Year 11 Chemistry Module 2 ⏱ ~35 min Lesson 7 of 20

Standard Solutions & Dilutions

A forensic toxicologist testing a blood sample can't use a vague "roughly 1 mol/L" acid — the result has to stand up in court. A pharmaceutical lab dissolving a drug standard can't afford to be off by 0.1%. This is why primary standards and volumetric flasks exist: chemistry where precision is not optional.

⚗️

📐

From L06 — still needed

c = n ÷ V

c = concentration (mol L⁻¹)
n = moles of solute (mol)
V = volume of solution (L)

⚠️ V must always be in litres

💧

New this lesson — dilution

c₁V₁ = c₂V₂

c₁ = initial concentration (mol L⁻¹)
V₁ = initial volume (L or mL)
c₂ = final concentration (mol L⁻¹)
V₂ = final volume (L or mL)

Units must match on both sides (both L or both mL)

📖 Know

Key Facts

Definition of a primary standard
Four properties a primary standard must have
Examples: Na₂CO₃, KIO₃, oxalic acid
The dilution formula c₁V₁ = c₂V₂

💡 Understand

Concepts

Why moles of solute are conserved during dilution
Why most reagents can't be used as primary standards
The role of a volumetric flask in accurate preparation

✅ Can Do

Skills

Describe the preparation of a standard solution
Identify whether a substance qualifies as a primary standard
Use c₁V₁ = c₂V₂ to solve dilution problems

📚 Core Content

🔬

Primary Standards

A standard solution is one whose concentration is known precisely. You can make a standard solution from scratch only if you start with a substance that meets strict criteria — a primary standard.

Most chemicals you'd find in a lab cannot be used as primary standards. Concentrated HCl, for example, is a liquid of variable concentration that absorbs water from air — you could never weigh out a precise amount. NaOH absorbs both CO₂ and water from air, changing its mass continuously.

The Four Properties of a Primary Standard

A primary standard must satisfy all four of the following:

Property	Why it matters	Example failure
High purity	If the substance contains impurities, the actual moles present will differ from the calculated value — the concentration will be wrong from the start.	NaOH absorbs CO₂ — not pure NaOH
Stable (doesn't react with air)	If the substance reacts with O₂, CO₂, or H₂O in the atmosphere, its composition changes between weighing and dissolving. The mass you weighed no longer represents the same number of moles.	Na reacts violently with moisture
High molar mass	A higher molar mass means you need to weigh out more grams per mole. This reduces the percentage error from the balance — a 0.001 g weighing error matters far less when you're weighing 200 g than when you're weighing 4 g.	HCl (MM = 36.46) — tiny masses, huge % error
Readily soluble in water	The substance must dissolve completely and quickly to form a homogeneous solution. An undissolved residue means not all the solute is in solution — the concentration is undefined.	BaSO₄ is insoluble — can't make a solution

Common primary standards in NSW HSC: Sodium carbonate (Na₂CO₃, MM = 105.99), potassium iodate (KIO₃, MM = 214.00), oxalic acid dihydrate (H₂C₂O₄·2H₂O, MM = 126.07), potassium hydrogen phthalate (KHP, MM = 204.22). All have high molar masses and are stable solids at room temperature.

Preparing a Standard Solution — Step by Step

This procedure is examinable. You may be asked to describe it and justify each step.

⚖️

1. Weigh the primary standard accurately

Use an analytical balance to weigh the required mass into a clean, dry weighing boat. Record the exact mass — use this value in calculations, not the theoretical target mass.

Equipment: analytical balance, weighing boat

💧

2. Dissolve in a small volume of distilled water

Transfer the solid to a beaker. Add a small volume (~50 mL) of distilled water and stir until completely dissolved. Using distilled (not tap) water prevents ionic impurities from changing the solution composition.

Equipment: beaker, glass rod

🧪

3. Transfer quantitatively to a volumetric flask

Pour the solution into a volumetric flask of the desired volume. Rinse the beaker and glass rod 2–3 times with distilled water, adding each rinse to the flask. This ensures all solute is transferred — a "quantitative transfer".

Equipment: volumetric flask (e.g. 250 mL), wash bottle

📏

4. Make up to the mark with distilled water

Add distilled water carefully until the bottom of the meniscus sits exactly on the calibration mark. Use a dropper pipette for the final additions. Stopper and invert several times to mix thoroughly.

Equipment: dropper pipette, stopper

Why a volumetric flask — not a measuring cylinder? Volumetric flasks are calibrated to contain a precise volume at a specific temperature (usually 20°C). The long, narrow neck means the meniscus can be read very precisely. A measuring cylinder is accurate to ±1–2 mL; a volumetric flask is accurate to ±0.1 mL or better.

💧

Dilution — c₁V₁ = c₂V₂

When you add water to a solution, you increase its volume but the number of moles of solute stays the same. This is the key insight behind dilution. The concentration must decrease to keep the moles constant.

Before dilution

n = c₁ × V₁

Small volume, high concentration
Same number of moles of solute

+H₂O

→

After dilution

n = c₂ × V₂

Larger volume, lower concentration
Moles unchanged: c₁V₁ = c₂V₂

Derivation: Since moles are conserved: n₁ = n₂
c₁V₁ = c₂V₂ (because n = cV for both)

Important: V₁ and V₂ must be in the same units (both L or both mL) — but they don't have to be litres, because they appear on both sides and the units cancel.

Serial Dilution

A serial dilution is a repeated sequence of dilutions, each reducing the concentration by the same factor. It's used to produce a range of very low concentrations from a concentrated stock — for example, when preparing calibration standards for spectroscopy.

Example: A 1:10 serial dilution starting at 1.00 mol L⁻¹:
Step 1: 10 mL of stock → 100 mL → 0.100 mol L⁻¹
Step 2: 10 mL of Step 1 → 100 mL → 0.0100 mol L⁻¹
Step 3: 10 mL of Step 2 → 100 mL → 0.00100 mol L⁻¹
Each step multiplies the concentration by ×0.1 (or ÷10).

🧮 Worked Examples

Worked Example 1 — Preparing a standard solution

Stepwise

A student dissolves 2.650 g of anhydrous sodium carbonate (Na₂CO₃) in distilled water and makes up to 250.0 mL in a volumetric flask. Calculate the exact concentration of the resulting standard solution. (Na = 22.990, C = 12.011, O = 15.999)

1

Calculate molar mass

MM(Na₂CO₃) = 2(22.990) + 12.011 + 3(15.999) = 105.989 g mol⁻¹
2

Convert mass to moles

n = m ÷ MM = 2.650 ÷ 105.989 = 0.025003 mol
3

Convert volume and calculate concentration

V = 250.0 mL ÷ 1000 = 0.2500 L

c = n ÷ V = 0.025003 ÷ 0.2500 = 0.1000 mol L⁻¹

✓ Answerc(Na₂CO₃) = 0.1000 mol L⁻¹

Worked Example 2 — Basic dilution calculation

Stepwise

100 mL of 2.00 mol L⁻¹ hydrochloric acid (HCl) is diluted to a final volume of 500 mL. Calculate the concentration of the diluted solution.

1

Identify variables

c₁ = 2.00 mol L⁻¹ | V₁ = 100 mL | V₂ = 500 mL | c₂ = ?

Units match (both mL) — no conversion needed here.
2

Apply and rearrange

c₁V₁ = c₂V₂

c₂ = c₁V₁ ÷ V₂ = (2.00 × 100) ÷ 500

c₂ = 200 ÷ 500 = 0.400 mol L⁻¹

✓ Answerc₂ = 0.400 mol L⁻¹

Worked Example 3 — Finding volume needed for dilution

Stepwise

What volume of 6.00 mol L⁻¹ sulfuric acid (H₂SO₄) must be diluted to 250 mL to give a 0.500 mol L⁻¹ solution?

1

Identify variables

c₁ = 6.00 mol L⁻¹ | V₁ = ? | c₂ = 0.500 mol L⁻¹ | V₂ = 250 mL
2

Rearrange and solve

V₁ = c₂V₂ ÷ c₁ = (0.500 × 250) ÷ 6.00

V₁ = 125 ÷ 6.00 = 20.8 mL

✓ AnswerV₁ = 20.8 mL of concentrated H₂SO₄

⚠️

Common Mistakes

Mixing up V₁ and V₂ in the dilution formula

V₁ is the volume of the concentrated solution you are measuring out, not the final volume. V₂ is always the larger, final volume. Students sometimes reverse these and get an answer that implies the diluted solution is more concentrated — which is physically impossible.

✓ Fix: Before substituting, sanity-check your answer. After dilution, c₂ must always be smaller than c₁. If your c₂ > c₁, you've swapped V₁ and V₂.

Using V₁ = volume of water added, not final volume

If a question says "100 mL of stock is diluted by adding 400 mL of water," students sometimes put V₂ = 400 mL. The correct V₂ is the total final volume = 100 + 400 = 500 mL.

✓ Fix: V₂ = total final volume = V₁ + volume of water added. Re-read the question: "made up to 500 mL" → V₂ = 500 mL. "400 mL of water added" → V₂ = V₁ + 400 mL.

Listing primary standard properties without explaining them

Short-answer questions almost always ask you to "state AND explain" each property. Writing "high purity" without explaining why purity matters scores 0–1 marks. The explanation is where the marks are.

✓ Fix: For each property, write a two-part answer: "It must be [property] because [consequence if it isn't]." Practise the explanation column in the table above.

📓 Copy Into Your Books

▼

📖 Primary Standard — 4 Properties

High purity — impurities change the actual moles present
Stable in air — reacting with O₂/CO₂/H₂O changes composition
High molar mass — reduces % weighing error
Readily soluble in water — must dissolve completely

🧪 Standard Solution Preparation

1. Weigh accurately on analytical balance
2. Dissolve in small volume of distilled water
3. Transfer quantitatively to volumetric flask (rinse ×3)
4. Make up to mark — use dropper for last drops

💧 Dilution Formula

c₁V₁ = c₂V₂
V₁ = volume of concentrated solution used
V₂ = total final volume of diluted solution
Units must match on both sides
c₂ must always be less than c₁

⚠️ Key Distinctions

Standard solution: concentration known precisely
Non-standard: concentration approximate (e.g. NaOH)
V₂ = total volume, NOT volume of water added
Moles conserved on dilution: n₁ = n₂

🧪 Activities

📊 Activity 1 — Dilution Drill

Applying c₁V₁ = c₂V₂

Four problems covering all rearrangements of the dilution formula. Work each one before revealing the answer.

1 50.0 mL of 3.00 mol L⁻¹ NaOH is diluted to 300 mL. Calculate the final concentration.

c₁ = 3.00, V₁ = 50.0 mL, V₂ = 300 mL c₂ = c₁V₁ ÷ V₂ = (3.00 × 50.0) ÷ 300 = 0.500 mol L⁻¹
2 What volume of 12.0 mol L⁻¹ HCl must be diluted to 1.00 L to give 0.250 mol L⁻¹ HCl?

c₁ = 12.0, V₂ = 1000 mL, c₂ = 0.250 V₁ = c₂V₂ ÷ c₁ = (0.250 × 1000) ÷ 12.0 = 20.8 mL
3 25.0 mL of a 0.400 mol L⁻¹ solution is diluted by adding 75.0 mL of water. What is the new concentration?

V₂ = 25.0 + 75.0 = 100.0 mL (total final volume) c₂ = (0.400 × 25.0) ÷ 100.0 = 0.100 mol L⁻¹
4 A student dilutes 10.0 mL of stock solution to 500 mL and measures the final concentration as 0.0200 mol L⁻¹. What was the concentration of the original stock solution?

V₁ = 10.0 mL, V₂ = 500 mL, c₂ = 0.0200 c₁ = c₂V₂ ÷ V₁ = (0.0200 × 500) ÷ 10.0 = 1.00 mol L⁻¹

Type your working for all four problems:

Complete in your workbook.

✏️ Complete in your workbook

🔍 Activity 2 — Evaluate These Substances

Would These Work as Primary Standards?

For each substance below, evaluate whether it could be used as a primary standard. Identify which property (or properties) it fails to meet and explain why.

Evaluate all four — write your reasoning for each:

A. Sodium hydroxide (NaOH, MM = 40.00 g mol⁻¹) — solid, but absorbs both CO₂ and water vapour from the air.

B. Potassium hydrogen phthalate (KHP, MM = 204.22 g mol⁻¹) — high-purity solid, stable in air at room temperature, soluble in water.

C. Hydrochloric acid (HCl gas dissolved in water, MM = 36.46 g mol⁻¹) — concentrated HCl is a liquid with a concentration that varies with temperature and storage.

D. Barium sulfate (BaSO₄, MM = 233.39 g mol⁻¹) — high purity, stable solid, does not react with air, high molar mass.

Write your evaluation for A, B, C, and D below:

Answer in your workbook.

✏️ Evaluate A, B, C, D in your workbook

❓ Multiple Choice

🎯

Test Your Knowledge

1. Which property of a primary standard reduces the percentage error in weighing?

High purity

Stability in air

High molar mass

Solubility in water

2. Why is NaOH unsuitable as a primary standard?

It has too high a molar mass

It absorbs CO₂ and H₂O from the air, changing its composition

It is insoluble in water

It reacts with the glass of the volumetric flask

3. 200 mL of 1.50 mol L⁻¹ NaCl is diluted to 600 mL. What is the new concentration?

0.250 mol L⁻¹

0.375 mol L⁻¹

4.50 mol L⁻¹

0.500 mol L⁻¹

4. Which statement about the dilution formula c₁V₁ = c₂V₂ is correct?

The moles of solute are conserved — adding water doesn't add or remove solute

The mass of solution is conserved — no particles are lost

The volume of solute is conserved — the solute volume doesn't change

The density of the solution is conserved — dilution doesn't change density

5. A student needs 250 mL of 0.100 mol L⁻¹ HCl, starting from 2.00 mol L⁻¹ HCl. What volume of the concentrated acid is required?

5.00 mL

10.0 mL

12.5 mL

20.0 mL

✍️ Short Answer

📝

Extended Questions

6. A student prepares a standard solution of potassium iodate (KIO₃) by dissolving 1.070 g of KIO₃ in distilled water and making up to 250.0 mL in a volumetric flask. (a) Calculate the concentration of the standard solution. (b) State two properties of KIO₃ that make it suitable as a primary standard. (K = 39.098, I = 126.90, O = 15.999) 4 MARKS

Type your answer:

Answer in workbook.

✏️ Answer in your workbook

7. A laboratory technician needs to prepare 500 mL of 0.0500 mol L⁻¹ sulfuric acid from a concentrated stock solution of 9.80 mol L⁻¹. (a) Calculate the volume of concentrated acid needed. (b) Describe the procedure the technician should follow, identifying the key piece of equipment used to ensure accuracy. 5 MARKS

Type your answer:

Answer in workbook.

✏️ Answer in your workbook

8. A student performs a 1:5 serial dilution of a 1.00 mol L⁻¹ glucose solution — that is, at each step they take 10.0 mL of the current solution and make it up to 50.0 mL. (a) Calculate the concentration after the first dilution. (b) Calculate the concentration after the third dilution. (c) How many moles of glucose are present in 25.0 mL of the third dilution? 4 MARKS

Type your answer:

Answer in workbook.

✏️ Answer in your workbook

✅ Comprehensive Answers

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🔍 Activity 2 — Primary Standard Evaluation

A. NaOH — Fails: stability in air. NaOH absorbs both CO₂ (reacting to form Na₂CO₃) and water vapour from the atmosphere. The mass you weigh out is therefore not pure NaOH — it contains Na₂CO₃ and adsorbed water. The moles of NaOH present are unknown, so an accurate concentration cannot be calculated.

B. KHP — Passes all four criteria. It is available in high purity, is stable at room temperature in dry air, has a high molar mass (204.22 g mol⁻¹) that minimises weighing error, and is freely soluble in water. KHP is one of the most widely used primary standards in titrimetric analysis.

C. HCl — Fails: purity and stability. Concentrated HCl is a solution of HCl gas in water — its concentration varies with temperature, age, and storage conditions. You cannot weigh out a precise number of moles. It is also volatile, losing HCl gas when opened. Fails both purity and stability criteria.

D. BaSO₄ — Fails: solubility. Although BaSO₄ meets the first three criteria (pure, stable, high MM = 233.39 g mol⁻¹), it is essentially insoluble in water (Ksp ≈ 1.1 × 10⁻¹⁰). You cannot make a homogeneous solution of a known concentration from an insoluble substance.

❓ Multiple Choice

1. C — High molar mass means more grams per mole — a weighing error of 0.001 g is a smaller percentage of 204 g than of 40 g.

2. B — NaOH reacts with atmospheric CO₂ and absorbs water vapour, changing its composition and mass over time.

3. D — c₂ = (1.50 × 200) ÷ 600 = 300 ÷ 600 = 0.500 mol L⁻¹.

4. A — Adding water increases volume but adds no solute — moles are conserved, so n₁ = n₂, giving c₁V₁ = c₂V₂.

5. C — V₁ = (0.100 × 250) ÷ 2.00 = 25.0 ÷ 2.00 = 12.5 mL.

📝 Short Answer Model Answers

Q6 (4 marks):

(a) MM(KIO₃) = 39.098 + 126.90 + 3(15.999) = 39.098 + 126.90 + 47.997 = 213.995 g mol⁻¹ n = m ÷ MM = 1.070 ÷ 213.995 = 0.005000 mol V = 0.2500 L; c = 0.005000 ÷ 0.2500 = 0.02000 mol L⁻¹

(b) Any two of: high purity (available in reagent-grade form); stable in air (does not absorb CO₂ or water); high molar mass (214 g mol⁻¹ — minimises % weighing error); readily soluble in water.

Q7 (5 marks):

(a) V₁ = c₂V₂ ÷ c₁ = (0.0500 × 500) ÷ 9.80 = 25.0 ÷ 9.80 = 2.55 mL

(b) Using a pipette (or measuring cylinder), measure out 2.55 mL of concentrated H₂SO₄. Add this slowly to approximately 400 mL of distilled water in a large beaker — always add acid to water. Stir to mix and allow to cool. Transfer to a 500 mL volumetric flask, rinsing the beaker 3 times with distilled water. Make up to the calibration mark with distilled water using a dropper pipette. Stopper and invert to mix. The key piece of equipment is the volumetric flask, which ensures the volume is accurate to ±0.1 mL.

Q8 (4 marks):

(a) c₂ = (1.00 × 10.0) ÷ 50.0 = 0.200 mol L⁻¹ (b) After step 2: (0.200 × 10.0) ÷ 50.0 = 0.0400 mol L⁻¹ After step 3: (0.0400 × 10.0) ÷ 50.0 = 8.00 × 10⁻³ mol L⁻¹ (c) n = c × V = 8.00 × 10⁻³ × 0.0250 = 2.00 × 10⁻⁴ mol

Mark lesson as complete

Tick when you've finished all activities and checked your answers.

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