Chemistry - Stoichiometry - Real Life Stoichiometry

Real Life Stoichiometry : Real Life Stoichiometry

Stoichiometry in the Real World : Stoichiometry in the Real World

Air Bag Design : Air Bag Design Exact quantity of nitrogen gas must be produced in an instant. Use a catalyst to speed up the reaction 2 NaN3(s) ? 2 Na(s) + 3 N2(g) 6 Na(s) + Fe2O3(s) ? 3 Na2O(s) + 2 Fe (s)

Airbag Design : Airbag Design 2 NaN3(s) ? 2 Na(s) + 3 N2(g) 6 Na(s) + Fe2O3(s) ? 3 Na2O(s) + 2 Fe(s) Assume that 65.1 L of N2 gas are needed to inflate an air bag to the proper size. How many grams of NaN3 must be included in the gas generant to generate this amount of N2? (Hint: The density of N2 gas at this temperature is about 0.916 g/L). How much Fe2O3 must be added to the gas generant for this amount of NaN3? 65.1 L N2 x 0.916 g/L N2 59.6 g N2 X = 92.2 g NaN3 X = 37.7 g Fe2O3 x g NaN3 = 59.6 g N2 1 mol N2 28 g N2 3 mol N2 2 mol NaN3 65 g NaN3 1 mol NaN3 x g Fe2O3 = 92.2 g NaN3 1 mol NaN3 65 g NaN3 2 mol NaN3 2 mol Na 1 mol Fe2O3 6 mol Na 159.6 g Fe2O3 1 mol Fe2O3

Water from a Camel : Water from a Camel Camels store the fat tristearin (C57H110O6) in the hump. As well as being a source of energy, the fat is a source of water, because when it is used the reaction takes place. x g H2O = 1 kg ‘fat” X = 1112 g H2O or 1.112 liters water 2 C57H110O6(s) + 163 O2(g) ? 114 CO2(g) + 110 H2O(l) 1000 g “fat” 1 kg “fat” 890 g “fat” 1 mol “fat” 110 mol H2O 2 mol “fat” 18 g H2O 1 mol H2O What mass of water can be made from 1.0 kg of fat?

Rocket Fuel : Rocket Fuel The compound diborane (B2H6) was at one time considered for use as a rocket fuel. How many grams of liquid oxygen would a rocket have to carry to burn 10 kg of diborane completely? (The products are B2O3 and H2O). B2H6 + O2 Chemical equation Balanced chemical equation X = 34,286 g O2 10 kg x g x g O2 = 10 kg B2H6 1000 g B2H6 1 kg B2H6 28 g B2H6 1 mol B2H6 3 mol O2 1 mol B2H6 32 g O2 1 mol O2 B2O3 + H2O 3 3

Water in Space : Water in Space In the space shuttle, the CO2 that the crew exhales is removed from the air by a reaction within canisters of lithium hydroxide. On average, each astronaut exhales about 20.0 mol of CO2 daily. What volume of water will be produced when this amount of CO2 reacts with an excess of LiOH? (Hint: The density of water is about 1.00 g/mL.) CO2(g) + 2 LiOH(s) ? Li2CO3(aq) + H2O(l) excess 20.0 mol x g X = 360 mL H2O Click Here x mL H2O = 20.0 mol CO2 1 mol H2O 1 mol CO2 1 mol H2O 18 g H2O 1 mL H2O 1 g H2O 22.4 L H2O Water is NOT at STP!

Lithium Hydroxide ScrubberModified by Apollo 13 Mission : Lithium Hydroxide ScrubberModified by Apollo 13 Mission Astronaut John L. Swigert holds the jury-rigged lithium hydroxide scrubber used to remove excess carbon dioxide from the damaged Apollo 13 spacecraft.

Water in Space : Water in Space In the space shuttle, the CO2 that the crew exhales is removed from the air by a reaction within canisters of lithium hydroxide. On average, each astronaut exhales about 20.0 mol of CO2 daily. What volume of water will be produced when this amount of CO2 reacts with an excess of LiOH? (Hint: The density of water is about 1.00 g/mL.) CO2(g) + 2 LiOH(s) ? Li2CO3(aq) + H2O(l) excess 20.0 mol x g X = 360 mL H2O x mL H2O = 20.0 mol CO2 1 mol H2O 1 mol CO2 1 mol H2O 18 g H2O 1 mL H2O 1 g H2O 22.4 L H2O Water is NOT at STP!

Real Life Problem Solving : Real Life Problem Solving Determine the amount of LiOH required for a seven-day mission in space for three astronauts and one ‘happy’ chimpanzee. Assume each passenger expels 20 mol of CO2 per day. (4 passengers) x (10 days) x (20 mol/day) = 800 mol CO2 Plan for a delay CO2(g) + 2 LiOH(s) ? Li2CO3(aq) + H2O(l) 800 mol X g Note: The lithium hydroxide scrubbers are only 85% efficient.

Slide 11 : x g CO2(g) + 2 LiOH(s) ? Li2CO3(aq) + H2O(l) 38,240 g 38,240 g LiOH 1:2 X g LiOH = 800 mol CO2 = 38,240 g LiOH Needed (actual yield) 0.85 x = 44,988 g LiOH 800 mol x 23.9 g/mol Note: The lithium hydroxide scrubbers are only 85% efficient. Amount of LiOH to be taken into space 2 mol LiOH 1 mol CO2 23.9 g LiOH 1 mol LiOH 1600 mol x g LiOH = 800 mol

Careers in Chemistry: Farming : Careers in Chemistry: Farming Farming is big business in the United States with profits for the lucky and possible bankruptcy for the less fortunate. Farmers should not be ignorant of chemistry. For instance, to be profitable, a farmer must know when to plant, harvest, and sell his/her crops to maximize profit. In order to get the greatest yield farmers often add fertilizers to the soil to replenish vital nutrients removed by the previous season’s crop. Corn is one product that removes a tremendous amount of phosphorous from the soil. For this reason, farmers will rotate crops and/or add fertilizer to the ground before planting crops for the following year. On average, an acre of corn will remove 6 kilograms of phosphorous from the ground. Assume you inherit a farm and must now have to purchase fertilizer for the farm. The farm is 340 acres and had corn planted the previous year. You must add fertilizer to the soil before you plant this years’ crop. You go to the local fertilizer store and find SuperPhosphateTM brand fertilizer. You read the fertilizer bag and can recognize from your high school chemistry class a molecular formula Ca3P2H14S2O21 (you don’t understand anything else written on the bag because it is imported fertilizer from Japan). You must decide how much fertilizer to buy for application to your corn fields. If each bag costs $54.73; how many bags of fertilizer must you purchase and how much will it cost you to add the necessary fertilizer to your fields? Given: 1 bag of fertilizer weighs 10,000 g [454 g = 1 pound]

Careers in Chemistry: Farming : 1000 g P Careers in Chemistry: Farming How much fertilizer will you need? Conversion Factor: 1 acre corn = 6 kg phosphorous If a bag of fertilizer has the formula Ca3P2H14S2O21, The molar mass of it is 596 g/mol. 3 Ca @ 40g/mol = 120 g 2 P@ 31 g/mol = 62 g 14 H@ 1 g/mol = 14 g 2 S@ 32 g/mol = 64 g 21 O @ 16 g/mol = 335 g Ca3P2H14S2O21 In a bag of fertilizer you have 10.4 % (by mass) phosphorous. A bag of fertilizer weighs 10,000 g (about 22 pounds). 10.4 % of 10,000 g = 2.04 x 106 g P 1040 g/bag Total Cost x g P = 340 acres 1 acre 6 kg P 1 kg P = 2.04 x 106 g P % P = part whole 62 g 596 g x 100 % 10.4 % Phosphorous = 596 g 1040 g phosphorous / bag of fertilizer = 1962 bags of fertilizer $107,380 (1962 bags of fertilizer)($54.73 / bag) =

Careers in Chemistry: Dentistry : Careers in Chemistry: Dentistry We learned that fluoride is an essential element to be taken to reduce teeth cavities. Too much fluoride can produce yellow spots on the teeth and too little will have no effect. After years of study it was determined that a quantity of 1 part per million (ppm) fluoride in the water supply is enough to significantly reduce cavities and not stain teeth yellow. Measure the mass of the mineral fluorite (chemically, CaF2). Use this sample to determine how much water must be added to yield a 1 ppm fluoride solution. Sounds difficult? Lets apply what we’ve learned this unit to solve this problem. 1 part per million = 1 atom of fluorine per 999,999 water molecules What information do we know: 1 mol CaF2 = 78.08 g CaF2 = 6.02 x 1023 molecules of CaF2 1 molecules of CaF2 = 2 atoms of F 1 mol H2O = 18 g H2O Density of water is 1 g/mL 1000 mL = 1 L and 3.78 L = 1 gallon mass of sample of CaF2 = 92.135 g

Careers in Chemistry: Dentistry : Careers in Chemistry: Dentistry Need 11,238 gallons of water needed to dissolve 91.235 g CaF2 to yield a 1 ppm F1- solution. Calcium Fluoride x atoms F = 92.135 g CaF2 1 mol CaF2 78 g CaF2 1 mol CaF2 6.02 x 1023 molecules CaF2 2 atoms F 1 molecules CaF2 = 1.42 x 1024 atoms F x gallons H2O = 1.42 x 1024 F atoms 999,999 H2O molecules 1 F atom 6.02 x 1023 H2O molecules 1 mol H2O 18 g H2O 1 mol H2O 1 mL H2O 1 g H2O 1000 mL H2O 1 L H2O 1 gallon H2O 3.78 L H2O =

Energy with Stoichiometry : Energy with Stoichiometry Keys Energy with Stoichiometry Energy with Stoichiometry

Energy with Stoichiometry : oxygen Energy with Stoichiometry methane + carbon dioxide water energy + + Given: 1 mol O2 yields 350 kJ CH4 O2 CO2 H2O + + + 2 2 100 g 100 g 350 kJ 700 kJ ? / 16 g/mol / 32 g/mol 6.25 mol CH4 3.125 mol O2 1 2 6.25 1.56 Limiting Excess ? kJ x kJ = 3.125 mol O2 2 mol O2 700 kJ = 1094 kJ smaller number is limiting reactant