Presentation is loading. Please wait.

Presentation is loading. Please wait.

PHYS377: A six week marathon through the firmament

Published byAlicia Herrera López Modified over 6 years ago

Similar presentations

Presentation on theme: "PHYS377: A six week marathon through the firmament"— Presentation transcript:

1 PHYS377: A six week marathon through the firmament
Week 3, May 10-12, 2009 by Orsola De Marco Office: E7A 316 Phone:

2 Overview of the course Where and what are the stars. How we perceive them, how we measure them. (Almost) 8 things about stars: stellar structure equations. The stellar furnace and stellar change. Stars that lose themselves and stars that lose it: stellar mass loss and explosions. Stellar death: stellar remnants. When it takes two to tango: binaries and binary interactions.

3 What powers a star? In the 1850s Helmholz thought it might be conversion of potential energy (i.e. the energy of gravity) into photons. This is too short a time! Why?

4 Eddington’s interpretation
Sun powered by gravity? Would last too short a time. : Discovery of radioactivity: could the sun be powered by radioactivity? No: stars do not have many radioactive elements, and their energy is dependent on temperature. 1905: Special Relativity E=mc2. 1920: Aston measures mass deficit. Eddington realizes! Arthur Eddington UK

5 Aston’s mass deficit Mass of 4 H nucleii = 6.6905 x 10-27 gr
Mass of 1 He nucleus = x gr Mass difference Dm = x gr DE = (Dm) c2 = 4.1 x J Is this a lot of energy? NOTE: 4.1 x J = 4.1 x J / 1.60 x J/eV = 26 MeV

6 There are a lot of H atoms in the Sun….
NH = MSun/mp = 1.2 x 1057 Number of reactions are NH/4 Each yields DE = 4.1 x J. Total energy E: NH/4 DE = 1.2 x 1045 J Lifetime of the sun = E/L = 100 Gyr Why is this age about 10 times the total lifetime of the Sun? We can now rewrite an equation for the main sequence lifetimes of stars.

7 The main sequence lifetime
Also known as the nuclear timescale

8 Stellar birth: the Virial Theorem
The Virial Theorem: the complex n-body problem has a surprisingly simply property: for a bound system, the total, time averaged, kinetic energy (K) is related to the total potential energy (U): 2K + U = 0

9 Stellar birth: consequences of the Virial theorem
For collapsing stars, equilibrium is reached when ½ of the gravitational energy is stored as thermal energy and the other ½ is radiated away. The collapse timescale of a star is therefore the time it takes to radiate the energy away, which is easily computed by U/L (L is the luminosity of a star). This is the Kelvin-Helmoltz timescale!

10 Stellar birth A molecular cloud is unstable against collapse if the time sound takes to reach the centre from the surface is longer than the free-fall time. This condition defines the Jeans length, the maximum radius that a cloud can have before it collapses to form a star.

11 Tunnelling! In order for protons to come close enough to react, their kinetic energies would have too be 1000 times higher than they are. Fortunately, there is a finite probability that a proton can gain that energy temporarily by quantum uncertainty. This means that there is a low but finite probability of nuclear fusion.

12 Three fusion chains for H and He “burning”
H to He: The pp chain H to He at higher T: The CNO cycle He to C and O: The triple alpha reaction. Reaction rate is a function of probability of a given reaction. Probability is a function of temperature. Equilibrium abundances depend on the reaction speed of the various reactions.

13 pp or CNO? csep10.phys.utk.edu/astr162/lect/energy/cno-pp.html

14 Equilibrium abundances
Start with the CNO cycle: 12C +1H -> 13N + g (106 years) 13N -> 13C + e+ + m (14 min) 13C +1H -> 14N + g (3x105 years) 14N +1H ->15O + g (3x 108 years) 15O -> 15N + e+ + m (82 sec) 15N + 1H -> 12C + 4He (104 years)

15 Equilibrium abundances
Although the CNO cycle does not create new C,N and O, their relative abundances are altered by the process. But what are the equilibrium abundances? For, e.g., 14N, one has to wait 3x108 years for its equilibrium value to be established: d14N/dt = 0 = 13C x reac. rate (13C + H) – 14N x reac. rate (14N + H) 14N / 13C = 3 x 108 / 3 x 105 = 1000; 12C/13C = 3.3; 14N/12C = 300 Equilibrium abundances are expected after the first dredge up.

16 On to He fusion Bottleneck: there are no stable elements of mass number 5 or 8, so He + p, or He + He, likely to happen in an H and He-rich environment, end up in products that vanish immediately. As the Tc rises 8Be, although unstable, can be formed at a rate high enough to result in a non zero abundance of this element which can the react with another 4He.

17 The end of the line: Fe Massive stars keep fusing core elements till the core is made of iron, which does not liberate energy by fusion because it has the lowest binding energy per nucleon. What happens then?

Download ppt "PHYS377: A six week marathon through the firmament"

Similar presentations

Stellar Structure Section 5: The Physics of Stellar Interiors Lecture 11 – Total pressure: final remarks Stellar energy sources Nuclear binding energy.

Stellar Structure Section 5: The Physics of Stellar Interiors Lecture 11 – Total pressure: final remarks Stellar energy sources Nuclear binding energy.
PH507 The Hydrostatic Equilibrium Equations for Stars

PH507 The Hydrostatic Equilibrium Equations for Stars
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?
Chapter 17 Star Stuff.

Chapter 17 Star Stuff.
Stellar Evolution Chapters 12 and 13. Topics Humble beginnings –cloud –core –pre-main-sequence star Fusion –main sequence star –brown dwarf Life on the.

Stellar Evolution Chapters 12 and 13. Topics Humble beginnings –cloud –core –pre-main-sequence star Fusion –main sequence star –brown dwarf Life on the.
Susan CartwrightOur Evolving Universe1 The Lives of Stars n From studying nearby stars and stellar clusters l most stars are on the main sequence l stars.

Susan CartwrightOur Evolving Universe1 The Lives of Stars n From studying nearby stars and stellar clusters l most stars are on the main sequence l stars.
Cosmology The Life-Histories of Stars. Nuclear Fusion  Stars produce light and heat because of the processes of nuclear fusion which take place within.

Cosmology The Life-Histories of Stars. Nuclear Fusion  Stars produce light and heat because of the processes of nuclear fusion which take place within.
1. accretion disk - flat disk of matter spiraling down onto the surface of a star. Often from a companion star.

1. accretion disk - flat disk of matter spiraling down onto the surface of a star. Often from a companion star.
Life and Evolution of a Massive Star M ~ 25 M Sun.

Life and Evolution of a Massive Star M ~ 25 M Sun.
The origin of the (lighter) elements The Late Stages of Stellar Evolution Supernova of 1604 (Kepler’s)

The origin of the (lighter) elements The Late Stages of Stellar Evolution Supernova of 1604 (Kepler’s)
The birth of a star Chapter 11 1.Where are the birth places of stars? 2.What are the main components of a protostar? 3.When and how a new is born? 4.What.

The birth of a star Chapter 11 1.Where are the birth places of stars? 2.What are the main components of a protostar? 3.When and how a new is born? 4.What.
Stellar Interiors Physical Astronomy Professor Lee Carkner Lecture 10.

Stellar Interiors Physical Astronomy Professor Lee Carkner Lecture 10.
Announcements Angel Grades are updated (but still some assignments not graded) More than half the class has a 3.0 or better Reading for next class: Chapter.

Announcements Angel Grades are updated (but still some assignments not graded) More than half the class has a 3.0 or better Reading for next class: Chapter.
Stellar Interiors Astronomy 315 Professor Lee Carkner Lecture 10.

Stellar Interiors Astronomy 315 Professor Lee Carkner Lecture 10.
Guest Lecturer: Dr W J Chaplin

Guest Lecturer: Dr W J Chaplin
Reminder n Please return Assignment 1 to the School Office by 13:00 Weds. 11 th February (tomorrow!) –The assignment questions will be reviewed in next.

Reminder n Please return Assignment 1 to the School Office by 13:00 Weds. 11 th February (tomorrow!) –The assignment questions will be reviewed in next.
Lecture 10 Energy production. Summary We have now established three important equations: Hydrostatic equilibrium: Mass conservation: Equation of state:

Lecture 10 Energy production. Summary We have now established three important equations: Hydrostatic equilibrium: Mass conservation: Equation of state:
Life Track After Main Sequence

Life Track After Main Sequence
Goal: To understand the lifetime of a star and how the mass of a star determines its lifetime Objectives: 1)To learn what defines a Main sequence star.

Goal: To understand the lifetime of a star and how the mass of a star determines its lifetime Objectives: 1)To learn what defines a Main sequence star.

Similar presentations

Ads by Google