How Much? The Amount of Chemical Change (DP IB Chemistry)

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  • True or False?

    A balanced chemical equation has the same number of atoms of each element on both sides.

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  • True or False?

    A balanced chemical equation has the same number of atoms of each element on both sides.

    True.

    A balanced chemical equation has the same number of atoms of each element on both sides, in accordance with the Law of Conservation of Mass.

  • What does a symbol equation use?

    A symbol equation uses the formulae of the reactants and products to show what happens in a chemical reaction.

  • What numbers are missing to balance this equation?

    .....H2O2 rightwards arrow .....H2O + ..... O2

    The missing numbers to balance the equation are:

    2H2O2 rightwards arrow 2H2O + O2

  • What are products?

    Products are the new substances which are on the right-hand side of the arrow in a chemical equation, formed by the reaction of reactants.

  • Write the symbol equation for the reaction of magnesium with chlorine to form magnesium chloride.

    The symbol equation for the reaction of magnesium with chlorine to form magnesium chloride is:

    Mg + Cl2 rightwards arrow MgCl2

  • True or False?

    The balanced symbol equation for the reaction of sodium with chlorine is:

    Na + Cl2 rightwards arrow NaCl2

    False.

    The balanced symbol equation for the reaction of sodium with chlorine is:

    2Na + Cl2 rightwards arrow 2NaCl

  • What numbers are missing to balance this equation?

    .....N2 + .....H2 .....NH3

    The missing numbers to balance the equation are:

    N2 + 3H2 2NH3

  • What is a state symbol?

    State symbols are used to specify the physical state of reactants and products in a chemical reaction.

  • True or False?

    When balancing equations, you should change the formulae of the compounds.

    False.

    When balancing equations, you should not change any of the formulae.

  • What do the following mean in a chemical equation?

    • (s)

    • (l)

    • (g)

    • (aq)

    In a chemical equation, the following mean:

    • (s) = solid

    • (l) = liquid

    • (g) = gas

    • (aq) = aqueous / dissolved in water.

  • Balance the following equation:

    .....Mg3N2 (s)  + .....H2O (l) → .....Mg(OH)2 (aq) + .....NH3 (aq)

    The balanced equation is:

    Mg3N2 (s)  + 6H2O (l) → 3Mg(OH)2 (aq) + 2NH3 (aq)

  • Write the balanced chemical equation for the thermal decomposition of calcium carbonate.

    The balanced chemical equation for the thermal decomposition of calcium carbonate is:

    CaCO3 (s)  → CaO(s) + CO2(g)

  • Balance the following equation:

    .....CO (g) + .....NO (g) → .....CO2 (g) + .....N2 (g)

    The balanced equation is:

    2CO (g) + 2NO (g) → 2CO2 (g) + N2 (g)

  • Write the balanced chemical equation for the formation of hydrogen chloride gas from its component elements.

    The balanced chemical equation for the formation of hydrogen chloride gas from its component elements is:

    H2 (g) + Cl2 (g) → 2HCl (g)

  • True or False?

    When completing reacting masses calculations, the mass unit (e.g. grams, tonnes) affects the calculation.

    False.

    When completing reacting masses calculations, the mass unit (e.g. grams, tonnes) does not affect the calculation.

    The mass unit only affects the final anwer as it must be given in the appropriate units.

  • What is the correct order of steps to complete a reacting mass calculation?

    1. Check the molar ratio in the equation.

    2. Determine the moles of the target chemical.

    3. Calculate the moles of the known chemical.

    4. Calculate the mass of the target chemical.

    5. Calculate relevant molar masses.

    6. Write a balanced symbol equation.

    The correct order of steps to complete a reacting mass calculation is:

    1. Write a balanced symbol equation.

    2. Calculate relevant molar masses.

    3. Calculate the moles of the known chemical.

    4. Check the molar ratio in the equation.

    5. Determine the moles of the target chemical.

    6. Calculate the mass of the target chemical.

  • Copper carbonate decomposes to form copper oxide and carbon dioxide.

    CuCO3 rightwards arrow CuO + CO2

    What is the molar ratio of copper carbonate to copper oxide?

    CuCO3 rightwards arrow CuO + CO2

    The molar ratio of copper carbonate to copper oxide is 1 : 1.

  • What mass of copper oxide can be formed from the thermal decomposition of 12.35 g of copper carbonate?

    CuCO3 rightwards arrow CuO + CO2

    CuCO3 rightwards arrow CuO + CO2

    12.35 g of copper carbonate = 12.35 / 123.5 = 0.1 moles.

    The molar ratio of copper carbonate to copper oxide is 1 : 1.

    So, 0.1 moles of copper oxide will be formed with a mass of 0.1 x 79.5 = 7.95 g.

  • Sodium chloride is formed from sodium and chlorine.

    2Na + Cl2 rightwards arrow 2NaCl

    What is the molar ratio of chlorine to sodium chloride?

    2Na + Cl2 rightwards arrow 2NaCl

    The molar ratio of chlorine to sodium chloride is 1 : 2.

  • What mass of sodium is required to form 11.7 g of sodium chloride?

    2Na + Cl2 rightwards arrow 2NaCl

    2Na + Cl2 rightwards arrow 2NaCl

    11.7 g of sodium chloride = 11.7 / 58.5 = 0.2 moles.

    The molar ratio of sodium to sodium chloride is 1 : 1.

    So, 0.2 moles of sodium chloride requires 0.2 moles of sodium with a mass of 0.2 x 23.0 = 4.6 g.

  • True or False?

    The masses of reactants in a reaction can be used to write a balanced equation for the reaction.

    False.

    The masses of reactants and products in a reaction can be used to write a balanced equation for the reaction.

  • How can the masses of the reactants and products be used to form a balanced chemical equation?

    How the masses of the reactants and products be used to form a balanced chemical equation:

    • Convert all masses to moles

    • Find the molar ratio of all chemicals

    • Simplify the molar ratio

    • Place these values in front of each chemical in the equation

  • True or False?

    3A + B rightwards arrow 2C + 2D

    The molar ratio of A : C is 2 : 3.

    False.

    3A + B rightwards arrow 2C + 2D

    The molar ratio of A : C is not 2 : 3.

    There are 3 moles of A and 2 moles of C, which means the ratio is 3 : 2.

  • What is the moles, mass, molar mass equation that is needed for reacting mass questions?

    The moles, mass, molar mass equation that is needed for reacting mass questions is:

    moles = mass / molar mass

  • 2Mg + O2 rightwards arrow2MgO

    How many moles of magnesium oxide can be produced from 6.0 g of magnesium?

    6.0 g of magnesium = 6.0 / 24 = 0.25 moles

    2Mg + O2 rightwards arrow2MgO

    The ratio of Mg : MgO is 1 : 1

    So, 0.25 moles of magnesium oxide can be produced from 6.0 g of magnesium.

  • 2Al2O3 rightwards arrow4Al + 3O2

    What is the maximum mass of aluminium that can be produced from 51 tonnes of aluminium oxide?

    Mr Al2O3 = 102

    Mr (Al2O3) = 102.

    Moles of aluminium oxide = 51 / 102 = 0.5.

    The ratio of Al2O3 : Al is 1 : 2.

    So, 0.5 moles of aluminium oxide will produce 1.0 moles of aluminium.

    So, the maximum mass of aluminum that can be produced is 27 tonnes.

  • Why should a chemical equation be balanced before performing reacting mass calculations?

    A chemical equation should be balanced before performing reacting mass calculations to ensure that the correct molar ratios are used in the calculations.

  • State the equation for molar gas volume using moles and volume.

    The equation for molar gas volume using moles and volume is:

    Molar gas volume = volume / moles

  • What are the conditions for standard temperature and pressure?

    The conditions for standard temperature and pressure are:

    • 0 oC / 273 K

    • 100 kPa

  • How do you calculate moles using volume and molar gas volume?

    The equation to calculate moles using volume and molar gas volume is:

    Moles = volume / molar gas volume

  • What volume does one mole of gas occupy at standard temperature and pressure?

    At standard temperature and pressure, one mole of gas occupies 22.7 dm3.

  • Complete the equation connecting moles, volume and molar gas volume.

    Volume =

    The equation connecting moles, volume and molar gas volume is:

    Volume = moles x molar gas volume

  • At STP, how much space, in dm3, does 1.5 moles of gas occupy?

    The amount of space, in dm3, that 1.5 moles of gas occupies is:

    • Volume = moles x molar gas volume

    • Volume = 1.5 x 22.7 = 34.05 dm3

  • True or False?

    To convert volume from dm3 to cm3, you multiply by 1000.

    True.

    To convert volume from dm3 to cm3, you multiply by 1000.

  • A cylinder contains 300 dm3 of gas. What is this volume in cm3?

    A 300 dm3 cylinder contains 300 000 cm3 of gas.

  • True or False?

    Avogadro’s Law states that equal amounts of gases occupy the same volume of space at the same temperature and pressure.

    True.

    Avogadro’s Law states that equal amounts of gases occupy the same volume of space at the same temperature and pressure.

  • How many moles of gas are in 68.1 dm3 at STP?

    There are 3 moles of gas in 68.1 dm3.

    moles = fraction numerator volume space open parentheses dm cubed close parentheses over denominator 22.7 end fraction space equals space fraction numerator 68.1 over denominator 22.7 end fraction =3

  • What volume would 2.5 moles of a gas occupy at STP?

    2.5 moles of gas will occupy 56.75 dm3 at RTP.

    • Volume (dm3) = moles x 22.7

    • Volume (dm3) = 2.5 x 22.7 = 56.75 dm3

  • What volume of ammonia is produced from 600 cm3 of hydrogen?

    N2 (g) + 3H2 (g) rightwards harpoon over leftwards harpoon  2NH3 (g)

    The volume of ammonia is produced from 600 cm3 of hydrogen is 400 cm3.

    N2 (g) + 3H2 (g) rightwards harpoon over leftwards harpoon  2NH3 (g)

    • hydrogen : ammonia = 3:2 ratio

    • volume of ammonia = 600 cm3 x 2 over 3 = 400 cm3

  • 250 cm3 of oxygen gas reacts with propane.

    Calculate the volume, in cm3, of carbon dioxide produced.

    C3H(g) + 5O2 (g) → 3CO(g) + 4H2O (g)

    If 250 cm3 of oxygen gas reacted reacted with propane, 150 cm3 of carbon dioxide is formed.

    C3H(g) + 5O2 (g) → 3CO(g) + 4H2O (g)

    • oxygen : carbon dioxide = 5:3 ratio

    • volume of carbon dioxide = 250 cm3 x 3 over 5 = 150 cm3

  • Calculate the volume, in cm3, of propane required to react with 500 cm3 oxygen.

    C3H(g) + 5O2 (g) → 3CO(g) + 4H2O (g)

    100 cm3 of propane was required to react with 500 cm3 oxygen.

    C3H(g) + 5O2 (g) → 3CO(g) + 4H2O (g)

    • propane : oxygen = 1:5 ratio

    • volume of propane = 500 over 5= 100 cm3

  • State the change in the number of gaseous moles for this reaction.

    4NH3 (g) + 5O2 (g) → 4NO (g) + 6H2O (l)

    The change in the number of moles of gas is 9 to 4 OR decreases by 5.

    4NH3 (g) + 5O2 (g) → 4NO (g) + 6H2O (l)

  • True or False?

    The molar volume of a gas depends on the type of gas.

    False.

    The molar volume of a gas is the same for all gases at STP (22.7 dm³ mol⁻¹).

  • What does the concentration of a solution refer to?

    Concentration refers to the amount of solid / solute there is in a specific volume of the liquid / solvent.

  • Using moles, volume in dm3 and concentration, complete the equation:

    Moles =

    Using moles, volume in dm3 and concentration, the equation is:

    Moles = concentration x volume

  • Calculate the number of moles of solute present in 2.0 dm3 of a solution whose concentration is 0.15 mol dm-3.

    To calculate the number of moles of solute present in 2.0 dm3 of a solution whose concentration is 0.15 mol dm-3:

    • Moles = concentration x volume

    • Moles = 0.15 x 2.0 = 0.3 moles

  • State the equation for concentration using moles and volume.

    The equation for concentration using moles and volume is:

    concentration = moles / volume

  • What is the concentration of a solution where 1.0 mole of solute is dissolved in 2.0 dm3 of water?

    The concentration of a solution where 1.0 mole of solute is dissolved in 2.0 dm3 of water is:

    • Concentration = moles / volume

    • Concentration = 1.0 / 2.0 = 0.5 mol dm-3

  • How do you calculate the volume of a solution using moles and concentration?

    The equation to calculate the volume of a solution using moles and concentration is:

    Volume = moles / concentration

  • What is volumetric analysis?

    Volumetric analysis is a process that uses the volume and concentration of one chemical reactant (a standard solution) to determine the concentration of another unknown solution.

  • Define the term titration.

    Titration is a technique used in volumetric analysis to determine the concentration of an unknown solution using a standard solution of known concentration.

  • What piece of equipment is used to measure a precise volume in a titration?

    A volumetric pipette is used to measure precise volumes in a titration.

  • True or False?

    In a titration, the indicator is added before any solutions are mixed.

    True.

    In a titration, a few drops of the indicator are added to the solution in the conical flask before adding the solution from the burette.

  • What is meant by concordant results in titration?

    Concordant results in titrations are multiple trials that yield very close or identical results, typically within 0.1 cm3.

  • What is a standard solution?

    A standard solution is a solution of accurately known concentration, used as a reference in volumetric analysis.

  • What is the formula for calculating concentration in mol dm-3?

    The formula for calculating concentration in mol dm-3 is:

    Concentration (mol dm-3) = moles / volume (dm3)

  • True or False?

    In concentration calculations, you always need to convert cm3 to dm3.

    True.

    In concentration calculations, you always need to convert cm3 to dm3 by dividing by 1000.

  • What is a back titration?

    A back titration is a technique used to find the concentration or amount of an unknown substance indirectly by reacting it with an excess of a known reactant and then titrating the excess.

  • Define the term monoprotic acid.

    A monoprotic acid is an acid that can donate one proton (H⁺ ion) per molecule in an aqueous solution.

  • Define limiting reactant.

    A limiting reactant is the reactant that is completely consumed in a chemical reaction and determines the amount of product formed.

  • What determines how much product can be formed in a reaction?

    The amount of product formed in a reaction is determined by the limiting reactant.

  • True or False?

    The limiting reactant is always the reactant with the smallest mass.

    False.

    The limiting reactant is not always the reactant with the smallest mass. It depends on the stoichiometry of the reaction.

  • When is a reactant in excess?

    A reactant is in excess when it is present in an amount greater than necessary to react with the limiting reactant.

  • State the steps to determine the limiting reactant.

    The steps to determine the limiting reactant are:

    1. Write the balanced equation for the reaction.

    2. Calculate the moles of each reactant.

    3. Compare the moles & deduce the limiting reactant.

  • True or False?

    There can be more than one limiting reactant in a reaction.

    False.

    There can only be one limiting reactant in a reaction.

  • What happens to the reactants in excess after the reaction is complete?

    After the reaction is complete, the reactants in excess remain unreacted.

  • How does the limiting reactant affect the yield of a reaction?

    The presence of a limiting reactant determines the maximum amount of product that can be formed, regardless of the amounts of other reactants present.

  • True or False?

    The limiting reactant is always completely consumed in a reaction.

    True.

    The limiting reactant is always completely consumed in a reaction.

  • What is an easy way to determine the limiting reactant?

    An easy way to determine the limiting reactant is:

    1. Find the moles of each substance.

    2. Divide by the coefficient in the equation.

    3. The lowest resulting number is the limiting reactant.

  • Define the term theoretical yield.

    Theoretical yield is the maximum amount of product that can be produced in a chemical reaction, calculated based on the limiting reactant.

  • What does percentage yield compare?

    Percentage yield compares the actual yield to the theoretical yield.

  • Define actual yield.

    Actual yield is the recorded amount of product obtained from a chemical reaction.

  • How is the actual yield determined?

    The actual yield can be determined by experiment only.

  • What is theoretical yield?

    Theoretical yield is the amount of product that would be obtained under perfect practical and chemical conditions.

  • What type of calculation lets you determine the theoretical yield?

    The type of calculation lets you determine theoretical yield is a reacting mass calculation.

  • State the equation for percentage yield.

    The equation for percentage yield is:

    (actual yield divided by theoretical yield) x 100

  • True or False?

    A high percentage yield is desirable for economic reasons.

    True.

    For economic reasons, the objective is to have as high a percentage yield as possible to increase profits and reduce costs and waste.

  • If the actual yield is 1.50 g and theoretical yield is 2.00g, what is the percentage yield?

    If the actual yield is 1.50 g and theoretical yield is 2.00g, the percentage yield is:

    (1.50 divided by 2.0) x 100 = 75%

  • True or False?

    A percentage yield of 100% is common in chemical reactions.

    False.

    A percentage yield of 100% is not common in chemical reactions.

  • What factors can reduce the percentage yield of a reaction?

    Factors that can reduce percentage yield include:

    • Incomplete reactions

    • Side reactions

    • Loss during processing

    • Reversible reactions.

  • What does a low percentage yield indicate about a reaction?

    A low percentage yield indicates that the reaction is inefficient, with significant loss of product or incomplete conversion of reactants.

  • How can percentage yield be improved in a chemical process?

    Percentage yield can be improved by optimizing reaction conditions, using catalysts, preventing side reactions, and improving separation and purification techniques.

  • What is atom economy?

    Atom economy is a measure of the efficiency of a chemical reaction in terms of how well reactants are utilised to produce useful products.

  • What information does atom economy give about a reaction?

    Atom economy tells us what percentage of the mass of reactants become useful products.

  • What is the atom economy of the following reaction?

    N2 (g) + 3H2 (g) ⇌ 2NH3 (g)

    The atom economy for N2 (g) + 3H2 (g) ⇌ 2NH3 (g) is 100% as there is only one product.

  • True or False?

    The higher the atom economy of a process then the more sustainable that process is.

    True.

    The higher the atom economy of a process then the more sustainable that process is

  • What is the atom economy for the production of CaO in the following reaction?

    CaCO3 → CaO + CO2

    Mr CaCO3 = 100, Mr CaO = 56, Mr CO2 = 44

    The atom economy for the production of CaO in the reaction is 56%.

  • How can the atom economy of a reaction be increased?

    The atom economy of a reaction can be increased by selling the by-products of the reaction.

  • What is the atom economy for the production of ethene?

    C2​H2​ + H2 ​→ C2​H4

    The atom economy for the production of ethene is 100%.

  • True or False?

    Higher atom economy indicates more waste generation.

    False.

    Higher atom economy means less waste production.

  • Why is waste reduction in chemical processes important?

    Waste reduction in chemical processes is important because it minimises environmental impact and is more sustainable.