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Quantum Theory: The Photoelectric Effect

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  • What is the photoelectric effect?

    The photoelectric effect is the emission of photoelectrons by certain metals when exposed to electromagnetic radiation, explained by light existing in bundles of energy called photons.
  • Why can't the photoelectric effect be explained using classical physics or wave theory of light?

    Classical physics and wave theory cannot explain the photoelectric effect because they do not account for the quantized nature of light energy required to eject electrons.
  • What does the photoelectric-effect experiment demonstrate about light?

    It shows that energy of a photon is proportional to its frequency and is related by the equation \(E = hf\).
  • How is the photon energy related to frequency?

    Photon energy E is proportional to frequency f by \(E = hf\), where h is Planck's constant.
  • Define threshold frequency (f0) and threshold wavelength (λ0).

    Threshold frequency is the minimum frequency of light needed to emit electrons; threshold wavelength is the corresponding maximum wavelength.
  • How do you calculate the energy of a photon given its wavelength?

    Energy E = \(\frac{hc}{\lambda}\), where h is Planck's constant, c is speed of light, and λ is wavelength.
  • What is the electron volt and how is photon energy calculated in electron volts?

    Electron volt (eV) is energy gained by an electron moving through 1 volt. Photon energy in eV = \(\frac{1240}{\lambda (nm)}\).
  • What is the work function (ϕ) for a metal?

    Work function is the minimum energy required to emit an electron from the metal surface.
  • How do different metals affect the work function?

    Different metals have different work functions, affecting the threshold frequency or wavelength needed to emit electrons.
  • Write the equation relating work function, threshold frequency, and threshold wavelength.

    \(\phi = hf_0 = \frac{hc}{\lambda_0}\).
  • How does the number of photoelectrons and their maximum kinetic energy depend on wavelength and intensity?

    Number of photoelectrons depends on light intensity; maximum kinetic energy depends on wavelength and frequency of the incident light.
  • Write the equation relating maximum kinetic energy of emitted electrons to photon energy and work function.

    \(KE_{max} = hf - \phi\), where KE is kinetic energy, hf is photon energy, and ϕ is work function.
  • Express maximum kinetic energy in terms of wavelength and threshold wavelength.

    \(KE_{max} = \frac{hc}{\lambda} - \frac{hc}{\lambda_0} = hc \left( \frac{1}{\lambda} - \frac{1}{\lambda_0} \right)\).
  • What is the stopping potential and how is it related to maximum kinetic energy?

    Stopping potential V_0 is the voltage needed to stop emitted electrons; \(KE_{max} = eV_0\).
  • How can you determine the threshold frequency and work function from a graph of maximum kinetic energy vs frequency?

    The x-intercept gives threshold frequency; slope gives Planck's constant; y-intercept gives negative work function.
  • What is the significance of Planck's constant in the photoelectric effect?

    Planck's constant h relates photon energy to frequency and is fundamental to quantization of light energy.
  • Describe the relationship between photon energy, work function, and emitted electron kinetic energy.

    Photon energy = work function + maximum kinetic energy of emitted electron.
  • What happens if the frequency of incident light is below the threshold frequency?

    No electrons are emitted because photon energy is insufficient to overcome the work function.
  • How does increasing light intensity affect the photoelectric effect?

    Increasing intensity increases the number of emitted photoelectrons but does not increase their maximum kinetic energy.
  • What experimental evidence supports the particle nature of light from the photoelectric effect?

    Instant emission of electrons and dependence on frequency, not intensity, supports light as photons with quantized energy.