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Atomic Structure & Periodicity

Atomic Structure & Periodicity. Electromagnetic Radiation. wavelength and frequency are inversely related. n = c/ l Photosynthesis uses light with a frequency of 4.54 x 10 14 s -1 . What is the wavelength of this light? 4.54 x 10 14 s -1 = 3.0 x 10 8 ms -1 / l l = 6.60 x 10 -7 m.

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Atomic Structure & Periodicity

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  1. Atomic Structure & Periodicity

  2. Electromagnetic Radiation

  3. wavelength and frequency are inversely related n = c/l Photosynthesis uses light with a frequency of 4.54 x 1014 s-1. What is the wavelength of this light? 4.54 x 1014s-1 = 3.0 x 108 ms-1/l l = 6.60 x 10-7 m

  4. E = hn • Max Plank found that energy is not continuous, but occurs in discrete units called QUANTA • h is Planck’s constant = 6.626 x 10-34 J s • gives energy PER PHOTON • It takes 382 kJ of energy to remove one MOLE of electrons from gaseous Cs. What is the wavelength associated with this energy?

  5. (382000 J/mol) x (1mol/6.022 x1023) = 6.343 x 10-19 J • = 9.57 x 1014 s-1 l = 3.13 x 10-7 m

  6. Einstein assigned the word PHOTON to mean a particle of light • E = hn and E = mc2 and n = c/l • Therefore the mass of a photon can be calculated: m = h/lc

  7. If light has mass, does matter have wavelength? DeBroglie equation: l = h/mv *mass must be in kilograms *velocity is in m/s

  8. Sample Problem Compare the wavelength of an electron (mass = 9.11 x 10-31 kg) traveling at 1.0 x 107 m/s to that of a ball (mass 0.10 kg) traveling at 35 m/s.

  9. electron (6.626 x 10-34 Js)/(9.11 x 10-34 x 1.0 x107) = 7.27 x 10-11 m ball (6.626 x 10-34 Js)/(0.10 x 35) = 1.89 x 10-34 m

  10. Light Continuous Spectrumis a “rainbow” LineSpectrum/EmissionSpectrum a series of bright colored lines with discrete wavelengths

  11. Let's look at some spectra!

  12. Bohr Model E = -2.178 x 10-18 J (z2/n2)

  13. DE = -2.178 x 10-18J (z2/nf2 – z2/ni2) Calculate the energy required to excite the hydrogen electron from n = 1 to n = 3. -2.178 x 10-18 (1/9 -1/1) = 1.936 x 10-18 J

  14. Polyelectronic Atoms Electron Correlation Problem Electrons repel each other, so solving for energy becomes complicated because of the electron-electron repulsions Effective Nuclear Charge Zactual – (effect of electron repulsions) The “effectiveness” of the nucleus is decreased by electron repulsions

  15. What determines Zeff? Shielding Inner electrons repel each other and in so doing, protect outer electrons from the pull of the nucleus Penetration Effect Although 90% of the time an outer electron is far from the nucleus, there is a chance it comes close to the nucleus. This ______ the effective nuclear charge.

  16. Finding the value of Zeff • Determine the ionization energy from experiment. • E = -2.178 x 10-18 (Zeff2/nf2 – Zeff2/ni2) • solve for Zeff where nf is infinity Note: E = (1310 kJ/mol) (Z2/n2)

  17. Sample Problem Calculate the effective nuclear charge on a 1s electron of a sodium atom. (IE = 139000 kJ/mol) 139000 kJ/mol = (1310 kJ/mol) (Z2/12) Z = +10.3

  18. Now try… Calculate the effective nuclear charge for a 3s electron in a sodium atom. (IE = 495 kJ/mol) 495 kJ/mol = 1310 kJ/mol (Z2/32) = +1.84 So the n = 1 electron was held by the nucleus 5.6 times more strongly than the n = 3 electron…

  19. Quantum Mechanical Model Hj = Ej wave functions = orbitals

  20. Probability Clouds j2 = probability of finding an electron

  21. Aufbau Principle As protons are added one by one to the nucleus to build up the element, electrons are similarly added to these orbitals. Add to the lowest energy level first until it is full, then add to next energy level.

  22. Order of Filling

  23. Hund’s Rule The lowest energy configuration for an atom has the maximum number of unpaired electrons. (electrons will go into degenerate orbitals singly before doubling up) Example: Oxygen 1s 2s 2p

  24. Pauli Exclusion Principle In a given atom, no two electrons can have the same set of four quantum numbers. **a maximum of 2 electrons can occupy an orbital, but they must have opposite spins** Electrons that are in the same orbital would have the same n, l, ml values, but different ms values (opposite spins)

  25. Valence Electrons electrons in outermost (highest) energy level Core Electrons the inner electrons (all but the valence e-)

  26. Let’s Try! Orbital Diagrams

  27. Let’s Try! Electron Configurations

  28. Quantum Numbers Principle Quantum Number (n) Relates size & energy of the orbital big n = higher energy = big orbital

  29. Angular Quantum Number (l) relates the shape of the orbital 0 = s 1 = p 2 = d 3 = f complex

  30. Magnetic Quantum Number (ml) Relates the orientation of the orbital in space Spin Quantum Number (ms) either + ½ or – ½

  31. Allowed Quantum Numbers n = natural numbers l = at least one less than n ml = -l to +l ms = + ½ or - ½

  32. Which are NOT allowed? n l ml ms 0 -1 0 0 1 0 0 + ½ 2 2 -2 - ½ 3 1 0 - ½ 7 3 -1 + ½

  33. Atomic Radius • relates the size of an atom • increases down and left

  34. Periodic Trends Can be explained by the following two facts! 1) As you move down a group on the periodic table…the number of energy levels increases. 2) As you move from left to right on the periodic table…the effective nuclear charge increases.

  35. Ionization Energy • energy required to remove an electron from a gaseous atom (to n = infinity) • Increases up and to the right • First IE is removing the outermost electron • Second IE is removing the next farthest e- and so on

  36. Periodic Trends Can be explained by the following two facts! 1) As you move down a group on the periodic table…the number of energy levels increases. 2) As you move from left to right on the periodic table…the effective nuclear charge increases.

  37. Ionic Radius • cation is smaller than its parent atom • anion is larger than its parent atom • within the + ions OR within the – ions size increases left and down

  38. Electron Affinity • energy associated with adding an electron to a gaseous atom or ion • generally increases up and right

  39. Electronegativity A measure of an atom’s ability to attract electrons from a bond. Increases up and to the right. What is the most electronegative element? Noble gases do not bond, so by definition have no electronegativity.

  40. So What? 1) As we move down, the outermost electrons are getting farther from the nucleus, so although the number of protons is increasing their effect is cancelled out by the increased electron repulsion (shielding)

  41. So What? 2)As we move across there are more protons, but the number of energy levels remains constant. So the valence electrons of each element are about the same distance from the nucleus BUT the nucleus is getting “stronger.”

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