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Light and Atoms Physics 113 Goderya Chapter(s): 7 Learning Outcomes:

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Presentation on theme: "Light and Atoms Physics 113 Goderya Chapter(s): 7 Learning Outcomes:"— Presentation transcript:

1 Light and Atoms Physics 113 Goderya Chapter(s): 7 Learning Outcomes:

2 The Atom Smallest part of matter Nucleus, Protons, Neutrons and Electrons The elementary particle Quark Symbol - Z X A Z = Atomic Number Number of protons A = Mass Number Electron (-) Nucleus Protons (+)NeutronsQuarks

3 Hydrogen Atom One proton in the nucleus one electron orbiting the nucleus Symbol - 1 H 1 Electron (-) Nucleus Proton (+) 1H11H1

4 Helium Atom Two proton and two neutrons in the nucleus Two electrons orbiting the nucleus Symbol - 2 He 4 2 He 4

5 The Chemical Elements Each chemical element has a specific atomic configuration. The periodic table will show this for any known chemical element.

6 The Bohr Atom Model The Energy of the electron orbits are quantized That is each orbit carries a discrete energy value The closer the orbit to the nucleus, the more negative is its energy value -E 1 -E 2 -E 3 -E 4 n1n1 n4n4 n3n3 n2n2 -E 1 < -E 2 < -E 3 < -E 4

7 The Bohr Atom Model Electrons can jump from one energy orbit to the other and absorb or emit energy The energy of each orbit is calculated by E n = -13.6 / n 2 (Z 2 ) eV n is orbit number and Z is the atomic number eV = electron Volts 1 eV = 1.602 x 10 -19 J -E l -E h n l n h

8 The Bohr Atom Model When an electron jumps from a higher orbit to a lower orbit the change in energy is ∆E = E h - E l The wavelength of emitted light is 1/  = Z 2 R (1/n l 2 - 1/n h 2 ) R is Rydberg constant = 1.097 x 10 -2 nm -1 -E l -E h n l n h Spectral line

9 The Bohr Atom Model Electrons can only jump to certain defined levels when it gains or loses energy. Because n h and n l are integers -E l -E h n l n h ∆E = E h - E l

10 The Bohr Atom Model Emission: (colored spectral lines) Transition from n h to n l level. ∆E = E h - E l Absorption: (dark spectral line) Transition from n h to n l level. -∆E = E h - E l -E l -E h n l n h Spectral line

11 F4-8 The Atomic Spectrum The emission of light from an atom can be mapped in a diagram called the spectrum 300nm 700nm500nm Orbit 6->2Orbit 5->2 Orbit 4->2Orbit 3->2 Hydrogen Helium

12 Lines of Hydrogen Most prominent lines in many astronomical objects: Balmer lines of hydrogen

13 The Balmer Lines n = 1 n = 2 n = 4 n = 5 n = 3 HH HH HH The only hydrogen lines in the visible wavelength range. Transitions from 2 nd to higher levels of hydrogen 2 nd to 3 rd level = H  (Balmer alpha line) 2 nd to 4 th level = H  (Balmer beta line) …

14 F4-9 Finger print of an Atom Every atom and molecule has its own distinct spectrum Spectra differ in number of lines and the spacing between the lines

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