Astronomy Day Three Radiation, E-M Spectrum, Black Body Radiation, Doppler Effect.

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Presentation transcript:

Astronomy Day Three Radiation, E-M Spectrum, Black Body Radiation, Doppler Effect

Types of Ionizing Radiation Alpha particles  einstein Beta particles  Gamma rays  neutron proton e- electron

PENETRATING ABILITY + +  -  

Paper ALPHA BETA GAMA WOOD CONCRETE SHIELDING

Light, a summary 1.Light travels at a speed of 300,000,000 meters per second a.Any light traveling that is detected will be traveling at 3 x 10 8 meters per second

Light, a summary 1.Light travels at a speed of 300,000,000 meters per second a.Any light traveling that is detected will be traveling at 3 x 10 8 meters per second. b.This was calculated long before it was found experimentally.

Light, a summary 1.Light travels at a speed of 300,000,000 meters per second a.Any light traveling that is detected will be traveling at 3 x 10 8 meters per second. b.This was calculated long before it was found experimentally. 2.Light is a "ray", "wave", "radiation", "particle" and probably more than anything else, it is a disturbance in the fabric of space itself.

Light, a summary 1.Light travels at a speed of 300,000,000 meters per second a.Any light traveling that is detected will be traveling at 3 x 10 8 meters per second. b.This was calculated long before it was found experimentally. 2.Light is a "ray", "wave", "radiation", "particle" and probably more than anything else, it is a disturbance in the fabric of space itself. a.A light wave has a wavelength, which is how long the wave is. b.A light wave has a frequency, which is how many waves pass a certain point each second (Hz) c.A light wave has a speed, which is always 3 x 10 8 meters per second. d.The wavelength x frequency = velocity.

More energy will produce shorter wavelengths of light.

A "ray" of light is passing by. It has a 6.9 x Hz. What can we know about this light?

Speed? Wavelength? Location on E-M spectrum?

A "ray" of light is passing by. It has a 6.9 x Hz. What can we know about this light? Speed?3 x 10 8 meters per second. Always. Wavelength? 3 x 10 8 = 6.9 x wavelength, So the wavelength = 3 x 10 8 ÷ 6.9 x 10 14, or 4.34 x meters Location on E-M spectrum? Visible. Blue.

KLIN radio (1,400 on your dial) has a frequency of 1,400,000 Hz. What is the wavelength of its signal?

The blackbody radiation curve will show the temperature of an object, based on where the peak of the curve is.

Our Sun has a temperature of about 6,000 K, why is that significant, based upon the location of the visible light area of the spectrum?

The Doppler effect is when the wavelength of an energy source is apparently changing, based upon the changing location of source or the observer.

The Doppler effect is when the wavelength or speed of an energy source is apparently changing, based upon the changing location of source or the observer. 45 mph Sound of engine will seem lower Sound of engine will seem higher

Show Doppler effect animation here

Airplane is flying at 400 m/s, and bullet shoots ahead at 400 m/s. What is the speed and direction of the bullet?

Straight ahead at 800 meters per second.

Both airplanes are flying at 400 m/s, and the lead airplane shoots straight back, with a bullet that has a speed of 400 m/s. What is the speed and direction of the bullet?

It will have a ground velocity of zero. It will fall straight down.

Both airplanes are flying at 400 m/s. Will the sound of plane "a" be higher, lower, or the same as plane "b", to the pilot of plane "b"? ab

Both airplanes are flying at 400 m/s. Will the sound of plane "a" be higher, lower, or the same as plane "b", to the person on the ground? ab

"a" will be higher, "b" will be lower. ab

a b Spaceship "b" shoots a "photon torpedo" at "a". What will be the speed of the "photon torpedo" when it reaches "a"? Speed is 1/4 cSpeed is 0 c

a b Spaceship "b" shoots a "photon torpedo" at "a". What will be the speed of the "photon torpedo" when it reaches "a"? Speed is 1/4 cSpeed is 0 c It MUST be 300,000,000 meters per second. ALWAYS

a b Speed is 1/4 c Both spacecraft are moving at great velocity from left to right. 1.Which will appear "blueshifted" to Albert? 2.Which will appear "redshifted" to Albert? 3.What color do they appear to each other?

a b Speed is 1/4 c Both spacecraft are moving at great velocity from left to right. 1.Which will appear "blueshifted" to Albert? "a" 2.Which will appear "redshifted" to Albert? "b" 3.What color do they appear to each other? Still green.

Self-Test: True or False, on page , just the evens Self-Test: Fill in the blank, on page , just the odds AND THEN DO ONE OF THE FOLOWING Problems on page 81 Problems 1 and 2 OR Collaborative Exercise Exercise one on page 82

Page 80 True and False (evens) 2.False, sound is not electromagnetic 4.False, interference is when crests and troughs collide 6.True. They all travel a 300,000 kilometers per second 8.False. Gamma radiation has the shortest wavelength of all 10.True. The exact amount of radiation that goes in will also come out 12.True. The higher the temperature, the higher the frequency 14.True. Doppler works for everything that is a wave.

Page 80 Fill in Blank (Odds) 1.300,000 kilometers per second, or 300,000,000 meters per second 3.Frequency 5Electrical and Magnetic nm would be red 9.Heat Kelvin (not degrees) 13.The object that is 1,200 K will emit twice as much energy as an object that is 1,000 K 15.Blue

1. Wavelength is 5.77 meters Frequency is 256 cycles per second Speed is 5.77 x 256 = 1,480 meters per second 2. Frequency is 100 MHz, or 1 x 10 8 / second Velocity is 3 x 10 8 meters/second Wavelength is ( 3 x 10 8 meters/second)÷(1 x 10 8 / second) = 3 meters