Presentation is loading. Please wait.

Presentation is loading. Please wait.

Basic Properties of Stars - 3

Published by Modified over 9 years ago

Similar presentations

Presentation on theme: "Basic Properties of Stars - 3"— Presentation transcript:

1 Basic Properties of Stars - 3
Luminosities Fluxes Magnitudes Absolute magnitudes

2 Solid Angle The solid angle, , that an object subtends at a point is a measure of how big that object appears to an observer at that point. For instance, a small object nearby could subtend the same solid angle as a large object far away. The solid angle is proportional to the surface area, S, of a projection of that object onto a sphere centered at that point, divided by the square of the sphere's radius, R. (Symbolically,  = k S/R², where k is the proportionality constant.) A solid angle is related to the surface area of a sphere in the same way an ordinary angle is related to the circumference of a circle.If the proportionality constant is chosen to be 1, the units of solid angle will be the SI steradian (abbreviated sr). Thus the solid angle of a sphere measured at its center is 4 sr,

3 For Fun 1) What is the angular size of the Sun as seen from Earth?
Radius Sun = 7.0 x 105 km Distance to Sun = 1.5 x 108 km 2) What is the solid angle of the Sun as seen from Earth? 3) What fraction of the sky does the disk of the Sun then cover?

4 Luminosities and magnitudes of stars
da r 

5 Luminosities and magnitudes of stars
Consider some source of radiation Intensity I = energy emitted at some frequency , per unit time dt, per unit area of the source dA, per unit frequency d, per unit solid angle d in a given direction (,) (see p ) Units: w m-2 Hz-1 ster-1 d = da/r2  d = da/r2 = 4r2/r2 = 4

6 Luminosities and magnitudes of stars §3.2
Luminosity is energy passing through closed surface encompassing the source (units watts) Luminosity L = IdAdd If source (star) radiates isotropically, its radiation at distance r is evenly distributed on a spherical surface of area 4  r2 Flux is then F = L / 4  r2 (w m-2) F falls off as 1 / r2 Inverse Square Law Solar constant is w m-2 Fig 4.3. An energy flux, which, at distance r from a point source, is distributed over an area A, is spread over an area 4A at a distance 2r. Thus, the flux density decreases inversely proportional to the distance squared.

7 Brightness, the magnitude scale §4.2-3
In 120 BC, Greek astronomer, Hipparchus, ranked stars in terms of importance (ie. brightness)  “magnitude” 1st magnitude were brightest  6th magnitude faintest visible stars (later extended to 0 and -1) Without realizing it, Hipparchus based his scheme on the sensitivity of the human eye to flux - logarithmic scale, not a linear one. Perceived brightness  log (actual flux)

8 Rigel & Betelgeuse - 0th Magnitude Stars

9 Brightness and the magnitude scale
Magnitude scale later standardized so that mag. = 1 is exactly 100 x brighter than mag. = 6 Difference of 5 mag = factor 100 in brightness Difference of 1 mag = factor in brightness i.e. (2.512)5 = 100 Note: smaller mag is brighter star We can quantify this definition of magnitude scale: Ratio of two brightness (flux) measurements is related to the corresponding magnitudes by b1/b2 = 100 (m2-m1)/5 b1 and b2 are fluxes and m1 and m2 are magnitudes NB that it is b1/b2 and m2 - m1

10 Brightness and the magnitude scale
This is usually expressed in the form: m2 - m1 = 2.5 log10 (b1/b2) Note that it is m2 - m1 on the left and b1/b2 on the right ratio apparent mag. difference         brightness  (b1/b2) m2-m1 1 = 10 = 100 = 1000 = 10,000 =

11 Brightness and the magnitude scale

12 1528 Latin translation of Ptolemy’s Almagest based on Hipparchus of 120 BC

13 Brightness and the magnitude scale
This is usually expressed in the form: m2 - m1 = 2.5 log10 (b1/b2) Note that it is m2 - m1 on the left and b1/b2 on the right ratio apparent mag. difference         brightness  (b1/b2) m2-m1 1 = 10 = 100 = 1000 = 10,000 =

14 Brightness and the magnitude scale
Since brightness of a given star depends on its distance, we define: Apparent magnitude, m (this represents flux) = magnitude measured from Earth Absolute magnitude, M (this represents luminosity) = magnitude that would be measured from a standard distance of 10 parsecs (chosen arbitrarily) m - M = 2.5log10 (B/b) Where B is the flux measured at 10 pc and b is flux measured at distance d to the star

15 Brightness and the magnitude scale
Using inverse square law, B/b = (d/10 pc)2 we get m - M = 2.5 log10 (d/10)2 = 5 log10 (d/10) = 5 (log10 d - log10 10 ) The last term is just = 1 so we have m - M = 5 log10 d - 5 or m - M = 5 log10 d/10 m - M is called the distance modulus and will appear often. d is distance to the star in parsecs.

16 Simple problems (a) What is the absolute magnitude M of the Sun?
(b) How much brighter or fainter in luminosity is the star Proxima Centauri compared to the Sun? Needed data: msun = -26.7; mproxima = 11.05 Parallax of proxima = 0.77” 1 pc = 206,265 AU (c) Total magnitude of a triple star is 0.0. Two of its components have magnitudes 1.0 and 2.0. What is magnitude of the third component?

Download ppt "Basic Properties of Stars - 3"

Similar presentations

E3 – Stellar distances. Parallax Parallax angle.

E3 – Stellar distances. Parallax Parallax angle.
7B Stars … how I wonder what you are.. 7B Goals Tie together some topics from earlier in the semester to learn about stars: How do we know how far away.

7B Stars … how I wonder what you are.. 7B Goals Tie together some topics from earlier in the semester to learn about stars: How do we know how far away.
1. absolute brightness - the brightness a star would have if it were 10 parsecs from Earth.

1. absolute brightness - the brightness a star would have if it were 10 parsecs from Earth.
Stars Flux and Luminosity Brightness of stars and the magnitude scale Absolute magnitude and luminosity Distance modulus Temperature vs heat Temperature.

Stars Flux and Luminosity Brightness of stars and the magnitude scale Absolute magnitude and luminosity Distance modulus Temperature vs heat Temperature.
Astronomical distances The SI unit for length, the meter, is a very small unit to measure astronomical distances. There units usually used is astronomy:

Astronomical distances The SI unit for length, the meter, is a very small unit to measure astronomical distances. There units usually used is astronomy:
Introduction to Stars. Stellar Parallax Given p in arcseconds (”), use d=1/p to calculate the distance which will be in units “parsecs” By definition,

Introduction to Stars. Stellar Parallax Given p in arcseconds (”), use d=1/p to calculate the distance which will be in units “parsecs” By definition,
Chapter 11 Surveying the Stars. I.Parallax and distance. II.Luminosity and brightness Apparent Brightness (ignore “magnitude system” in book) Absolute.

Chapter 11 Surveying the Stars. I.Parallax and distance. II.Luminosity and brightness Apparent Brightness (ignore “magnitude system” in book) Absolute.
Properties of The Stars - Brightness. Do all stars appear the same? How are they different? Which one looks the coolest? Hottest? Are they all the same.

Properties of The Stars - Brightness. Do all stars appear the same? How are they different? Which one looks the coolest? Hottest? Are they all the same.
Measurements of Luminosity For a refresher on Stefan’s Law, upon which this tutorial is based, please consult the Tutorial on Continuous Spectra.

Measurements of Luminosity For a refresher on Stefan’s Law, upon which this tutorial is based, please consult the Tutorial on Continuous Spectra.
OPTION E - ASTROPHYSICS E3 Stellar distances Parallax method

OPTION E - ASTROPHYSICS E3 Stellar distances Parallax method
Measuring Distance and Size of Stars Physics 113 Goderya Chapter(s): 9 Learning Outcomes:

Measuring Distance and Size of Stars Physics 113 Goderya Chapter(s): 9 Learning Outcomes:
Stellar Magnitudes and Distances Ways of measuring a star’s brightness and distance. Ohio University - Lancaster Campus slide 1 of 46 Spring 2009 PSC 100.

Stellar Magnitudes and Distances Ways of measuring a star’s brightness and distance. Ohio University - Lancaster Campus slide 1 of 46 Spring 2009 PSC 100.
Chapter 3 Continuous Spectrum of Light 3

Chapter 3 Continuous Spectrum of Light 3
Chapter 14 Surveying the Stars. Luminosity and Apparent Brightness.

Chapter 14 Surveying the Stars. Luminosity and Apparent Brightness.
Slide 1 The Family of Stars Chapter 9. Slide 2 Part 1: measuring and classifying the stars What we can measure directly: – Surface temperature and color.

Slide 1 The Family of Stars Chapter 9. Slide 2 Part 1: measuring and classifying the stars What we can measure directly: – Surface temperature and color.
Lecture 3PHYS1005 – 2003/4 Lecture 3: Astronomical Magnitudes Objectives: To define what is meant by brightness To justify the inverse square law To describe.

Lecture 3PHYS1005 – 2003/4 Lecture 3: Astronomical Magnitudes Objectives: To define what is meant by brightness To justify the inverse square law To describe.
Chapter 8: The Family of Stars.

Chapter 8: The Family of Stars.
Nature of Stars. Parallax is denoted by ‘p’. Distance (d) is measured in parsec. d = 1 parsec = the distance at which a star has a parallax (p)

Nature of Stars. Parallax is denoted by ‘p’. Distance (d) is measured in parsec. d = 1 parsec = the distance at which a star has a parallax (p)
Lecture 3PHYS1005 – 2003/4 Lecture 3: Astronomical Magnitudes Objectives: To define what is meant by brightness To justify the inverse square law To describe.

Lecture 3PHYS1005 – 2003/4 Lecture 3: Astronomical Magnitudes Objectives: To define what is meant by brightness To justify the inverse square law To describe.
Chapter 2: The Sky. Common Units we will use Common Conversions.

Chapter 2: The Sky. Common Units we will use Common Conversions.

Similar presentations

Ads by Google