Chem Saver Pg 18 Electrons absorb energy and jump to excited state Electrons release energy as a photon and fall back to ground state.

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Chem Saver Pg 18 Electrons absorb energy and jump to excited state Electrons release energy as a photon and fall back to ground state

Chem Saver p 18

Investigation 1.Study the spectrum of the hydrogen atom. Draw lines in the correct part of the spectrum shown below. You will see dozens of lines, but concentrate on the three brightest lines. R O Y G B i V

H (1e-)

Hydrogen Spectrum 1.What is it that causes purple light to be a different color than red light? 2.What is the relationship between the number of energy levels that an electron falls and the energy of the photon that is emitted when it falls? 3.Why is it that no two elements have the exact same emission spectrum? Click Here for Demonstration Click Here for Demonstration

2. The greater the change in energy for an electron, the higher the frequency of the light seen. Red light has the lowest frequency, violet light has the highest frequency, and the other colors have frequencies in between. Match the changes in energy levels shown below with the colored line it represents in the spectrum. BA C Red Line _____ Blue-green Line ____ Violet Line ______ A B C

3. The red line represents a wavelength of 656 nm, the blue-green line represents a wavelength of 486 nm, and the violet line represents a wavelength of 434 nm. Using the information that 1 m = 1 x 10 9 nm, convert each of these wavelengths from nanometers to meters. Red light = m Blue-green light = m Violet light = m 6.56 x x x 10 -7

4. Calculate the frequency of each color of light using this equation: f = c/, Frequency = speed of light = 3 x 10 8 m/s wavelength wavelength Frequency of red light ___________ Hz Frequency of blue-green light _______Hz Frequency of violet light ___________ Hz 4.57 x x x frequency Speed of light wavelength

E = hf 5. Calculate the energy of each color of light using the equation, E = hf Energy = 6.63x * f Energy of red light ___________ J Energy of blue-green light _________J Energy of violet light ___________ J 3.03 x x x Energy frequency Planck’s constant

a.Which orbit has the greatest energy? b.Which orbit has the least energy? 6.

When an electron jumps from E 2 to E 1, the amount of energy in the light would be E 2 - E 1 or (–3.4) - (–13.6) = 10.2 units of energy. 7. Calculate the amount of energy in the light when an electron jumps from the following energy levels. a) E 3 to E 1 c) E 4 to E 2 b) E 3 to E 2 d) E 5 to E 2

8. Every possible jump corresponds to light of a different energy. How many different energies of light can be emitted from hydrogen when the electron jumps down to E 1 from E 2, E 3, E 4, E 5, and E 6 ?

Is the relationship between wavelength and frequency a direct or an inverse relationship? Is the relationship between wavelength and frequency a direct or an inverse relationship?Inverse Is the relationship between energy and frequency a direct or an inverse relationship? Is the relationship between energy and frequency a direct or an inverse relationship?Direct