Useful Props Empty plastic milk jug – one gallon size. Small bag of birdseed. A peppercorn The Bucket, fabric, marble, and 8 oz (medium yellow) weight A quarter (25-cent piece) 1” marble Play-doh® spaceship (Form the Play-doh® into a spaceship, but don’t let it dry out – it will not stretch properly if it is too dry – knead with a drop or two of water and seal in its container for a few hours to re-soften.) Script for “A Galaxy Full of Black Holes” PowerPoint SLIDE SCRIPT 1 To the audience: How many of you have heard about black holes? How many have seen TV shows or movies about them? QUESTIONS TO STIMULATE DISCUSSION (this will help assess the knowledge of your audience): What can you tell me about Black Holes? How do you suppose nature makes black holes? What is a black hole? Our Milky Way Galaxy, as well as the other galaxies in the universe are full of black holes. How are black holes made? Where are they, and how do we find them? 2 Black holes were predicted as a theoretical object about a hundred years ago, long before there was any evidence that they actually existed. Nobody, not even Einstein, believed they could actually exist. Today we have abundant evidence that black holes are distributed throughout our Galaxy and other galaxies.3 According to Einstein, mass causes space to bend around it. Matter AND light moving near a massive object, like the Earth, are forced to take a curved path around that object. Scientists have accumulated much observational evidence that massive objects actually do bend space, like the bending of starlight around the Sun during an eclipse. DEMO: (USE BUCKET, STRETCH FABRIC, SMALL MARBLE, AND 8 OZ (medium) WEIGHT) Have someone roll a marble across the fabric of space with no mass in it, then with the weight in the middle. Compare the paths of the marbles. For more details see the activity “Gravity and the Fabric of Space”. The Moon orbits the Earth in a curved path. So does a spaceship orbiting the Moon. But we can speed up a spaceship and it will leave the pull of the Moon and come back to Earth. The more massive the object, the more space bends around it. And the harder it becomes to escape its gravitational pull. Until you get to the mass of black hole. Black holes in essence wrap space completely around them, trapping everything inside. A black hole will swallow anything that crosses within this distance from the black hole. (Wrap a tag end of the fabric around a 1” marble.) -- IMAGE and additional info: The image shows an object like Earth bending space. Think of space as a stretched rubber sheet. When something heavy is placed on the sheet, it causes it to dip. The heavier the object, the deeper the resulting gravitational well. In the words of John Wheeler "matter tells space how to curve". Once one accepts the curvature of space, it is rather easy to see that smaller objects will move along the straightest possible line that they can in that curved space. However, this straightest possible line has different properties than in flat space. In fact, the line itself looks curved, as shown above. Again in the words of Wheeler, the curved space tells the matter how to move. Once space itself is curved, everything moving in it is affected. Thus not only particles, but light too must feel the effects of gravity. Images and text courtesy of Professor Gabor Kunstatter, University of Winnipeg4 Here is an artist’s conception of a black hole. What is a black hole? The density of a black hole is so great it would be like taking the whole Earth and crushing into a volume smaller than a 1” marble. Black holes are called “black” because we cannot see them - no light comes out of them. No light can reflect off them. They swallow all matter and all light that comes too near - within a certain distance called the “event horizon”. If you come within that distance of a black hole, you will be pulled in. Nothing can stop you. We can escape from the surface of Earth in a spaceship if the spaceship is accelerated fast enough (about 11 km/sec). But black holes are called “holes” because nothing can escape from them - you would need a force that could accelerate your spaceship to faster than the speed light travels to escape from a black hole - and nothing we know of can exceed the speed of light (speed light travels in a vacuum: 300,000 km/sec or 186,000 miles/sec) --- Additional information: Hawking radiation: Theoretically, a very tiny amount of radiation may come from black holes. To read more about this: http://casa.colorado.edu/~ajsh/hawk.htmlhttp://superstringtheory.com/blackh/blackh3.html 5 If we could use a scale like we have on Earth to weigh things elsewhere in the Solar System or the Galaxy, this is what you would weigh. Weight is a measure of the force of gravity. The more massive the object you are standing on (or near) is, the more gravitational force you would feel and the more you’d weigh. Gravitational force is based on the mass of the object and your distance from its center. The Sun has more mass than the Moon. YOUR mass does not change, just the force of gravity. You would still look the same. Let’s pretend that you weigh 150 pounds here on Earth. Can you jump up? On the moon, would it be easier or harder to jump up? How about on the Sun? <CLICK> But how much harder would it be to jump away from a black hole? 6 Our Milky Way galaxy is over 12 billion years old and the Solar System including Earth has been here over 4-1/2 billion years. How have we existed so long if black holes are so dangerous? --- Background: Of the 200 billion stars, 22 billion are similar to our Sun. Currently only 100,000 or so are massive enough(Spectral Type O) to be candidates for future black holes.7 “Let’s discuss these questions about black holes.” Discuss these displayed questions with your audience. This will help you generally assess their level of knowledge about black holes. 8 So where do the millions of black holes come from? Scientists have discovered and classified black holes into three categories. What does “stellar” mean? Yes, star-like. These black holes have masses comparable to the mass of stars. Supermassive: millions to billions of times the mass of theSun And, the creatively named, “mid-mass”: between these two extremes. Where do we find each kind? --- Additional information: http://chandra.harvard.edu/chronicle/0403/dark/ Your