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1993 AP Physics B Free-Response
... a. Determine the speed of the blue light in the glass. b. Determine the wavelength of the red light in the glass. c. Determine the frequency of the red light in the glass. d. On the figure above, sketch the approximate paths of both the red and the blue rays as they pass through the glass and back o ...
... a. Determine the speed of the blue light in the glass. b. Determine the wavelength of the red light in the glass. c. Determine the frequency of the red light in the glass. d. On the figure above, sketch the approximate paths of both the red and the blue rays as they pass through the glass and back o ...
The Structure of the Earth
... • The core is 2300km in diameter • It is made of solid iron and nickel (solid because of the pressure of all the other layers) • The core is the hottest layer at 4000C So easy to present the info in a new way (another diagram), giving students the chance to look at things from a different angle ...
... • The core is 2300km in diameter • It is made of solid iron and nickel (solid because of the pressure of all the other layers) • The core is the hottest layer at 4000C So easy to present the info in a new way (another diagram), giving students the chance to look at things from a different angle ...
1. This question is about forces on charged particles in electric and
... As the shuttle orbits the Earth with speed v, the conducting cable is moving at right angles to the Earth’s magnetic field. The magnetic field vector B makes an angle θ to a line perpendicular to the conducting cable as shown in diagram 2. The velocity vector of the shuttle is directed out of the ...
... As the shuttle orbits the Earth with speed v, the conducting cable is moving at right angles to the Earth’s magnetic field. The magnetic field vector B makes an angle θ to a line perpendicular to the conducting cable as shown in diagram 2. The velocity vector of the shuttle is directed out of the ...
Chapter 18 Test Review Chapter Summary 18.1. Static Electricity
... • Define electric charge, and describe how the two types of charge interact. • Describe three common situations that generate static electricity. • State the law of conservation of charge. 18.2. Conductors and Insulators • Define conductor and insulator, explain the difference, and give examples of ...
... • Define electric charge, and describe how the two types of charge interact. • Describe three common situations that generate static electricity. • State the law of conservation of charge. 18.2. Conductors and Insulators • Define conductor and insulator, explain the difference, and give examples of ...
Electric Potential 1. A negative charge q is fired through small hole
... 1. A negative charge q is fired through small hole in the negative plate as shown in the sketch. The oppositely charged metallic plates have charge Q and area A each. (a) Draw and label the direction of electric force and field on the charge q when it is moving in between the oppositely charged plat ...
... 1. A negative charge q is fired through small hole in the negative plate as shown in the sketch. The oppositely charged metallic plates have charge Q and area A each. (a) Draw and label the direction of electric force and field on the charge q when it is moving in between the oppositely charged plat ...
A Brief History of Planetary Science
... Hertz found that if he set up an oscillation in one circuit and then put another one nearby (with the same frequency) it would also have oscillations ...
... Hertz found that if he set up an oscillation in one circuit and then put another one nearby (with the same frequency) it would also have oscillations ...
PHY 1361 General Physics II Fall 2006 Practice Test #2
... A particle (charge = +2.0 mC) moving in a region where only electric forces act on it has a kinetic energy of 5.0 J at point A. The particle subsequently passes through point B which has an electric potential of +1.5 kV relative to point A. Determine the kinetic energy of the particle as it moves th ...
... A particle (charge = +2.0 mC) moving in a region where only electric forces act on it has a kinetic energy of 5.0 J at point A. The particle subsequently passes through point B which has an electric potential of +1.5 kV relative to point A. Determine the kinetic energy of the particle as it moves th ...
Electromagnetic Waves
... Speed of electromagnetic waves all waves travel at the same speed in a vacuum, like space, EMW travel at 300,000 km per second When EMW travel through our atmosphere, they travel more slowly but they are still the fastest waves Takes 8 minutes for sunlight to reach earth! ...
... Speed of electromagnetic waves all waves travel at the same speed in a vacuum, like space, EMW travel at 300,000 km per second When EMW travel through our atmosphere, they travel more slowly but they are still the fastest waves Takes 8 minutes for sunlight to reach earth! ...
Charged Particles
... that you used in an earlier challenge? CHALLENGE 7 (VELOCITY FILTER) One interesting use of perpendicular electric and magnetic fields is as a velocity filter. A velocity filter permits particles (in this case electrons) that are traveling a certain speed to go straight through but deflects particle ...
... that you used in an earlier challenge? CHALLENGE 7 (VELOCITY FILTER) One interesting use of perpendicular electric and magnetic fields is as a velocity filter. A velocity filter permits particles (in this case electrons) that are traveling a certain speed to go straight through but deflects particle ...