Presentation is loading. Please wait.

Presentation is loading. Please wait.

Chapter 18 Evolution from the Main Sequence Astro1010-lee.com UVU Survey of Astronomy.

Published byJennifer Blair Modified over 9 years ago

Similar presentations

Presentation on theme: "Chapter 18 Evolution from the Main Sequence Astro1010-lee.com UVU Survey of Astronomy."— Presentation transcript:

1 Chapter 18 Evolution from the Main Sequence Astro1010-lee.com twlee2016@gmail.com UVU Survey of Astronomy

2 Chapter 18 Evolution from the Main Sequence During its stay on the main sequence, any fluctuations in a star’s condition are quickly restored; the star is in equilibrium. Astro1010-lee.com twlee2016@gmail.com UVU Survey of Astronomy

3 Chapter 18 Evolution from the Main Sequence Again to follow the post-main-sequence evolution of a star we will resort to the stage method. Not every star adheres to this sequence but it serves to describe the steps that many stars take Astro1010-lee.com twlee2016@gmail.com UVU Survey of Astronomy

4 Chapter 18 Even while on the main sequence, Stage 7, the composition of a star’s core is changing. Eventually, as hydrogen in the core is consumed, the Star leaves the main sequence, Stage 8. Its evolution from then on depends very much on the mass of the star: Low-mass stars go quietly.Medium- mass stars struggle.High-mass stars go out with a bang! Astro1010-lee.com twlee2016@gmail.com UVU Survey of Astronomy

5 Chapter 18 Evolution from the Main Sequence When the fuel in the core is used up the fusion ceases. The result is a contraction of the Star and the formation of a new fusion furnace in a shell around the helium core. This is Stage 8 Astro1010-lee.com twlee2016@gmail.com UVU Survey of Astronomy

6 Chapter 18 Evolution from the Main Sequence Stage 9: The Red-Giant Branch. The now much larger surface of the furnace causes outer layers of the star to expand and cool. It is now a red giant, extending out beyond the orbit of Mercury. Despite its cooler surface temperature, its luminosity increases enormously due to its large size. Astro1010-lee.com twlee2016@gmail.com UVU Survey of Astronomy

7 Chapter 18 Evolution from the Main Sequence Stage 10: Helium fusion. Once the core temperature has risen to 100,000,000 K, the helium in the core can fuse, through a three-alpha process: The 8 Be nucleus is highly unstable, and will decay in about 10 –12 sec unless an alpha particle fuses with it first. This is why high temperatures and densities are necessary. Astro1010-lee.com twlee2016@gmail.com UVU Survey of Astronomy

8 Chapter 18 Evolution from the Main Sequence The helium flash: The pressure within the helium core is almost totally due to “electron degeneracy” – two electrons cannot be in the same quantum state, so the core cannot contract beyond a certain point. This pressure is almost independent of temperature so when the helium starts fusing, the pressure cannot adjust and the core explodes completely disrupting the surrounding shell furnace. Helium begins to fuse extremely rapidly; within hours to days the enormous energy output is over, but the star is now on its way to White Dwarf, Stage 13 Astro1010-lee.com twlee2016@gmail.com UVU Survey of Astronomy

9 Chapter 18 Evolution from the Main Sequence Stage 10. Disruption of the hydrogen furnace throws the star out of equilibrium and it starts to shrink, but it has much heat to dissipate from the Helium Flash. The result is the surface gets smaller as the surface temperature gets higher, causing movement across the graph toward the blue while maintaining nearly the same brightness. Astro1010-lee.com UVU Survey of Astronomy

10 Chapter 18 Evolution from the Main Sequence Stages 11 and 12 depend very much on the mass of the star. From.5 to 1.4 solar masses the transition from the horizontal branch White Dwarf goes smoothly. From 1.4 to about 5.5 solar masses they must shed the extras mass to get down to the Chandrasakar limit of 1.4 solar masses, then they can transition to White Dwarf. Astro1010-lee.com twlee2016@gmail.com UVU Survey of Astronomy

11 Chapter 18 Evolution from the Main Sequence Horizontal Branch, Stage 10. The Helium Flash has disrupted the nuclear shell and the star is dying. There is much heat to be shed before the star can become a White Dwarf. The star shrinks by gravity but remains bright by the surface getting hotter. Stars over 1.4 Solar masses also must rid themselves of the extra mass. Astro1010-lee.com twlee2016@gmail.com UVU Survey of Astronomy

12 Chapter 18 Evolution from the Main Sequence The Instability Strip, still Stage 10.. As the dying star moves along the horizontal branch it encounters a region, discovered by Hertsprung, called the Instability Strip. The star becomes a variable star changing brightness slightly in a very few days. Astro1010-lee.com twlee2016@gmail.com UVU Survey of Astronomy

13 Absolute Magnitude Period RR Lyras Chapter 18 Evolution from the Main Sequence Cephieds Henrietta Levitt discovered a direct relationship of Period to Luminosity of the Cephied Variables and the RR Lyra Variables It was later shown that there are two families of Cephieds Astro1010-lee.com twlee2016@gmail.com UVU Survey of Astronomy

14 Chapter 18 Evolution from the Main Sequence Some stars with more than about 5.5 solar masses have a different problem. The Helium flash becomes a permanent nuclear furnace. The Helium core fuses helium to carbon and the shield furnace continues to fuse Hydrogen to Helium and the star is now in a some what stable state. Many stars go into a new Red Giant condition for a period. This is the Asymptotic Giant Branch, Stage 11 Astro1010-lee.com twlee2016@gmail.com UVU Survey of Astronomy

15 Chapter 18 Evolution from the Main Sequence End Chapter 18 Astro1010-lee.com twlee2016@gmail.com UVU Survey of Astronomy

16 Chapter 18 Evolution from the Main Sequence UVU Survey of Astronomy

Download ppt "Chapter 18 Evolution from the Main Sequence Astro1010-lee.com UVU Survey of Astronomy."

Similar presentations

Stellar Evolution (of sun-like stars)

Stellar Evolution (of sun-like stars)
Notes 30.2 Stellar Evolution

Notes 30.2 Stellar Evolution
Lecture PowerPoint Chapter 20 Astronomy Today, 5th edition Chaisson

Lecture PowerPoint Chapter 20 Astronomy Today, 5th edition Chaisson
Prof. D.C. Richardson Sections

Prof. D.C. Richardson Sections
Life as a Low-mass Star Image: Eagle Nebula in 3 wavebands (Kitt Peak 0.9 m).

Life as a Low-mass Star Image: Eagle Nebula in 3 wavebands (Kitt Peak 0.9 m).
Stellar Evolution. The Mass-Luminosity Relation Our goals for learning: How does a star’s mass affect nuclear fusion?

Stellar Evolution. The Mass-Luminosity Relation Our goals for learning: How does a star’s mass affect nuclear fusion?
Announcements Homework 10 due Monday: Make your own H-R diagram!

Announcements Homework 10 due Monday: Make your own H-R diagram!
Copyright © 2010 Pearson Education, Inc. Clicker Questions Chapter 12 Stellar Evolution.

Copyright © 2010 Pearson Education, Inc. Clicker Questions Chapter 12 Stellar Evolution.
Stellar Evolution Describe how a protostar becomes a star.

Stellar Evolution Describe how a protostar becomes a star.
Chapter 16: Evolution of Low-Mass Stars

Chapter 16: Evolution of Low-Mass Stars
Objectives Determine the effect of mass on a star’s evolution.

Objectives Determine the effect of mass on a star’s evolution.
Stellar Evolution. Basic Structure of Stars Mass and composition of stars determine nearly all of the other properties of stars Mass and composition of.

Stellar Evolution. Basic Structure of Stars Mass and composition of stars determine nearly all of the other properties of stars Mass and composition of.
© 2005 Pearson Prentice Hall This work is protected by United States copyright laws and is provided solely for the use of instructors in teaching their.

© 2005 Pearson Prentice Hall This work is protected by United States copyright laws and is provided solely for the use of instructors in teaching their.
Astronomy 1 – Fall 2014 Lecture 12; November 18, 2014.

Astronomy 1 – Fall 2014 Lecture 12; November 18, 2014.
What is the Lifecycle of a Star? Chapter 30.3. Stars form when a nebula contracts due to gravity and heats up (see notes on formation of the solar system).

What is the Lifecycle of a Star? Chapter Stars form when a nebula contracts due to gravity and heats up (see notes on formation of the solar system).
Chapter 11 The Lives of Stars. What do you think? Where do stars come from? Do stars with greater or lesser mass last longer?

Chapter 11 The Lives of Stars. What do you think? Where do stars come from? Do stars with greater or lesser mass last longer?
The Helium Flash and Stages 10 and 11 M < 8 M . Electron degeneracy pressure: the pressure exerted by electrons caused by the confinement in the small.

The Helium Flash and Stages 10 and 11 M < 8 M . Electron degeneracy pressure: the pressure exerted by electrons caused by the confinement in the small.
Chapter 20 Stellar Evolution

Chapter 20 Stellar Evolution
Stellar Evolution. The H-R Diagram There are patterns in the HR diagram. Most stars lie on the main sequence, and obey a mass-luminosity relation. (Low.

Stellar Evolution. The H-R Diagram There are patterns in the HR diagram. Most stars lie on the main sequence, and obey a mass-luminosity relation. (Low.
Lecture Outlines Astronomy Today 8th Edition Chaisson/McMillan © 2014 Pearson Education, Inc. Chapter 20.

Lecture Outlines Astronomy Today 8th Edition Chaisson/McMillan © 2014 Pearson Education, Inc. Chapter 20.

Similar presentations

Ads by Google