HELP ME PHYS 123 Direction: Solve the problem given. Type in your final answer on the box and submit your solution in the folder.Problem:A sodium surface is illuminated with light of wavelength 0.300 mm. The work function for sodium is 2.46 ev. Calculate the maximum kinetic energy of theejected photoelectrons.Answer: \blank nm.Answer: 1.67Direction: Solve the problem given. Type in your final answer on the box and submit your solution in the folder.Problem:X-rays of wavelength 0.200 000 nm are scattered from a block of material. The scattered x-rays are observed at an angle of 45.0° to the incident beam.Compute the fractional change in the energy of a photon in the collision.Answer: -3.54x10^-8Direction: Solve the problem given. Type in your final answer on the box and submit your solution in the folder.Problem:Singly ionized helium,Het, a hydrogen-like system, has one electron in the orbit corresponding to n = 1 when the atom is in its ground state. Find theenergy of the system in the ground state in electron volts.Answer:0.0265

Answered: Image /qna-images/answer/5111702f-3fc2-4ba3-b74a-6d4c38353e5d.jpg

Direction: Solve the problem given. Type in your final answer on the box and submit your solution in the folder. Problem: A sodium surface is illuminated with light of wavelength 0.300 mm. The work function for sodium is 2.46 ev. Calculate the maximum kinetic energy of the ejected photoelectrons. Answer: \blank nm. Answer: 1.67

Direction: Solve the problem given. Type in your final answer on the box and submit your solution in the folder. Problem: A sodium surface is illuminated with light of wavelength 0.300 mm. The work function for sodium is 2.46 ev. Calculate the maximum kinetic energy of the ejected photoelectrons. Answer: \blank nm. Answer: 1.67

University Physics Volume 3

17th Edition

ISBN:9781938168185

Author:William Moebs, Jeff Sanny

Publisher:William Moebs, Jeff Sanny

Chapter6: Photons And Matter Waves

Section: Chapter Questions

Problem 137AP: A laser with a power output of 2.00 mW at a 400-nm wavelength is used to project a beam of light...

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A 400-nm laser beam is projected onto a calcium electrode. The power of the laser beam is 2.00 mW and the work function of calcium is 2.31 eV. (a) How many photoelectrons per second are ejected? (b) What net power is carried away by photoelectrons?
Estimate the work function of aluminum, given that the wavelength of 304 nm is the longest wavelength that a photon may have to eject a photoelectron from aluminum photoelectrode.
Estimate the binding energy of electrons in magnesium, given that the wavelength of 337 nm is the longest wavelength that a photon may have to eject a photoelectron from magnesium photoelectrode.
Based on the same question, (Blue monochromatic light is used to shine on the Potassium metal surface in the photoelectric effect experiment) a) If the metal surface changes to Cesium, calculate the negative voltage needed to stop the electron from moving c) When the metal surface reverts to silver, Explain the galvanometer reading use: cesium = 2.14 eV silver = 4.26 eV
1. Starting from the law of conservation of total energy, show that Vstop= (KE)max/22. The energy density of electromagnetic radiation in some region of space is 3.2 × 10-8 J/m3. Assume that the radiation has a wavelength 610 nm. What is the photon density? 3.The maximum energy of photoelectrons from Al is 2.3 eV for radiation of 200 nm and 0.9 eV for radiation of 216 nm. Use these data to calculate the Planck’s constant and the work function of Al. 4. The threshold wavelength for the photoelectric effect in tungsten is 270 nm. Calculate the work function of tungsten, and calculate the maximum kinetic energy that a photoelectron can have when radiation of 120 nm falls on tungsten
A given material has a work function of 9.0 eV, answer a) If light is incident with wavelength λ= 1500 x 10-10this material is plated photoelectrons will be created b) If the wavelength of the incident light is lambda λ= 1200 * 10 -10 m what is the energy of the photoelectron more energetic cjected from the board? c) What is the cutting potential that must be applied to the device in order to cancel the emission of these photoelectrons? (alternative 1:) a) Yes, b) KMAX= 3.3 eV; c) V=4140 V (Alternative 2:) a) Yes; b) KMAX=1.36 eV: c) V=-1.36 V (alternative 3:) a) Yes; b) KMAX=3.3 eV c) V=33 V (alternative 4:) a) No b) KMAX =1.36 eV: c)V=-1.36 V (alternative 5:) a) Yes; b) KMAX=6543 eV; c) V =3.3 V
The work function for indium is 4.12 eV. (a) Convert the value of the work function from electron volts to joules. J(b) Find the cutoff frequency for indium. Hz(c) What maximum wavelength of light incident on indium releases photoelectrons from the indium's surface? nm(d) If light of energy 8.64 eV is incident on indium, what is the maximum kinetic energy of the ejected photoelectrons? Give the answer in electron volts. eV(e) For photons of energy 8.64 eV, what stopping potential would be required to arrest the current of photoelectrons? V
When ultraviolet light with a wavelength of 264 nmnm falls upon a clean metal surface, the stopping potential necessary to terminate the emission of photoelectrons is 0.178 VV . A) What is the photoelectric threshold wavelength for this metal? Express your answer in nanometers. B) What is the work function for the metal? Express your answer in electronvolts.
The work function of lithium is W0 = 2.93 eV. (a) What is the maximum wavelength of incident light for which photoelectrons will be released from lithium? m(b) What is the minimum frequency of incident light, called the cutoff frequency, for which photoelectrons will be released from lithium? Hz(c) What is the maximum kinetic energy of photoelectrons emitted by lithium if 8.30-eV photons strike its surface? eV
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The photoelectric work function of potassium is 2 eV. What potential difference would be applied between a potassium surface and the collector in order to just prevent the collection of electrons when the surface is illuminated by 350 nm?
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