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Bohr Model of the Atom. Outline Emission spectrum of atomic hydrogen. The Bohr model. Extension to higher atomic number. Photon Emission. Relaxation from one energy level to another by emitting a photon. With D E = hc/ l If l = 440 nm, DE = 4.5 x 10 -19 J. Emission.
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Bohr Model of the Atom Outline • Emission spectrum of atomic hydrogen. • The Bohr model. • Extension to higher atomic number.
Photon Emission • Relaxation from one energy level to another by emitting a photon. • With DE = hc/l • If l = 440 nm, DE = 4.5 x 10-19 J Emission
“Continuous” spectrum “Quantized” spectrum Emission spectrum of H DE DE Any DE is possible Only certain DE are allowed
Emission spectrum of H (cont.) Light Bulb Hydrogen Lamp Quantized, not continuous
Emission spectrum of H (cont.) We can use the emission spectrum to determine the energy levels for the hydrogen atom.
Balmer Model • Joseph Balmer (1885) first noticed that the frequency of visible lines in the H atom spectrum could be reproduced by: n = 3, 4, 5, ….. • The above equation predicts that as n increases, the frequencies become more closely spaced.
Rydberg Model • Johann Rydberg extends the Balmer model by finding more emission lines outside the visible region of the spectrum: n1 = 1, 2, 3, ….. n2 = n1+1, n1+2, … Ry = 3.29 x 1015 1/s • This suggests that the energy levels of the H atom are proportional to 1/n2
The Bohr Model • Niels Bohr uses the emission spectrum of hydrogen to develop a quantum model for H. • Central idea: electron circles the “nucleus” in only certain allowed circular orbits. • Bohr postulates that there is Coulomb attraction between e- and nucleus. However, classical physics is unable to explain why an H atom doesn’t simply collapse.
The Bohr Model (cont.) • Bohr model for the H atom is capable of reproducing the energy levels given by the empirical formulas of Balmer and Rydberg. Z = atomic number (1 for H) n = integer (1, 2, ….) • Ry x h = -2.178 x 10-18 J (!)
The Bohr Model (cont.) • Energy levels get closer together as n increases • at n = infinity, E = 0
The Bohr Model (cont.) • We can use the Bohr model to predict what DE is for any two energy levels
The Bohr Model (cont.) • Example: At what wavelength will emission from n = 4 to n = 1 for the H atom be observed? 1 4
The Bohr Model (cont.) • Example: What is the longest wavelength of light that will result in removal of the e- from H? 1
Extension to Higher Z • The Bohr model can be extended to any single electron system….must keep track of Z (atomic number). Z = atomic number n = integer (1, 2, ….) • Examples: He+ (Z = 2), Li+2 (Z = 3), etc.
Extension to Higher Z (cont.) • Example: At what wavelength will emission from n = 4 to n = 1 for the He+ atom be observed? 2 1 4
Where does this go wrong? • The Bohr model’s successes are limited: • Doesn’t work for multi-electron atoms. • The “electron racetrack” picture is incorrect. • That said, the Bohr model was a pioneering, “quantized” picture of atomic energy levels.