Molar Volume of a Gas (Edexcel International A Level Chemistry)

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Core Practical 1: Measuring the Molar Volume of a Gas

Measuring gas volumes

  • The volume of gas produced in a reaction can be measured by collecting the gas with a gas syringe or by the displacement of water

gas-syringe

Gas syringe equipment for collecting the gas produced in a reaction

downward-displacement-gas-collection-blank

Displacement of water equipment for collecting the gas produced in a reaction

Sample method

  • For the reaction of hydrochloric acid and sodium carbonate

Na2CO3 (s) + 2HCl (aq) → 2NaCl (aq) + H2O (l) + CO2 (g)

  1. Measure out a fixed volume of hydrochloric acid, e.g. 25.0 cm3, into a conical flask
  2. Add a known mass of sodium carbonate, e.g. 0.05 g, to the conical flask
  3. Immediately connect the gas syringe delivery tube
  4. Allow the reaction to go to completion
  5. Record the volume of carbon dioxide produced
  6. Repeat the experiment with different masses of sodium carbonate, e.g. 0.10 g, 0.15 g, 0.20 g, 0.25 g... 0.50 g
  7. Some assumptions are made about the experiment:
    • The amount of gas lost between adding the sodium carbonate and connecting the delivery tube is negligible
    • The delivery tube set up is airtight so no gas is lost
    • The reaction does go to completion

Sample results

Mass Volume Results Table

mass-volume-results-table

  • The results are then plotted on to a graph
    • Mass of sodium carbonate on the x-axis and volume or carbon dioxide produced on the y-axis
  • Anomalous results are ignored and one straight line (or one smooth curve) of best fit is added

mass-volume-graph

Analysis

  • Read off the volume of gas produced for a sensible mass of sodium carbonate, e.g. 0.35 g produces 79.0 cm3 
    • The mass of sodium carbonate may be specified in an exam question

Na2CO3 (s) + 2HCl (aq) → 2NaCl (aq) + H2O (l) + CO2 (g)

  • From the reaction equation, one mole of sodium carbonate produces one mole of carbon dioxide
  • Calculate the molar mass of sodium carbonate 
    • (2 x 23.0) + 12.0 + (3 x 16.0) = 106.0
  • Calculate the number of moles of sodium carbonate, using the mass from your graph reading
    • Moles equals fraction numerator mass over denominator molar space mass end fraction equals fraction numerator 0.35 over denominator 106.0 end fraction equals0.0033 moles
  • Convert the volume of carbon dioxide from your graph reading from cm3 to dm3 
    • fraction numerator 79.0 space cm cubed over denominator 1000 end fraction= 0.079 dm3
  • Calculate the molar volume of gas produced:
    • Molar gas volume begin mathsize 14px style equals fraction numerator volume space over denominator moles end fraction equals fraction numerator 0.079 over denominator 0.0033 end fraction equals end style23.93 dm3 

mass-volume-graph-with-reading

Application

  • This experiment can be used to determine the identity of an unknown metal, M, in a metal carbonate, MCO3 
  • This process can be applied to thermal decomposition of metal carbonates as well as their reaction with acid

Worked example

At room temperature and pressure, 0.950 g of a Group 2 metal carbonate, MCO3, reacted with hydrochloric acid to produce 226.0 cm3 of carbon dioxide.

Deduce the identity of the metal M.

Answer:

Step 1: Find the number of moles of carbon dioxide released using the volume produced at room temperature and pressure:

    • number of moles of CO2 = fraction numerator volume space of space gas space open parentheses dm cubed close parentheses over denominator molar space gas space volume space open parentheses dm cubed close parentheses end fraction
    • n(CO2) = begin mathsize 14px style fraction numerator 0.226 over denominator 24 end fraction end style = 0.009417 mol

Step 2: Find the number of moles of metal carbonate, MCO3 

    • One mole of metal carbonate will release one mole of carbon dioxide
    • Number of moles of CO2 = number of moles of MCO3 
    • n(MCO3) = 0.009417 mol

Step 3: Calculate the molar mass of MCO3 

    • Mr = begin mathsize 14px style mass over moles end style
    • Mr = begin mathsize 14px style fraction numerator 0.950 over denominator 0.009417 end fraction end style  = 100.9 g mol-1 

Step 4: Calculate the atomic mass of M in MCO3 and deduction of the Group 2 metal

    • Mr = Σ(atomic masses)
    • 100.9 = M + 12.0 + (3 x 16.0)
    • M = 100.9 - 60.0 = 40.9 g mol-1 
    • The closest Group 2 atomic mass is calcium at 40.1 g mol-1, therefore the metal M is calcium

Examiner Tip

Careful: Examiners can write these questions to include the following distractions:

  • The molar mass of the metal carbonate / MCO3 is close to the mass of a Group 2 metal
    • The mass of the carbonate ion needs to be subtracted from the molar mass in order to deduce the identity of the metal
  • The atomic mass of the metal is close the atomic mass of another metal, not necessarily a Group 2 metal
    • Read the question as it will provide information about the metal 

The above points can be applied to any metal carbonate, not just Group 2 metal carbonates although they are the most common

Hazards, risks and precautions

  • The hazards associated with acids depend on the type and concentration of the acid
  • Most dilute acids either require no hazard symbol or they are an irritant, so require the symbol to show they are harmful to health
    • Eye protection should be worn when handling
  • Moderately concentrated acids are often corrosive
    • In addition to eye protection, gloves should also be worn
  • Some concentrated acids, e.g. nitric acid, are oxidising which can cause or intensify a fire in contact with combustible materials
    • Eye protection and gloves are necessary when handling concentrated acids and the use of a fume cupboard is often required

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Richard

Author: Richard

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Richard has taught Chemistry for over 15 years as well as working as a science tutor, examiner, content creator and author. He wasn’t the greatest at exams and only discovered how to revise in his final year at university. That knowledge made him want to help students learn how to revise, challenge them to think about what they actually know and hopefully succeed; so here he is, happily, at SME.