Progression of Learning
G.2.a: Kinetic theory
G.2.a.i: Explains the macroscopic behaviour of a gas (e.g. compressibility, expansion, diffusion) using kinetic theory
Boyle's Law and Charles's Law
Diffusion
Temperature and Particle Motion
G.2.b: General gas law
G.2.b.ii: Determines the relationship between the pressure of a gas and its temperature when the number of moles of gas and the volume are kept constant
G.2.b.vi: Applies the mathematical relationship between the pressure, volume, number of moles and temperature of a gas (p1V1/n1T1 = p2V2/n2T2)
G.2.d: Dalton’s law
G.2.d.i: Explains qualitatively the law of partial pressures
G.2.d.ii: Applies the mathematical relationship between the total pressure of a mixture of gases and the partial pressures of the component gases (ptotal = ppA + ppB + ppC + …)
E.1.b: Interprets the energy diagram of a chemical reaction
E.3.a: Explains qualitatively the enthalpy change of substances during a chemical reaction
E.4.b: Determines the molar heat of a reaction using Hess’s Law or bonding enthalpies
R.1.i: Determines experimentally the factors that influence the reaction rate
R.1.a: Nature of the reactants
R.1.a.i: Explains the effect of the nature of the reactants on the reaction rate
R.1.b: Concentration
R.1.b.i: Explains the effect of the concentration of the reactants on the reaction rate
R.1.c: Surface area
R.1.c.i: Explains the effect of the surface area of reactants on the reaction rate
R.1.d: Temperature
R.1.d.i: Explains the effect of the temperature of the reactants on the reaction rate
R.1.e: Catalysts
R.1.e.i: Explains the effect of a catalyst on the reaction rate
Chemical Changes
Collision Theory
R.2.a: Describes the relationship between the concentration of the reactants and the reaction rate using algebraic expressions
R.2.b: Determines the effect of a variation in the concentration of a reactant on the reaction rate, using the related algebraic expression
CE.1.i: Explains qualitatively the state of dynamic equilibrium
Equilibrium and Concentration
Equilibrium and Pressure
CE.1.a: Temperature
CE.1.a.i: Explains the effect of a temperature change on a system’s state of equilibrium
CE.1.b: Pressure
CE.1.b.i: Explains the effect of a pressure change on a system’s state of equilibrium
CE.1.c: Concentration
CE.1.c.i: Explains the effect of a change in the concentration of a reactant or a product on a system’s state of equilibrium
CE.2.a: Predicts the direction of the shift in equilibrium of a system following a change in concentration, temperature or pressure
Diffusion
Equilibrium and Concentration
Equilibrium and Pressure
CE.2.b: Predicts the effects of a shift in equilibrium on the concentrations of reactants and products
Equilibrium and Concentration
Equilibrium and Pressure
Correlation last revised: 9/16/2020