Quantum Physics: Determining Planck's Constant and Work Function

In summary, this conversation is discussing the photoelectric effect and how it can be used to determine Planck's constant and the work function of a metal. The formula KE(max) = eV(0) is mentioned as a way to calculate the maximum kinetic energy of the ejected photoelectrons.
  • #1
Tokimasa
17
0
In a photoelectric experiment, light is incident on a metal surfact. Photoelectrons are ejected, producing a current. A reverse potantial is applied and adjusted until the current drops to 0 (this is called the stopping potential). This fata is collected for stopping potentials (listed first) for four different frequencies (listed second): [typo volts that reads 0,] and 2E14Hz; 0.9V and 4E14Hz; 2V and 7E14Hz; 3V and 9.3E14Hz.

Determine an experimental value for Planck's constant. What is the work function of the metal?

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Can someone tell me what formulas to use?
 
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  • #2
No, we can not do that...not until you show some effort. What do you think ? Does your text not talk about the Photoelectric Effect ? Does it not give you a formula ?

https://www.physicsforums.com/showthread.php?t=28
 
  • #3
Gokul43201 said:
No, we can not do that...not until you show some effort. What do you think ? Does your text not talk about the Photoelectric Effect ? Does it not give you a formula ?

https://www.physicsforums.com/showthread.php?t=28

Well, I'm given two formulas for Photoelectric Effect wiht little about them. The only one that I have no idea what it is states: KE[max] = eV[0]. I know that eV is electron Volts, but I don't think that's what the formula is saying.
 
  • #4
Tokimasa said:
: KE[max] = eV[0]. I know that eV is electron Volts, but I don't think that's what the formula is saying.
KE(max) : maximum kinetic energy (~0.5mv^2) of ejected photoelectron
e : charge on the electron = 1.6 * 10^-19 coulombs
V(0) : applied stopping potential in volts
 

FAQ: Quantum Physics: Determining Planck's Constant and Work Function

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