The Quantum Model.notebook

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The Quantum Model

Unit D: Lesson 5

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Summary of the Bohr ModelAbsorption (nf > ni). • electron "jumps" to a higher energy level, it must

absorb energy. • dark lines correspond to specific photon

wavelengths needed for an electron to jump from lower to higher energy levels

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• Emission (nf < ni).

• electron "falls" to a lower orbit, energy is emitted.

• Emission lines correspond to specific photon wavelengths emitted when an electron jumps from higher to lower energy levels.

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• Eg) In an atom, an electron goes from the first orbital E = -24.0 eV to the 5th orbital. A photon with wavelength of 5.40 x 10-8m is absorbed. What is the energy of the 5th orbital for this atom?

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Quantum Model of the Atom• Recall de Broglie - particles have wave

properties because they have momentum

Particle: p = mv Photon:

∴ de Broglie’s wavelength is

• de Broglie predicted that electrons travel in a wave-like pattern

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• de Broglie model suggests that the electrons travel in a standing wave pattern

• orbitals exist only where the standing wave produces constructive interference (the circumference of the wave must be a whole multiple of one wavelength)

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• If the wave doesn’t fit, it will add destructively to itself and collapse. If the wave fits the radius, the electron is very stable. It exists as a circular standing wave

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circumference of the orbit = whole number of wavelengths

• NOTE: the number of standing wavelengths corresponds to the orbit number

• n =1 means 1 wavelength

• n = 2 means 2 wavelengths and so on

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• the standing wave is how electrons can occupy an orbit without giving off energy

• the atom only has specific energy levels indicating that the energies of the electrons are quantized

 

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Contemporary Model• the electron stops being a particle orbiting the

nucleus at a certain point

• Instead, an electron’s mass and charge can be thought of as “spread out” as a standing wave around the nucleus.

• The electron is not really at any one position as a particle, it's everywhere as a wave.

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Electron Cloud Model• The electrons have become a “cloud” of electrons.

• This is essentially the model used today.

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Example:• Determine the de Broglie wavelength for the

electron in the 2nd Bohr orbit for hydrogen where the energy level is 3.40 eV.

Solution:

1. Convert energy into joules

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Solution:2. Recognize that de Broglie’s wavelength requires velocity so calculate velocity from energy using

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Solution:3. Solve for wavelength

Remember this formula is not on the formula sheet.

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Eg. 2 Find the λ of an electron that was accelerated by a potential difference of 500V.

1. Determine energy.

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2. Determine velocity.

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3. Determine wavelength

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Warning:

• Do not find energy using Ek=1/2mv2 and then use E = hc/λ to find wavelength – it implies the mass ‘stops’ and changes its energy into EMR.

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Assignment: • Workbook p. 300 #1b,2-7, 8a