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The Shell Model of the Atom and its Relation to the Periodic Table

The Orderly Atom

Essential Connection: The Bohr model introduced the idea of "shells" or energy levels. This model perfectly explains why the Periodic Table is shaped the way it is. As you move across the table, you fill up these shells in a predictable pattern.

🔢 Shell Capacity: \(2n^2\) 📊 Periods = Shells ⚗️ Groups = Valence Electrons

1. Electron Shells and Energy Levels

Electrons do not fly around randomly. They occupy specific regions called shells (or energy levels). Each shell can hold a maximum number of electrons determined by a simple mathematical rule.

Maximum Electrons per Shell

The maximum number of electrons (\(N\)) that can occupy a shell with principal quantum number \(n\) is given by: \[ N = 2n^2 \]

Where \(n = 1, 2, 3, 4...\)

🔵 Shell K (n=1)

Closest to the nucleus (lowest energy).

Max Capacity: \(2(1)^2 = 2\) electrons.

🟠 Shell L (n=2)

Second energy level.

Max Capacity: \(2(2)^2 = 8\) electrons.

🟢 Shell M (n=3)

Third energy level.

Max Capacity: \(2(3)^2 = 18\) electrons. (Note: For CSEC, we often focus on filling the first 20 elements, so this acts like a capacity of 8 until Calcium).

2. Interactive: Building the Atom

🔬 Electron Filling Simulator

Use the buttons below to add electrons one by one. Watch how they fill the inner shells first before moving to the outer ones. This simulates how elements are arranged in the Periodic Table (from Hydrogen to Calcium).

Total Electrons 0

                Config: Empty
            

3. Relating Shells to the Periodic Table

The Periodic Table is not just a random list; it is a map of electronic structure. As you go from left to right across a row (Period), you are adding one electron at a time.

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Periods (Rows)

The Period Number tells you how many electron shells (energy levels) an atom has.

Period 1: 1 shell (e.g., H, He)
Period 2: 2 shells (e.g., C, O, Ne)
Period 3: 3 shells (e.g., Na, Cl, Ar)

↕️

Groups (Columns)

The Group Number (for Groups I, II, III... VII) tells you the number of electrons in the outermost shell (Valence Electrons).

Group I: 1 Valence Electron (Very reactive)
Group II: 2 Valence Electrons
Group VIII (0): Full outer shell (Noble Gases, stable)

🎯 The "Inert Pair" & Stability

Atoms "want" to have a full outer shell (like Noble Gases).

Group I elements (like Sodium) have 1 electron in their outer shell. It is easier to lose this one electron to empty the shell and reveal the full one underneath.
Group VII elements (like Chlorine) have 7 electrons in their outer shell. It is easier to gain one electron to fill the shell to 8.

4. Valence Electrons and Chemical Properties

The number of electrons in the outermost shell is called the Valency. It determines how an atom reacts.

Element	Symbol	Atomic No.	Configuration	Valence Electrons	Group
Lithium	Li	3	2, 1	1	I
Neon	Ne	10	2, 8	8 (Full)	VIII (0)
Aluminum	Al	13	2, 8, 3	3	III
Potassium	K	19	2, 8, 8, 1	1	I

CSEC Practice Questions

Test Your Understanding

1. An element has the electronic configuration 2, 8, 3. Which statement is correct?

It is in Period 2.

It has 3 valence electrons.

It is a Noble Gas.

Its proton number is 8.

The outermost shell (3rd shell) has 3 electrons. The period is 3 (3 shells), and the atomic number is \(2+8+3 = 13\).

2. Which of the following elements is in the same Group as Silicon (Si, atomic number 14)?
(Hint: Si config is 2, 8, 4)

Oxygen (2, 6)

Neon (2, 8)

Carbon (2, 4)

Magnesium (2, 8, 2)

Silicon has 4 valence electrons (Group IV). Carbon also has 4 valence electrons in its outer shell, so they belong to the same Group.

3. The maximum number of electrons that can occupy the second shell (L) is:

Using \(2n^2\), for the second shell (\(n=2\)): \(2 \times (2)^2 = 8\).

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