1. Types of Chemical Reactions

2.  There are only five (5) different types of chemical reactions: 1) Double Replacement 2) Single Replacement 3) Synthesis/Formation 4) Decomposition 5) Combustion

3. Reaction Type 1 – Double Replacement  Occur between two ionic compounds Does not happen with covalent compounds  Involves an exchange of cations (positive ions)  The cation of one compound trades places with the cation of another compound to form two new compounds

4. Double Replacement - Characteristics  occur in solution when the compounds are in an aqueous state (aq) reactants are either aqueous to begin with, or solid compounds dissolved in water to form an aqueous solution of ions  in order to drive the reaction, one of the products must be removed from the aqueous solution  this can occur via one of three ways:

5. Double Replacement - Characteristics 1) Formation of a precipitate (an insoluble solid forms in the solution)  i.e.: AgNO 3 (aq) + NaCl (aq) = NaNO 3 (aq) + AgCl (s)  Solid silver chloride is formed as precipitate and comes out of the solution

6. Double Replacement - Characteristics 2) Formation of a gas  i.e.: FeS (aq) + 2HCl (aq) = H 2 S (g) + FeCl 2 (aq)  Hydrogen sulfide gas is formed and comes out of the solution

7. Double Replacement - Characteristics 3) Water is formed when a hydrogen cation unites with a hydroxide anion  i.e.: NaOH (aq) + HCl (aq) = HOH (l) + NaCl (aq)  Water (HOH) is formed and comes out of the solution

8. Identifying a Double Replacement Reaction  Double replacement reactions always have two ionic compounds on the REACTANTS side AND on the PRODUCTS side of an equation  *Two compounds react to form two new compounds* AB + CD  CB + AD ○ A & C are cations, B & D are anions ○ A & C switch places

9. Reaction Type # 2 – Single Replacement

10. Single Replacement Reactions: Characteristics:  Atom (s) of a lone element replace the atom (s) of an element in a compound Metals replace metals (or cations replace cations) Non-metals replace non-metals (or anions replace anions)

11. Single Replacement Reactions: Characteristics:  Metal Cation Replacement: For the reaction: A + BC  B + AC A and B are cations A “replaces” B in the compound

12. Single Replacement Reactions: Characteristics:  Non-metal Anion Replacement: For the reaction: D + EF  ED + F D & F are anions D “replaces” F in the compound Non metal replacements usually involve halogens

13. Restrictions on Single Replacement Reactions  Activity Series: A characteristic of metals and halogens referring to their reactivity Determines whether or not a single replacement reaction will occur or not Metals: on page 155 (table 7-2) there is an activity series of metals arranged in order of decreasing activity Non-metals (Halogens) : as you move down the group on the periodic table activity decreases

14. Restrictions on Single Replacement Reactions  A single replacement reaction WILL NOT OCCUR if the reactivity of the pure element reactant is less than that of the compound reactant i.e.: Sn (s) + NaNO 3 (aq)  no reaction b/c tin is less reactive than sodium

15. Restrictions on Single Replacement Reactions  A single replacement reaction WILL OCCUR if the reactivity of the pure element reactant is greater than that of the compound reactant i.e.: Zn (s) + H 2 SO 4 (aq)  ZnSO 4 (aq) + H 2 (g) Reaction occurs because the reactivity of zinc is higher than hydrogen

16. Identifying Single Replacement Reactions  Single replacement reactions ALWAYS have 1 lone element and 1 compound on the reactants side and the products side  Reactants will always be: 1 lone element + 1 compound  Products will always be: 1 lone element + 1 compound

17. Reaction Type #3 - Decomposition  Occurs when a single compound breaks down into two or more components  Energy is required for them to occur  Reactants will always be: 1 compound  Products will always be: ALWAYS more products than reactants 2 components (either compounds or elements)  i.e.: AB  A + B

18. Decomposition Example:  One unit breaks down into its component parts  i.e. – The marriage of Brad Pitt and Jennifer Aniston breaks into the single Brad Pitt and the single Jennifer Aniston

19. Reaction Type #4 – Synthesis/Formation  Occurs when two or more components come together to form one compound  Energy is released when these reactions occur  Reactants will always be: ALWAYS more reactants than products! 2 or more components (either elements or compounds)  Products will always be: 1 single compound  i.e.: A + B  AB

20. Synthesis/Formation Example  Two individual components coming together to form one unit  i.e. – single Robert Pattinson and a single Kristen Stewart come together to form a totally awesome Twilight couple OMG OMG LOL ECLIPSE! LIKE TOTALLY AWESOME!

21. Special Cases for Decomposition & Synthesis/Formation Reactions  Decomposition and Synthesis/Formation Reactions are opposite processes (duh)  Special Case #1: A non metal oxide + water combine to form an acid ○ i.e.: SO 3 + H 2 O  H 2 SO 4 AND an acid will decompose to form a non- metal oxide + water ○ i.e.: H 2 SO 4  SO 3 + H 2 O

22. Special Cases for Decomposition & Synthesis/Formation Reactions  Special Case #2 A metal oxide + water combine to form a metal hydroxide ○ i.e.: CaO + H 2 O  Ca(OH) 2 A metal hydroxide will decompose into a metal oxide + water ○ i.e.: Ca(OH) 2  CaO + H 2 O

23. Special Cases for Decomposition & Synthesis/Formation Reactions  Special Case #3: All carbonates decompose into carbon dioxide and an oxide i.e.: CaCO 3  CaO + CO 2 Vice versa for synthesis/formation reactions  Special Case #4: All chlorates decompose into oxygen and a binary salt i.e.: KClO 3  KCl + O 2 Vice versa for synthesis/formation reactions

24. Reaction Type #5 - Combustion  Also known as BURNING  Hydrocarbon Compound composed of only carbon and hydrogen and sometimes oxygen  Reactants will always be: Hydrocarbon + oxygen  Products will always be: Carbon dioxide + water  i.e.: C 6 H 6 + O 2  CO 2 + H 2 O