Chemistry 40S Atomic Structure (This unit has been adapted from https://bblearn.merlin.mb.ca)

Chemistry 40S Atomic Structure (This unit has been adapted from https://bblearn.merlin.mb.ca) Name: 1

Lesson 1: The Nature of Light Goals: Describe light in terms of electromagnetic energy. Describe the electromagnetic spectrum. Describe the relationship between frequency, wavelength and energy of light. Identify an element based on its flame test. Describe line and continuous spectra. Wavelength Frequency 2

What relationship do you notice between wavelength and frequency? Frequency, Wavelength, Energy, and Electromagnetic Spectrum Max Planck If we shine sunlight through a prism we get a rainbow of colours, known as a spectrum. Each colour in the rainbow represents light of a different frequency or wavelength. 3

The visible spectrum is actually a very small portion of the entire electromagnetic spectrum. Line Spectra 4

Element Colour Practice: The Nature of Light 1. Put the following in order of increasing energy: green light, x-rays, radio, red light, ultraviolet, microwaves, blue light, gamma rays. 2. Describe the relationship between frequency, wavelength and energy. 5

3. Why is light called electromagnetic radiation? 4. Compare and contrast line and continuous spectra. 5. Give the colour for the flame test of each of the following: a) Copper b) Strontium c) Lithium d) Potassium e) Barium f) Calcium g) Sodium 6

Lesson 2: The Quantum Mechanical Model of the Atom Goals: Explain the development of the Quantum Mechanical Model of the atom. Explain the formation of line spectra. The Model of the Atom John Dalton: Joseph John Thompson: 7

Earnest Rutherford Explanation of Line Spectra Neil Bohr 8

Quantum Theory Albert Einstein Louis de Broglie 9

The Quantum Mechanical Model of the Atom Werner Heisenberg Erwin Schrödinger 10

Orbitals s-orbitals p-orbitals 11

d-orbitals 12

Practice: The Quantum Mechanical Model of the Atom 1. Identify the contribution made by each of the following to atomic theory. a) Rutherford b) Heisenberg c) Planck d) Bohr e) de Broglie f) Schrödinger 2. Describe s, p and d-orbitals. What do they represent? How are they different from each other? 13

Lesson 3: Electron Configurations Goals: Write the electron configuration of atoms and ions. Write the valence electron configuration of and atom or ion. The Orbitals Principle Quantum Number: Main Energy Level (n) Number of Orbitals (n 2 ) Type of Orbitals The Pauli Exclusion Principle Wolfgang Pauli 14

Principle Quantum Number: Main Energy Level (n) Number of Orbitals (n 2 ) Type of Orbitals Number of Electrons (2n 2 ) The Electron Configuration 15

Aufbau Principle 16

Hund s Rule Friedich Hund Element Filling of Orbitals Electron Configuration 1s 2s 2px 2py 2pz 17

Zig-Zag Rule 7s 7p 6s 6p 6d 5s 5p 5d 5f 4s 4p 4d 4f 3s 3p 3d 2s 2p 1s Example 1: Write the complete electron configuration for magnesium. Use the Zig-Zag Rule to assist you. Example 2: Write the complete electron configuration for germanium. Use the Zig-Zag Rule to assist you. 18

Exceptions to the Rules 19

Electron Configurations of Ions Example 3: Write the complete electron configuration for the chloride ion, Cl -. Example 4: Write the complete electron configuration for the calcium ion, Ca 2+. 20

Example 5: Write the complete electron configuration for the iron (II) ion, Fe 2+. Example 6: Write the complete electron configuration for the iron (III) ion, Fe 3+. 21

Valance Configurations Example 7: Write the valence electron configuration for fluorine. Example 8: Write the valence electron configuration for germanium. 22

Practice: Electron Configurations 1. How many electrons in an atom can have the designation? a) 1s b) 2p c) 3px d) 6f e) 3dxy f) n = 2 g) 4p h) n = 5 2. Write complete electronic configurations for the following atoms and ions: a) P b) Ca c) Cu d) Rh e) Sb 3+ f) Ni 2+ g) Fe 2+ h) Ni 4+ i) Zn 2+ j) Br k) Sn 2+ l) Co 3+ 23

3. How many unpaired electrons are there in each of the following: a) Mn b) As c) Sr d) Tl + e) Cu 2+ f) V 3+ g) Sn h) Lu 4. Write the electronic configurations for the valence electrons of each of the following: a) Mg b) P c) Se d) Pb 2+ e) Br f) S 2- g) Ni h) Ag + i) N 3- j) Fe 3+ 24

Lesson 4: Electronegativity Goals: Use electronegativity values to predict the type of bond between two atoms. Describe a bond in terms of polar covalent, non-polar covalent and ionic. Electronegativity 25

Polar, Non-Polar, and Ionic Bonds Electronegativity Difference Character of Bond Percent Ionic Character Example 1: What type of bond forms between sodium and chlorine in NaCl? Example 2: What type of bond forms between sulphur and oxygen in SO3? 26

Example 3: What type of bond forms between aluminum and chlorine in AlCl3? Practice: Electronegativity Answer the following questions. Refer to the Electronegativity Table when needed. 1. Describe the trend of electronegativity on the periodic table. 2. Describe each of the following in terms of electronegativity. a) non-polar covalent bond b) polar covalent bond c) ionic bond 27

3. Describe the following as non-polar covalent, polar covalent, or ionic. a) N and H b) F and F c) Ca and O d) Al and Br e) H and I f) K and Cl 4. List the following in increasing ionic character. a) Mg-F, Ca-I, Ca-Cl, Mg-Cl b) Al-Cl, H-Cl, K-Cl, Cu-Cl c) C-O, C-H, C-F, C-Br d) S-Cl, H-C, H-F, H-H, H-Cl, H-O 28

Lesson 5: Lewis Dot Structure Goals: Draw dot diagrams for covalent compounds. Dot Structures for Atoms and Octet Rule Gilbert Lewis 29

Drawing Lewis Dot Structure Example 1: Draw the Lewis Dot structure for HF. 30

Example 2: Draw the Lewis structure for CO2. Example 3: Draw the Lewis structure for the sulphate ion, SO4 2-. 31

Practice: Lewis Dot Structure 1. Draw the Lewis structure for each of the following. a) NH3 b) SO3 c) BrF d) O2 e) PO4 3 f) CH4 g) HCN h) N2 i) Cl2O j) ClO3 - k) CO3 2- l) SiF4 32

Lesson 6: Ionization Energy and Periodic Trends Goals: Describe the factors that affect the force on an electron. Explain the trends in atomic radius, ionic radius and ionization energy. A Force on an Electron Atomic Radii 33

Atomic Radii (pm) of Group 1 Atom Ionic Radii 34

Periodic Trends and Ionization Energy 35

36

Practice: Ionization Energy and Periodic Trends 1. Briefly explain why barium has a lower first ionization energy than calcium. 2. Given the following elements and their electron configuration. Which element will have the lowest first ionization energy? Why? Element A 1s 2 2s 2 2p 6 3s 2 3p 6 4s 2 Element B 1s 2 2s 2 2p 6 3s 2 3p 5 Element C 1s 2 2s 2 2p 6 3s 2 3p 6 4s 1 Element D 1s 2 2s 2 2p 6 3s 2 3p 6 37

3. The first four ionization energies (IE) for the element aluminum are as follows: IE1 = 577 kj/mol IE2 = 1 817 kj/mol IE3 = 2 745 kj/mol IE4 = 11 580 kj/mol How many valence electrons does aluminum have? 4. An atom has the following successive ionization energy levels. IE1 = 737 kj/mol IE2 = 1 450 kj/mol IE3 = 7 731 kj/mol IE4 = 10 545 kj/mol IE5 = 13 627 kj/mol How many valence electrons does this element have? Explain. 5. Which of these elements would have the highest value for the second ionization energy? Why? K Si Ar Br 38

6. Which of the following has the largest atomic radius and which has the smallest? Explain. Nitrogen Antimony Arsenic 7. For each of the following properties: atomic radius first ionization energy ionic radius Indicate which has the larger value fluorine or bromine. 8. Arrange the following from largest to smallest. Explain the order. Ne, Mg 2+, F -, Na +, O 2-39

40