1) As a main-sequence star, the Sun's hydrogen supply should last about 10 billion years from the zero-age
More informationThe Later Evolution of Low Mass Stars (< 8 solar masses)
The sun - past and future The Later Evolution of Low Mass Stars (< 8 solar masses) During 10 billion years the suns luminosity changes only by about a factor of two. After that though, changes become rapid
More information10/29/2009. The Lives And Deaths of Stars. My Office Hours: Tuesday 3:30 PM - 4:30 PM 206 Keen Building. Stellar Evolution
of s Like s of Other Stellar The Lives And Deaths of s a Sun-like s More 10/29/2009 My Office Hours: Tuesday 3:30 PM - 4:30 PM 206 Keen Building Test 2: 11/05/2009 of s Like s of Other a Sun-like s More
More informationSupernovae and cosmology
Supernovae and cosmology On the Death of Stars and Standard Candles Gijs Hijmans Supernovae Types of Supernovae Type I Ia (no hydrogen but strong silicon lines in spectrum) Ib (non ionized helium lines)
More informationStars & Galaxies. Chapter 27, Section 1. Composition & Temperature. Chapter 27 Modern Earth Science Characteristics of Stars
Stars & Galaxies Chapter 27 Modern Earth Science Chapter 27, Section 1 27.1 Characteristics of Stars Composition & Temperature Scientists use the following tools to study stars Telescope Observation Spectral
More informationAstronomy Notes Chapter 13.notebook. April 11, 2014
All stars begin life in a similar way the only difference is in the rate at which they move through the various stages (depends on the star's mass). A star's fate also depends on its mass: 1) Low Mass
More informationThe Deaths of Stars. The Southern Crab Nebula (He2-104), a planetary nebula (left), and the Crab Nebula (M1; right), a supernova remnant.
The Deaths of Stars The Southern Crab Nebula (He2-104), a planetary nebula (left), and the Crab Nebula (M1; right), a supernova remnant. Once the giant phase of a mediummass star ends, it exhales its outer
More informationLecture notes 9: The end states of stars
Lecture notes 9: The end states of stars We have seen that the two most important properties governing the structure of a star such as the Sun are 1. self gravitation; a star obeying the ideal equation
More informationλ = 650 nm = c = m s 1 f =? c = fλ f = c λ = ( m s 1 ) ( m) = = Hz T = 1 f 4.
Chapter 13 Stars Section 13.1 Astronomical measurements Worked example: Try yourself 13.1.1 CALCULATING THE FREQUENCY AND PERIOD OF LIGHT The speed of light in a vacuum is approximately 3.0 10 8 m s 1.
More informationChapter 12 Stellar Evolution
Chapter 12 Stellar Evolution Guidepost Stars form from the interstellar medium and reach stability fusing hydrogen in their cores. This chapter is about the long, stable middle age of stars on the main
More informationStars, Galaxies & the Universe Announcements. Stars, Galaxies & the Universe Lecture Outline. HW#7 due Friday by 5 pm! (available Tuesday)
Stars, Galaxies & the Universe Announcements HW#7 due Friday by 5 pm! (available Tuesday) Midterm Grades (points) posted today in ICON Exam #2 next week (Wednesday) Review sheet and study guide posted
More informationThe Stellar Graveyard Neutron Stars & White Dwarfs
The Stellar Graveyard Neutron Stars & White Dwarfs White Dwarfs White dwarfs are the remaining cores of low-mass (M < 8M sun ) stars Electron degeneracy pressure supports them against gravity Density ~
More informationStellar Evolution ASTR 2110 Sarazin. HR Diagram vs. Mass
Stellar Evolution ASTR 2110 Sarazin HR Diagram vs. Mass Trip to Conference Away on conference in the Netherlands next week. Molly Finn, TA, will be our guest lecturer Stellar Evolution ASTR 2110 Sarazin
More informationL = 4 d 2 B p. 4. Which of the letters at right corresponds roughly to where one would find a red giant star on the Hertzsprung-Russell diagram?
Fall 2016 Astronomy - Test 3 Test form B Name Do not forget to write your name and fill in the bubbles with your student number, and fill in test form B on the answer sheet. Write your name above as well.
More informationL = 4 d 2 B p. 1. Which outer layer of the Sun has the highest temperature? A) Photosphere B) Corona C) Chromosphere D) Exosphere E) Thermosphere
Fall 2016 Astronomy - Test 3 Test form A Name Do not forget to write your name and fill in the bubbles with your student number, and fill in test form A on the answer sheet. Write your name above as well.
More informationThe Electromagnetic Spectrum
The Electromagnetic Spectrum Three Kinds of Spectra Sun: The Nearest Star Radius 696,000 km 109 Re Mass 2 x 10^30 kg 300,000 Me Density 1400 kg/m^3 Luminosity 3.8x10^26 Watts (board calc.) Comp. 70% H,
More informationInstructor: Juhan Frank. Identify the correct answers by placing a check between the brackets ë ë.
Name:... ASTRONOMY 1102 í 1 Instructor: Juhan Frank Third Test ífall 1999í Friday November 12 Part I í Multiple Choice questions è3 ptsèquestion; total = 60 ptsè Identify the correct answers by placing
More informationWhite Dwarf Stars as Probes of Physical and Astrophysical Processes
White Dwarf Stars as Probes of Physical and Astrophysical Processes M I K E M O N T G O M E R Y D E P A R T M E N T O F A S T R O N O M Y, M C D O N A L D O B S E R V A T O R Y A N D T H E T E X A S C
More informationStars & Galaxies. Chapter 27 Modern Earth Science
Stars & Galaxies Chapter 27 Modern Earth Science Chapter 27, Section 1 27.1 Characteristics of Stars How do astronomers determine the composition and surface temperature of a star? Composition & Temperature
More informationProtostars on the HR Diagram. Lifetimes of Stars. Lifetimes of Stars: Example. Pressure-Temperature Thermostat. Hydrostatic Equilibrium
Protostars on the HR Diagram Once a protostar is hot enough to start, it can blow away the surrounding gas Then it is visible: crosses the on the HR diagram The more the cloud, the it will form stars Lifetimes
More informationStellar Midlife. A. Main Sequence Lifetimes. (1b) Lifetime of Sun. Stellar Evolution Part II. A. Main Sequence Lifetimes. B. Giants and Supergiants
Stellar Evolution Part II 1 Stellar Midlife 2 Stellar Midlife A. Main Sequence Lifetimes B. Giants and Supergiants C. Variables (Cepheids) Dr. Bill Pezzaglia Updated Oct 9, 2006 A. Main Sequence Lifetimes
More information