Presentation is loading. Please wait.

Presentation is loading. Please wait.

NASA’s Mysteries of the Universe: Dark Matter Janet Moore NASA Educator Ambassador Janet Moore NASA Educator Ambassador.

Published byFelicity Allen Modified over 9 years ago

Similar presentations

Presentation on theme: "NASA’s Mysteries of the Universe: Dark Matter Janet Moore NASA Educator Ambassador Janet Moore NASA Educator Ambassador."— Presentation transcript:

1 NASA’s Mysteries of the Universe: Dark Matter Janet Moore NASA Educator Ambassador Janet Moore NASA Educator Ambassador

2 Merry-Go-Round

3

4 Solar System

5

6

7

8 In Summary - Solar System F Orbital speed depends on force of gravity F Force of gravity depends on mass within the radius F Therefore, orbital speed depends on mass within the radius

9 What About Galaxies? F How would you expect stars to move around in a spiral galaxy? F What would you expect the mass distribution in a spiral galaxy to be?

10 The Activity - NGC 2742 F You will be given: F Rotation Curve (velocity vs. radius) F Luminosity Curve (luminosity vs. radius) F Use the Data Chart to analyze the mass in the galaxy F G = 4.31 x 10 -6

11 Sample Data Chart RadiusRot. Vel. Grav. Mass Lum.Lum. Mass Lum/ Grav 1801.5 e93 e86 e80.4 31006.9 e91 e92 e90.29 51201.7 e102 e94 e90.24 81403.6 e103.5 e97 e90.19

12 Evidence for Dark Matter F Light (visible matter) drops off as you go farther out in a galaxy F BUT... Velocities do not drop off F Result: Dark Matter mass is about 10x Luminous Matter mass F Light (visible matter) drops off as you go farther out in a galaxy F BUT... Velocities do not drop off F Result: Dark Matter mass is about 10x Luminous Matter mass

13 What is Dark Matter? F Baryonic (Normal) Matter: F Low mass stars, brown dwarfs (likely), large planets, meteoroids, black holes, neutron stars, white dwarfs, hydrogen snowballs, clouds in halo. F Non-Baryonic (Exotic) Matter: F Hot Dark Matter: fast-moving at time of galaxy formation, eg massive neutrinos F Cold Dark Matter: slow-moving at times of galaxy formation, eg WIMPs -- particle detector experiments looking for them F Baryonic (Normal) Matter: F Low mass stars, brown dwarfs (likely), large planets, meteoroids, black holes, neutron stars, white dwarfs, hydrogen snowballs, clouds in halo. F Non-Baryonic (Exotic) Matter: F Hot Dark Matter: fast-moving at time of galaxy formation, eg massive neutrinos F Cold Dark Matter: slow-moving at times of galaxy formation, eg WIMPs -- particle detector experiments looking for them

14 NASA’s Fermi Mission

15 Common Core Mathematical Practices F Make sense of problems and persevere in solving them. F Reason abstractly and quantitatively. F Construct viable arguments and critique the reasoning of others. F Model with mathematics. F Use appropriate tools strategically. F Attend to precision. F Look for and make use of structure. F Look for and express regularity in repeated reasoning. F Make sense of problems and persevere in solving them. F Reason abstractly and quantitatively. F Construct viable arguments and critique the reasoning of others. F Model with mathematics. F Use appropriate tools strategically. F Attend to precision. F Look for and make use of structure. F Look for and express regularity in repeated reasoning.

16 Mathematical modeling F 1. Observing a phenomenon, delineating the problem situation inherent in the phenomenon, and discerning the important factors that affect the problem. F 2. Conjecturing the relationships among factors and interpreting them mathematically to obtain a model for the phenomenon. F 3. Applying appropriate mathematical analysis to the model. F 4. Obtaining results and reinterpreting them in the context of the phenomenon under study and drawing conclusions. Swetz, F., & Hartzler, J. S. (1991). Mathematical modeling in the secondary school curriculum: A resource guide of classroom exercises. (pp. 2-3). Reston, VA: National Council of Teachers of Mathematics. F 1. Observing a phenomenon, delineating the problem situation inherent in the phenomenon, and discerning the important factors that affect the problem. F 2. Conjecturing the relationships among factors and interpreting them mathematically to obtain a model for the phenomenon. F 3. Applying appropriate mathematical analysis to the model. F 4. Obtaining results and reinterpreting them in the context of the phenomenon under study and drawing conclusions. Swetz, F., & Hartzler, J. S. (1991). Mathematical modeling in the secondary school curriculum: A resource guide of classroom exercises. (pp. 2-3). Reston, VA: National Council of Teachers of Mathematics.

17 Questions? Janet Moore www.NASAJanet.com JanetMoore@gmail.com epo.sonoma.edu Janet Moore www.NASAJanet.com JanetMoore@gmail.com epo.sonoma.edu

Download ppt "NASA’s Mysteries of the Universe: Dark Matter Janet Moore NASA Educator Ambassador Janet Moore NASA Educator Ambassador."

Similar presentations

NASAs Supernova Mathematics Janet Moore NASA Educator Ambassador Janet Moore NASA Educator Ambassador 1 NCTM Chicago Regional November 29, 2012 NCTM Chicago.

NASAs Supernova Mathematics Janet Moore NASA Educator Ambassador Janet Moore NASA Educator Ambassador 1 NCTM Chicago Regional November 29, 2012 NCTM Chicago.
Common Core Mathematical Practices. People who are good in math… Make sense of problems.

Common Core Mathematical Practices. People who are good in math… Make sense of problems.
Math Extension Activity JCPS Analytical and Applied Sciences.

Math Extension Activity JCPS Analytical and Applied Sciences.
Standards for Mathematical Practice

Standards for Mathematical Practice
Week 10 Dark Matter Reading: Dark Matter: 16.1, 16.5d (4 pages)

Week 10 Dark Matter Reading: Dark Matter: 16.1, 16.5d (4 pages)
Middle School Family and Consumer Science and Middle School Technology Education Support Standards for Mathematical Practice.

Middle School Family and Consumer Science and Middle School Technology Education Support Standards for Mathematical Practice.
Dark Matter Da yang Jacob Daeffler. What do we mean by dark matter? Material whose presence can be inferred from its effects on the motions of stars and.

Dark Matter Da yang Jacob Daeffler. What do we mean by dark matter? Material whose presence can be inferred from its effects on the motions of stars and.
Chapter 16 Dark Matter And The Fate Of The Universe.

Chapter 16 Dark Matter And The Fate Of The Universe.
Mathematical Practices 1.Make sense of problems and persevere in solving them. 2.Reason abstractly and quantitatively. 3.Construct viable arguments and.

Mathematical Practices 1.Make sense of problems and persevere in solving them. 2.Reason abstractly and quantitatively. 3.Construct viable arguments and.
FALL 2011 MATHEMATICS SOL INSTITUTES Mr. Michael Bolling, Mathematics Coordinator Dr. Deborah Wickham, Elementary Mathematics Specialist.

FALL 2011 MATHEMATICS SOL INSTITUTES Mr. Michael Bolling, Mathematics Coordinator Dr. Deborah Wickham, Elementary Mathematics Specialist.
Common Core Math: the what and the why. “A generation ago, teachers could expect that what they taught would last their students a lifetime. Today, because.

Common Core Math: the what and the why. “A generation ago, teachers could expect that what they taught would last their students a lifetime. Today, because.
The Milky Way PHYS390 Astrophysics Professor Lee Carkner Lecture 19.

The Milky Way PHYS390 Astrophysics Professor Lee Carkner Lecture 19.
The Milky Way Galaxy 19 April 2005 AST 2010: Chapter 24.

The Milky Way Galaxy 19 April 2005 AST 2010: Chapter 24.
The latest experimental evidence suggests that the universe is made up of just 4% ordinary matter, 23% cold dark matter and 73% dark energy. These values.

The latest experimental evidence suggests that the universe is made up of just 4% ordinary matter, 23% cold dark matter and 73% dark energy. These values.
Class 23 : The mass of galaxies and the need for dark matter How do you measure the mass of a galaxy? What is “dark matter” and why do we need it?

Class 23 : The mass of galaxies and the need for dark matter How do you measure the mass of a galaxy? What is “dark matter” and why do we need it?
Copyright © 2010 Pearson Education, Inc. Dark Matter and Dark Energy.

Copyright © 2010 Pearson Education, Inc. Dark Matter and Dark Energy.
GALAXY FORMATION AND EVOLUTION - 2. DISCOVER Magazine’s 2007 Scientist of the Year David Charbonneau, of the Harvard-Smithsonian Canter for Astrophysics.

GALAXY FORMATION AND EVOLUTION - 2. DISCOVER Magazine’s 2007 Scientist of the Year David Charbonneau, of the Harvard-Smithsonian Canter for Astrophysics.
18 Dark Matter Join me on the Dark Side. 18 Goals The Universe is expanding. Will it expand forever? Depends on mass? How do we know the mass of the universe?

18 Dark Matter Join me on the Dark Side. 18 Goals The Universe is expanding. Will it expand forever? Depends on mass? How do we know the mass of the universe?
The Milky Way. Structure of the Milky Way The Milky Way.

The Milky Way. Structure of the Milky Way The Milky Way.
The Milky Way Galaxy.

The Milky Way Galaxy.

Similar presentations

Ads by Google