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Lesson 24 Molecular Mass and Moles. Objectives: - The student will determine the molecular mass of a formula. - The student will convert between mass and moles for a formula.
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Lesson 24 Molecular Mass and Moles Objectives: - The student will determine the molecular mass of a formula. - The student will convert between mass and moles for a formula.
I. Molecular Mass a. The molecular mass of a formula is the mass of that formula expressed in grams per mole. b. This is calculated by adding up the masses of all of the elements contained in the formula for a compound. c. Example: H2O contains 2 hydrogen atoms and 1 oxygen atom. When we look on the periodic table, i. Oxygen = 16.00 g/mol ii. Hydrogen = 1.01 g/mol d. Therefore, 2 x 1.01 + 1 x 16.00 = 18.02 g/mol for water, or H2O.
e. Examples: f. If a formula contains parenthesis with subscripts following, the subscript should be multiplied through the parenthesis to calculate the number of atoms of each element g. Examples: Mg3(PO4)2
II. Conversion between mass and moles a. The conversion between mass and moles of a substance is accomplished using dimensional analysis. b. Use the molecular mass of the compound as the conversion factor – example: 18.02 g H2O / 1 mol H2O. Flip it upside down if needed to cancel units. i. If given grams: multiply by 1 mole/ molecular mass to convert to moles. ii. If given moles: multiply by molecular mass/ 1 mole to convert to grams.
III. Conversion between moles and particles a. The conversion between moles and number of particles ( atoms, molecules, or formula units) is also accomplished with dimensional analysis. b. Avagadro’s Principle states that there are 6.02 x 1023 particles in one mole. This is then becomes a conversion factor with Avagadro’s number and 1 mole as the two terms. c. The direction in which you are converting determines which goes on top.
IV. Conversion between mass and number of particles a. There is no direct conversion between mass and number of particles. b. This must be done through a two step process. c. First convert mass to moles as described in II above. d. Then convert moles to particles as described in III above.
Formula Mass Problems Level 1 1. Find the molecular mass of each of the following compounds. a. KClb. NaFc. HId. LiBre. RbBrf. BaCl2g. CaI2h. Na2Si. MgSj. AlP
2. Find the mass of each of the following, expressed in grams.a. 1.00 mol of CaOb. 1.00 mol of BeSec. 1.00 mol of KFd. 1.00 mol of SrOe. 2.00 mol of MgI2f. 2.00 mol of Li3Pg. 5.00 mol of CaCl2h. 0.50 mol of FeBr2i. 0.20 mol of Cu2Oj. 0.40 mol of Hg2Cl2
3. Find the amount of moles in each of the following masses.a. 18.02 g of H2Ob. 80.92 g of HBrc. 17.04 g of NH3d. 190.42 g of MgCl2e. 36.75 g of K2Sf. 25.38 g of SnI2g. 11.98g of FeOh. 15.0 g of KBri. 25.0 g of SrSj. 50.0 g of AlF3
Level 21. Find the molecular mass of each of the following compounds.a. HNO3b. Fe2O3c. H3PO4d. K2SO4e. Be5As2f. NH4NO3g. RbSO3h. Li2CO3i. Mg(OH)2j. Al2(SO4)3
2. Find the mass of each of the following, expressed in grams.a. 1.00 mol of HC2H3O2b. 2.50 mol of K2CrO4c. 0.50 mol of Ca(ClO3)2d. 0.25 mol of Ba(NO3)2e. 0.375 mol of Na2Cr2O7f. 0.25 mol of NaC2H3O2g. 0.152 mol of H3PO4h. 0.0582 mol of Li2SO4i. 0.418 mol of Fe(NO3)3j. 1.872 mol of Cu(C2H3O2)2
3. Find the amount of moles in each of the following masses.a. 100.00 g of CaCO3b. 100.00 g of Ni(NO3)2c. 50.00 g of C6H12O6d. 25.00 g of K3PO4e. 15.57 g of Bi(OH)3f. 3.50 g of AsCl3g. 0.572 g of Ca3P2h. 1.750 g of Ca(C2H3O2)2i. 4.904 g of Al(NO3)3j. 27.85 g of Fe3(PO4)2
4. Find the amount of formula units (particles) of each of the masses listed in question #3.a. 100.00 g of CaCO3b. 100.00 g of Ni(NO3)2c. 50.00 g of C6H12O6d. 25.00 g of K3PO4e. 15.57 g of Bi(OH)3f. 3.50 g of AsCl3g. 0.572 g of Ca3P2h. 1.750 g of Ca(C2H3O2)2i. 4.904 g of Al(NO3)3j. 27.85 g of Fe3(PO4)2