The energy required to remove an electron from a surface of a solid element is called its work function. If a minimum of 410.1 kJ/mol is required to remove electrons from Bi atoms on a surface of a sample of bismuth, what is the maximum wavelength (λmax) of light that can remove an electron from a Bi atom on this surface? If the same bismuth surface is irradiated with light of λ=239.7 nm, what is the maximum kinetic energy that a released electron could have?
The energy required to remove an electron from a surface of a solid element is called its work function. If a minimum of 410.1 kJ/mol is required to remove electrons from Bi atoms on a surface of a sample of bismuth, what is the maximum wavelength (λmax) of light that can remove an electron from a Bi atom on this surface? If the same bismuth surface is irradiated with light of λ=239.7 nm, what is the maximum kinetic energy that a released electron could have?
Chemistry & Chemical Reactivity
9th Edition
ISBN:9781133949640
Author:John C. Kotz, Paul M. Treichel, John Townsend, David Treichel
Publisher:John C. Kotz, Paul M. Treichel, John Townsend, David Treichel
Chapter6: The Structure Of Atoms
Section: Chapter Questions
Problem 11PS: An energy of 3.3 1019 J/atom is required to cause a cesium atom on a metal surface to lose an...
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The energy required to remove an electron from a surface of a solid element is called its work function.
If a minimum of 410.1 kJ/mol is required to remove electrons from Bi atoms on a surface of a sample of bismuth, what is the maximum wavelength (λmax) of light that can remove an electron from a Bi atom on this surface?
If the same bismuth surface is irradiated with light of λ=239.7 nm, what is the maximum kinetic energy that a released electron could have?
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