Answer:-
This question is solved by using simple concept of photoelectric effect which involves the kinetic energy and work function of the metal.
The answer is given in the image,
This question has multiple parts. Work all the parts to get the most points. The energy...
3 attempts left Check my work Be sure to answer all parts. Calculate the wavelength (in nm) of light with energy 1.61 x 10-20 J per photon. For light of wavelength 450 nm, calculate the number of photons per joule. x 10 photons/J Enter your answer in scientific notation. Determine the binding energy (in eV) of a metal if the kinetic energy possessed by an ejected electron (using one of the photons with wavelength 450 nm) is 2.93 x 10""'J....
Which of the following statements is correct for photoelectric effect? (A) In order to eject electrons from a metal surface, the wavelength of photon must be shorter than the threshold wavelength. (B) In order to eject electrons from a metal surface, the frequency of photon must be lower than the cut-off frequency. (C) The work function increases with increasing the frequency of photons. (D) The work function increases with increasing the wavelength of photons. (E) The kinetic energy of ejected...
hf = + (1/2) mv2 and hf = + eVs work fucntion e = 1.60 x 10-19 C, h = 6.63 x 10-34 J s, m- mass of electron = 9.11 x 10-31 kg 1. The work function for lithium is 4.6 x 10-19 J. (a) Calculate the lowest frequency of light that will cause photoelectric emission. (b) What is the maximum energy of the electrons emitted when a light of 7.3 x 1014 Hz is...
A metal surface has a minimum binding energy of 2.34x10-19 J/electron. An incident light of 345 nm wavelength was directed onto the metal. Answer the following questions: a. What is the frequency of the incident light? b. How much energy per photon is projected onto the metal surface? c. How much energy per mole is projected onto the metal surface? d. What is the kinetic energy given to one electron that is released from the metal from the photoelectric effect?...
The binding energy of titanium is 4.20 x 10 -18 J per electron and you shine light that has a frequency of 7.85 x 10 15 Hz. If 125 photons are absorbed by the Ti metal, then _____________ electrons should be ejected and each should have a Kinetic Energy of ________________. (SHOW WORKING)
In the photoelectric effect experiment, a beam of light is shining on a metal surface and the electrons are emitted from the metal. One of the three key findings is that a minimum frequency of light is required for emission of electrons. This minimum frequency is found to be 5.5 × 1014 s-1 for an unknown metal. 4 Briefly describe the other two findings and draw a plot fo the KE of emitted electrons against light frequency. (a) (6 marks)...
Problem 5. a. What is the energy in joules and electron volts of a photon of 520-nm green light? b. What is the maximum kinetic energy of electrons ejected from calcium by 520-nm green light, given that the binding energy (or work function) of electrons for calcium metal is 2.71 eV?
Problem 5. a. What is the energy in joules and electron volts of a photon of 520-nm green light? b. What is the maximum kinetic energy of electrons ejected from calcium by 520-nm green light, given that the binding energy (or work function) of electrons for calcium metal is 2.71 eV?
Be sure to answer all parts. Calculate the wavelength (in nm) of light with energy 1.71 × 10−20 J per photon.m For light of wavelength 450 nm, calculate the number of photons per joule. photons/J Enter your answer in scientific notation. Determine the binding energy (in eV) of a metal if the kinetic energy possessed by an ejected electron (using one of the photons with wavelength 450 nm) is 2.38 × 10−19 J.
Beryllium has a work function of 5.0 eV. Calculate the minimum frequency of light that would eject electrons in the photoelectric effect experiment. If light of frequency 8*1015 Hz was used, what would be the maximum kinetic energy of the ejected electrons? ????max = hf - Wo I know how to calculate the maximum kinetic energy for this question using the formula above but what formula would be used to calculate the minimum frequency needed to eject the electrons? I...