The periodic table | AQA GCSE Chemistry Notes

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The key idea

Elements in the same group have the same number of outer electrons and similar chemical properties.The periodic table is arranged in order of increasing atomic number.

Periodic Table

Use the labels to explain the scientific relationship shown.

Revision notes

The bit that matters

Keep the idea tight, then use the worked example to practise the exact exam wording.

Structure of the periodic table

The periodic table arranges all known elements in order of increasing atomic number.Elements in the same vertical column (group) share the same number of electrons in their outer shell and have similar chemical properties.Elements in the same horizontal row (period) have the same number of electron shells.

History of the periodic table

Early attempts at classifying elements, such as Newlands' law of octaves, arranged elements by atomic mass but placed dissimilar elements in the same group.Mendeleev improved this by leaving gaps for undiscovered elements and predicting their properties.When these predictions were confirmed, the periodic table gained wide acceptance.The modern table is arranged by atomic number, not atomic mass.

Group 1 — alkali metals

The alkali metals (Li, Na, K, Rb, Cs, Fr) all have one electron in their outer shell.They react vigorously with water to produce a metal hydroxide and hydrogen gas, and they lose their outer electron easily to form +1 ions.Reactivity increases down the group as the outer electron becomes easier to remove.

Group 7 — halogens

The halogens (F, Cl, Br, I, At) all have seven electrons in their outer shell and form −1 ions. g.Cl₂) and are oxidising agents that react with metals to form salts called halides.Reactivity decreases down the group as the outer shell becomes further from the nucleus and harder to fill.

Key terms

Definitions to learn

Period

A horizontal row of elements in the periodic table; all elements in a period have the same number of electron shells.

Group

A vertical column of elements in the periodic table; all elements in a group have the same number of outer electrons.

Alkali metals

The elements in Group 1 of the periodic table, which have one outer electron and react vigorously with water.

Halogens

The elements in Group 7 of the periodic table, which have seven outer electrons and form −1 ions.

Noble gases

The elements in Group 0 with full outer shells, making them very unreactive.

Transition metals

The block of metals in the middle of the periodic table, which form coloured compounds and can have variable oxidation states.

Worked example

Explain why potassium is placed in Group 1 of the periodic table.

Potassium has the electronic structure 2, 8, 8, 1.

It has one electron in its outer shell.

Elements with one outer electron are in Group 1.

Final answer

Potassium is in Group 1 because it has one electron in its outer shell.

Exam habit

In periodic table questions, always link the group number to the number of outer electrons and the period number to the number of electron shells.

Watch out

Do not say elements are arranged in order of atomic mass. The modern table uses atomic number.

Examiner tips

How to score full marks

1State the group number AND the number of outer electrons together — e.g. 'Group 1 because it has 1 outer electron'.
2For reactivity trends: Group 1 increases DOWN (easier to lose e⁻); Group 7 decreases DOWN (harder to gain e⁻) — these are opposite trends.
3Mendeleev's key contribution was leaving GAPS — always mention this when explaining why his table was accepted.

Practice questions

Try these yourself

Open each answer only after you have explained the full chemical process.

1State what is meant by a period in the periodic table.[1 mark]

Mark scheme

1.Think about the rows.

A period is a horizontal row of elements in the periodic table (1).

2Give two properties of the noble gases that explain why they are unreactive.[2 marks]

Mark scheme

1.Consider their electronic structures.

Any two from: full outer shell (1); do not readily gain, lose or share electrons (1); stable electronic configuration (1).

3Explain why elements in the same group have similar chemical properties.[2 marks]

Mark scheme

1.Link to outer electrons.

Elements in the same group have the same number of electrons in their outer shell (1), so they react in similar ways (1).

4State one limitation of Newlands' law of octaves.[2 marks]

Mark scheme

1.Think about properties of the elements placed in the same group.

Newlands placed elements with very different properties in the same group (1) because he forced elements into groups of eight without leaving gaps for undiscovered elements (1).

5Explain how Mendeleev's periodic table was different from Newlands' and why it was more successful.[4 marks]

Mark scheme

1.Consider gaps and predictions.

Mendeleev left gaps for undiscovered elements (1) and predicted their properties (1). When these elements were discovered their properties matched his predictions (1), providing strong evidence for his arrangement (1).

6Describe the trend in reactivity as you go down Group 1.[3 marks]

Mark scheme

1.Link to ionisation energy or ease of losing an electron.

Reactivity increases down Group 1 (1) because the outer electron is further from the nucleus and more shielded (1), so it is lost more easily during reactions (1).

7Explain why the atomic radius increases down Group 1.[2 marks]

Mark scheme

1.Link to number of electron shells.

Each element down the group has an extra electron shell (1), so the outer electrons are further from the nucleus (1).

8Explain why elements in Group 7 become less reactive going down the group.[3 marks]

Mark scheme

1.Compare ability to gain an electron.

Going down Group 7 the outer shell is further from the nucleus (1) and there is more shielding (1), so it is harder to attract an additional electron to complete the outer shell (1).

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