Presentation is loading. Please wait.

Presentation is loading. Please wait.

(for low mass stars– like the Sun)

Published byAlbert Lorentz Modified over 6 years ago

Similar presentations

Presentation on theme: "(for low mass stars– like the Sun)"— Presentation transcript:

1 (for low mass stars– like the Sun)
Stellar Evolution (for low mass stars– like the Sun)

2 Stellar Evolution... Refers to the life cycle of stars
is based on the H-R diagram. Theoretical plots of the H-R diagram are compared to real star data and observations. (Computer simulations of the nuclear reactions inside a star match up with what we observe. )

3 I. First stage of a star’s life: Protostar
A. protostar formed by gravitational contraction (accretion) of dust/gas B. contraction causes 1. Pressure to rise 2. Temp. to rise C. Infrared and microwave radiation given off; radiation sweeps away gases and may cause interstellar gases to glow

4

5 Star-disk systems in Orion's Trapezium

6

7 II. Protostar to Main Sequence Star
D. At temps. around 10 million K, nuclear fusion (hydrogen to helium) takes place. E. diagram

8 F. hydrostatic equilibrium--a balance between pressure of gases and gravity
Hydrostatic equilibrium: the star is now stable and remains main sequence for the majority of its life…our Sun is a class G2V star

9 G. How does mass affect the time of star formation?
--larger masses contract faster and burn brighter H. How does the mass of main sequence star affect its lifetime? --larger masses die faster (run out of hydrogen faster)

10 The Main Sequence Lifetime for Stars of Different Masses

11 III. Red Giants A. Eventually, hydrogen is used up and core is primarily helium B. Gravity causes temperatures to rise to ~100 million K and a hydrogen shell around the helium core starts to burn

12 Red Giants C. energy released causes 1. Star to be brighter
2. Size to increase D. Expansion causes the overall surface temperature to decrease E. Further contraction at the core causes Heavier elements to form (carbon & oxygen)

13 Red Giants F. Examples are 1. Betelgeuse (actually a red supergiant)
2. Arcturus (appear red/orange in the sky)

14 IV. Planetary nebula stage – Red Giant star loses mass, forming a planetary nebula

15 V. White dwarf stars…these are Ancient, White Dwarf Stars in the Milky Way Galaxy
A. White dwarfs radiate their energy and will fade out over time (over few million years). Their collapse is prevented by degenerate electrons.

16 For our sun…all this takes ~10 billion years from beginning to end.

17 Many have been detected in star forming regions like the Orion Nebula.
What’s a brown dwarf? A “failed star” too small to start H fusion to He Hard to find because they are very faint and cool; emit mostly in the infrared. Many have been detected in star forming regions like the Orion Nebula.

Download ppt "(for low mass stars– like the Sun)"

Similar presentations

Notes 30.2 Stellar Evolution

Notes 30.2 Stellar Evolution
Stellar Evolution Astrophysics Lesson 12. Learning Objectives To know:-  How stars form from clouds of dust and gas.  How main sequence stars evolve.

Stellar Evolution Astrophysics Lesson 12. Learning Objectives To know:-  How stars form from clouds of dust and gas.  How main sequence stars evolve.
George Observatory The Colorful Night Sky.

George Observatory The Colorful Night Sky.
Star Formation and the Interstellar Medium

Star Formation and the Interstellar Medium
Stellar Evolution Describe how a protostar becomes a star.

Stellar Evolution Describe how a protostar becomes a star.
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.
The Evolution of Stars - stars evolve in stages over billions of years 1.Nebula -interstellar clouds of gas and dust undergo gravitational collapse and.

The Evolution of Stars - stars evolve in stages over billions of years 1.Nebula -interstellar clouds of gas and dust undergo gravitational collapse and.
NOT THOSE TYPES OF STARS! LIFE CYCLE OF STARS WHAT IS A STAR? Star = ball of plasma undergoing nuclear fusion. Stars give off large amounts of energy.

NOT THOSE TYPES OF STARS! LIFE CYCLE OF STARS WHAT IS A STAR? Star = ball of plasma undergoing nuclear fusion. Stars give off large amounts of energy.
Stars, Galaxies, and the Universe Section 2 Section 2: Stellar Evolution Preview Key Ideas Classifying Stars Star Formation The Main-Sequence Stage Leaving.

Stars, Galaxies, and the Universe Section 2 Section 2: Stellar Evolution Preview Key Ideas Classifying Stars Star Formation The Main-Sequence Stage Leaving.
STARS By Bodin Lay. Types of Stars Main Sequence Stars - The main sequence is the point in a star's evolution during which it maintains a stable nuclear.

STARS By Bodin Lay. Types of Stars Main Sequence Stars - The main sequence is the point in a star's evolution during which it maintains a stable nuclear.
Stellar Life Stages Star Birth and Death.

Stellar Life Stages Star Birth and Death.
Pg. 12.  Mass governs a star’s properties  Energy is generated by nuclear fusion  Stars that aren’t on main sequence of H-R either have fusion from.

Pg. 12.  Mass governs a star’s properties  Energy is generated by nuclear fusion  Stars that aren’t on main sequence of H-R either have fusion from.
Astronomy – Stellar Evolution What is a Star? Stars are hot bodies of glowing gas that start their life in Nebulae.(1) 2.

Astronomy – Stellar Evolution What is a Star? Stars are hot bodies of glowing gas that start their life in Nebulae.(1) 2.
The Life Cycles of Stars RVCC Planetarium - Last updated 7/23/03.

The Life Cycles of Stars RVCC Planetarium - Last updated 7/23/03.
Stellar Evolution: After the main Sequence Beyond hydrogen: The making of the elements.

Stellar Evolution: After the main Sequence Beyond hydrogen: The making of the elements.
1 Stellar Lifecycles The process by which stars are formed and use up their fuel. What exactly happens to a star as it uses up its fuel is strongly dependent.

1 Stellar Lifecycles The process by which stars are formed and use up their fuel. What exactly happens to a star as it uses up its fuel is strongly dependent.
The Lives and Deaths of Stars

The Lives and Deaths of Stars
A Note Taking Experience.

A Note Taking Experience.
Life Cycle of Stars Birth Place of Stars:

Life Cycle of Stars Birth Place of Stars:

Similar presentations

Ads by Google