IB Science — Grade 9 & 10 — Study Booklet

Your path to
medicine
starts here.

A full study booklet covering Biology and Chemistry for Grade 9 and 10. Built bite-size for 1-hour daily sessions. You've got this.

● Biology G9 + G10 ● Chemistry G9 + G10 ⚕ Pre-Med Track
4
Subject Areas
20+
Topics Covered
1h
Daily Sessions
HL
DP Target Level
Scroll to begin
Daily Schedule

Your bite-size
study plan

One hour a day. Alternating between Bio and Chem. Each session has a clear focus — start, do, done. No overwhelm.

Week 1–2
Cell Biology Foundations
  • Prokaryotes vs Eukaryotes
  • Cell organelles
  • Cell membrane
  • Diffusion & Osmosis
Biology · 2×30min blocks
Week 1–2
Atomic Structure
  • Protons, neutrons, electrons
  • Atomic & mass number
  • Electron shells
  • Periodic table
Chemistry · 2×30min blocks
Week 3–4
Cell Division & Genetics
  • Mitosis & cell cycle
  • Cancer
  • DNA structure
  • Genes & alleles
Biology · 2×30min blocks
Week 3–4
Bonding & Reactions
  • Ionic & covalent bonding
  • Naming compounds
  • Types of reactions
  • Balancing equations
Chemistry · 2×30min blocks
"The science of today is the technology of tomorrow — and the medicine of next decade."
You chose to care about this. That already makes you different.
Biology — Grade 9 G9
Topics to cover
01
Cell Biology
~3 sessions
02
Genetics & Heredity
~3 sessions
03
Body Systems
~4 sessions
Bio G9 · Lesson 01

Cell Biology

Every living thing is made of cells — the smallest unit of life. In IB biology, your first big job is understanding the difference between the two fundamental cell types.

Prokaryotic cells (like bacteria) have no membrane-bound nucleus. Their DNA floats freely in the cytoplasm. They are small (1–10 µm) and were the first life on Earth.

Eukaryotic cells (like yours) have a nucleus surrounded by a membrane. They contain organelles — specialised compartments each with a job. Animal, plant, and fungal cells are all eukaryotic.

The fluid mosaic model describes the cell membrane: a phospholipid bilayer with proteins embedded throughout. It controls what enters and leaves the cell.

Movement across membranes happens three ways: diffusion (passive, high to low), osmosis (water across a semi-permeable membrane), and active transport (against the gradient, uses ATP).

The cell cycle has three phases: Interphase (G1, S, G2), Mitosis, and Cytokinesis. Mitosis produces two identical daughter cells. When this process goes wrong — cancer can form.

Key facts to memorise
  • Mitochondria = powerhouse (ATP via aerobic respiration)
  • Ribosomes = protein synthesis (only organelle in prokaryotes)
  • Cell wall: present in plants, fungi, bacteria — NOT in animal cells
  • Osmosis = movement of water from high water potential to low
  • Stem cells are undifferentiated — they can become specialised
  • Benign tumour = doesn't spread; Malignant = metastasises
Diagram — Prokaryote vs Eukaryote
PROKARYOTE EUKARYOTE DNA No nucleus Ribosomes Flagellum Nucleus Mito. ER vacuole
Diagram — Fluid Mosaic Membrane
channel protein carrier head tail tail head Phospholipid Bilayer — Fluid Mosaic Model
🧠
ADHD Focus Tip — Cell Biology
Draw the cell from memory after reading. Don't look. Even a rough sketch activates recall far better than re-reading. Set a 10-minute timer: read → close → draw → check. That's one session done.
Quiz

Test: Cell Biology

Q1 / 5Multiple Choice
Which of the following is found in a prokaryotic cell but NOT a eukaryotic cell?
Q2 / 5Multiple Choice
Osmosis is best defined as:
Q3 / 5Multiple Choice
What makes a tumour malignant rather than benign?
Q4 / 5Multiple Choice
The fluid mosaic model describes the cell membrane as:
Q5 / 5Short Answer
Explain why active transport requires ATP but diffusion does not.
Progress0 / 5
Cell Biology Quiz
Bio G9 · Lesson 02

Genetics & Heredity

DNA (deoxyribonucleic acid) is the molecule of inheritance. It forms a double helix — two strands wound around each other, held together by base pairs. The bases are: Adenine–Thymine (A-T) and Cytosine–Guanine (C-G). Remember: A pairs with T, C pairs with G.

A gene is a section of DNA that codes for a protein. The different versions of a gene are called alleles. Alleles can be dominant (expressed even with one copy, written as capital) or recessive (only expressed with two copies, written as lowercase).

Your genotype is the alleles you carry (e.g. Bb). Your phenotype is the physical trait expressed (e.g. brown eyes). If both alleles are the same = homozygous. If different = heterozygous.

Punnett squares predict the probability of offspring genotypes and phenotypes. In codominance, both alleles are expressed equally (e.g. blood type AB). Sex-linked traits are carried on the X chromosome — more common in males (XY) than females (XX).

Mutations are changes in the DNA sequence. They can be spontaneous or caused by mutagens (UV radiation, certain chemicals). Not all mutations are harmful — some are neutral, and occasionally beneficial.

Key terms to know
  • Homozygous dominant: AA — Heterozygous: Aa — Homozygous recessive: aa
  • Punnett square: cross parents' alleles to find offspring ratios
  • 3:1 phenotype ratio in monohybrid cross of two heterozygotes
  • Chromosomes come in homologous pairs (23 pairs in humans)
  • Sex chromosomes: Female = XX, Male = XY
  • Codominance: both alleles visible (e.g. roan coat in cattle)
Diagram — DNA Structure & Punnett Square
DNA DOUBLE HELIX A — T C — G T — A G — C A — T C — G T — A 5' end 3' end PUNNETT SQUARE (Bb × Bb) B b B b BB Bb Bb bb Brown (dominant) Blue (recessive) 3 Brown : 1 Blue phenotype ratio
Quiz

Test: Genetics & Heredity

Q1 / 4Multiple Choice
In DNA, which base pairs with Adenine (A)?
Q2 / 4Multiple Choice
Two heterozygous brown-eyed parents (Bb × Bb) have children. What fraction are expected to have blue eyes (bb)?
Q3 / 4Multiple Choice
A woman with blood type AB has children with a man with blood type O. This is an example of:
Q4 / 4Short Answer
Explain why sex-linked recessive conditions like colour blindness are more common in males than females.
Progress0 / 4
Genetics Quiz
"ADHD isn't a deficit of attention — it's a surplus of it, waiting for the right subject. You found yours."
Keep going. One topic at a time.
Biology — Grade 10 G10
Topics to cover
04
DNA & Molecular Biology
~3 sessions
05
Evolution & Ecology
~3 sessions
06
Plant Biology
~2 sessions
Bio G10 · Lesson 04

DNA & Molecular Biology

At G10 level, you go deeper into how DNA actually works. Transcription converts DNA into mRNA in the nucleus. Translation reads the mRNA at ribosomes to build proteins from amino acids.

The genetic code is a triplet code — every three bases (a codon) codes for one amino acid. There are 20 amino acids and 64 possible codons, so the code is degenerate (multiple codons for the same amino acid).

DNA replication is semi-conservative: each new DNA molecule contains one old strand and one new strand. The enzyme helicase unwinds the double helix; DNA polymerase adds new complementary bases.

Proteins are central to biology — enzymes, hormones, antibodies, and structural proteins. The shape of a protein determines its function. Enzymes are biological catalysts: they lower activation energy, have an active site complementary to their substrate, and are affected by temperature and pH.

Key facts
  • DNA → (Transcription) → mRNA → (Translation) → Protein
  • Transcription happens in the NUCLEUS
  • Translation happens at RIBOSOMES in cytoplasm
  • Enzyme + Substrate → Enzyme-Substrate Complex → Products
  • Lock and key model: specific substrate fits specific active site
  • Induced fit model: active site changes shape slightly to fit substrate
  • Denaturing = permanent shape change of enzyme at extreme temp/pH
Diagram — Transcription & Translation
NUCLEUS DNA Template Strand transcription mRNA (codons: AUG...) exits to cytoplasm CYTOPLASM Ribosome reads codons translation Polypeptide chain (protein) ENZYME-SUBSTRATE substrate active site
Quick memory trick — DNA to Protein
"DNA → mRNA → Protein" — think of it like a recipe: DNA is the original cookbook (stays safe in the nucleus), mRNA is the photocopy you take to the kitchen (cytoplasm), and the ribosome is the chef that follows the recipe to make a dish (protein).
Quiz

Test: DNA & Molecular Biology

Q1 / 3Multiple Choice
Where does translation take place?
Q2 / 3Multiple Choice
An enzyme is denatured when:
Q3 / 3Short Answer
Describe what happens during DNA replication. Name one enzyme involved.
Progress0 / 3
Molecular Biology Quiz
Chemistry — Grade 9 G9
Topics to cover
07
Atomic Structure
~2 sessions
08
Bonding & Compounds
~3 sessions
09
Reactions & Energy
~3 sessions
Chem G9 · Lesson 07

Atomic Structure

Everything is made of atoms. An atom has a nucleus (protons + neutrons) surrounded by electrons in shells. The number of protons = atomic number (Z). The total of protons + neutrons = mass number (A).

Isotopes are atoms of the same element with different numbers of neutrons (different mass number, same atomic number). For example, Carbon-12 and Carbon-14 are both carbon, but C-14 has 2 extra neutrons.

Electrons fill shells in order: shell 1 holds max 2, shell 2 holds max 8, shell 3 holds max 8 (at this level). The number of electrons in the outermost shell (valence electrons) determines reactivity and chemical behaviour.

The periodic table is arranged by increasing atomic number. Elements in the same group have the same number of valence electrons and similar properties. Periods (rows) correspond to number of electron shells.

Periodic trends: atomic radius decreases across a period (more protons pull electrons closer); ionisation energy increases across a period. Both reverse down a group.

Key facts
  • Proton: +1 charge, in nucleus | Neutron: 0 charge, in nucleus | Electron: –1 charge, in shells
  • Atomic number = number of protons = number of electrons (neutral atom)
  • Mass number = protons + neutrons
  • Isotopes: same element, different mass number
  • Group 1 = alkali metals (1 valence e⁻, very reactive)
  • Group 17 = halogens (7 valence e⁻, very reactive)
  • Group 18 = noble gases (full outer shell, very unreactive)
Diagram — Bohr Atom Models
HYDROGEN (H) p⁺ Z=1 · 1 electron CARBON (C) 6p⁺ 6n Z=6 · Config: 2,4 PERIOD TABLE SNIPPET H 1 He 2 Noble Li 3 Be 4 Group 1 Group 2 Group 18 P1 P2
Chem G9 · Lesson 08

Bonding & Compounds

Atoms bond to achieve a full outer electron shell (usually 8 — the octet rule). There are three main types of bonding in IB Chemistry.

Ionic bonding: a metal gives electrons to a non-metal. The metal becomes a positive ion (cation); the non-metal becomes a negative ion (anion). Electrostatic attraction holds the lattice together. Ionic compounds have high melting points, conduct electricity when dissolved or melted, and are usually solid at room temperature.

Covalent bonding: two non-metals share electron pairs. Can be single (sharing 1 pair), double (2 pairs), or triple (3 pairs) bonds. Covalent molecules generally have lower melting points and don't conduct electricity.

Metallic bonding: metal cations sit in a sea of delocalised electrons. This explains why metals conduct electricity and heat, are malleable, and have high melting points.

VSEPR theory predicts molecular shape based on the number of electron pairs around the central atom. Linear (CO₂), trigonal planar (BF₃), tetrahedral (CH₄), bent (H₂O).

Key comparisons
  • Ionic: metal + non-metal, electron TRANSFER, giant lattice
  • Covalent: non-metal + non-metal, electron SHARING, molecules
  • Metallic: metals only, delocalised electrons, lattice of cations
  • High melting point ≠ necessarily ionic (diamond is covalent, very high MP)
  • NaCl naming: sodium chloride (metal first, then -ide for non-metal)
Diagram — Types of Bonding
IONIC (NaCl) Na Cl e⁻ transfer electrostatic attraction Giant ionic lattice COVALENT (H₂O) O H H lone pairs bent shape (104.5°) shared electron pairs METALLIC M⁺ M⁺ M⁺ M⁺ M⁺ M⁺ M⁺ M⁺ M⁺ delocalised e⁻ (sea)
Quiz

Test: Atomic Structure & Bonding

Q1 / 4Multiple Choice
An element has atomic number 11 and mass number 23. How many neutrons does it have?
Q2 / 4Multiple Choice
Which type of bonding is present in NaCl (sodium chloride)?
Q3 / 4Multiple Choice
What explains why metals conduct electricity?
Q4 / 4Short Answer
State the electron configuration of Sodium (Na, Z=11) and explain why it is reactive.
Progress0 / 4
Chem G9 Quiz
"Every doctor who ever saved a life once struggled with the periodic table. You're exactly where you need to be."
Grade 9 is the foundation. HL Bio & HL Chem await — and you've got this.
Chemistry — Grade 10 G10
Topics to cover
10
The Mole & Stoichiometry
~3 sessions
11
Acids, Bases & Redox
~3 sessions
12
Organic Chemistry Intro
~2 sessions
Chem G10 · Lesson 10

The Mole &
Stoichiometry

The mole is the chemist's counting unit. 1 mole = 6.022 × 10²³ particles (Avogadro's number). This connects the microscopic world of atoms to measurable masses in the lab.

Molar mass (M) is the mass of one mole of a substance in g/mol. It equals the relative atomic/molecular mass from the periodic table. For example, 1 mol of H₂O = 18 g/mol.

The core formula: n = m / M (moles = mass ÷ molar mass). Master this — it comes up in every stoichiometry problem.

Stoichiometry uses balanced equations to calculate how much reactant you need or how much product you'll make. The coefficients in a balanced equation give mole ratios. The limiting reagent is the one that runs out first and determines how much product forms.

Percentage yield = (actual yield / theoretical yield) × 100%. Real reactions are rarely 100% efficient.

Key formulas
  • n = m / M (moles = mass ÷ molar mass)
  • n = c × V (moles = concentration × volume in litres)
  • Avogadro's number = 6.022 × 10²³ mol⁻¹
  • % yield = (actual/theoretical) × 100
  • % purity = (pure mass / total mass) × 100
  • Always balance the equation BEFORE calculating
Diagram — Mole Triangle & Stoichiometry Steps
THE MOLE TRIANGLE m (mass, g) n (moles) M (molar mass) Cover n → m÷M · Cover m → n×M STOICHIOMETRY STEPS STEP 1 Balance the chemical equation STEP 2 n = m / M for the known reactant STEP 3 Use mole ratio from equation STEP 4 m = n × M for the unknown e.g. 2H₂ + O₂ → 2H₂O: 2:1:2 mole ratio
🔢
ADHD Tip — Mole Calculations
Always write out n = m / M before plugging in numbers. Every. Single. Time. The formula is your anchor — it stops your brain from rushing ahead and making errors. Write the formula → identify what you know → solve. Three steps, done.
Chem G10 · Lesson 11

Acids, Bases &
Redox

Acids donate protons (H⁺ ions) to solution. Bases accept protons. This is the Brønsted-Lowry definition. The pH scale runs 0–14: acidic (pH <7), neutral (pH 7), basic/alkaline (pH >7). Each unit is 10× difference in concentration.

Strong acids (HCl, H₂SO₄, HNO₃) fully dissociate in water. Weak acids (ethanoic acid, carbonic acid) partially dissociate. The same applies for bases.

Acid + Base → Salt + Water (neutralisation). Acid + Metal → Salt + Hydrogen. Acid + Carbonate → Salt + Water + CO₂.

Redox reactions: Oxidation = loss of electrons; Reduction = gain of electrons. Remember: OIL RIG (Oxidation Is Loss, Reduction Is Gain). In every redox reaction, one species is oxidised while another is reduced simultaneously.

Oxidation state (or oxidation number) tracks electron changes. It helps identify what's oxidised and what's reduced in complex reactions.

pH & Redox essentials
  • OIL RIG: Oxidation Is Loss (of e⁻), Reduction Is Gain (of e⁻)
  • Reducing agent: loses electrons (gets oxidised)
  • Oxidising agent: gains electrons (gets reduced)
  • pH = −log[H⁺] — every unit change = 10× concentration change
  • Indicators: litmus (red/blue), universal (rainbow), phenolphthalein (clear/pink)
  • Buffer solutions resist change in pH — important for blood chemistry (medicine!)
Diagram — pH Scale & Redox
pH SCALE 012 345 67 8910 1112 ← ACIDIC NEUTRAL ALKALINE → HCl lemon vinegar pure H₂O baking soda NaOH blood (7.35-7.45) REDOX — ELECTRON TRANSFER Zn gets oxidised Cu²⁺ gets reduced 2e⁻ OIL: Loses electrons RIG: Gains electrons
Quiz

Test: Mole, Acids & Redox

Q1 / 4Multiple Choice
How many moles are in 36g of water (H₂O, molar mass = 18 g/mol)?
Q2 / 4Multiple Choice
In the reaction Mg + 2HCl → MgCl₂ + H₂, which species is oxidised?
Q3 / 4Multiple Choice
A solution with pH 3 compared to one with pH 5 is:
Q4 / 4Short Answer
Define "limiting reagent" and explain why it matters in stoichiometry calculations.
Progress0 / 4
Chem G10 Quiz
Your future

The DP Path
to Medicine

For IB DP → Medicine, you'll almost certainly need both HL Biology AND HL Chemistry. Here's exactly what that means and how to prepare from where you are now.

HL Biology — Required for Medicine
Why HL Bio?

Nearly every medical school worldwide requires HL Biology for IB students. It covers biochemistry, genetics, physiology, and ecology at a level that directly feeds into medical school curricula.

Topics you're building now (cell biology, DNA, genetics) are the exact foundations of HL Bio Units 1–4. Starting to love this content in Grade 9 is a real advantage.

→ Your G9 and G10 Biology directly prepares you for this.

HL Chemistry — Also Required
Why HL Chem?

HL Chemistry is required or strongly recommended for medicine. Pharmacology, biochemistry, and physiology are deeply chemical. Understanding how drugs work, how the body metabolises compounds, and how lab tests function all require strong chemistry.

Organic chemistry (which you'll start in G10) is especially important — the structure of drugs, amino acids, and metabolic molecules are all organic chemistry.

→ Your G9 and G10 Chem gives you the language you need.

Recommended Third HL
Maths AA or Psychology?

Most pre-med IB students take: HL Bio + HL Chem + HL Maths AA (Analysis & Approaches). Maths is required by many universities for science degrees.

If Maths is very difficult, HL Psychology is a strong alternative — it links well to medicine and is very manageable alongside HL Bio + Chem.

Starting from Grade 9
You're in the right place

Grade 9 is the ideal time to build the foundations. You don't need to be perfect now — you need to understand the core ideas, build study habits, and develop genuine interest.

Your 1-hour daily sessions, your curiosity, and your ambition toward medicine are all exactly what's needed. The students who succeed in HL Bio and Chem are the ones who started caring early. That's you.

"Medicine is a calling. And callings are never found — they're built, one study session at a time."
You studied today. That matters. Come back tomorrow.