1. Zumdahl • Zumdahl • DeCoste
World of
CHEMISTRY

2. Chapter 11
Modern Atomic Theory

3. Review Trends in the periodic table:
certain elements grouped together because they behave similarly
there is great similarities within groups, but the differences
in behavior between groups is what we will be studying.
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4. Objective: To describe Rutherford’s model of the atom
11.1 Rutherford’s Atom
Objective: To describe Rutherford’s model of the atom
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5. Review of the composition of an atom
Nucleus
Proton (+)
Orbital's
Electrons (-)
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6. Figure 11.1: The Rutherford atom.
Rutherford’s model shows a very small nucleus with electrons arranged in such a way that he believed they revolved around the nucleus (i.e. like the solar system)
What Rutherford could not explain was why the negative electrons aren’t attracted into the positive protons, causing the atom to collapse.
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7. Objective: To explore the nature of electromagnetic radiation.
11.2 Energy and Light
Objective: To explore the nature of electromagnetic radiation.
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8. Electromagnetic radiation
The energy transmitted from one place to another by light.
Types of electromagnetic radiation
X-Rays
The white light from a light bulb
Microwaves used to cook
Radio waves that transmit sound
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9. Figure 11.2: A seagull floating on the ocean moves up and down as waves pass.
Notice that the
gull just moves
up and down
with the motion
of the waves, it
does not move
forward.
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10. 3 Components of Waves Wavelengths Frequency speed
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11. A wavelength (λ) is the distance between two consecutive wave peaks.
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12. Figure 11.3: The wavelength of a wave.
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13. Frequency (nu ν )
Frequency indicates how many wave peaks pass a certain point per given time period.
i.e how many times does the sea gupp go up and down per minute.
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14. Speed
Speed of the wave indicates how fast a given peak travels through the water.
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15. Light (electromagnetic radiation) Travels in Waves
Different forms of electromagnetic radiation travel at different wavelengths
Refer pg 325, fig. 11.4
Sunlight: ultraviolet radiation and visible light
Glowing coals transmits heat via infrared radiation.
Microwave radiation: water molecules absorb the microwave and this energy is transferred to other molecules by collision (KE).
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17. Light = waves that carry energy
Photons – tiny energy packets that travel through space in a beam of light.
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18. Figure 11.5: Electromagnetic radiation.
A beam of
light can be pictured in two
ways: as a wave and as a
stream of individual packets of energy called photons
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19. Figure 11.6: Photons of red and blue light.
The photons of red light (long wavelengths) carries less energy than a photon of blue light (shorter wavelengths).
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20. 11.3 Emission of Energy by Atoms
Objective: To see how atoms emit light Video – flame test
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21. The heat from the flame causes atoms to absorb energy.
The Colors of Flames Result from Atoms Releasing Energy by Emitting Visible Light
The heat from the flame causes atoms to absorb energy.
The electrons become excited.
Energy is released in the form of light
The energy is carried by photons
Energy change = energy carried by the photon
High energy photons = short-wavelengths
Low-energy photons = long-wavelengths
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22. Figure 11.6: Photons of red and blue light.
The photons of red light (long wavelengths) carries less energy than a photon of blue light (shorter wavelengths).
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23. Figure 11.8: An excited lithium atom emitting a photon of red light to drop to a lower energy state.
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24. What is the difference between the frequency of a wave and its speed?
Focus Questions 11.1 – 11.3
What was wrong with Rutherford’s model of the atom? Why did it need to be modified
What is the difference between the frequency of a wave and its speed?
What is the relationship between the wavelength of light and the energy of a photon?
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25. 4. How can red light improve germination and production in tomato crops?

26. 11.4 The Energy Levels of Hydrogen
Objective: To understand how the emission spectrum of hydrogen demonstrates the quantized nature of energy.
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30. Figure 11.9: A sample of H atoms receives energy from an external source.
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31. Figure 11.9: The excited atoms release energy by emitting photons.
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32. Figure 11.10: An excited H atom returns to a lower energy level.
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33. Figure 11.11: Colors and wavelengths of photons in the visible region.
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34. Figure 11.12: The color of the photon emitted depends on the energy change that produces it.
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35. Figure 11.13: Each photon emitted corresponds to a particular energy change.
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36. Figure 11.14: Continuous and discrete energy levels.
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37. Figure 11.15: The difference between continuous and quantized energy levels.
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38. 11.5 The Bohr Model of the Atom
Objective: To learn about Bohr’s model of the hydrogen atom
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39. Figure 11.17: The Bohr model of the hydrogen atom.
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40. 11.6 The Wave Mechanical Model of the Atom
Objective: To understand how electron’s position is represented in the wave mechanical model
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41. Figure 11.18: A representation of the photo of the firefly experiment.
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42. Figure 11.19: The orbital that describes the hydrogen electron in its lowest possible energy state.
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43. Figure 11.20: The hydrogen 1s orbital.
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44. 11.7 The Hydrogen Orbitals
Objective: To learn about the shapes of orbitals designated by s, p, and d
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45. Focus Questions 11.4 – 11.6
Figure contains four colored lines. You already know that hydrogen has only one electron. How can we get four lines from one electron?
What is wrong with the Bohr model of the atom?
How does the wave mechanical model of the atom differ from Bohr’s model?
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46. Figure 11.21: The first four principle energy levels in the hydrogen atom.
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47. Figure 11.22: How principal levels can be divided into sublevels.
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48. Figure 11.23: Principal level 2 shown divided into the 2s and 2p sublevels.
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49. Figure 11.24: The relative sizes of the 1s and 2s orbital's of hydrogen.
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50. Figure 11.25: The three 2p orbital's.
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51. Figure 11.26: Diagram of principal energy levels 1 and 2.
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52. Figure 11.27: Relative sizes of the spherical 1s, 2s, and 3s orbital's of hydrogen.
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53. Figure 11.28: The shapes and labels of the five 3d orbital's.
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54. 11.8 The Wave Mechanical Model: Further Development
Objectives: To review the energy levels and orbitals of the wave mechanical model of the atom To learn about electron spin
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55. Focus Question 11.7 – 11.8
What is the difference between an orbit and an orbital in atomic theory?
Draw Figure and fill in the different types of sublevels for each principal energy level.
Tell how many orbitals are found in each type of sublevels: s, p, d, f.
What is the Pauli exclusion principal and how does it help us determine where an electron is found within the atom?
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56. 11.9 Electron Arrangement in the First Eighteen Atoms on the Periodic Table
Objectives: To understand how the principal energy levels fill with electrons in atoms beyond hydrogen To learn about valence electrons and core electrons
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57. 11.10 Electron Configuration and the Periodic Table
Objective: To learn about the electron configuration of atoms with Z greater than 18
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58. Figure 11.30: Partial electron configurations for the elements potassium through krypton.
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59. Figure 11.31: Orbital's being filled for elements in various parts of the periodic table.
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60. Figure 11.34: Periodic table with atomic symbols, atomic numbers, and partial electron configurations.
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61. 11.11 Atomic Properties and the Periodic Table
Objective: To understand the general trends in atomic properties in the periodic table.
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62. Figure 11.35: Classification of elements as metals, nonmetals, and matalloids.
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63. Figure 11.36: Relative atomic sizes for selected atoms.
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64. Write the orbital diagram for the elements listed below.
Focus Questions
Write the orbital diagram for the elements listed below.
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65. 2. what is the difference between a valence electron and the core electron? Select an element from row 3 and label both using its electron configuration.
3. Elements in vertical columns (families) show similar chemical behavior. How are their electron configurations similar?
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66. 4. Using their positions on the periodic table, write the valence-electron configuration for the following elements. 5. What chemical properties distinguishes a metal from non-metal. 6. How can the property in question 5 be explained using ionization energy trends?
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