Presentation is loading. Please wait.

Presentation is loading. Please wait.

From Molecular Cores to Stars Examining Herbig-Haro 46/47 © 2005 The University of Texas at Austin For classroom instruction Production supported by a.

Published byScot Morrison Modified over 8 years ago

Similar presentations

Presentation on theme: "From Molecular Cores to Stars Examining Herbig-Haro 46/47 © 2005 The University of Texas at Austin For classroom instruction Production supported by a."— Presentation transcript:

1 From Molecular Cores to Stars Examining Herbig-Haro 46/47 © 2005 The University of Texas at Austin For classroom instruction Production supported by a NASA Education/Public Outreach grant

2 Color Calibration White Red Green Blue Yellow Magenta Cyan Make sure that your video projector accurately reproduces these colors, especially yellow (Y) and green (G). YG

3 1. What part of the electromagnetic spectrum are you seeing in each image? The tiny dots of light are stars. Most of the stars are far behind this nebula in the foreground that is made of gas and dust. i. Which image shows the infrared light? ii. Which image shows the visible light? iii. What evidence in the images supports your decision? ABCDEFGHI 1 2 3 4 5 ABCDEFGHI 1 2 3 4 5

4 Primary Colors RedGreenBlue

5 Primary Colors RedGreenBlue

6 Primary Colors RedGreenBlue

7 Primary Colors RedGreenBlue

8 =++ =+ =+ =+

9 Secondary Colors MagentaYellowCyan

10 Secondary Colors MagentaYellowCyan

11 Secondary Colors MagentaYellowCyan

12 Secondary Colors MagentaYellowCyan

13 =++ =+ =+ =+

14 The infrared image “colors” correspond to infrared wavelengths of light, not visible colors. Visible colors range in wavelength from 0.4 to 0.7 micrometers. The light wavelengths in the infrared image range from 3.6 to 8.0 micrometers. To make sense of the infrared image, astronomers assign visible colors to infrared wavelengths to produce a “false color” image, like the one you are examining: 3.6 micrometers = blue (shortest wavelength), 4.6 and 5.8 micrometers combined = green, and 8.0 micrometers = red (longest wavelength). What do the colors in the infrared image mean? ABCDEFGHI 1 2 3 4 5 ABCDEFGHI 1 2 3 4 5 HH 46/47 infraredHH 46/47 visible 0.40.83.64.65.88.0 VisualIR wavelength in micrometers False colors 8 µm4.5 µm + 5.8 µm3.6 µm

15 i. Which false colors in the infrared image represent the hottest material? The coolest? ii. Why do you think the other stars in the infrared image are false blue and white? iii. If a feature appears white in the infrared image, what does that indicate about the energy distribution in infrared wavelengths? 2. Examine the infrared image of HH 46/47 ABCDEFGHI 1 2 3 4 5 ABCDEFGHI 1 2 3 4 5 HH 46/47 infraredHH 46/47 visible 0.40.83.64.65.88.0 VisualIR wavelength in micrometers False colors 8 µm4.5 µm + 5.8 µm3.6 µm

16 ABCDEFGHI 1 2 3 4 5 ABCDEFGHI 1 2 3 4 5 i. What is the dark blob (centered at E4) in the visible light image? Explain. ii. What are the points of light surrounding the dark blob in the visible light image? Explain. 3. Examine the visible light image of HH 46/47 HH 46/47 infrared 1.25 ly HH 46/47 visible 0.40.83.64.65.88.0 VisualIR wavelength in micrometers False colors 8 µm4.5 µm + 5.8 µm3.6 µm

17 List the prominent features in each image, and how you think they are related. 4. Compare and contrast the two images IR image featureVisible image featureRelationship ABCDEFGHI 1 2 3 4 5 ABCDEFGHI 1 2 3 4 5 HH 46/47 infrared 1.25 ly HH 46/47 visible 0.40.83.64.65.88.0 VisualIR wavelength in micrometers False colors 8 µm4.5 µm + 5.8 µm3.6 µm

18 The tube shaped “smoke ring” in the infrared image (E2, E3, F3, G4) is an outflow of gas and dust from the forming star. The gas is expanding rapidly, with maximum speeds approaching 100 kilometers per second. Include supporting evidence in your explanations. Why do you think the gas and dust are emitting infrared light? 5. Evidence of motion ABCDEFGHI 1 2 3 4 5 ABCDEFGHI 1 2 3 4 5 HH 46/47 infrared 1.25 ly HH 46/47 visible 8 µm4.5 µm + 5.8 µm3.6 µm 0.40.83.64.65.88.0 VisualIR wavelength in micrometers False colors

19 http://www.hq.nasa.gov/office/pao/History/EP-177/ch2-4.html Displayed in a close-up under an electron microscope, this tiny bit of cosmic dust may be our first sample of a passing comet. Less than one- tenth of a millimeter across, the particle is composed of millions of even tinier crystals. Although chemically similar to some meteorites, its fluffy, crystalline structure is unlike that of any known meteorite. Electron Microscope Image of Space Dust 0.1 mm

20 STScI-2001-13 Image by Akira Fujii The constellation of Orion Betelgeuse Rigel Orion Nebula Orion’s Belt What is inside the Orion Nebula ? http://hubblesite.org/newscenter/newsdesk/archive/releases/2001/13/video/b Animation Credit: Zolt Levay (STScI) and Bryan Preston (STScI and Max-Q Digital)STScI Animation Credit: NASA and Walt Feimer (STScI)NASASTScI http://hubblesite.org/newscenter/newsdesk/archive/releases/1994/24/video/a

21 6. What happens after star formation? These is a visible wavelength images of an object in the Orion Nebula taken with the Hubble Space Telescope. i. What is the bright spot in the center of image A? ii. What about the dark oval in image A and the dark disk in image B? iii. Where do you think the planets would form? Image Credit: Mark McCaughrean (Max-Planck-Institute for Astronomy), C. Robert O'Dell (Rice University), and NASA A B C Side view of A http://hubblesite.org/newscenter/newsdesk/archive/releases/1994/24/image/c

22 ABCDEFGHI 1 2 3 4 5 ABCDEFGHI 1 2 3 4 5 Wink slides: Switch, or wink, between the two following slides to compare and contrast the images.

23 ABCDEFGHI 1 2 3 4 5 8 µm4.5 µm + 5.8 µm3.6 µm

24 ABCDEFGHI 1 2 3 4 5

25 Big Bang H and He Clouds Clump & Collapse Sub-stellar Proto Star Proto Planetary Disc Planets Supernova Planetary nebula Star Dust & Gas White Dwarf Neutron Star Black Hole Dust to Dust Cycle

26 Big Bang H and HeCloudsClump & Collapse Sub-stellar Objects Proto Star Proto Planetary Disc Planets Supernova “Planetary” Nebula Star Inter-stellar Medium White Dwarf Black Hole Neutron Star Spitzer Space Telescope Cores to Discs Legacy Team Li, Be C, N, O,…

Download ppt "From Molecular Cores to Stars Examining Herbig-Haro 46/47 © 2005 The University of Texas at Austin For classroom instruction Production supported by a."

Similar presentations

LESSON 13: Origins of the Universe

LESSON 13: Origins of the Universe
Big Questions If astronomers measure an object’s apparent brightness (flux), what do they need to know to figure out how far away that object is? Why are.

Big Questions If astronomers measure an object’s apparent brightness (flux), what do they need to know to figure out how far away that object is? Why are.
Stars The life and death of stars in our universe.

Stars The life and death of stars in our universe.
Chapter 19: Between the Stars: Gas and Dust in Space.

Chapter 19: Between the Stars: Gas and Dust in Space.
Electromagnetic Spectrum. Properties of EM Waves EM Waves have frequency, amplitude, wavelength and speed Almost all EM Waves are invisible with the exception.

Electromagnetic Spectrum. Properties of EM Waves EM Waves have frequency, amplitude, wavelength and speed Almost all EM Waves are invisible with the exception.
The Life Cycle of Stars. If you were preparing a timeline of your life, what would you include?

The Life Cycle of Stars. If you were preparing a timeline of your life, what would you include?
14.2 Galactic Recycling Our Goals for Learning How does our galaxy recycle gas into stars? Where do stars tend to form in our galaxy?

14.2 Galactic Recycling Our Goals for Learning How does our galaxy recycle gas into stars? Where do stars tend to form in our galaxy?
Chapter 29 Review Stars.

Chapter 29 Review Stars.
Microwave: The Cosmic Microwave Background (CMB). Shortly after the Big Bang, the Universe cooled enough to allow atoms to form. After this point in time,

Microwave: The Cosmic Microwave Background (CMB). Shortly after the Big Bang, the Universe cooled enough to allow atoms to form. After this point in time,
Types of Stars Life Cycle of Stars Galaxies

Types of Stars Life Cycle of Stars Galaxies
The Hubble Space Telescope Carrie Murray NASA Top Stars, 2010.

The Hubble Space Telescope Carrie Murray NASA Top Stars, 2010.
The Universe PHYSICAL SCIENCE Our Place in the Universe Scale of the Universe.

The Universe PHYSICAL SCIENCE Our Place in the Universe Scale of the Universe.
Stars, Galaxies, and the Universe

Stars, Galaxies, and the Universe
Electromagnetic Spectrum. Different forms of radiation arranged in order according to their wavelength. – Travels through space at 300,000 km/s or 186,000.

Electromagnetic Spectrum. Different forms of radiation arranged in order according to their wavelength. – Travels through space at 300,000 km/s or 186,000.
The Big Bang, Galaxies, & Stars

The Big Bang, Galaxies, & Stars
Astronomy Unit Review. Topics Solar system(planets, asteroid belt, meteor, meteoroid, meteorite, comet etc) Measurement (AU and Light Years) Sun (structure;

Astronomy Unit Review. Topics Solar system(planets, asteroid belt, meteor, meteoroid, meteorite, comet etc) Measurement (AU and Light Years) Sun (structure;
TOPIC: Astronomy AIM: What are stars?

TOPIC: Astronomy AIM: What are stars?
STARS BALL OF GASES, MOSTLY HYDROGEN AND HELIUM Are all stars the same color? NO! Color- determined by surface temperature.

STARS BALL OF GASES, MOSTLY HYDROGEN AND HELIUM Are all stars the same color? NO! Color- determined by surface temperature.
Key Ideas How are stars formed?

Key Ideas How are stars formed?
Astronomy and the Electromagnetic Spectrum

Astronomy and the Electromagnetic Spectrum

Similar presentations

Ads by Google