Chemical Reactions: An Introduction Chapter 6

1. Chemical Reactions:An IntroductionChapter 6

2. Chemical Reactions • Reactions involve chemical changes in matter resulting in new substances • Reactions involve rearrangement and exchange of atoms to produce new molecules • Elements are not transmuted during a reaction Reactants  Products

3. Evidence of Chemical Reactions • a chemical change occurs when new substances are made • visual clues (permanent) • color change, precipitate formation, gas bubbles, flames, heat release, cooling, light • other clues • new odor, permanent new state

5. Chemical Equations • Shorthand way of describing a reaction • Provides information about the reaction • Formulas of reactants and products • States of reactants and products • Relative numbers of reactant and product molecules that are required • Can be used to determine weights of reactants used and of products that can be made

6. Conservation of Mass • Matter cannot be created or destroyed • In a chemical reaction, all the atoms present at the beginning are still present at the end • Therefore the total mass cannot change • Therefore the total mass of the reactants will be the same as the total mass of the products

7. O H H O + + C O O C H H H H O 1 C + 4 H + 2 O 1 C + 2 O + 2 H + O 1 C + 2 H + 3 O Combustion of Methane • methane gas burns to produce carbon dioxide gas and liquid water • whenever something burns it combines with O2(g) CH4(g) + O2(g)  CO2(g) + H2O(l)

8. O O O O H H H H + + + C C + H H O O O O H H 1 C + 4 H + 4 O 1 C + 4 H + 4 O Combustion of MethaneBalanced • to show the reaction obeys the Law of Conservation of Mass it must be balanced CH4(g) + 2 O2(g)  CO2(g) + 2 H2O(l)

9. Writing Equations • Use proper formulas for each reactant and product • proper equation should be balanced • obey Law of Conservation of Mass • all elements on reactants side also on product side • equal numbers of atoms of each element on reactant side as on product side • balanced equation shows the relationship between the relative numbers of molecules of reactants and products • can be used to determine mass relationships

10. Symbols Used in Equations • symbols used after chemical formula to indicate state • (g) = gas; (l) = liquid; (s) = solid • (aq) = aqueous, dissolved in water

11. Sample – Recognizing Reactants and Products • when magnesium metal burns in air it produces a white, powdery compound magnesium oxide • burning in air means reacting with O2 • Metals are solids, except for Hg which is liquid • write the equation in words • identify the state of each chemical magnesium(s) + oxygen(g) magnesium oxide(s) • write the equation in formulas • identify diatomic elements • identify polyatomic ions • determine formulas Mg(s) + O2(g) MgO(s)

12. Balancing by Inspection • Count atoms of each element • polyatomic ions may be counted as one “element” if it does not change in the reaction Al + FeSO4Al2(SO4)3 + Fe 1 SO4 3 • if an element appears in more than one compound on the same side, count each separately and add CO + O2 CO2 1 + 2 O 2

13. Balancing by Inspection • Pick an element to balance • avoid elements from 1b • Find Least Common Multiple and factors needed to make both sides equal • Use factors as coefficients in equation • if already a coefficient then multiply by new factor • Recount and Repeat until balanced

14. A bombardier beetle defending itself.

15. Examples • when magnesium metal burns in air it produces a white, powdery compound magnesium oxide • burning in air means reacting with O2 • write the equation in words • identify the state of each chemical magnesium(s) + oxygen(g) magnesium oxide(s) • write the equation in formulas • identify diatomic elements • identify polyatomic ions • determine formulas Mg(s) + O2(g) MgO(s)

16. Examples • when magnesium metal burns in air it produces a white, powdery compound magnesium oxide • burning in air means reacting with O2 • count the number of atoms of on each side • count polyatomic groups as one “element” if on both sides • split count of element if in more than one compound on one side Mg(s) + O2(g) MgO(s) 1  Mg 1 2  O  1

17. Examples • when magnesium metal burns in air it produces a white, powdery compound magnesium oxide • burning in air means reacting with O2 • pick an element to balance • avoid element in multiple compounds • find least common multiple of both sides & multiply each side by factor so it equals LCM Mg(s) + O2(g) MgO(s) 1  Mg 1 1 x 2  O  1 x 2

18. Examples • when magnesium metal burns in air it produces a white, powdery compound magnesium oxide • burning in air means reacting with O2 • use factors as coefficients in front of compound containing the element • if coefficient already there, multiply them together Mg(s) + O2(g)  2 MgO(s) 1  Mg 1 1 x 2  O  1 x 2

19. Examples • when magnesium metal burns in air it produces a white, powdery compound magnesium oxide • burning in air means reacting with O2 • Recount Mg(s) + O2(g) 2MgO(s) 1  Mg 2 2  O  2 • Repeat 2 Mg(s) + O2(g) 2MgO(s) 2 x 1  Mg 2 2  O  2

20. Examples • Under appropriate conditions at 1000°C ammonia gas reacts with oxygen gas to produce gaseous nitrogen monoxide and gaseous water • write the equation in words • identify the state of each chemical ammonia(g) + oxygen(g) nitrogen monoxide(g) + water(g) • write the equation in formulas • identify diatomic elements • identify polyatomic ions • determine formulas NH3(g) + O2(g) NO(g) + H2O(g)

21. Examples • Under appropriate conditions at 1000°C ammonia gas reacts with oxygen gas to produce gaseous nitrogen monoxide and gaseous water • count the number of atoms of on each side • count polyatomic groups as one “element” if on both sides • split count of element if in more than one compound on one side NH3(g) + O2(g) NO(g) + H2O(g) 1  N 1 3  H  2 2  O  1 + 1

22. Examples • Under appropriate conditions at 1000°C ammonia gas reacts with oxygen gas to produce gaseous nitrogen monoxide and gaseous water • pick an element to balance • avoid element in multiple compounds • find least common multiple of both sides & multiply each side by factor so it equals LCM NH3(g) + O2(g) NO(g) + H2O(g) 1  N 1 2 x 3  H  2 x 3 2  O  1 + 1

23. Examples • Under appropriate conditions at 1000°C ammonia gas reacts with oxygen gas to produce gaseous nitrogen monoxide and gaseous water • use factors as coefficients in front of compound containing the element 2 NH3(g) + O2(g) NO(g) + 3 H2O(g) 1  N 1 2 x 3  H  2 x 3 2  O  1 + 1

24. Examples • Under appropriate conditions at 1000°C ammonia gas reacts with oxygen gas to produce gaseous nitrogen monoxide and gaseous water • Recount 2 NH3(g) + O2(g) NO(g) + 3 H2O(g) 2  N 1 6  H  6 2  O  1 + 3 • Repeat 2 NH3(g) + O2(g) 2 NO(g) + 3 H2O(g) 2  N 1 x 2 6  H  6 2  O  1 + 3

25. Examples • Under appropriate conditions at 1000°C ammonia gas reacts with oxygen gas to produce gaseous nitrogen monoxide and gaseous water • Recount 2 NH3(g) + O2(g) 2NO(g) + 3 H2O(g) 2  N 2 6  H  6 2  O  2 + 3

26. Examples • Under appropriate conditions at 1000°C ammonia gas reacts with oxygen gas to produce gaseous nitrogen monoxide and gaseous water • Repeat • A trick of the trade, when you are forced to attack an element that is in 3 or more compounds – find where it is uncombined. You can find a factor to make it any amount you want, even if that factor is a fraction! • We want to make the O on the left equal 5, therefore we will multiply it by 2.5 2 NH3(g) + 2.5 O2(g) 2NO(g) + 3 H2O(g) 2  N 2 6  H  6 2.5 x 2  O  2 + 3