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HIGHER GRADE CHEMISTRY CALCULATIONS

HIGHER GRADE CHEMISTRY CALCULATIONS. Avogadro’s constant is the number of ‘elementary particles’ in one mole of a substance. It has the value of 6.02 x 10 23 mol -1 . Worked example 1. Calculate the number of atoms in 4 g of bromine. Avogadro and the Mole.

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HIGHER GRADE CHEMISTRY CALCULATIONS

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  1. HIGHER GRADE CHEMISTRY CALCULATIONS Avogadro’s constant is the number of ‘elementary particles’ in one mole of a substance. It has the value of 6.02 x 1023 mol-1. Worked example 1. Calculate the number of atoms in 4 g of bromine. Avogadro and the Mole.. Step 1:- Identify the elementary particles present  Br2 molecules 1 mole  6.02 x 1023 Br2 molecules Step 2:- Change from moles to a mass in grams 160g  6.02 x 1023 Br2 molecules Step 3:- Use proportion. 4 g  4/160 x 6.02 x 1023 Br2 molecules  1.505 x 1022 Br2 molecules Step 4:- Change from number of molecules to number of atoms. 1.505 x 1023 Br2 molecules  2 x 1.505 x 1022 Br atoms  3.01 x 1022 Br atoms

  2. Calculations for you to try. • How many atoms are there in 0.01 g of carbon? The elementary particles  C atoms. 1 mole  6.02 x 1023C atoms. 12 g  6.02 x 1023C atoms. So 0.01 g  0.01/12 x 6.02 x 1023C atoms.  5.02 x 1020 C atoms 2. How many oxygen atoms are there in 2.2 g of carbon dioxide? The elementary particles  CO2 molecules. 1 mole  6.02 x 1023CO2 molecules 44 g  6.02 x 1023CO2 molecules So 2.2 g  2.2/44 x 6.02 x 1023C atoms.  3.01 x 1022 CO2 molecules The number of oxygen atoms  2 x 3.01 x 1022  6.02 x 1022 O atoms Higher Grade Chemistry

  3. Calculations for you to try. • Calculate the number of sodium ions in 1.00g of sodium carbonate. The elementary particles  (Na+)2CO32- formula units 1 mole  6.02 x 1023(Na+)2CO32- formula units 106g  6.02 x 1023(Na+)2CO32- formula units So 1.00g  1.00/106 x 6.02 x 1023 (Na+)2CO32- formula units  5.67 x 1021 (Na+)2CO32- formula units The number of Na+ ions  2 x 5.67 x 1021  1.13 x 1022 Na+ ions 4. Calculate the number of protons in 0.1g of nitrogen gas? The elementary particles  N2 molecules. 1 mole  6.02 x 1023N2 molecules 28 g  6.02 x 1023N2 molecules So 0.1 g  0.1/28 x 6.02 x 1023N2 molecules  2.15 x 1021 N2 molecules The number of N atoms  2 x 2.15x 1021 The number of protons  7 x 2 x 2.21 x 1021  3.1 x 1022. Higher Grade Chemistry

  4. So 2.408 x 1022 O atoms mol of N2O4 0.01 mol 2.408 x 1022 2.408 x 1024 Calculations for you to try. 5. A sample of the gas dinitrogen tetroxide, N2O4, contained 2.408 x 1022oxygen atoms. What mass of dinitrogen tetroxide was present? The elementary particles  N2O4 molecules 1 mole  6.02 x 1023 N2O4 molecules 1 mole  4 x 6.02 x 1023 O atoms  2.408 x 1024 O atoms 1 mole of N2O4 92 g So 0.01 mole  0.92 g Higher Grade Chemistry

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