14. The photoelectric effect shows that the nature of light is: (explain it) a. wave. b....

15. Light behaves primarily like a wave when: EXPLAIN IT a. travels in a vacuum. b....

15. Light behaves primarily like a wave when: EXPLAIN IT a. travels in a vacuum. b. interacts with matter.

1)Choose the experiments below that have been used to show the wave-like nature of light: 1-Photoelectric...

1)Choose the experiments below that have been used to show the wave-like nature of light: 1-Photoelectric effect   2-Two-slit experiment with light 3-Compton effect 4-Hertz's experiments 5-Rutherford Scattering    6-Davisson-Germer experiment 7-Two slit experiment with electrons 2)Choose the experiments below that have been used to show the particle-like nature of light 1- Hertz's experiments 2-Two-slit experiment for light 3-Photoelectric effect 4-Compton effect 5-Rutherford scattering 6-Davisson-Germer experiment 7-Two-slit experiment for electrons 3)Choose the experiments below that have been used to show the particle-like...

True or false for the following: A) Light can be totally internally reflected when it tries...

True or false for the following: A) Light can be totally internally reflected when it tries to go from a less dense material (smaller n) into a more dense material (larger n). B) The frequency of the light also changes when it travels between different mediums. C) When a light wave travels from a more dense medium (like water) into vacuum (complete lack of matter), the velocity of the light decreases.

A current is detected in a photoelectric-effect experiment when the cathode is illuminated with green light....

A current is detected in a photoelectric-effect experiment when the cathode is illuminated with green light. Part A Will a current necessarily be detected if the cathode is illuminated with blue light? Select the correct answer and explanation. (1)Photons of blue light have less energy than photons of green light. Therefore, if there is a current in a photoelectric-effect apparatus with green light, then there could be no current with blue light. (2)Photons of blue light have less energy than...

Explain the photoelectric effect concept and discuss one application using this effect by detailing its way...

Explain the photoelectric effect concept and discuss one application using this effect by detailing its way of working. b) (15 points) Explain the difference between emission and absorption spectra of Hydrogen using the keywords: atoms, absorption/emission, wavelength, light intensity. Give an example where we can see such light absorption/emission by hydrogen atom.

While studying the photoelectric effect, a chemist finds that light with the frequency of 5.6 x...

While studying the photoelectric effect, a chemist finds that light with the frequency of 5.6 x 10(14) Hz is insufficient to eject electrons from a metal surface. Which of the following might the chemist reasonably try if the goal is to eject electrons? a. using light with frequency of 4.6 x 10(14) Hz b. using light with frequency of 6.6 x 10(14) Hz c. increasing the amplitude of the radiant light d. decreasing the amplitude of the radiant light What...

Consider the photoelectric effect where light shines on a surface made out of an unknown metal....

Consider the photoelectric effect where light shines on a surface made out of an unknown metal. When yellow light is shown on the cathode, a current is detected in the circuit. a) This light is removed and orange light is now shown on the cathode. Is it certain, or is it possible, that a current will be detected flowing through the circuit? b) Now the orange light is removed and violet light is now shown on the cathode. Is it...

Utilizing the photoelectric effect, a student fund that it required light with a maximum wavelength of...

Utilizing the photoelectric effect, a student fund that it required light with a maximum wavelength of 351 nm to dislodge electrons from a polished zinc metal surface. A) What is the work function of this metal in joules? B) what is the velocity, in m.s-1, of the ejected electron when incident radiation of 298 nm is used (hint: me = 9.11 x 10 -31kg ). I dont need just the answer, I got this wrong and need to know how...

5. The light of frequency 8.9 x 10^14 Hz falls on a photoelectric surface. When the...

5. The light of frequency 8.9 x 10^14 Hz falls on a photoelectric surface. When the retarding potential of 0.85 V is applied, the maximum speed with which an electron reaches the collector plate is 4.9 x 10^5 m/s. Find: a) the maximum kinetic energy( in joules) of an electron as it leaves the photoelectrode b) the work function (in eV) of the photoelectrode c) the threshold frequency (in Hz) of the photoelectrode

14. Explain and describe how waves can be categorized according to the following: (a) how it...

14. Explain and describe how waves can be categorized according to the following: (a) how it vibrates a medium (b) the type of medium it vibrates 15. (a) Make a sketch of a simple standing wave. (b) Label the nodes and antinodes. (c) State which would be caused by destructive interference. Explain your reasoning. 25. Explain the concept of polarization and what this “proves” about light. Be clear.