Year 11 Chemistry Module 2 ⏱ ~25 min Lesson 4 of 20

Gases & Molar Volume

Imagine you have one mole of golf balls and one mole of beach balls. They both contain the same number of objects — but they take up very different amounts of space. Now imagine the opposite: one mole of hydrogen gas and one mole of oxygen gas. At the same temperature and pressure, they take up exactly the same volume. This is one of the most surprising facts in chemistry — and it's the foundation of all gas calculations.

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Formula Reference — This Lesson

V = n × V_m

V = volume of gas (L) n = amount of substance (mol) V_m = molar volume (L mol⁻¹)

Find V: V = n × V_m | Find n: n = V ÷ V_m | Find V_m: V_m = V ÷ n

📖 Know

Key Facts

Molar volume at STP = 22.4 L mol⁻¹
Molar volume at SATP = 24.8 L mol⁻¹
The formula V = n × V_m

💡 Understand

Concepts

Why all ideal gases have the same molar volume
The difference between STP and SATP
When to use each molar volume value

✅ Can Do

Skills

Calculate V from n using V = n × V_m
Calculate n from V by rearranging
Select the correct V_m value for given conditions

📚 Core Content

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Why All Gases Have the Same Molar Volume

At the same temperature and pressure, one mole of any ideal gas occupies the same volume. This is Avogadro's law. It seems strange at first — surely a mole of large CO₂ molecules takes more space than a mole of tiny He atoms?

The key insight is that in a gas, the molecules are so far apart that the actual size of the molecule barely matters. The volume of a gas is almost entirely empty space between particles. What determines the volume is the number of particles (which determines how hard they collectively push on the container walls) and the temperature and pressure. Since one mole always means the same number of particles (N_A), one mole of any gas at the same conditions occupies the same volume.

Golf balls vs beach balls, revisited: If you filled a room with golf balls, you'd fit more in than beach balls — because the objects themselves take up space. But if you replaced both with gas molecules and blew them around in a container, the container pressure (and thus volume) would be set by the number of collisions per second, not the size of each particle. Same number of particles = same pressure = same volume.

Standard Conditions

Molar volume only has a fixed value at a defined temperature and pressure. Two standard conditions are used in HSC Chemistry:

Standard Conditions

STP

Temperature: 0°C (273.15 K)
Pressure: 100 kPa

V_m = 22.4 L mol⁻¹

Older standard — still appears in some exam questions

Standard Conditions

SATP

Temperature: 25°C (298.15 K)
Pressure: 100 kPa

V_m = 24.8 L mol⁻¹

Current IUPAC standard — used in most NSW HSC resources

Which one to use? Read the question carefully. If it says "standard laboratory conditions", "25°C and 100 kPa", or "SATP" — use 24.8 L mol⁻¹. If it says "0°C" or "STP" — use 22.4 L mol⁻¹. If no conditions are stated, use 24.8 L mol⁻¹ as the default for NSW HSC.

⚖️

The Formula: V = n × V_m

This formula works exactly like n = m ÷ MM from Lesson 2, but for gases. Instead of converting between mass and moles using molar mass, you convert between volume and moles using molar volume.

V_m

Cover what you want → remaining two show the operation

Units check: n = V ÷ V_m gives: L ÷ L mol⁻¹ = L × mol L⁻¹ = mol ✓
V = n × V_m gives: mol × L mol⁻¹ = L ✓

🧮 Worked Examples

Worked Example 1 — Finding volume: two entry points compared

Compare Two Methods

What volume does 3.5 mol of nitrogen gas (N₂) occupy at SATP?

Method A — Direct formula

Known: n = 3.5 mol
V_m = 24.8 L mol⁻¹ (SATP)

V = n × V_m
V = 3.5 × 24.8

V = 86.8 L

Method B — Via mass first

MM(N₂) = 2 × 14.007 = 28.014 g mol⁻¹
m = 3.5 × 28.014 = 98.05 g

n = 98.05 ÷ 28.014 = 3.5 mol
V = 3.5 × 24.8

V = 86.8 L

Which method is better here? Method A — always use the direct formula when moles are already given. Method B adds unnecessary steps and introduces rounding error. Method B would only make sense if the question gave you mass and asked for volume.

✓ Answer V = 86.8 L at SATP

Worked Example 2 — Finding moles from volume: two conditions compared

Compare Two Methods

A 4.96 L sample of carbon dioxide gas is collected. How many moles does it contain — and does the answer change depending on the conditions?

At SATP (25°C, 100 kPa)

V_m = 24.8 L mol⁻¹

n = V ÷ V_m
n = 4.96 ÷ 24.8

n = 0.200 mol

At STP (0°C, 100 kPa)

V_m = 22.4 L mol⁻¹

n = V ÷ V_m
n = 4.96 ÷ 22.4

n = 0.221 mol

Key takeaway: The same volume of gas contains different amounts depending on temperature. At lower temperature (STP), gas is more compressed — so 4.96 L contains more moles. At higher temperature (SATP), the gas expands — same volume contains fewer moles. Always state and use the correct conditions.

✓ Answer n = 0.200 mol (SATP) or 0.221 mol (STP)

⚠️

Common Mistakes — Don't Lose Easy Marks

Using the wrong molar volume value

Using 22.4 L mol⁻¹ for SATP conditions (or vice versa) gives a completely wrong answer. A student who correctly sets up n = V ÷ V_m but uses 22.4 instead of 24.8 will lose marks even though their method is right.

✓ Fix: Underline the conditions stated in the question before picking a V_m value. Default to 24.8 L mol⁻¹ for NSW HSC unless told otherwise.

Applying molar volume to liquids or solids

V = n × V_m only works for gases. One mole of liquid water does NOT occupy 24.8 L — it occupies about 18 mL. The huge molar volume of gases is a result of their widely spaced particles.

✓ Fix: Check the state of matter in the question. Gas → use V = n × V_m. Solid or liquid → use n = m ÷ MM.

Not converting units before substituting

V_m is in litres per mole (L mol⁻¹). If a question gives volume in mL or cm³, convert to litres first (divide by 1000). Substituting mL directly into the formula gives an answer 1000× too large.

✓ Fix: Convert volume to litres before substituting. 500 mL = 0.500 L; 2400 cm³ = 2.400 L.

📓 Copy Into Your Books

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📖 Key Definitions

Molar volume (V_m) — volume occupied by 1 mol of any ideal gas at specified T and P
STP — 0°C, 100 kPa → V_m = 22.4 L mol⁻¹
SATP — 25°C, 100 kPa → V_m = 24.8 L mol⁻¹

📐 Formula & Rearrangements

V = n × V_m (find volume)
n = V ÷ V_m (find moles)
V_m = V ÷ n (find molar volume)

✅ Units Check

V in litres (L) — convert mL ÷ 1000
n in mol
V_m in L mol⁻¹
L ÷ L mol⁻¹ = mol ✓

💡 When to Use

Gas state only — not liquids/solids
Always state conditions (SATP or STP)
NSW HSC default: 24.8 L mol⁻¹
Can chain with n = m ÷ MM for multi-step problems

🧪 Activities

📊 Activity 1 — Practice Drill

Applying V = n × V_m

Three problems using the formula in both directions. State the conditions and V_m value you are using in each answer.

1 Calculate the volume occupied by 2.50 mol of oxygen gas (O₂) at SATP.

SATP → V_m = 24.8 L mol⁻¹ V = n × V_m = 2.50 × 24.8 = 62.0 L
2 A 11.2 L sample of hydrogen gas (H₂) is collected at STP. How many moles does it contain?

STP → V_m = 22.4 L mol⁻¹ n = V ÷ V_m = 11.2 ÷ 22.4 = 0.500 mol
3 A balloon contains 8.40 g of methane gas (CH₄) at SATP. Calculate the volume of the balloon. (C = 12.011, H = 1.008)

Step 1: MM(CH₄) = 12.011 + 4(1.008) = 16.043 g mol⁻¹ n = m ÷ MM = 8.40 ÷ 16.043 = 0.524 mol Step 2: SATP → V_m = 24.8 L mol⁻¹ V = n × V_m = 0.524 × 24.8 = 13.0 L

Type your working below before revealing answers above:

Complete these problems in your workbook.

✏️ Complete in your workbook

🔢 Activity 2 — Data Analysis

Comparing Gas Volumes

The table below shows experimental measurements of equal-mole samples of different gases at SATP. Analyse the data and answer the questions below.

Gas	Formula	Molar Mass (g mol⁻¹)	Amount (mol)	Measured Volume (L)
Helium	He	4.003	1.00	24.8
Nitrogen	N₂	28.014	1.00	24.8
Carbon dioxide	CO₂	44.009	1.00	24.8
Sulfur dioxide	SO₂	64.058	1.00	24.8
Xenon	Xe	131.29	1.00	24.8

Questions — answer all three:

A. The molar masses in the table range from 4.003 to 131.29 g mol⁻¹ — a factor of ~33. Yet all measured volumes are identical. In 2–3 sentences, explain why this result is consistent with Avogadro's law.

B. If the experiment were repeated using 2.00 mol of each gas instead of 1.00 mol, what would the measured volume be for each gas? Show a calculation for one gas to support your answer.

C. A student claims that 1.00 mol of liquid water would also occupy 24.8 L at 25°C. Is this correct? Explain your reasoning. (Density of water ≈ 1.00 g mL⁻¹)

Type your responses below:

Answer A, B, and C in your workbook.

✏️ Answer A, B, and C in your workbook

❓ Multiple Choice

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Test Your Knowledge

1. What is the molar volume of an ideal gas at SATP (25°C, 100 kPa)?

22.4 L mol⁻¹

24.8 L mol⁻¹

24.0 L mol⁻¹

22.8 L mol⁻¹

2. How many moles of gas are in a 49.6 L sample collected at SATP?

1.00 mol

1.50 mol

2.00 mol

2.50 mol

3. Which statement about molar volume is correct?

All ideal gases have the same molar volume at the same temperature and pressure

Heavier gases have a larger molar volume because the molecules take up more space

Molar volume applies equally to gases, liquids, and solids at standard conditions

At STP, the molar volume is larger than at SATP because the pressure is higher

4. A sample of chlorine gas (Cl₂) has a mass of 35.45 g. What volume does it occupy at SATP? (Cl = 35.45 g mol⁻¹)

24.8 L

44.6 L

22.4 L

12.4 L

5. A gas sample occupies 620 mL at SATP. How many moles does it contain?

15.38 mol

0.040 mol

0.025 mol

0.062 mol

✍️ Short Answer

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Extended Questions

6. State Avogadro's law and use it to explain why one mole of helium gas (M = 4.003 g mol⁻¹) and one mole of sulfur hexafluoride gas (SF₆, M = 146.06 g mol⁻¹) occupy the same volume at the same temperature and pressure. 3 MARKS

Type your answer below:

Answer in your workbook.

✏️ Answer in your workbook

7. A laboratory produces 4.40 g of carbon dioxide gas (CO₂) during a reaction at SATP. Calculate: (a) the number of moles of CO₂ produced, and (b) the volume this gas occupies at SATP. (C = 12.011, O = 15.999) 4 MARKS

Type your answer below:

Answer in your workbook.

✏️ Answer in your workbook

8. A student collects 3.72 L of an unknown gas at STP and determines it has a mass of 7.44 g. Calculate the molar mass of the gas and suggest what the gas might be. Show all working. 4 MARKS

Type your answer below:

Answer in your workbook.

✏️ Answer in your workbook

✅ Comprehensive Answers

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🔢 Activity 2 Model Answers

A. Avogadro's law states that equal amounts (moles) of any ideal gas at the same temperature and pressure occupy the same volume. All five samples contain exactly N_A particles, so they exert the same pressure on their container at the same temperature, and thus occupy the same volume. The mass (and thus the molar mass) of each molecule is irrelevant because gas volume is dominated by empty space between particles, not the size of the molecules themselves.

B. All gases would occupy 2 × 24.8 = 49.6 L. For example, for N₂: V = 2.00 × 24.8 = 49.6 L.

C. The student is incorrect. The molar volume of 24.8 L mol⁻¹ applies only to gases. Liquid water at 25°C has a density of 1.00 g mL⁻¹, so 1.00 mol (18.015 g) of water occupies only 18.015 mL = 0.018 L — nearly 1400 times less than 24.8 L. In liquids, molecules are densely packed with no significant empty space between them.

❓ Multiple Choice

1. B — 24.8 L mol⁻¹ at SATP (25°C, 100 kPa). 22.4 L mol⁻¹ is for STP (0°C).

2. C — n = 49.6 ÷ 24.8 = 2.00 mol.

3. A — Avogadro's law: equal moles of ideal gases → equal volumes at same T and P.

4. D — MM(Cl₂) = 2 × 35.45 = 70.90 g mol⁻¹. n = 35.45 ÷ 70.90 = 0.500 mol. V = 0.500 × 24.8 = 12.4 L.

5. C — Convert: 620 mL = 0.620 L. n = 0.620 ÷ 24.8 = 0.025 mol.

📝 Short Answer Model Answers

Q6 (3 marks): Avogadro's law states that equal volumes of all ideal gases at the same temperature and pressure contain the same number of molecules [1]. Both 1 mol He and 1 mol SF₆ contain exactly 6.022 × 10²³ molecules [1]. Gas volume is determined by the number of particle–wall collisions per second (pressure) and temperature, not by the mass of individual molecules — so despite SF₆ being ~36× heavier, both samples occupy the same volume at the same T and P [1].

Q7 (4 marks):

(a) MM(CO₂) = 12.011 + 2(15.999) = 44.009 g mol⁻¹ n = m ÷ MM = 4.40 ÷ 44.009 = 0.100 mol (b) V = n × V_m = 0.100 × 24.8 = 2.48 L

Q8 (4 marks):

STP → V_m = 22.4 L mol⁻¹ n = V ÷ V_m = 3.72 ÷ 22.4 = 0.1661 mol MM = m ÷ n = 7.44 ÷ 0.1661 = 44.8 g mol⁻¹ ≈ 44 g mol⁻¹

A molar mass of ~44 g mol⁻¹ is consistent with carbon dioxide (CO₂, MM = 44.009 g mol⁻¹) or propane (C₃H₈, MM = 44.097 g mol⁻¹). At STP, CO₂ is the more likely candidate in a typical lab context.

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Gases & Molar Volume

Formula Reference — This Lesson

Key Facts

Concepts

Skills

Why All Gases Have the Same Molar Volume

Standard Conditions

The Formula: V = n × Vm

Worked Example 1 — Finding volume: two entry points compared

Worked Example 2 — Finding moles from volume: two conditions compared

Common Mistakes — Don't Lose Easy Marks

📓 Copy Into Your Books

📖 Key Definitions

📐 Formula & Rearrangements

✅ Units Check

💡 When to Use

Applying V = n × Vm

Comparing Gas Volumes

Test Your Knowledge

Extended Questions

✅ Comprehensive Answers

🔢 Activity 2 Model Answers

❓ Multiple Choice

📝 Short Answer Model Answers

Mark lesson as complete

The Formula: V = n × V_m

Applying V = n × V_m