Supplemental Activities. Module: Atomic Theory. Section: Electromagnetic Radiation and Matter

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Supplemental Activities Module: Atomic Theory Section: Electromagnetic Radiation and Matter

Introduction to Electromagnetic Radiation Activity 1 1. What are the two components that make up electromagnetic radiation? 2. Please match the symbol on the left to the appropriate description on the left. E a. wavelength, m λ ν h b. the speed of light in a vacuum, 3.00 x 10 8 m/s c. energy, J d. Planck s constant, 6.626 x 10 34 Js c e. frequency, Hz or s 1 3. Please write at least two valid equations that use the symbols listen in question 2 above. Activity 2 1. List the regions of electromagnetic radiation in decreasing order from highest energy to lowest energy. 2. What is the range of wavelengths for visible light? Range of frequencies?

3. A hypothetical wave has a frequency of 1.0 x 10 15 Hz. What is its hypothetical, approximate wavelength? State in which region of light this wave exists. 4. A hypothetical wave has a wavelength of 10 5 m. What is its hypothetical, approximate frequency? State in which region of light this wave exists. 5. Electrons are charged and so are attracted to the side of a static electric field. In an oscillating electric field, electrons also. 6. Electrons are charged and so are attracted to the side of a static electric field. In an oscillating electric field, electrons also. 7. How would doubling the frequency (v, pronounced nu, not vee) of a given wave affect the following values? a. λ b. c c. E d. h 8. Without calculations, rank the frequency of the following waves from highest to lowest frequency: waves with wavelengths of 300 nm, 1 m, 1 km, and 300 Å. Blackbody Radiation and Ultraviolet Catastrophe Activity 1 1. Classical mechanics made a prediction about the power/intensity emitted by black body radiators at shorter and shorter wavelengths. What was this prediction and did it match the experimental observations?

2. The scientist suggested a solution to this problem dubbed the. 3. This scientist s suggestion indicated that the emission of a particular frequency requires an oscillator to have a energy. Since physical objects have a limited number of oscillation energies, they have a limited number of emitted frequencies. The Photoelectric Effect Activity 1 Activity 3 1. Draw a picture illustrating the photoelectric effect. Describe the figure and explain how frequency and work function (Φ) relate to the kinetic energy of the emitted electron. 2. You shine 500 nm light on a metal and electrons come off. What will happen if you shine 400 nm light of the same intensity on the metal? a. fewer electrons will come off but with the same velocities b. nothing c. electrons will come off with higher velocities d. the two situations will be identical 3. Explain your answer choice in question 2 above. Devise experiments that would produce the other three outcomes that you did not choose.

Activity 4 1. Describe the relationship between frequency of incident light and the kinetic energy of ejected electrons. 2. A packet of quantized energy associated with electromagnetic radiation is called a. 3. Famous scientist proposed the idea of a photon after interpreting the results of the effect. He noted that increasing the intensity of light corresponded to electrons being ejected. However, if no electrons were being ejected in the first place, would happen even if the intensity were increased. This led him to develop the idea of of light rather than waves of light energy that interact individually with electrons. Activity 5 1. A photon with enough energy, 5.1 electron volts (ev) of energy to be precise, will eject an electron from a piece of gold. What frequency and wavelength does light with this energy have? Note: 1eV = 1.60 x 10 19 joules. 2. Recalling that photon of 5.1 electron volts (ev) of energy will eject an electron from a piece of gold, what would happen if you were to shine a light of 6.5 ev on the gold surface? How is this the same or different from using light of 3.0 ev? What if the metal was Cesium (Φ = 2.1 ev) or Platinum (Φ = 6.35 ev) instead? Wave-Particle Duality and Uncertainty

Activity 1 1. Young s double slit experiment and the observation of diffraction patterns suggest that light behaves as a. 2. The ultraviolet catastrophe outcomes and the photoelectric effect suggest that light behaves as a. 3. What does the phrase wave-particle duality mean in your own words? Activity 2 1. What did Louis de Broglie propose about matter both large and small? 2. What equation describes his idea? Please indicate what each variable means (include units). 3. Please calculate the wavelength of a neutron traveling at the speed of light (in a vacuum). Activity 3 1. Briefly explain Heisenberg s uncertainty principle in your own words. 2. What equation describes this principle? Please indicate what each variable means (include units).

3. Assume that an atom is approximately 0.4nm in diameter and that this value is the uncertainty in position for an electron in an atom. What would the uncertainty in momentum be for this electron? What would the uncertainty in velocity be for this electron?

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