Honors Chemistry – Final Exam Review
Chapter 5: Periodic Law
Define the following terms:
periodicity, atomic number, periodic law, main group elements, atomic radius,
ionization energy, electron affinity, valence electrons, Electronegativity, lanthanides,
actinides, alkali metals, alkaline-earth metals, transition elements, halogens
Essential questions and content:
 Explain the role of Mendeleev in the development of the periodic table.
 Describe the organization of the modern periodic table.
 Describe how elements belonging to a group or period are related in terms of
the number of valence electrons or energy level that is being filled.
 Locate and describe the general properties of the alkali metals, the alkaline
earth metals, the transition metals, the halogens, and noble gases.
 Define ionization energy, electron affinity, and electronegativity.
 Describe and explain the trend in atomic radii, ionization energy, metallic
character, and electronegativity within a group or period on the periodic
table.
 Describe the differences in chemical behavior of elements as one proceeds
across a period or down a group.
 List and compare the properties of metals, metalloids, and nonmetals.
 Predict the charges on ions from the location on the periodic table.
Chapter 6: Chemical Bonding
Define the following terms:
chemical bond, ionic bonding, covalent bonding, nonpolar and polar covalent bonds,
bond length, bond energy, lattice energy, ionic compound, formula unit, crystal
lattice, delocalized electrons, metallic bonding, hybridization, intermolecular forces,
molecule, molecular compound, octet rule, unshared pair, single bond, double bond,
triple bond, resonance, malleability, ductility, VSEPR theory, dipole, dipole-dipole
forces, hydrogen bonding, London dispersion forces
Essential questions and content:
 Explain why bonds form
 Describe the nature of ionic and covalent bonds.
 Predict bond type using relative positions on the periodic table.
 Describe a polar covalent bond.
 Differentiate between ionic and covalent using the chemical formulas.
 Describe the arrangement of ions in a crystal lattice.
 List and explain the physical properties of ionic compounds.
 Draw Lewis diagrams for molecular substances.
 Differentiate between single, double, and triple covalent bonds.
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Define resonance and explain how it contributes to bond theory.
Explain VSEPR theory.
Use VSEPR theory to predict the shapes of molecules.
Explain how hybridization relates the shape of molecules to the orbitals
occupied by the electrons.
Predict the polarity of molecules
Describe the types of intermolecular forces of attraction: London dispersion,
dipole-dipole forces, and hydrogen bonds.
Predict the type of intermolecular force given the formula of the molecule.
Describe the electron-sea model of metallic bonding.
Give the characteristic properties of a metallic crystal.
Describe a covalent network solid and give the characteristic properties.
Classify the substance by bond type given the structure, formula, or physical
properties.
Predict and explain the physical properties of a substance given the bond
type.
Chapter 10: Physical Characteristics of Gases
Define the following terms:
ideal gas, elastic collisions, temperature, diffusion, effusion, real gas, pressure,
barometer, manometer, STP, partial pressure, kinetic molecular theory, absolute zero
Essential Question and Content:
 List the physical properties of a gas.
 Use the KMT to explain the physical properties of a gas.
 Explain what gas pressure is and how it is measured.
 State the standard conditions for temperature and pressure.
 Use Boyle’s Law to calculate volume and pressure changes at constant
temperature.
 Use Charles’ Law to calculate volume and temperature changes at constant
pressure.
 Use the Law of Gay-Lussac to calculate pressure and temperature changes at
constant volume.
 Use the combined gas law to correct the volume of a gas for a new pressure
and temperature.
 Apply Dalton’s Law of Partial Pressure to determine the pressure of a
mixture of gases or the partial pressure of a gas in a mixture.
Chapter 11: Molecular Composition of Gases
Define the following terms:
Avogadro’s Law, molar volume, ideal gas law, ideal gas constant
Essential Questions and Content:
 State Avogadro’s Law and explain its significance.
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Define the standard molar volume of a gas and use it to calculate gas mass
and volume.
State the ideal gas equation.
Derive the ideal gas constant and state its units.
Use the ideal gas equation to calculate the amount of gas at any condition of
temperature and pressure.
Use the ideal gas equation to calculate the molar mass of a gas given its
density.
Explain how Avogadro’s law applies to the volumes of gases in a chemical
reaction.
Apply the principles of stoichiometry to determine the volume of any gas that
is produced or consumed in a chemical reaction.
State graham’s law of effusion.
Determine the relative rate of effusion of two gases of known molar masses
using Graham’s Law.
Chapter 12: Liquids and Solids
Define the following terms:
surface tension, capillary action, vaporization, evaporation, boiling, freezing,
amorphous, unit cell, equilibrium, Le Chatelier’s Principle, equilibrium vapor
pressure, volatile liquid, normal boiling point, molar heat of vaporization, molar
heat of fusion, triple point, critical temperature, critical pressure, specific heat,
crystalline solids, melting point, supercooled liquids, condensation, sublimation,
deposition
Essential Questions and Content:
 List and compare the physical properties of liquids and solids.
 Explain the properties of liquids and solids according to the KMT.
 Describe the process by which solids change into liquids and liquids into
gases.
 Distinguish between amorphous and crystalline solids.
 Define crystal structure and unit cell.
 Explain the relationship between equilibrium and changes of state.
 Define Le Chatelier’s Principle.
 Predict the change in state using Le Chatelier’s principle
 Describe the energy changes that take place in processes of boiling, melting
and sublimation.
 Define what is meant by the vapor pressure of a liquid or solid.
 Explain the relationship between vapor pressure, volatility, boiling point, and
the strength of the forces holding particles together.
 Define the molar heat of vaporization and molar heat of fusion.
 Calculate the amount of heat energy absorbed or released when a given
quantity of substance changes state.
 Interpret a phase diagram.
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Explain the physical properties of water in terms of the intermolecular forces
that exist between molecules.
Chapter 13: Solutions
Define the following terms:
solution, soluble, homogeneous, heterogeneous, solute, solvent, suspension, colloid,
solution equilibrium, saturated solution, unsaturated solution, supersaturated
solution, solubility, hydration, miscible, immiscible, heat of solution, concentration,
molarity, molality, electrolyte, nonelectrolyte
Essential Questions and Content:
 Identify the types of solutions
 Describe the solution process in terms of the interaction between solute and
solvent.
 Distinguish between saturated, unsaturated, and supersaturated solutions.
 Describe the factors that affect solubility and the rate at which the solute
dissolves.
 Define molarity and calculate its value given the amount of solute in a given
volume of solution.
 Define molality and calculate its value given the amount of solute dissolved
in a given mass of solvent.
Chapter 14: Ions in Aq. Solutions and Colligative Properties
Define the following terms:
colligative property, freezing point depression, boiling point elevation
Essential Questions and Content:
 Describe the colligative properties of a solution.
 Calculate the freezing point depression or boiling point elevation of a
solution.
Chapter 17: Reaction Energy and Reaction Kinetics
Define the following terms:
heat, temperature, specific heat, heat of reaction, enthalpy, enthalpy change, molar
heat of formation, molar heat of combustion, entropy, free energy, reaction rate,
chemical kinetics, rate law, calorimeter, thermochemistry, reaction mechanism,
intermediates, collision theory, activation energy, activated complex, catalyst,, ratedetermining step
Essential Questions and Content:
 Distinguish between heat and temperature.
 Define the units of heat energy.
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Perform specific heat calculations.
Define the change in enthalpy as the heat of reaction at constant pressure.
Associate energy changes to the bond making and bond breaking processes
that occur in a reaction.
Differentiate between exothermic and endothermic reactions.
Label and interpret energy diagrams.
Use calorimetry data to determine the change in enthalpy.
Define the heat of formation and relate it to the stability of a compound.
Use Hess’s Law to determine the heat of reaction given appropriate data.
Explain the relationship between the enthalpy change and the tendency of a
reaction to occur.
Define entropy.
Calculate the change in entropy given the absolute entropy values.
Explain the relationship between entropy change and the tendency of a
reaction to occur.
Define the change in free energy.
Use the Gibbs equation to determine the change in free energy.
Relate the sign of ∆G to the spontaneity of a reaction.
Define the reaction mechanism
Interpret a reaction pathway using collision theory.
Define activation energy.
Draw and label energy diagrams showing the activation energy and the
activated complex.
Define the rate of reaction and describe how it can be determined.
List and explain factors which affect the rate of reaction.
Define a catalyst and describe how it can affect the rate of reaction.
Explain the rate law for a chemical reaction.
Determine the rate law for a chemical reaction given appropriate kinetics
data.
Discuss the relationship between the rate law and the reaction mechanism.