B1 Synthesis: Required Practicals and Exam Skills

You have now worked through the whole of Topic B1 of OCR Gateway Science A — cells, sub-cellular structures, microscopy, DNA, enzymes, respiration and photosynthesis. This final lesson pulls it all together. It revisits the required practicals as a set, drills the calculations that earn reliable marks (magnification, rate and the inverse-square law), highlights the command words OCR uses, and warns you about the misconceptions that catch students out. Treat it as a revision and exam-technique session rather than new content.

By the end you should be able to recall the B1 required practicals and their key techniques, perform every B1 calculation confidently, interpret command words, and avoid the most common B1 errors.

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How the B1 Topics Fit Together

It helps to see B1 as one connected system — from the smallest scale (DNA and enzymes) up to the cell-level processes that power life.

flowchart TD
  A["Cells<br/>(eukaryotic / prokaryotic)"] --> B["Sub-cellular structures<br/>+ specialised cells"]
  B --> C["DNA in the nucleus<br/>codes for proteins"]
  C --> D["Enzymes<br/>(proteins that catalyse reactions)"]
  D --> E["Respiration<br/>(releases energy from glucose)"]
  D --> F["Photosynthesis<br/>(makes glucose using light)"]
  E -.->|"glucose + oxygen"| F
  F -.->|"glucose + oxygen"| E

Notice the loop at the bottom: photosynthesis makes the glucose and oxygen that respiration uses, and respiration releases the carbon dioxide and water that photosynthesis uses. Enzymes (coded by DNA) control both. This big picture is exactly the kind of synoptic link that lifts an answer.

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The B1 Required Practicals at a Glance

Practical	What you change / measure	Key technique	Top marks come from
Using a light microscope	Observe and draw cells	Stain with iodine; lower coverslip slowly	Avoiding air bubbles; starting on low power; a labelled drawing with scale
Effect of pH on amylase	Change pH; measure time for starch to be digested	Iodine indicator (blue-black → orange/brown)	Keeping temperature constant; using $\frac{1}{\text{time}}$time1​ as the rate
Effect of light on photosynthesis	Change lamp distance; count O₂ bubbles	Pondweed + sodium hydrogencarbonate	Heat shield to control temperature; bubbles per minute as the rate

Exam Tip: For every practical, examiners reward identifying the independent variable (what you change), the dependent variable (what you measure) and the control variables (what you keep the same). For the amylase practical the control variable that scores most often is temperature.

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Mastering the B1 Calculations

Three calculation types recur in B1. Here is each one again, with a fresh worked example so you can check your method.

1. Magnification

$\text{magnification} = \frac{\text{image size}}{\text{actual size}}$magnification=actual sizeimage size​

Worked example: A chloroplast has an actual length of $5 \text{ }\mu\text{m}$5 μm. In a drawing it is $30 \text{ mm}$30 mm long. Find the magnification.

Convert to the same unit: $30 \text{ mm} = 30\,000 \text{ }\mu\text{m}$30 mm=30000 μm. Then:

$\text{magnification} = \frac{30\,000 \text{ }\mu\text{m}}{5 \text{ }\mu\text{m}} = 6000$magnification=5 μm30000 μm​=6000

Answer: $\times 6000$×6000.

2. Rate of reaction

$\text{rate} = \frac{\text{change in quantity}}{\text{time}}$rate=timechange in quantity​

Worked example: In a photosynthesis experiment $45 \text{ cm}^3$45 cm3 of oxygen is collected in $90 \text{ s}$90 s. Find the rate.

$\text{rate} = \frac{45 \text{ cm}^3}{90 \text{ s}} = 0.5 \text{ cm}^3/\text{s}$rate=90 s45 cm3​=0.5 cm3/s

Answer: $0.5 \text{ cm}^3/\text{s}$0.5 cm3/s.

3. Inverse-square law (Higher)

$\text{light intensity} \propto \frac{1}{d^{2}}$light intensity∝d21​

Worked example: At $15 \text{ cm}$15 cm the relative light intensity ($\frac{1}{d^{2}}$d21​) is $\frac{1}{15^{2}} \approx 0.00444$1521​≈0.00444. What is it at $30 \text{ cm}$30 cm?

$\frac{1}{30^{2}} = \frac{1}{900} \approx 0.00111$3021​=9001​≈0.00111

Comparing: $\dfrac{0.00444}{0.00111} = 4$0.001110.00444​=4. Doubling the distance ($15 \to 30$15→30) reduces the intensity to one quarter — the inverse-square law in action.

Exam Tip: Always show three lines — equation, substitution, answer with unit — and convert units first. Method marks are awarded for visible working even if the final number slips.

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Command Words You Will Meet in B1

OCR uses specific command words that tell you exactly what kind of answer to give. Reading them correctly is worth easy marks.

Command word	What it asks for
State / Name / Give	A short fact, no explanation (e.g. "Name the gas produced...")
Describe	Say what happens, in order, with no need for reasons (e.g. describe the trend on a graph)
Explain	Give reasons why — use "because", "so that", "this means that"
Compare	Give similarities and differences, ideally point-by-point
Calculate	Work out a number — show working and give a unit
Suggest	Apply your knowledge to an unfamiliar context

Exam Tip: The difference between describe and explain decides many marks. "The rate increases as temperature rises" describes; "...because the molecules have more kinetic energy and collide more often" explains. If the command word is explain, you must give the reason.

Reading graphs in B1

Several B1 topics are tested through graphs — enzyme rate against temperature or pH, and photosynthesis rate against light, CO₂ or temperature. A reliable routine for any graph question is:

1. Read the axes first — what is plotted against what, and in what units?
2. Describe the overall trend in words: does the line rise, fall, level off, or peak? Use comparative language ("rises steeply at first, then levels off").
3. Quote figures from the graph to support what you say (e.g. "the rate doubles from 10 °C to 20 °C") — this turns a description into an evidenced one.
4. If asked to explain, give the biology behind the shape (collisions, denaturation, a factor becoming limiting).

A line that rises then plateaus almost always means a limiting factor (or enzyme saturation). A line that rises to a peak then falls almost always means denaturation above an optimum. Recognising these two shapes instantly will earn marks across the topic.

Memory checklist — the facts to know cold

Use this as a final recall list. Cover the right-hand column and test yourself.

Prompt	Answer
Deciding feature of a eukaryotic cell	Has a nucleus (membrane-bound)
Site of aerobic respiration	Mitochondria
Site of photosynthesis	Chloroplasts (contain chlorophyll)
Base-pairing rule	A–T and G–C
Definition of a gene	Section of DNA that codes for a protein
Definition of the genome	The entire genetic material of an organism
Definition of an enzyme	Biological catalyst, speeds up reactions, not used up
Shape model for enzymes	Lock-and-key; substrate fits active site
Aerobic respiration equation	glucose + oxygen → carbon dioxide + water
Anaerobic in animals	glucose → lactic acid
Anaerobic in plants/yeast	glucose → ethanol + carbon dioxide
Photosynthesis equation	carbon dioxide + water → glucose + oxygen
Magnification equation	image size ÷ actual size

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Planning an Investigation: The Skills OCR Tests

Beyond the three named practicals, OCR expects you to be able to plan and evaluate an experiment in general. The same handful of ideas comes up again and again, so it is worth learning them as a checklist you can apply to any B1 practical: