CHM 101 – Chapter Six

1. CHM 101 – Chapter Six The Wave Nature of Light Quantized Energy and Photons Line Spectra and the Bohr Atom The Wave Behavior of Matter Quantum Mechanics and Atomic Orbitals Representations of Orbitals\ Many Electron Atoms Electronic Configurations Electronic Configurations and the Periodic Table CHM 101 - Reeves

2. The Wave Nature of Light Electromagnetic radiation ranges from long wave length (low frequency) radio waves to short wave length (high frequency) gamma and cosmic rays. CHM 101 - Reeves

3. The Wave Nature of Light A local radio station broadcasts at a frequency of 91.3 MHz. What is the wave length of the electromagnetic radiation on which this signal is broadcast? What is the frequency of red light that has a wave length of 650 nm? CHM 101 - Reeves

4. Quantized Energy & Photons When an object is heated, it often glows. As the temperature rises, the color of the emitted light changes. CHM 101 - Reeves

5. Quantized Energy & Photons To explain the spectral profile of black body radiation, Max Planck postulated that light’s energy (E) is proportional to its frequency (n). CHM 101 - Reeves

6. Quantized Energy & Photons Both the earth (<T> = 289K) and the sun (<T> = 5880K) are (imperfect) black body radiators. CHM 101 - Reeves

7. Quantized Energy & Photons Einstein applied this idea to explain the photoelectric effect. When light with a frequency below a fundamental frequency (n < n0) irradiates the surface, no electrons are observed. When light of higher frequency (n > n0) irradiates the surface, electrons are observed instantly. Higher frequencies produce electrons with higher kinetic energies. CHM 101 - Reeves

8. The Wave Nature of Light What is the energy of a photon with a frequency of 8x1017 s-1? What is the energy of a mole of photons each with a wave length of 200 nm? CHM 101 - Reeves

9. The Bohr Atom When visible light is directed through a prisim, a continuous spectrum of colors (frequencies) is observed. CHM 101 - Reeves

10. The Bohr Atom When light emitted by excited atoms is directed through prisim, spectra consisting of lines at discrete wave lengths are observed. CHM 101 - Reeves

11. The Bohr Atom When light emitted by excited atoms is directed through prisim, spectra consisting of lines at discrete wave lengths are observed. CHM 101 - Reeves

12. The Bohr Atom Balmer observed that the wave lengths (l) of the lines in this spectrum could be calculated using the equation: Where n1 and n2 are integers, and n2 > n1, and RH is the Rydberg Constant (1.10x107 m-1, 2.18x10-18 J). Although this equation predicts every line observed in the hydrogen emission spectrum, scientists could not explain why the emission spectra of atoms consist of lines CHM 101 - Reeves

13. To explain these spectra, Neils Bohr proposed a model for the atom in which the eletron must occupy orbitals with radius proportional to the square of an integer n. Thus, The Bohr Atom where n is an integer > 0, and a0 is the Bohr radius, 53 pm. a0 4a0 9a0 CHM 101 - Reeves

14. The Bohr Atom The total energy of an electron bound to a hydrogen atom is Bohr argued that when light is absorbed by the hydrogen atom, an electron jumps from a lower energy state (n1) to a higher energy state (n2). The energy of the absorbed photon equals the difference in energy between the higher and lower state. Consider the 121nm photon. CHM 101 - Reeves

15. The Wave Behavior of Matter • Although Bohr's theory was very successful at predicting the line spectrum of hydrogen, it failed to predict the spectra of any of the other atoms. • Since electromagnetic radiation behaves like particles as well as waves, DeBorglie proposed that electrons (and all other forms of matter) might behave like waves. • Thus, the integers found in the Bohr theory would arise naturally if the behavior of the electron were that of a standing wave. CHM 101 - Reeves

16. The Wave Behavior of Matter For a standing wave on a string of length L: Thus, the quantization (n = integer) arises naturally from the fact that the ends are fixed. CHM 101 - Reeves

17. The Wave Behavior of Matter DeBroglie pictured the electron as a standing waved confined to an orbital of radius r. CHM 101 - Reeves

18. Quantum Mechanics & Atomic Orbitals • Using de Broglie's hypothesis, Irwin Schrodinger solved the hydrogen atom problem using classical "wave motion" equations. • The resulting wave functions were used to determine the probable locations of electrons as well as electron energies • The solutions requires the existence of 3 quantum numbers, labeled n, l and ml. Results agreed exactly with the experimental results for hydrogen, and worked for other atoms as well. • The orbitals predicted by the wave functions represent volumes within which there is a 90% probability of finding the electrons that occupying it. CHM 101 - Reeves

19. Orbitals with the same value of n, the radial quantum number, are in the same shell. The larger the n value of an orbital, the larger its radius and the higher its energy. Quantum Mechanics & Atomic Orbitals • Each shell is divided into n subshells, each corresponding to a different value of l, and containing a different number of orbitals. CHM 101 - Reeves

20. Quantum Mechanics & Atomic Orbitals How many orbitals are in the 6p subshell? Which of the following subshell designations is/are not allowed? 4s: 2d: 6f: CHM 101 - Reeves

21. Representations of Orbitals CHM 101 - Reeves

22. The Wave Behavior of Matter • The principle quantum number (n) defines the shell. • The subshell is defined by a combination of two quantum numbers, n and l. • The orbital is defined by a combination of three quantum numbers, n, l and ml. CHM 101 - Reeves

23. The Wave Behavior of Matter Indicate the subshell in which each of the following orbitals is found: 3, 1, -1: 4, 2, 0: 3, 3, -3: 6, 0, -1: CHM 101 - Reeves

24. The Wave Behavior of Matter Although orbitals are characterized by three quantum numbers, electrons that occupy the same orbital in different identical atoms display differences in magnetic properties. CHM 101 - Reeves

25. Many-electron atoms Although orbitals are characterized by three quantum numbers, electrons that occupy the same orbital in different identical atoms display differences in magnetic properties. The difference in the paths of silver atoms was caused by difference in the direction of the magnetic field associated with the electron's spin. CHM 101 - Reeves

26. Many-electron atoms Electron spin is quantized with quantum numbers ms = or Thus, the electron is characterized by four quantum numbers. The Pauli Exclusion Principle states: No two electrons in the same atom can have the same four quantum numbers. Since electrons in the same orbitals have the same values of n, l, and ml, they must have different values of ms. The Pauli Exclusion principle requires that each orbital contain no more than two electrons of opposite spin. The Aufbau principle states that electrons be placed in the atom in the order of lowest to highest energy orbitals. CHM 101 - Reeves

27. Many-electron atoms In hydrogen and other one electron systems (He+, Li2+), the energy of an orbital depends only on the value of the quantum number n. Energy CHM 101 - Reeves

28. Many-electron atoms For all atoms or ions with two or more electrons, the energy depends on n and l. Energy CHM 101 - Reeves

29. Electronic Configurations The electronic configuration of an element lists the occupied subshells followed by a superscript indicating the number of electrons it contains. B: 15P: H: C: 24Cr: He: N: Li: O: Be: F: Ne: CHM 101 - Reeves

30. Electronic Configurations For an anion, add the extra electrons to the lowest energy orbital that is not fully occupied (LUMO). 17Cl: 17Cl-: 33As: 33As3-: For a cation, remove the extra electrons from the highest energy orbital that is occupied (HOMO), except that valence s electrons are removed before the d electrons in the shell below . 20Ca: 20Ca2+: 26Fe3+: 26Fe2+: 26Fe: CHM 101 - Reeves

31. Many-electron atoms Orbital Diagrams depict electrons as arrows whose directions indicate their spin. OR OR Energy 7N: 1s2 2s2 2p3 Hund's rule: When electrons fill degenerate orbitals, the lowest energy (ground state) configuration occurs when the maximum number of electrons have parallel spins. CHM 101 - Reeves

32. Periodic Connections CHM 101 - Reeves