Lesson Objectives

• Identify the different blocks of the periodic table

• Describe the electron configurations using different methods

• Draw Valance electron structures for different atoms

Organizing the Periodic Table

• The periodic table is organized into periods and groups

  • Periods: Horizontal Rows

  • Groups: Vertical Columns

• We can divide the periodic table into different blocks based on the highest-level subshells with electrons

  • s

  • p

  • d

  • f​

S-block

P-block

d-block

f-block

Electron Configurations​

• Electron Configurations: The way in which electrons are arranged in various orbitals around the nuclei of atoms

  • Electrons fill orbitals following certain rules​

  • Energy plays a major role in how electrons arrange themselves in an atom

  • Three rules for Electron Configurations

The Aufbau Principle

• The Aufbau Principle: Electrons occupy the lowest energy sub-shells first​

  • This makes elements more stable

  • the 1s orbitals will always fill before the 2s orbitals

  • Order: 1s, 2s, 2p, 3s, 3p, 4s, 3d, 4p....

    • d sub-shells always a lower energy level than the rest of the period

  ​

Hunds Rule

• Hunds Rule: In sub-shells with multiple orbitals (p, d, f), all orbitals must be filled before getting a second electron

  • Every orbital has to get an electron before getting seconds

Pauli's Exclusion Principle

• Pauli's Exclusion principle: electrons in the same orbital can not be in the same spot at the same time

  • Spin: a property of electrons that describes their orientation in an orbital

  • We show this with two verticle arrows pointing in opposite directions

Writing Electron Configurations Sample Problem 1

• Step 1: Use the Atomic number to determine the number of electrons

  • Example: Oxygen​

Writing Electron Configurations Sample Problem 1

• Step 1: Use the Atomic number to determine the number of electrons

  • Example: Oxygen​ has the atomic number of 8, so it has 8 electrons

• Step 2: Use arrows to represent the number of electrons in each orbitals

  • Start in the 1s sub-shell

  • Each orbital in a shell has to get an electron before it can get a second one

  • Electrons in the same orbital spin in opposite directions​

Writing Electron Configurations Sample Problem 1

• Step 1: Use the Atomic number to determine the number of electrons

  • Example: Oxygen​ has the atomic number of 8, so it has 8 electrons

• Step 2: Use arrows to represent the number of electrons in each orbitals

  • Start in the 1s sub-shell

  • Each orbital in a shell has to get an electron before it can get a second one

  • Electrons in the same orbital spin in opposite directions​

Writing Electron Configurations Sample Problem 2

• Write the Electron Configuration for Nickel

• Step 1: Use the Atomic number to determine the number of electrons

Writing Electron Configurations Sample Problem 2

• Write the Electron Configuration for Nickel

  • Step 1: Use the Atomic number to determine the number of electrons

    • Example: Nickel has the atomic number of 28, so it has 28 electrons

  • Step 2: Use arrows to represent the number of electrons in each orbitals

    • Start in the 1s sub-shell

    • Each orbital in a shell has to get an electron before it can get a second one

    • Electrons in the same orbital spin in opposite directions​

Writing Electron Configurations Sample Problem 3

• Write the Electron Configuration for Silicon

• Step 1: Use the Atomic number to determine the number of electrons

Writing Electron Configurations

• Step 1: Use the Atomic number to determine the number of electrons

  • Example: Silicon​ has the atomic number of 14, so it has 14 electrons

• Step 2: Use arrows to represent the number of electrons in each orbitals

  • Start in the 1s sub-shell

  • Each orbital in a shell has to get an electron before it can get a second one

  • Electrons in the same orbital spin in opposite directions​

Writing Electron Configurations

• Step 1: Use the Atomic number to determine the number of electrons

  • Example: Silicon​ has the atomic number of 14, so it has 14 electrons

• Step 2: Use arrows to represent the number of electrons in each orbitals

  • Start in the 1s sub-shell

  • Each orbital in a shell has to get an electron before it can get a second one

  • Electrons in the same orbital spin in opposite directions​

Exceptions to Electron Configuration Rules

• Some elements do not follow the normal electron configuration rules that others do

  • Chromium: 1s² 2s² 2p⁶ 3s² 3p⁶ 4s² 3d⁵ 4s¹

  • Copper: 1s² 2s² 2p⁶ 3s² 3p⁶ 4s² 3d¹⁰ 4s¹

Noble Gas Configurations

• Electron Configurations can get long

• Noble Gases: the last group of the periodic table

• You can shorten the writing by starting with the Noble Gas before the element, and only writing what is in the period of the component in questions​

Noble Gas Configuration Sample Problem 1

• Write the Noble Gas Configuration for Sulfur​

  • Step 1: Identify the Noble gas that comes before sulfur

    ​

Noble Gas Configuration Sample Problem 1

• Write the Noble Gas Configuration for Sulfur​

  • Step 1: Identify the Noble gas that comes before sulfur

    • The Noble Gas before sulfur is Neon

  • Step 2: Write Neon's Chemical Symbol in Brackets

  • Step 3: Continue the configuration from where Neon is

    • Shortened Configuration: [Ne] 3s¹3p⁴

    ​

Noble Gas Configuration Sample Problem 2

• Write the Noble Gas Configuration for Potassium

  • Step 1: Identify the Noble Gas that comes before Potassium.​

Noble Gas Configurations Sample 2

• Write the Noble Gas Configuration for the element Potassium

  • Step 1: Identify the Noble Gas that comes before Potassium

    • The noble Gas before Sulfur is Argon (Ar)

  • Step 2: Write Argon's Chemical Symbol in Brackets

  • Step 3: Continue the configuration from where Argon is

    • Shortened Configuration: [Ar] 4s¹​

Valence Electrons

• Electrons in an element are divided into two groups

  • Core electrons:​ exist in the inner and lower energy shells

  • Valence Electrons: electrons in the outermost p energy shell

    • are most involved in reactions

    • are unstable unless they have a full electron shell

      • Noble Gases have a full shell, which is why they don't react

      • The Octet Rule: Atoms are most stable when they have a total of eight electrons in their outer shell, and will respond to gain or lose the electrons needed

Identifying Valence Electrons

• ​Counted by Looking at the Group numbers

  • Group 1=1, Group2=2

  • Groups 13-18: Valence electrons = Group number-10

    • Group 13=3, Group 14=4, Group 15=5, Group 16=6 Group 17=7, Group 18=8

• Shown Using Electron Dot Structures​

  • A visual representation of the valence electrons in an element​

Valence Electrons Sample Problem 1

• ​Sample Problem: Draw the electron dot structure for Sodium

  • Step 1: Identify which group Sodium is in

Valence Electrons Sample Problem 1

• ​Sample Problem: Draw the electron dot structure for Sodium

  • Step 1: Identify which group Sodium is in

    • Sodium is in group 1 so it has 1 Valance Electron

  • Step 2: Write the Element symbol

  • Step 3: Draw dots around the Symbol, one for each valance electron

    • Start at the top and go clockwise

    • Don't Double up until all four sides have one​

Valence Electrons Sample Problem 2

• ​Sample Problem: Draw the electron dot structure for the Silicon

  • Step 1: Identify which group Silicon is in

Valence Electrons Sample Problem 2

• ​Sample Problem: Draw the electron dot structure for the Silicon

  • Step 1: Identify which group Sodium is in

    • Silicon is in group 14 and has 4 Valance Electrons

  • Step 2: Write the Element symbol

  • Step 3: Draw dots around the Symbol, one for each valance electron

    • Start at the top and go clockwise

    • Don't Double up until all four sides have one​

Valence Electrons Sample Problem 3

• ​Sample Problem: Draw the electron dot structure for Chlorine

  • Step 1: Identify which group Chlorine is in​

Valence Electrons Sample Problem 3

• ​Sample Problem: Draw the electron dot structure for Chlorine

  • Step 1: Identify which group Chlorine is in

    • Chlorine is in group 17 and has 7 Valance Electrons

  • Step 2: Write the Element symbol

  • Step 3: Draw dots around the Symbol, one for each valance electron

    • Start at the top and go clockwise

    • Don't Double up until all four sides have one​