1
Weigh a known mass of solid (e.g. 10 g KNO₃) into a boiling tube
2
Add 10 cm³ of distilled water to the boiling tube
3
Place the boiling tube in a hot water bath and heat, stirring until all solid dissolves
4
Remove from water bath and allow to cool slowly while stirring continuously
5
Record the temperature at which the first crystals appear — this is the saturation temperature
⚠ Watch closely — crystals appear suddenly
6
Repeat with different masses of solid (e.g. 15 g, 20 g, 25 g) to get results at different temperatures
7
Calculate solubility (g per 100 g water) and plot solubility against temperature

📋Key Information

Variables

Independent	Temperature of solution
Dependent	Mass of solid that dissolves
Control	Volume of water, type of solid

Key Result

Solubility of most solids increases with temperature. The solubility curve shows this relationship.

Calculating Solubility

If 12 g KNO₃ dissolves in 20 g water at 50°C:
Solubility = (12 ÷ 20) × 100 = 60 g per 100 g water

Key Definition

Saturated solution: a solution in which no more solute can dissolve at that temperature

Always stir continuously while cooling — this gives a more accurate crystallisation point

Never heat above the required temperature — it changes the equilibrium and gives inaccurate results

Active Recall Flashcards

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Q — Define

What is a saturated solution?

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Answer

A solution in which no more solute can dissolve at that temperature

Q — Recall

How does solubility of most solids change as temperature increases?

tap to flip

Answer

Solubility increases as temperature increases

Q — Method

Why must you stir continuously while the solution cools?

tap to flip

Answer

To give a more accurate crystallisation point — ensures even cooling and prevents missing the moment crystals first appear

Q — Apply

A saturated KNO₃ solution at 80°C is cooled to 20°C. What happens?

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Answer

Crystals form — the solution contains more dissolved solid than can remain dissolved at 20°C

Core Practical 02

Chromatography

Spec ref: 1.7 · Investigate mixtures using paper chromatography

Purpose: To separate and identify the components of a mixture of dyes or inks using paper chromatography and calculate Rf values.

🔬Step-by-Step Method

1
Draw a pencil baseline 2 cm from the bottom of the chromatography paper
Must be pencil — ink would run with the solvent
2
Place small spots of each sample on the baseline using a capillary tube. Allow to dry between applications
3
Pour solvent (e.g. water or ethanol) into the beaker to a depth of 1 cm
⚠ Solvent level MUST be below the baseline
4
Place paper in the solvent — do not let spots touch the solvent directly
5
Wait until the solvent front is near the top of the paper
6
Remove paper immediately and mark the solvent front with a pencil
⚠ Do this instantly — solvent evaporates quickly
7
Measure distances and calculate Rf values for each spot

📋Key Information

Rf Formula

Rf = distance travelled by spot ÷ distance travelled by solvent front

Rf is always between 0 and 1

Interpreting Results

Pure substance	Produces one spot
Mixture	Produces more than one spot
Identification	Match Rf to reference values

Mark the solvent front in pencil immediately on removal — if you wait, it evaporates and Rf cannot be calculated

Rf values only compare if the SAME solvent and SAME paper are used

If spots overlap: make the initial spots smaller / use less concentrated samples. Overlapping spots cannot be identified.

Active Recall Flashcards

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Q — Recall

Why is the baseline drawn in pencil, not pen?

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Answer

Pencil is insoluble in the solvent — ink would run and interfere with the results

Q — Recall

Why must the solvent be below the baseline?

tap to flip

Answer

If above the baseline, the spots would dissolve directly into the solvent instead of being carried up the paper

Q — Calculate

Spot travels 4.8 cm. Solvent front travels 8.0 cm. Calculate Rf.

tap to flip

Answer

Rf = 4.8 ÷ 8.0 = 0.60

Q — Interpret

A chromatogram shows 4 spots for a food dye. What does this tell you?

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Answer

The food dye is a mixture of 4 components / is not a pure substance

Q — Explain

Why must you mark the solvent front immediately?

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Answer

The solvent evaporates quickly after removal — the front disappears and Rf cannot be calculated

Core Practical 03

Combustion & Reduction

Spec ref: 2.22–2.24 · Combustion of Mg and reduction of copper oxide

Purpose: Part A — investigate the combustion of magnesium and confirm mass changes. Part B — reduce copper oxide using hydrogen gas.

🔥Part A — Combustion of Magnesium

1
Weigh a clean crucible + lid. Record mass.
2
Add coiled magnesium ribbon. Weigh crucible + lid + Mg.
3
Heat strongly with lid on, lifting the lid briefly at intervals
⚠ Lid prevents MgO smoke escaping — but must allow air in
4
Continue until no further reaction — all Mg burned to white MgO
5
Cool completely, then reweigh. Mass should have increased.

⚗Part B — Reduction of Copper Oxide

1
Place black copper oxide powder in a hard glass tube
2
Pass hydrogen gas through the tube to displace all air
Test escaping H₂ — squeaky pop confirms no air
3
Heat strongly while continuing to pass hydrogen gas
4
Observe: black CuO → pink/orange copper metal; water condenses at cool end
5
Keep H₂ flowing while cooling — prevents re-oxidation of copper
⚠ Critical step — do not turn off H₂ until cool

⚗Key Equations

2Mg + O₂ → 2MgO (combustion — mass increases)

CuO + H₂ → Cu + H₂O (reduction — black → pink/orange)

In calculations: mass of oxygen gained = (final mass) − (mass of Mg before). Always set out three masses first.

The most common error: forgetting to lift the lid allows MgO smoke to escape → loss of mass → wrong results

Safety: never look directly at burning magnesium — the intense white light can permanently damage eyes. Use eye protection at all times.

Active Recall Flashcards

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Q — Explain

Why is the lid lifted briefly during Mg combustion?

tap to flip

Answer

To let air in (so Mg can react with O₂) but prevent MgO smoke escaping — escaping smoke would cause a loss of mass

Q — Recall

What observation shows copper oxide has been reduced?

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Answer

The black solid turns pink/orange — copper metal has formed

Q — Explain

Why must H₂ keep flowing while the tube cools?

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Answer

If H₂ stops, air enters the hot tube and re-oxidises the copper back to black copper oxide

Q — Identify

In CuO + H₂ → Cu + H₂O, which is the reducing agent?

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Answer

H₂ (hydrogen) is the reducing agent — it removes oxygen from CuO (and is itself oxidised to H₂O)

Q — Safety

State one hazard of using H₂ and one precaution.

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Answer

Hazard: H₂ is highly flammable/explosive with air. Precaution: expel all air before heating; test escaping gas with a lit splint first

Core Practical 04

Acid-Metal Reactions

Spec ref: 2.19–2.20 · Compare reactions of metals with dilute acids

Purpose: To investigate and compare how different metals react with dilute acids, measuring the rate of hydrogen gas production.

🔬Step-by-Step Method

1
Measure 20 cm³ of dilute HCl into a conical flask using a measuring cylinder
2
Weigh a measured mass of metal (e.g. 0.5 g). Record mass.
3
Connect the flask to a gas syringe or inverted measuring cylinder over water
4
Add metal to acid and immediately start the stopwatch
5
Record volume of H₂ collected every 30 seconds for 5 minutes
6
Repeat with Mg, Zn, and Fe — keeping all other variables the same
7
Plot volume of gas vs time for each metal on the same axes

📋Key Information

Expected Rate Order

Mg > Zn > Fe > Cu (no reaction)

Variables

Independent	Type of metal
Dependent	Volume of H₂ per unit time
Control	Volume of acid, concentration, mass of metal, temperature

Alternative Method — Mass Loss

Place flask on a balance, add metal and acid. Record mass every 30 s — mass decreases as H₂ escapes. Faster mass loss = more reactive metal.

Gas Test

Lit splint → squeaky pop confirms hydrogen

When asked to “justify using data” — always quote specific numbers with units from the table

Copper produces NO gas — it is below hydrogen in the reactivity series

Active Recall Flashcards

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Q — Recall

What gas is produced when metals react with dilute acids? How do you test for it?

tap to flip

Answer

Hydrogen gas — test with a lit splint → squeaky pop

Q — Explain

Why does copper produce no gas with dilute HCl?

tap to flip

Answer

Copper is below hydrogen in the reactivity series — it is not reactive enough to displace hydrogen from the acid

Q — Recall

State three variables that must be controlled.

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Answer

Volume of acid · concentration of acid · mass of metal · temperature (any three)

Q — Apply

Mg stops producing gas at 120 s but Zn continues. Why?

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Answer

Mg is completely used up at 120 s — no reactant remains. Zn is less reactive so still reacting at 120 s

Core Practical 05

Preparation of Copper Sulfate

Spec ref: 2.35 · Prepare hydrated copper sulfate crystals

Purpose: To prepare pure, dry hydrated copper sulfate crystals (CuSO₄·5H₂O) by reacting excess copper oxide with dilute sulfuric acid.

🔬Step-by-Step Method

1
Warm 25 cm³ of dilute sulfuric acid gently in a beaker (do not boil)
2
Add excess black copper oxide powder in small amounts, stirring after each addition
Stop adding CuO when no more dissolves
3
Filter the hot mixture through filter paper in a funnel — excess CuO is residue; blue CuSO₄ solution passes through as filtrate
CuO excess ensures all acid is used up
4
Heat the filtrate gently to evaporate — stop when crystals begin to form on a glass rod dipped in the solution
5
Leave to cool slowly — blue crystals of CuSO₄·5H₂O form
6
Filter crystals, pat dry with filter paper, leave in warm place to complete drying

📋Key Information

Equation

CuO + H₂SO₄ → CuSO₄ + H₂O

Why Excess CuO?

Ensures all the acid is used up — any remaining acid would contaminate the crystals. Excess CuO is removed by filtration.

Observations

• Black CuO dissolves → solution turns blue
• Blue crystals form on cooling

Never boil the filtrate — overheating drives off water of crystallisation, giving white anhydrous CuSO₄ (not the desired product)

“Filter to remove impurities” = 0 marks. Say specifically: excess copper oxide is removed by filtration

Active Recall Flashcards

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Q — Explain

Why is excess CuO added rather than the exact amount?

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Answer

To ensure all the acid is used up — remaining acid would contaminate the crystals. Excess CuO is removed by filtration.

Q — Method

How is excess copper oxide removed from the solution?

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Answer

Filtration — excess CuO stays on filter paper; copper sulfate solution passes through as filtrate

Q — Predict

What happens if the filtrate is heated too strongly?

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Answer

White anhydrous CuSO₄ powder forms — not the desired blue hydrated crystals. Water of crystallisation is driven off.

Q — Recall

What are the two observations when CuO is added to warm H₂SO₄?

tap to flip

Answer

Black CuO dissolves · solution turns blue

Core Practical 06

Preparation of Lead Sulfate

Spec ref: 2.38 · Prepare lead sulfate by precipitation

Purpose: To prepare a sample of dry lead sulfate using a precipitation reaction — used for insoluble salts that cannot be made by crystallisation.

🔬Step-by-Step Method

1
Measure 25 cm³ of lead(II) nitrate solution into a beaker
2
Add 25 cm³ of sodium sulfate solution — white precipitate forms immediately
3
Stir to ensure complete precipitation
4
Filter — lead sulfate precipitate collected on filter paper as residue
5
Wash residue with distilled water (three times) to remove soluble NaNO₃ impurities
⚠ Washing is essential — don’t skip this step
6
Dry at low temperature in an oven or leave in a warm place

📋Key Information

Full Equation

Pb(NO₃)₂(aq) + Na₂SO₄(aq) → PbSO₄(s) + 2NaNO₃(aq)

Ionic Equation

Pb²⁺(aq) + SO₄²⁻(aq) → PbSO₄(s)

Why precipitation?

Lead sulfate is insoluble — it cannot be made by crystallisation. Precipitation is used for all insoluble salts.

The ionic equation includes only Pb²⁺ and SO₄²⁻ — spectator ions (Na⁺ and NO₃⁻) are omitted

Washing the precipitate is essential — NaNO₃ would otherwise contaminate the lead sulfate product

Active Recall Flashcards

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Q — Recall

Name the two solutions mixed to make lead sulfate.

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Answer

Lead(II) nitrate solution + sodium sulfate solution

Q — Explain

Why is the precipitate washed with distilled water?

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Answer

To remove soluble impurities — sodium nitrate (NaNO₃) — which would otherwise contaminate the product

Q — Write

Write the ionic equation for the precipitation reaction.

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Answer

Pb²⁺(aq) + SO₄²⁻(aq) → PbSO₄(s)
(Na⁺ and NO₃⁻ are spectator ions — omit them)

Q — Explain

Why is precipitation used rather than crystallisation?

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Answer

Lead sulfate is insoluble — it cannot be dissolved and crystallised. Precipitation forms it directly as a solid.

Core Practical 07

Energy Changes — Exothermic & Endothermic

Spec ref: 3.1–3.5 · Investigate temperature changes in reactions

Purpose: To measure temperature changes in chemical reactions and classify them as exothermic (temperature rises) or endothermic (temperature falls).

🌡Method — Solution Reactions

1
Measure a fixed volume of solution into a polystyrene cup
Polystyrene cup = good insulator → less heat loss
2
Record the initial temperature (T₁) with a thermometer
3
Add the second reagent (solution or solid) and stir immediately
4
Record the maximum temperature (T₂ for exothermic) or minimum temperature (T₂ for endothermic)
5
Calculate ΔT = T₂ − T₁
6
Calculate energy change using q = mcΔT

📋Key Information

Key Formula

q = m × c × ΔT

q = energy (J) · m = mass of solution (g)
c = 4.2 J g⁻¹ °C⁻¹ · ΔT = temperature change (°C)

For mixed solutions: m = total volume

If mixing 25 cm³ + 25 cm³, use m = 50 g (assuming density = 1 g/cm³)

m = TOTAL volume of both solutions combined — the most common error is using only one volume

Exothermic: ΔT is positive (temperature rises). Endothermic: ΔT is negative (temperature falls)

Temperature-Time Graph Shape

Exothermic: flat line → sharp rise when reagent added → gradual fall as heat lost to surroundings.
Endothermic: flat line → sharp fall → gradual return toward room temperature.

Active Recall Flashcards

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Q — Recall

What is the formula for calculating energy change?

tap to flip

Answer

q = m × c × ΔT
c for water = 4.2 J g⁻¹ °C⁻¹

Q — Calculate

25 cm³ NaOH + 25 cm³ HCl. Temperature rises from 19.5°C to 26.3°C. Calculate q.

tap to flip

Answer

m = 50 g · ΔT = 6.8°C
q = 50 × 4.2 × 6.8 = 1428 J

Q — Explain

Why is a polystyrene cup used instead of a glass beaker?

tap to flip

Answer

Polystyrene is a good insulator — reduces heat loss to surroundings, giving more accurate temperature readings

Q — Classify

Classify: combustion of methane, photosynthesis, dissolving NH₄NO₃

tap to flip

Answer

Combustion: exothermic · Photosynthesis: endothermic · Dissolving NH₄NO₃: endothermic

Q — Improve

Suggest two reasons why actual energy is lower than theoretical value in combustion experiments.

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Answer

Heat lost to surroundings / air · Incomplete combustion of fuel · Not all heat transferred to water

Core Practical 08

Electrolysis

Spec ref: 1.46–1.60C · Investigate electrolysis of solutions

Purpose: To investigate the products of electrolysis of different solutions and identify gases produced at each electrode.

⚡Step-by-Step Method

1
Set up the electrolysis cell with two carbon electrodes connected to a d.c. power supply
2
Fill the cell with the chosen electrolyte (e.g. dilute H₂SO₄, CuSO₄ solution, or brine)
3
Place inverted test tubes filled with the electrolyte over each electrode to collect gas
4
Switch on the power supply and wait until a reasonable volume of gas has been collected
5
Test each gas to identify it — see key information panel
6
Observe any colour changes in the solution during electrolysis
7
Repeat with different electrolytes and record all observations

📋Products Summary

Electrolyte	Cathode	Anode
Dilute H₂SO₄	H₂	O₂
CuSO₄ (carbon)	Cu	O₂
CuSO₄ (copper)	Cu	Cu dissolves
Brine (conc.)	H₂	Cl₂

Gas Tests

Cathode H₂Lit splint → squeaky pop

Anode O₂Glowing splint relights

Anode Cl₂Bleaches damp litmus paper

CuSO₄ ratioH₂:O₂ volume = 2:1

Copper Purification (Spec 1.56–1.57)

Anode	Impure copper — dissolves: Cu → Cu²⁺ + 2e⁻
Cathode	Pure copper — deposited: Cu²⁺ + 2e⁻ → Cu
Solution	Stays blue — Cu²⁺ replaced as fast as removed
Anode sludge	Impurities (Ag, Au) fall off — do not dissolve

With copper electrodes in CuSO₄: solution stays blue (anode dissolves, replacing Cu²⁺). With carbon electrodes: solution fades as Cu²⁺ is used up

Copper purification is separately examined — know both electrode equations and why the solution stays blue

Active Recall Flashcards

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Q — Recall

What is the test for chlorine gas? State the observation.

tap to flip

Answer

Hold damp litmus paper near the gas — it is bleached / turns white

Q — Explain

Why does CuSO₄ solution stay blue when copper electrodes are used?

tap to flip

Answer

The copper anode dissolves, releasing Cu²⁺ into solution at the same rate Cu²⁺ is deposited at the cathode — concentration stays constant

Q — Recall

Why are carbon electrodes used instead of metals?

tap to flip

Answer

Carbon is inert — it does not react with the electrolyte or dissolve, giving uncontaminated results

Q — Explain

Why is twice the volume of gas collected at the cathode vs anode in dilute H₂SO₄?

tap to flip

Answer

From the equations, H₂:O₂ molar ratio = 2:1 — twice as many moles of H₂ are produced per mole of O₂

Q — Recall

Write the electrode equations for electrolysis of brine.

tap to flip

Answer

Cathode: 2H⁺ + 2e⁻ → H₂
Anode: 2Cl⁻ → Cl₂ + 2e⁻

Q — Purification

In copper purification, why does the CuSO₄ solution stay blue throughout?

tap to flip

Answer

The impure copper anode dissolves, releasing Cu²⁺ at the same rate Cu²⁺ is deposited at the cathode — concentration stays constant

Core Practical 09

Rusting

Spec ref: 2.28 · Investigate conditions necessary for iron to rust

Purpose: To determine which conditions (air/oxygen and water) are necessary for iron to rust by using a controlled experiment with five test tubes.

🔬Step-by-Step Method

1
Set up 3 test tubes, each containing a clean iron nail
2
Tube 1: add a little water (air + water present — control)
3
Tube 2: add silica gel to absorb all moisture (dry air only — no water)
Seal the top of the tube
4
Tube 3: add boiled (deaerated) water + seal with oil layer (water only — no air)
Boiling removes dissolved oxygen
5
Leave all tubes for one week at room temperature
6
Observe each tube and record whether rusting has occurred

📋Expected Results

Tube 1 (air + water)	Rusts — both conditions present
Tube 2 (dry air only)	No rust — no water
Tube 3 (water, no air)	No rust — no oxygen

Conclusion

Both oxygen AND water are needed for iron to rust.

Rust Prevention Methods

Painting · Greasing · Galvanising (Zn coating)
Sacrificial protection · Stainless steel · Electroplating

For galvanising — zinc corrodes sacrificially even when scratched because Zn is MORE reactive than Fe

Active Recall Flashcards

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Q — Recall

State the two conditions required for iron to rust.

tap to flip

Answer

Oxygen (from air) AND water — both must be present

Q — Explain

Why does the nail in boiled water + oil NOT rust?

tap to flip

Answer

Boiling removed dissolved oxygen; oil prevents oxygen re-entering. No oxygen present → one condition missing → no rusting

Q — Explain

Why does galvanised iron not rust even when scratched?

tap to flip

Answer

Zinc is more reactive than iron — it corrodes sacrificially in preference to the iron underneath

Q — Explain

Why does stainless steel not rust even though it contains iron?

tap to flip

Answer

Chromium forms a thin, impermeable oxide layer on the surface — prevents O₂ and water reaching the iron underneath

Core Practical 10

Rates of Reaction

Spec ref: 3.9–3.16 · Investigate factors affecting the rate of reaction

Purpose: To investigate how concentration, temperature, surface area and catalysts affect the rate of the reaction between marble chips and hydrochloric acid.

📈Method A — Gas Volume (CaCO₃ + HCl)

1
Measure 30 cm³ of dilute HCl into a conical flask
2
Weigh 2 g of marble chips. Add to flask and immediately seal with a bung connected to a gas syringe
3
Start stopwatch when marble chips added
4
Record volume of CO₂ in the gas syringe every 30 seconds
5
Repeat changing ONE variable at a time (concentration, temperature, chip size)
6
Plot volume vs time — steeper initial gradient = faster rate

Method B — Mass Loss

Place flask on a balance. Add CaCO₃ and HCl — leave flask open. Record mass every 30 s. Mass decreases as CO₂ escapes. Faster mass loss = faster rate. Plot mass vs time.

Method C — Disappearing Cross (Na₂S₂O₃ + HCl)

Reaction: Na₂S₂O₃ + 2HCl → 2NaCl + SO₂ + S + H₂O
Place flask on paper with a cross. Add Na₂S₂O₃ and HCl. Time until cross disappears through cloudy sulfur precipitate.
Rate = 1 ÷ time | Shorter time = faster rate

Disappearing cross: subjective endpoint — different observers judge differently. State this as a limitation.

📋Factors & Explanations

Concentration ↑	Rate ↑ — more frequent collisions
Temperature ↑	Rate ↑ — more frequent AND more energetic collisions; more particles exceed Ea
Surface area ↑	Rate ↑ — more particles exposed, more collisions
Catalyst added	Rate ↑ — lower activation energy pathway

Equation

CaCO₃ + 2HCl → CaCl₂ + H₂O + CO₂

Temperature: must state TWO things — more frequent collisions AND more particles exceed activation energy. One point = 1 mark, not 2.

All curves level off at the same final volume if the same mass of marble chips is used — final volume depends on amount of reactant, not rate

Active Recall Flashcards

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Q — Explain (2 marks)

Explain why increasing temperature increases the rate of reaction.

tap to flip

Answer

Particles move faster → more frequent collisions. More particles have energy ≥ activation energy → greater proportion of successful collisions

Q — Explain

Why does marble powder react faster than marble chips?

tap to flip

Answer

Powder has a much larger surface area — more particles exposed, more collisions per second with acid

Q — Interpret

Three curves reach the same final volume but at different rates. What does this mean?

tap to flip

Answer

Same amount of reactant was used in all three (same final volume). Only the rate differed — the limiting reactant determines final volume, not rate

Q — Recall

State one limitation of the disappearing cross method.

tap to flip

Answer

Subjective — different observers judge different endpoints. The point at which the cross “disappears” varies between people.

Q — Explain

How does a catalyst increase the rate of reaction?

tap to flip

Answer

Provides an alternative reaction pathway with a lower activation energy — more particles have sufficient energy to react

Q — Method

Describe the disappearing cross method. What is measured and how is rate calculated?

tap to flip

Answer

Na₂S₂O₃ + HCl → cloudy sulfur. Time until cross disappears through flask. Rate = 1 ÷ time. Shorter time = faster rate.

Core Practical 11

Catalytic Decomposition

Spec ref: 3.13 · Investigate catalytic decomposition of hydrogen peroxide

Purpose: To compare the effectiveness of different catalysts on the rate of decomposition of hydrogen peroxide (H₂O₂).

🔬Step-by-Step Method

1
Measure 20 cm³ of hydrogen peroxide into a conical flask connected to a gas syringe
2
Weigh 0.5 g of catalyst (e.g. MnO₂). Record mass.
3
Add catalyst to the flask, seal immediately and start the stopwatch
4
Record volume of O₂ every 30 seconds for 5 minutes
5
Repeat with different catalysts (Fe₂O₃, raw potato/liver) keeping mass constant
6
Recover and reweigh catalyst at end — confirm mass unchanged

📋Key Information

Equation

2H₂O₂ → 2H₂O + O₂

Gas Test

Hold a glowing splint to the gas — it relights → confirms oxygen

After the experiment

Recover and reweigh catalyst — mass is unchanged (catalyst is not consumed)

Both curves reach the same final volume — because the same amount of H₂O₂ was used. The catalyst only affects the RATE, not the total amount of O₂ produced.

Catalyst mass stays the same at end — this is a guaranteed exam question. Students who write “it decreases” are confusing catalyst with reactant.

Active Recall Flashcards

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Q — Recall

Write the balanced equation for the decomposition of hydrogen peroxide.

tap to flip

Answer

2H₂O₂ → 2H₂O + O₂

Q — Recall

What happens to the catalyst mass at the end of the experiment?

tap to flip

Answer

Mass stays the same / unchanged — a catalyst is not consumed in the reaction; it is regenerated

Q — Explain

Why do both catalyst curves reach the same final volume of O₂?

tap to flip

Answer

Same volume of H₂O₂ was used — the total O₂ depends on the amount of H₂O₂, not the catalyst. Catalyst only changes rate.

Q — Explain

Why does raw potato cause H₂O₂ to decompose?

tap to flip

Answer

Raw potato contains the enzyme catalase — a biological catalyst that decomposes H₂O₂ by lowering the activation energy

Core Practical 12

Preparation of Ethyl Ethanoate

Spec ref: 4.43C · Prepare a sample of an ester

Purpose: To prepare a sample of ethyl ethanoate by reacting ethanol with ethanoic acid in the presence of a concentrated sulfuric acid catalyst.

⚗Step-by-Step Method

1
Mix ethanol and ethanoic acid in a round-bottomed flask or test tube
2
Add a few drops of concentrated sulfuric acid as catalyst. Handle with extreme care.
3
Heat gently using a water bath — do NOT use a Bunsen burner
⚠ Both reagents are flammable — no naked flame
4
Pour the mixture carefully into sodium carbonate solution in a separating funnel
5
Shake gently — CO₂ is produced (effervescence). Release gas pressure regularly.
6
Allow layers to separate — ester floats as upper layer; aqueous layer below
7
Run off lower aqueous layer and collect the ester (upper layer)
8
Identify the product by its distinctive fruity smell

📋Key Information

Equation (reversible!)

CH₃COOH + C₂H₅OH ⇌ CH₃COOC₂H₅ + H₂O

Why Na₂CO₃ solution is used

Neutralises unreacted ethanoic acid → removes it
Neutralises H₂SO₄ catalyst → removes it
Dissolves ethanol → removes it
Leaves insoluble ester as upper layer

Ester layer

Upper layer — ester is less dense than water

Key Observation

When mixture added to Na₂CO₃ solution: effervescence observed — CO₂ gas produced as Na₂CO₃ neutralises the acid.
Na₂CO₃ + H₂SO₄ → Na₂SO₄ + H₂O + CO₂

The reversible sign ⇌ is required in the equation — writing → instead loses a mark

Never heat with a Bunsen burner — ethanol and ethanoic acid are both flammable

Active Recall Flashcards

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Q — Recall

Name the catalyst used and explain why a water bath is used.

tap to flip

Answer

Catalyst: concentrated H₂SO₄. Water bath used because ethanol and ethanoic acid are flammable — no naked flame

Q — Explain

Why is sodium carbonate solution used to wash the product?

tap to flip

Answer

Neutralises and removes unreacted ethanoic acid, the H₂SO₄ catalyst, and dissolves ethanol — leaving pure ester

Q — Explain

Which layer contains the ester and why?

tap to flip

Answer

Upper layer — ethyl ethanoate is less dense than water and immiscible (does not mix) with the aqueous layer

Q — Recall

What observation identifies the product as an ester?

tap to flip

Answer

A distinctive fruity smell — esters are volatile compounds with characteristic fruity odours

Q — Write

Write the equation for preparation of ethyl ethanoate. What sign is essential?

tap to flip

Answer

CH₃COOH + C₂H₅OH ⇌ CH₃COOC₂H₅ + H₂O
The reversible sign ⇌ is essential — writing → loses a mark

Mintnote Science

IGCSE ChemistryCore Practicals

IGCSE Chemistry
Core Practicals