Chapter 7: Chemical Reactions

1. Chapter 7: Chemical Reactions Section 7.1 Describing Reactions

2. Chemical Reactions • http://www.youtube.com/watch?v=Mx5JJWI2aaw&feature=related

3. Equations • • Examples: • With words • carbon + oxygen -------> carbon dioxide • With formulas (a chemical equation) • C + O2 ----------> CO2

4. The Law of Conservation of Mass • conservation of mass clip

5. Balancing Equations • Look at this equation: N2H4 + O2 ---> N2 + H2O •Are the numbers of nitrogen atoms, hydrogen, and oxygen atoms the same on both sides? NO! We need to balance the equation. do this by changing the coefficients (the numbers that appear before the formulas). When there is no other, a coefficient of 1 is assumed.

6. N= H= O= N= H= O = N2H4 + O2 N2 + H2O When you add a coefficientof 2, you get this balanced equation: N2H4 + O2 N2 + 2H2O

7. More practice with balancing equations • Balance these three equations: • Cu + O2 --------> CuO • H2O2 -------> H2O + O2 • Mg + HCl ------> H2 + MgCl2

8. Moles •

9. A mole is a lot of things! • To comprehend the enormous size of Avogadro’s number, 6.02 x 1023, here are some analogies. • Would a mole of rice grains fill our chemistry lab? • Would a mole of rice grains fit in our school? • 1 mole of rice grams would cover all the land area of the whole world to a depth of 75 meters

10. 1 mole of rice has more grains than the number grains of all rice grown since the beginning of time!

11. 1 mole of watermelon seeds: • Would be found in a watermelon slightly larger than the moon!

12. 1 mole pennies divided equally between every person on earth: • Each person would receive 1 x 1014 pennies. • Personal spending at the rate of $1 million per day would use up each person’s wealth in just under 3000 years! • Life would not be comfortable. The surface of our planet would be buried in copper coins to a depth of about 420 m.

13. Each human being has about 60 million body cells (6 x 1013) • Assume that the earth’s population is 6 billion (6 x 109), the total number of living body cells on the earth at the present time is 3.6 x 1023 or a little more than half a mole!

14. Molar Mass • CO2: carbon (12 g) + oxygen (2g x 16g) = 44g

15. Mole-Mass Conversions • Example: • You have 55 grams of CO2. How many moles of CO2 do you have?

16. More calculations….

17. Examples to work • How much oxygen is needed to make 144 grams of water? • two things are needed to work this problem ~ a balanced equation and molar masses. • first step is to find out how many moles of water we are trying to make. 144 g of H2O x 1 mol H2O = 8 mol H2O 18 g H2O

18. Next step…. • Next step - go to the balanced equation for a ratio of moles of oxygen to moles of water. 2H2 + O2 --------> 2H2O 1 mol O2OR 2 mol H2O 2 mol H2O 1 mol O2

19. Next step…. • convert moles of water you are trying to make and then to moles of oxygen needed to make that amount of water. 8 mol H2O x 1 mol O2 = 4 mol O2 2 mol H2O

20. Finally….. • Convert the moles of oxygen needed to the mass of oxygen needed. 4 mol O2 x 32 grams = 128 grams 1 mol O2 So, 128 grams of oxygen must be used in order to produce 144 grams of water.

21. The End