The Mole

2. The Mole

3. The Mole • A mole is defined as the number of particles in exactly 12g of Carbon-12. This number = 6.02 x 1023 particles. • 6.02 x 1023is called Avagadro’s Number after AmadeoAvagardro who determined the volume of 1 mol of gas in 1811 • Memorize this number: • 1 mol = 6.02 x 1023of something

4. The Mass of a Mole • Atomic Mass is the relative mass of single atom of an element in amu • Atomic masses on the periodic table can be used to determine molar masses. • Molar Mass is the mass of 1 mole of something in grams • If the atomic mass of carbon is 12.011 amu, then the molar mass of carbon is 12.011 g/mol • IN SHORT: The molar mass of any element is exactly equal to its atomic mass – just change the units

5. Moles of Compounds • In a mole of a chemical compound (molecule or formula unit), there is also one or more moles of each atom. • For example: • In 1 mol of CCl2F2 (Freon), there is: • 1 mol C • 2 mol Cl • 2 mol F • If you have 2 mol of MgCl2, there is: • 2 mol Mg • 4 molCl • (Multiply the coefficient x the subscript!)

6. The Mole: In Short • A mole is 6.02 x 1023of anything, just like a dozen is 12 of anything. • Atomic mass units (amu) is a way of comparing the sizes of different elements. • atomic mass in amu= molar mass in g

7. Using the Mole • You should be able to: • Convert Moles to Particles • Convert Particles to Moles • Convert Moles to Mass • Convert Mass to Moles • Convert Mass to Particles • Convert Particles to Mass • Determine percent composition • Determine empirical formula • Determine molecular formula • We are going to practice this a lot!!!!!

8. Preliminary: Moles to Mass of an Element • Determine the numbers of moles of each element in 1 mole of CaF2. • 1 mole of Ca • 2 mole of F • Determine the number of grams of each element in 1 molof CaF2. • 1 molCa x 40.1 g/mol = 40.1 grams Ca • 2 mol F x 18.9 g/mol = 37.8 grams F

9. Preliminary: Moles to Mass of Molecule • Determine the number of grams of each element in 1 molof CaF2. • 1 molCa x 40.1 g/mol = 40.1 grams Ca • 2 mol F x 18.9 g/mol = 37.8 grams F • What is the molar mass of CaF2? • 1 molCa + 2 mol F = 1 mole CaF2 • 40.1 g Ca + 37.8g F = 77.9 g CaF2

10. Preliminary: Mass of a Compound To find the mass of a compound, simply add up the molar mass of each of its atoms. For example, calculate the molar mass of CO2.

11. Reminders!! • Particles can mean: atoms, molecules, formula units, etc. • Covalent compounds = molecules • Ionic compounds = formula units • Use the factor-label method!!! • Learn how to multiply and divide with exponents on your calculator! (Check with me if you need help).

12. The Flow Chart Part Pieces Atoms Molecules Ions Etc. ÷ Avo’s # x Molar Mass Mass (g) Moles ÷ Molar Mass x Avo’s #

13. #1 Moles to Particles Determine the number of formula units in 4.3 moles of NaCl. • Multiply the number of moles by the appropriate conversion factor for Avogadro’s number. (Multiply by Avogadro’s #).

14. Practice: Moles to Particles • Determine the number of atoms in 2.50 mol Zn. • Determine the number of formula units (i.e., particles of an ionic compound) in 3.25 mol AgNO3. • Determine the number of molecules in 11.5 mol H2O.

15. Practice: Moles to Particles (x) • Determine the number of atoms in 2.50 mol Zn. • Determine the number of formula units (i.e., particles of an ionic compound) in 3.25 mol AgNO3. • Determine the number of molecules in 11.5 mol H2O. NOTE: DON’T FORGET SIGNIFICANT DIGITS!!! 1.51 x 1024 1.96 x 1024 6.92 x 1024

16. #2 Particles to Moles • How many moles are there in 5.64x1025 atoms of Fe? • Multiply the number of atoms by the appropriate conversion factor for Avogadro’s number. (Divide by Avogadro’s #).

17. Practice: Particles to Moles How many moles contain each of the following? • 5.75x1024 atoms of Al • 3.75x1024 molecules of CO2 • 3.58x1023 formula units of ZnCl2 • 2.50x1020 atoms of Fe • 3.4x1017 atoms of Na

18. Practice: Particles to Moles How many moles contain each of the following? • 5.75x1024 atoms of Al • 3.75x1024 molecules of Co2 • 3.58x1023 formula units of ZnCl2 • 2.50x1020 atoms of Fe • 3.4x1017 atoms of Na 9.55 mol 6.23 mol 0.594 mol 4.15x10-4 mol 5.64x10-7mol

19. Practice • WS #1 Moles to Particles

20. #3 Moles to Mass If you have 0.0450 mol of Cr, how many grams do you have? • Determine the molar mass of Cr from the periodic table: 52.00 g/mol (same number as the atomic mass) • Multiply the number of moles by the conversion factor. (Multiply by the molar mass).

21. Practice: Moles to Mass (x) Convert from moles to mass: • 3.57 mol Al • 42.6 mol Si • 3.45 mol Co • 2.45 mol Zn • 8.2 mol Pb

22. Practice Convert from moles to mass: • 3.57 mol Al • 42.6 mol Si • 3.45 mol Co • 2.45 mol Zn • 8.2 mol Pb 96.3 g 1.2 x 103 g 203 g 1.60 x 102 g 1.7 x 103 g

23. #4 Mass to Moles How many moles of Ca are in 525g of Ca? • Determine the molar mass of Ca from the periodic table: 40.08 g/mol • Multiply the given mass (525g) by the conversion factor. (Divide by the molar mass).

24. Practice: Mass to Moles Convert from mass to moles: • 25.5 g Ag • 300.0 g S • 125 g Zn • 99g O • 1.0 kg Fe

25. Practice: Mass to Moles Convert from mass to moles: • 25.5 g Ag • 300.0 g S • 125 g Zn • 99g O • 1.0 kg Fe 0.236 mol 9.355 mol 1.91 mol 6.2 mol 17.9 mol

26. Practice • WS #2 Mole to Mass • WS #3 Mixed One-Step Mole WS

27. Multi-Step Problems How many molecules are there in 24 g of FeF3? How many grams are there in 7.5 x 1023 molecules of AgNO3? Calculate the molar mass of AgNO3. Divide the number of molecules by Avogadro’s number. This gives you the number of moles. Multiply the number of moles by the molar mass. • Calculate the molar mass of FeF3 • Divide the mass you have by the molar mass. This gives you the number of moles. • Multiply the number of moles by Avogadro's number.

28. #5 Mass to Particles Calculate the number of atoms in a 25.0 g nugget of pure gold (Au). • Convert mass to moles (mass ÷ molar mass) • Convert moles to atoms (moles x 6.02 x 1023)

29. Practice: Mass to Particles • How many atoms are there in 14 g of C?

30. #6 Particles to Mass What is the mass of 5.50 x 1022 He atoms? • Convert atoms to moles (atoms ÷ 6.02 x 1023) • Convert moles to mass (moles x molar mass)

31. Practice: Particles to Mass • What is the mass of 7.6 x 1024 atoms of Ca?

32. Practice: Mass to Atoms and Atoms to Mass Convert to Atoms Convert to Mass 6.02 x 1024 atoms Bi 1.00 x 1024 atoms Mn 3.40 x 1022 atoms He 1.50 x 1015 atoms N 1.50 x 1015 atoms U • 55.2 g Li • 0.230 g Pb • 11.5 g Hg • 45.6 g Si • 0.120 kg Ti

33. Practice: Mass to Atoms and Atoms to Mass Convert to Atoms Convert to Mass 6.02 x 1024 atoms Bi 1.00 x 1024 atoms Mn 3.40 x 1022 atoms He 1.50 x 1015 atoms N 1.50 x 1015 atoms U • 55.2 g Li • 0.230 g Pb • 11.5 g Hg • 45.6 g Si • 0.120 kg Ti 4.79 x 1024 atoms 2.09 x 103 g 6.68 x 1020 atoms 91.3 g 3.45 x 1022atoms 0.226 g 9.77 x 1023atoms 3.49 x 10-8 g 1.51 x 1024 atoms 5.93 x 10-7 g

34. Practice • WS #4 Two-Step Mole Conversions • WS #5 Mixed Problems w/ Naming  • WS #6 Mixed Problems

35. Percent Composition by Mass • The percent composition by mass tells you what percent an element is out of a compound. • For example: • Hydrogen (H) is 11.2% of H2O by mass

36. The Steps: Percent by Mass • Find the molar mass of the elements in the compound. • Find the molar mass of the compound. • Divided the molar mass of each element by the molar mass of the compound and multiply by 100%. • (Make sure you multiply the mass of the element by the number of moles present in the compound)

37. Example: Find the percent composition of each of the elements in NaHCO3

38. Practice • Determine the percent by mass of each element in calcium chloride (CaCl2). • Calculate the percent by mass of each element in sodium sulfate (Na2SO4) • Calculate the percent composition of phosphoric acid (H3PO4).

39. Practice • Determine the percent by mass of each element in calcium chloride (CaCl2). • Ca = 36.11%, Cl = 63.89% • Calculate the percent by mass of each element in sodium sulfate (Na2SO4) • Na = 32.37%, S = 22.58%, O = 45.05% • Calculate the percent composition of phosphoric acid (H3PO4). • H= 3.08%, P = 31.61%, O = 65.31%

40. Practice: Percent Composition • WS #7 Percent Composition by Mass • WS #8 Percent Composition Hard

41. Molecular Formula vs. Empirical Formula • A molecular formula indicates the actualnumber of elements in a covalent compound. • We call the mass (in amu) of the molecular formula the molecular mass. • Remember: we can convert molecular mass to molar mass by simply changing the units (amu g/mol). • The empirical formula for a molecule is the smallest whole-number ratio of the elements. It may or may not be the same as the molecular formula. • We call the mass (in amu) of the empirical formula the formula mass. • Remember: we can convert the formula mass to a molar mass simply by changing the units (amu g/mol).

42. A Few Key Conceptual Points: • The molecular formula can be the same as or different from the empirical formula. • Ionic compounds ONLY have empirical formulas (lowest whole number ratios) because of their crystal lattice structure. • Only covalent compounds can have molecular formulas that differ from their empirical formulas. • For covalent compounds, it is the molecular formula that occurs in real life.

43. Example: Empirical vs. Molecular • The molecular formula for glucose (a product of photosynthesis) is C6H12O6. • The empirical formula is CH2O. • The molecular formula for glucose is 6 times the empirical formula.

44. 2 New Skills to Learn • How to calculate empirical formula from percent composition. • How to calculate molecular formula from empirical formula and molar mass.

45. #1 Calculating Empirical Formula from Percent Composition • Assume you have a 100 g sample and convert your percentages to masses. • Divide the masses that you have from step #1 by their molar masses to determine the mole ratios. • Calculate the simplest ratio by dividing each mole amount from #2 by the smallest mole amount that you calculatedfrom #2. • Convert to the smallestwhole-numberratio by multiplying all molar amounts by a common multiple. (No parts of atoms rule).

46. Example: Calculating Empirical Formula from Percent Composition • Example: Imagine that you know the percent composition of a compound, ethane. • Problem: Determine the empirical formula from the percent composition: • C = 79.9% • H = 20.1%

47. The Steps • Assume you have 100 g • 79.9% C = 79.9g C and 20.1% H = 20.1g H • Divide the mass of each element by its molar mass. • (79.9g ÷ 12.01 g/mol) = 6.65 mol • (20.1g ÷ 1.01g/mol) = 19.9 mol • Divide the molar amounts from step 2 by the smallest molar amount (6.65 mol). • (6.65 mol C ÷ 6.65 mol) = 1 C • (19.9 mol H ÷ 6.65 mol) = 3 H • Determine the ratio of elements and convert to whole numbers by multiplying by a common multiple if necessary. • Therefore, the empirical formula for ethane is CH3

48. Practice: Empirical Formula from Percent Composition • Determine the empirical formula for the following compounds based on the percent composition given. • 36.84% nitrogen, 63.16% oxygen • 35.98% aluminum, 64.02% sulfur • 81.82% carbon, 18.18% hydrogen N2O3 Al2S3 C3H8

49. Skill 2: Molecular Formula from Empirical Formula • A covalent compounds molecular formula is some integer multiple of the empirical formula. • i.e., Molecular formula = n(empirical formula) • Where n= natural numbers (1, 2, 3, etc.) • The molecular formula is found by comparing the ratio of the molecular mass to the formula mass.

50. Example • Molecular mass of acetylene = 26.04 amu • Formula mass of acetylene = 13.02 amu • The ratio of molecular mass to formula mass: • (26.04 amu)/(13.02 amu) = 2 • Therefore: the molecular mass is 2x the formula mass, so the molecular formula has 2x the number of each elements found in the empirical formula.