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Chapter 3 Stoichiometry: Calculations with Chemical Formulas and Equations

Chapter 3 Stoichiometry: Calculations with Chemical Formulas and Equations. Law of Conservation of Mass.

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Chapter 3 Stoichiometry: Calculations with Chemical Formulas and Equations

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  1. Chapter 3Stoichiometry:Calculations with Chemical Formulas and Equations

  2. Law of Conservation of Mass “We may lay it down as an incontestable axiom that, in all the operations of art and nature, nothing is created; an equal amount of matter exists both before and after the experiment. Upon this principle, the whole art of performing chemical experiments depends.” --Antoine Lavoisier, 1789

  3. 3.1 Chemical Equations Concise representations of chemical reactions.

  4. CH4 (g) + 2 O2 (g) CO2 (g) + 2 H2O (g) Anatomy of a Chemical Equation Reactants  Products “yield”

  5. The states of the reactants and products are written in parentheses to the right of each compound. (g) = gas, (s) = solid, (l) = liquid, (aq) = aqueous CH4 (g) + 2 O2 (g) CO2(g) + 2 H2O(g) Anatomy of a Chemical Equation

  6. Coefficients are inserted to balance the equation. CH4 (g) + 2 O2 (g) CO2(g) + 2 H2O(g) Anatomy of a Chemical Equation

  7. Subscripts and Coefficients Give Different Information • Subscripts tell the number of atoms of each element in a molecule • Coefficients tell the number of molecules

  8. 3.2 Patterns of Chemical Reactivity (Reaction Types)

  9. Examples: N2 (g) + 3 H2 (g) 2 NH3 (g) C3H6 (g) + Br2 (l)  C3H6Br2 (l) 2 Mg (s) + O2 (g)  2 MgO (s) Two or more substances react to form one product Combination (Synthesis) Reactions

  10. Examples: CaCO3 (s) CaO (s) + CO2 (g) 2 KClO3 (s)  2 KCl (s) + O2 (g) 2 NaN3 (s) 2 Na (s) + 3 N2 (g) One substance breaks down into two or more substances Decomposition Reactions

  11. Examples: CH4 (g) + 2 O2 (g) CO2 (g) + 2 H2O (g) C3H8 (g) + 5 O2 (g)  3 CO2 (g) + 4 H2O (g) Rapid reactions that produce a flame Most often involve hydrocarbons reacting with oxygen in the air Combustion Reactions

  12. Single Displacement • Double Displacement (Exchange, or Metathesis reactions)

  13. 3.3 Formula Weights

  14. Formula Weight (FW) • Sum of the atomic weights for the atoms in a chemical formula. • For example, the formula weight of calcium chloride, CaCl2, is Ca: 1 x (40.1 amu) + Cl: 2 x (35.3 amu) 111.1 amu • These are generally reported for ionic compounds. • Because ionic substances, such as NaCl, exist as three-dimensional arrays of ions (see Fig 2.23), it is not accurate to speak of molecules of NaCl. The term formula unit represents the chemical formula of the substance, i.e., NaCl. (one Na+ + one Cl-) • The formula weight of NaCl, CaCl2, or any ionic substance, is the mass of one formula unit.

  15. C: 2 x (12.0 amu) + H: 6 x (1.0 amu) 30.0 amu Molecular Weight (MW) • The sum of the atomic weights of the atoms in a molecule. • A molecule is an electrically neutral group of two or more atoms held together by chemical bonds. Molecules are distinguished from ions by their lack of electrical charge. • Molecular weight is also referred to as molecular mass. • For example, the molecular weight of ethane, C2H6, is: • The molecular weights of molecules can be determined by mass spectrometry.

  16. (number of atoms)(atomic weight) x 100 % element = (FW of the compound) Percent Composition • One can find the percentage of the mass of a compound that comes from each of the elements in the compound by using this equation:

  17. (2)(12.0 amu) %C = (30.0 amu) x 100 24.0 amu = 30.0 amu = 80.0% Percent Composition So the percentage of carbon in ethane is…

  18. 3.4 Avogadro’s Number and the Mole

  19. Avogadro’s Number • 6.022 x 1023 • 1 mole contains as many particles (atoms or molecules)as are in 12 grams of isotopically pure 12C.

  20. Molar Mass • By definition, this is the mass of 1 mol of a substance (i.e., g/mol) • The molar mass of an element is the mass number for the element that we find on the periodic table • The formula weight (in amu’s) will be the same number as the molar mass (in g/mol)

  21. Mole Relationships • One mole of atoms, ions, or molecules contains Avogadro’s number of those particles • One mole of molecules or formula units contains Avogadro’s number times the number of atoms or ions of each element in the compound

  22. Interconverting masses, moles and particles • Moles provide a bridge from the molecular scale to the real-world scale. • See sample exercise 3.12

  23. 3.5 Empirical Formulas from Analyses

  24. Calculating Empirical Formulas • One can calculate the empirical formula from the percent composition. • Empirical means “based on observation and experiment.” • Chemists use various experimental techniques, such as combustion analysis (pg 98 and Fig 3.12) to determine empirical formulas.

  25. Assuming 100.00 g of para-aminobenzoic acid, calculate number of moles of each element: C: 61.31 g x = 5.105 mol C H: 5.14 g x = 5.09 mol H N: 10.21 g x = 0.7288 mol N O: 23.33 g x = 1.456 mol O 1 mol 16.00 g 1 mol 14.01 g 1 mol 1.01 g 1 mol 12.01 g The compound para-aminobenzoic acid (you may have seen it listed as PABA on your bottle of sunscreen) is composed of carbon (61.31%), hydrogen (5.14%), nitrogen (10.21%), and oxygen (23.33%). Find the empirical formula of PABA.

  26. Calculate the mole ratio by dividing by the smallest number of moles: C: = 7.005  7 H: = 6.984  7 N: = 1.000 O: = 2.001  2 5.09 mol 0.7288 mol 0.7288 mol 0.7288 mol 5.105 mol 0.7288 mol 1.458 mol 0.7288 mol

  27. The mole ratios (rounded to whole numbers) become the subscripts for the empirical formula: C7H7NO2 • The mole ratios might have to be multiplied by a whole number to produce integer ratios. -- Ex: If the calculated mole ratios are 1, 2.5, 3, 2 multiply all by 2 to get the correct whole number mole ratio of 2, 5, 6, 4

  28. 3.6 Quantititave Information from Balanced Equations

  29. Stoichiometric Calculations • Stoichiometry: The study of the quantities of substances consumed and produced in a chemical reaction. • The coefficients in the balanced equation give the ratio of moles of reactants and products. • The concept of the mole allows us to convert this information into the masses of the substances.

  30. From the mass of Substance A you can use the ratio of the coefficients of A and B to calculate the mass of Substance B formed (if it’s a product) or used (if it’s a reactant)

  31. C6H12O6 + 6 O2 6 CO2 + 6 H2O • Ex: How many grams of water are produced by the combustion of 1.00 gram of glucose?

  32. Gas Stoichiometry • Solution Stoichiometry

  33. How Many Hamburgers Can I Make? 3.7 Limiting Reactants • You can make hamburgers until you run out of one of the ingredients. • Once you run out this ingredients you cannot make more hamburgers. • In this example the hamburger patty is the limiting reactant, because it will limit the number of hamburgers you can make. • The unused ingredients are excess.

  34. In chemistry, the limiting reactant (reagent) is the reactant present in the smallest stoichiometric amount • In other words, it’s the reactant you’ll run out of first. • For example, in this reaction the H2 is used up first.

  35. The O2 would be the excess reactant because some remains unreacted at the end of the reaction.

  36. Calculating the Amount of Product Formed from a Limiting Reactant • See sample exercise 3.18 • Assuming one reactant is completely consumed, calculate how much of the second reactant is needed. By comparing the calculated amount with the available amount, we can determine which is limiting. • Use the limiting reactant to determine the quantity of product possible.

  37. Theoretical and Actual Yields • The theoretical yield is the amount of product that is stoichiometrically calculated to be produced. • This is different from the actual yield, the amount of product actually produced and measured. • The percent yield is a comparison of the amount actually obtained to the amount it was possible to make: • See sample exercise 3.20.

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