6. Lead (Pb) O = 4.3 eV Copper (Cu) 0 = 4.7 eV Nickel (Ni) O = 5.2 eV Three different metals are exposed to identical light beams, each with a photon flux of 100 photons/s and a photon energy of 5.0 eV (which corresponds to a wavelength of 248 nm). How does the maximum speed v of the photoelectrons from each metal compare? VPb > VCu = VNi Vpb> VCu > VNi VPb = VCu = VNi Vpb < VCu = VNi Vpb < VCu < VNi

6. Lead (Pb) O = 4.3 eV Copper (Cu) 0 = 4.7 eV Nickel (Ni) O = 5.2 eV Three different metals are exposed to identical light beams, each with a photon flux of 100 photons/s and a photon energy of 5.0 eV (which corresponds to a wavelength of 248 nm). How does the maximum speed v of the photoelectrons from each metal compare? VPb > VCu = VNi Vpb> VCu > VNi VPb = VCu = VNi Vpb < VCu = VNi Vpb < VCu < VNi

Modern Physics

3rd Edition

ISBN:9781111794378

Author:Raymond A. Serway, Clement J. Moses, Curt A. Moyer

Publisher:Raymond A. Serway, Clement J. Moses, Curt A. Moyer

Chapter3: The Quantum Theroy Of Light

Section: Chapter Questions

Problem 20P

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