Ch 7.1 Forming Ions

1. Ch 7.1 Forming Ions

2. Review… • Cations are Groups 1A, 2A, and 3A • They have positive charges. • Anions are Groups 5A, 6A, and 7A • They have negative charges • They end in “ide” • Majority of elements in Groups 4A and 8A do not usually form ions. • These are called monatomic ions!

3. Ions of Transition Metals • Some transition metals in Groups 1B-8B form more than one cation with different charges. • Examples: • Iron forms Fe2+ and Fe3+ • Two methods of naming: • Stock System: Iron (II) ion and Iron (III) ion • Classical name: Ferrous ion and Ferric ion *We will use the stock system.

4. Common Metal Ions with More than One Ionic Charge

5. Common Metal Ions with More than One Ionic Charge

6. Other Transition Metal Ions • Some transition metals have only one charge and do not use a Roman numeral. • Examples (Write on your periodic table!) • Silver: Ag+ • Cadmium: Cd2+ • Zinc: Zn2+

7. Polyatomic Ions • The names of most polyatomic anions end in “-ite” or “-ate” • The “-ite” ending indicates one less oxygen atom than the “-ate” ending • Remember to use parentheses if more than one is needed.

8. Writing a Formula Write the formula that will form between Ba and Cl Solution: 1. Write the positive ion of metal first, and then negative ion Ba2+Cl 2. Do the charges equal zero? NO!! 3. Use Criss-Cross method – write subscripts Ba2+ Cl1BaCl2

9. Learning Check Write the correct formula for the compounds containing the following ions: 1. Na+, S2- 2. Al3+, Cl- 3. Mg2+, N3- 4. Al3+, S2-

10. Solution 1. Na+, S2- Na2S 2. Al3+, Cl- AlCl3 3. Mg2+, N3- Mg3N2 4. Al3+, S2- Al2S3

11. Binary Compound: is composed of two elements and can be either ionic or molecular.

12. Naming Binary Ionic Compounds • To name a binary ionic compound, place the cation name first, followed by the anion name. • Remember the anion ends in “-ide” • Examples: • Cs2O • NaBr • CuO Cesium Oxide Sodium Bromide Copper(II) Oxide

13. Naming Compounds withPolyatomic Ions • State the cation first and then the anion just as you did in naming binary ionic compounds. • KNO3 • Mg(ClO2)2 Potassium Nitrate Magnesium Chlorite

14. Naming Binary Molecular Compounds • Binary molecular compound: must be composed of two nonmetals • Use prefixes to indicate the number and kind of atom in the compound • Use the following general format: 1st name: prefix + element name 2nd name: prefix + element name + “ide” If there is only 1 of the 1st element, no prefix.

16. Anyone want a cold glass of dihydrogen monoxide?

17. Examples • Name the following • CO • CO2 • N2O • Cl2O8 Carbon Monoxide Carbon Dioxide Dinitrogen Monoxide Dichlorine Octoxide

18. Writing Formulas for Binary Molecular Compounds • Use the prefixes in the name to tell you the subscript of each element in the formula. • Then write the correct symbols for the two elements with the appropriate subscripts. • The least electronegative element is written first • Dinitrogen Tetroxide - N2O4

19. Examples • Write formulas for the following: • Nitrogen Monoxide • Carbon Tetrachloride • Diphosphorous Pentoxide NO CCl4 P2O5

20. Naming Acids • An acid is a compound that contains one or more hydrogen atoms and produces hydrogen ions (H+) when dissolved in water. • All acids begin with hydrogen • General Format: HnX • “X” represents a monatomic or polyatomic anion. • “n” represents the number of hydrogen ions

21. 3 Rules for Naming Common Acids • If the name of “X” ends in -ate: ____________-ic acid • If the name of “X” ends in -ite: ____________-ous acid • If the name of “X” ends in -ide: hydro-__________-ic acid

22. Name these acids • H2SO4 • HCl • H2S • HNO3 • HClO2 Sulfuric Acid Hydrochloric Acid Hydrosulfuric Acid Nitric Acid Chlorous Acid

23. Writing Formulas for Acids • If the acid ends in –ic, then “X” ends in –ate • If the acid ends in –ous, then “X” ends in –ite • If the acid has hydro-______-ic, then “X” ends in –ide. • The subscript on hydrogen is equal to the charge of “X”.

24. Write the Formula for the Following Acids HBr • Hydrobromic Acid • Carbonic Acid • Phosphoric Acid • Sulfurous Acid H2CO3 H3PO4 H2SO3

25. Homework • 7.1 pg 251 #14, 15(a-d), 41 • Look at page 226 and 230 for help with acids.

26. Ch 7.3 Using Chemical Formulas

27. The Mass of a Mole of an Element • Molar Mass: is the atomic mass of an element expressed in grams/mole (g/mol). • Carbon = 12.01 g/mol • Hydrogen = 1.01 g/mol • When dealing with molar mass, round off to two decimals. 12.011 g/mol  12.01 g/mol

28. The Mass of a Mole of a Compound • You calculate the mass of a molecule by adding up the molar masses of the atoms making up the molecules. • Example: H2O • H = 1.01 g x 2 atoms = 2.02 g/mol • O = 16.00 g x 1 atom = 16.00 g/mol • Molar Mass of H2O = 2.02 g/mol + 16.00 g/mol = 18.02 g/mol • This applies to both molecular and ionic compounds

29. Find the molar mass of PCl3 • P = 30.97 g x 1 atom = 30.97 g/mol • Cl = 35.45 g x 3 atoms = 106.35 g/mol • PCl3 = 30.97 g + 106.35 g = 137.32 g/mol • What is the molar mass of Sodium Hydrogen Carbonate (NaHCO3) ? • Na = 22.99 g x 1 atom = 22.99 g/mol • H = 1.01 g x 1 atom = 1.01 g/mol • C = 12.01 g x 1 atom = 12.01 g/mol • O = 16.00 g x 3 atoms = 48.00 g/mol • NaHCO3 = 22.99 + 1.01 + 12.01 + 48.00 = 84.01 g/mol

30. Converting Moles to Mass • You can use the molar mass of an element or compound to convert between the mass of a substance and the moles of a substance. • Mass (g) = # of moles x mass (g) 1 mole Example: If molar mass of NaCl is 58.44 g/mol, what is the mass of 3.00 mol NaCl? Mass of NaCl = 3.00 mol x 58.44g = 1 1 mol 175 g NaCl

31. Example 2: Moles to Mass • What is the mass of 9.45 mol of Aluminum Oxide (Al2O3)? • Find molar mass of Al2O3 = 101.96 g/mol • Mass = 9.45 mol Al2O3x 101.96 g Al2O3 1 1 mol Al2O3 = 964 g Al2O3

32. Converting Mass to Moles • You can invert the conversion factor to find moles when given the mass. • Moles = mass (g) x 1 mole mass (g) Example: If molar mass of Na2SO4 142.05 g/mol, how many moles is 10.0 g of Na2SO4? Moles Na2SO4 = 10.0 g Na2SO4x 1 mol Na2SO4 = 1 142.05 g Na2SO4 = 0.0704 mol Na2SO4

33. Example 2: Mass to Moles • How many moles are in 75.0 g of Dinitrogen Trioxide? • Find molar mass of N2O3 = 76.02 g/mol • Moles = 75.0 g N2O3x 1 mole N2O3 = 1 76.02 g N2O3 N2O3 0.987 mol N2O3

34. Homework • 7.3 pg 253 #30-31

35. Percent Composition • Percent Composition: the relative amount of the elements in a compound. • Also known as the percent by mass • It can be calculated in two ways: • Using Mass Data • Using the Chemical Formula % mass of element= mass of element x100% mass of compound

36. Example • When a 13.60 g sample of a compound containing Mg and O is decomposed, 5.40 g O is obtained. What is the % composition of this compound? Mass of compound: 13.60 g Mass of oxygen: 5.40 g O Mass of magnesium: 13.60 g - 5.40 g = 8.20 g Mg % Mg = 8.20 g Mg x 100% = 13.60 g % O = 5.40 g O x 100% = 13.60 g 60.3% 39.7%

37. Find the percent composition of Cu2S. • Find mass of Cu and S • Cu = 63.55 x 2 = 127.10 g • S = 32.07 g • Find mass of Cu2S • 127.10 g + 32.07 g = 159.17 g % Composition • Cu = 127.10 g x 100% = 159.17 g • S = 32.07 g x 100% = 159.17 g 79.85% 20.15%

38. Find the percentage by mass of water in the hydrate Na2CO310H2O • Find the mass of 10H2O • H2O = 10 mol x 18.02 g/mol = 180.2 g • Find the mass of Na2CO310H2O • Na2CO3 = 1 mol x 105.99 g/mol =105.99 g • 105.99 g + 180.2 g = 286.2 g • % By Mass of Water • H2O = 180.2 g H2O x 100% = 286.2 g Na2CO310H2O 62.96%

39. Homework • 7.3 pg 253 #32-33, 47

40. Ch 7.4Determining Chemical Formulas

41. Empirical Formulas • Empirical Formula: shows the smallest whole-number ratio of the atoms of the elements in a compound. • Example: • The Empirical Formula for Hydrogen Peroxide (H2O2) is HO with a 1:1 ratio. • The Empirical Formula for Carbon Dioxide (CO2) is CO2 with a 1:2 ratio.

42. Determining the Empirical Formula of a Compound • A compound is found to contain 25.9% Nitrogen and 74.1% Oxygen. What is the Empirical Formula of the compound? • 25.9 g N x 1 mol N = 14.01 g N • 74.1 g O x 1 mol O = 16.00 g O • N1.85O4.63 = N1O2.5 = N2O5 1.85 mol N 4.63 mol O

43. Molecular Formulas • Molecular Formula: tells the actual number of each kind of atom present in a molecule of a compound • Example: • The Molecular Formula for Hydrogen Peroxide is H2O2. • The Molecular Formula for Carbon Dioxide is CO2 • It is possible to find the Molecular Formula using the Empirical Formula if you know the molar mass of the compound.

44. Finding the Molecular Formula • Calculate the molecular formula of a compound whose molar mass is 60.0 g/mol and empirical formula is CH4N • Step 1: Find the empirical formula molar mass • 12.01 + (4 x 1.01) + 14.01 = 30.06 g/mol • Step 2: Divide molar mass by EF molar mass • 60.0 g/mol = 1.99  2 30.06 g/mol • Step 3: Multiply empirical formula by 2 • CH4N x 2 = C2H8N2

45. Homework • 7.4 pg 253 #36-38