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General Chemistry · Reactions & Bonding

Chemical Reactions, Balancing, and Bonding

Practise balancing chemical equations by adjusting coefficients until every atom is conserved, then build the combination reactions from your assignment — pairing each element set to its product, its balanced equation, and its bond type (ionic or covalent).

Theory — Reactions, Balancing, and Bonding

Combination Reactions

In a combination (synthesis) reaction, two or more elements join to form a single compound. The ratio in which they combine is set by the charges (for ionic compounds) or the shared electrons (for covalent compounds). For example, calcium and oxygen combine to form calcium oxide, CaO.

Balancing Equations

A balanced equation has the same number of each kind of atom on both sides — mass is conserved. We balance by placing coefficients in front of formulas; we never change subscripts, because that would change the substance. Remember that several elements occur as diatomic molecules: H₂, O₂, N₂, F₂, Cl₂, Br₂, I₂.

Example — Balancing skeleton:  __ H₂ + __ O₂ → __ H₂O
balanced:  2 H₂ + 1 O₂ → 2 H₂O

Left: H = 4, O = 2  ·  Right: H = 4, O = 2
Adjust coefficients only — never subscripts — until both sides match

Ionic vs Covalent Bonds

A metal + non-metal typically forms an ionic compound (electrons transferred, named with the metal then the non-metal as an -ide). Two non-metals form a covalent compound (electrons shared).

Ionic

Metal + non-metal. Electrons transferred. e.g. CaO, LiBr, MgF₂, ZnCl₂.

Covalent

Non-metal + non-metal. Electrons shared. e.g. NH₃, H₂O, CO.

Conservation

Atoms are neither created nor destroyed — coefficients make both sides equal.

CombinationProductBond type
Ca + OCaO (calcium oxide)ionic
N + 3HNH₃ (ammonia)covalent
2H + OH₂O (water)covalent
Mg + 2FMgF₂ (magnesium fluoride)ionic

Apparatus

The equipment a real reaction-types experiment uses. In the simulation these are modelled for you, but the readings correspond to what each instrument would measure.

holds samples
Test tube rack
Holds small-scale reactions to observe the reaction type.
reagent solutions
Reagent bottles
Provide the reactant solutions added drop by drop.
provides heat
Bunsen burner
Heats reactions and runs combustion and flame tests.
holds solutions
Beaker
For precipitation and acid-base demonstrations.
mixes solutions
Stirring rod
Mixes reactants to start and observe the change.
evaporates samples
Watch glass
Evaporates solutions to reveal solid products.

Instructions — Running the Virtual Experiment

This activity supports the Week 5 research lab. The simulation is for practice and to build understanding; your full research (element data, electronic configurations, periodic-table positions, and uses) is done as described in the assignment. Record your practice work and screenshots in your lab report.

Part 1 — Balancing Practice (Balancing tab)
1
Open Simulation → Balancing. For each skeleton equation, type whole-number coefficients into the boxes. The atom tally shows the count of each element on the left and right.
2
Adjust the coefficients until every element matches on both sides, then click Check. Record at least three balanced equations and a screenshot in your report.
Part 2 — Combination Reactions (Reactions tab)
1
Open Reactions. Select each element pair from your assignment (for example Ca with O). The panel shows the product name and formula, the balanced equation, and whether the bond is ionic or covalent.
2
For each pair, record the product name, formula, balanced equation, and bond type. Use these to confirm your own research results, and include the names, atomic numbers, electronic configurations, periodic-table positions, and uses in your written lab report as described in the assignment.

Simulation — Balancing and Combination Reactions

Reactions & Bonding Virtual LabBalance equations, then build the combinations
Left side (reactants)
Right side (products)

Choose an equation

How to balance
Rulecoefficients only
GoalL = R for each atom
Diatomic elements: H₂ O₂ N₂ F₂ Cl₂ Br₂.
2 Ca + O₂ → 2 CaO
Ionic

Choose a combination

Product
ElementsCalcium + Oxygen
Compoundcalcium oxide
FormulaCaO
Bond typeionic
Use: refractories, cement, and as a drying agent.

Team Questions

Question 1. Balance: __ H₂ + __ O₂ → __ H₂O. Type the three coefficients in order, separated by commas (e.g. 2,1,2).
Question 2. When calcium (one mole) combines with oxygen (one mole), what is the formula of the product? (Type it — e.g. CaO)
Question 3. Is the bond in NH₃ (from N + 3H) ionic or covalent? (Type ionic or covalent)
Question 4. Balance: __ Al + __ Cl₂ → __ AlCl₃. Type the three coefficients (e.g. 2,3,2).
Question 5. Magnesium combines with fluorine (Mg with 2F). What is the product formula? (Type it)
Question 6. When you balance an equation, are you allowed to change the subscripts in a formula? (Type yes or no)
Question 7 — Challenge. Element X is a metal and element Y is a non-metal. Would the compound they form most likely be ionic or covalent? (Type ionic or covalent)

Example Lab Report

This is a research lab. The sample below shows the expected format for one combination; in your full report, work through each element set as described in the assignment, including names, atomic numbers, electronic configurations, periodic-table positions, particle counts, balanced equations, and uses.

Chemical Reactions and Activity Series

Chemistry | Section: [Your Section] | Date: [Date]

Lab Members: [Names of all members present]

Title

Combination reactions of element pairs: products, balanced equations, bonding, and uses.

Method

For each element set, information was researched from reputable chemistry references on the web. The virtual lab was used for practice — balancing equations and confirming products and bond types. Screenshots of the practice simulation are included where relevant.

Results and Calculations (worked example: Ca with O)

Elements: Calcium (Ca) and Oxygen (O).

Calcium: atomic number 20, atomic mass 40.08, Group 2, Period 4; electronic configuration 2, 8, 8, 2; 20 protons, 20 electrons, 20 neutrons (in Ca-40).

Oxygen: atomic number 8, atomic mass 16.00, Group 16, Period 2; electronic configuration 2, 6; 8 protons, 8 electrons, 8 neutrons (in O-16).

Compound formed: calcium oxide, CaO (ionic — metal + non-metal).

Balanced equation:  2 Ca + O₂ → 2 CaO

Uses: calcium oxide (quicklime) is used in cement and mortar, in steelmaking, and as a drying agent.

Discussion / Conclusions

Each combination pairs the elements in the ratio set by their combining capacities, and the balanced equations confirm conservation of mass. Ionic products formed between metals and non-metals (e.g. CaO, LiBr, MgF₂, ZnCl₂), while covalent products formed between non-metals (e.g. NH₃, H₂O, CO). The compounds have wide practical uses — for instance ammonia in fertilisers, water as a universal solvent, and zinc chloride as a soldering flux.

Practice Questions

Show all work. Remember diatomic elements (H₂, O₂, N₂, F₂, Cl₂, Br₂) and balance with coefficients only.

Question 1
Balance: N₂ + H₂ → NH₃. Give the coefficients and state the bond type of the product.
Hint: 1, 3, 2; NH₃ is covalent (two non-metals).
Question 2
Lithium combines with bromine. Write the product formula and the balanced equation, and classify the bond.
Hint: LiBr; 2Li + Br₂ → 2LiBr; ionic.
Question 3
Zinc combines with chlorine (Zn with 2Cl). Write the formula, balanced equation, and one use of the product.
Hint: ZnCl₂; Zn + Cl₂ → ZnCl₂; used as a soldering flux / wood preservative.
Question 4
Explain why we may change coefficients but never subscripts when balancing an equation.
Hint: changing a subscript changes the identity of the substance.
Question 5
Carbon combines with oxygen in a 1:1 mole ratio. Write the product formula and balanced equation, and state the bond type.
Hint: CO; 2C + O₂ → 2CO; covalent.
Question 6 — Challenge
Iron combines with oxygen to form iron(II) oxide. Write the balanced equation, then explain how the equation would differ if iron(III) oxide (Fe₂O₃) formed instead.
Hint: 2Fe + O₂ → 2FeO; for Fe₂O₃ it is 4Fe + 3O₂ → 2Fe₂O₃.