Unit 3 Stoichiometry

Unit 3 Stoichiometry

The Mole (mol)

• A large number used for counting particles
• The representative particle of an:

Element =atoms

Molecular Compound (covalent) = molecules

Ionic Compound = formula Units

• It is the number of particles in exactly 12 grams of carbon 12.
• Equal to 6.022 x 1023 of anything, no matter what the substance
• 6.022 x 1023 is called Avogadro’s number

Example 1

Convert 1.35 moles of carbon disulfide(CS2) into molecules?

Example 2

How many moles are in 3.59 x 1021 formula units of sodium nitrate, NaNO3

Molar Mass (Molecular Weight)

• Mass of 1 mole of a substance

• For elements, it is the amount in grams numerically equal to the atomic mass in amu’s
• For compounds, add up the individual atomic masses of the elements that make it up.

Remember a subscript in a chemical formulas tells you how many atoms of an element you have and this must be accounted for

• Represented by M and has the units grams/mol

Example 3

Calculate the mass of one carbon atom. ______

Example 4

Calculate the mass of 1 mole of carbon atoms. ______

Example 5

Calculate the mass of 1 mole of lithium atoms. ______

**** For any Element : Atomic Mass (AMU) = Molar Mass (grams).****

Example 6

What is the molar mass of sulfur dioxide?

Example 7

Calculate the molar mass of Al2O3

Conversions using Molar Mass

Example 8

How many moles of calcium carbonate are in a stick of chalk with a mass of 14.8 g.

Example 9

How many atoms are in 0.551 g of potassium ?

Example 10

How many hydrogen atoms are in 72.5 g of C3H8O ?

Percent Composition

• Percent that each element in a compound is composed of

HOW TO:

Calculate the molar mass of the compound. Then divide the total mass of each element, by the molar mass(total mass of the compound), and multiply by 100.

Check you answer to see if the total of the percent masses of all elements equals 100%

Example 11

Calculate the mass percent of each element in C2H6O

Example 12

Calculate the percent composition of water in the hydrate, CaSO4 · 2H2O

Empirical Formula

• The lowest whole number ratio of atoms in a chemical formula
• Ionic compound chemical formulas are ALWAYS empirical.
• From % composition, you can determine the empirical formula, based on mole ratios

HOW TO:

Remember this rhyme: Percent to mass, mass to mole, divide by small, multiply till whole (last step is not always mandatory)

• Steps to calculating empirical formula

1. If you are given a % composition, assume you have 100 grams and switch the % unit to g. If you are given the actual number of grams of each element, use those instead
2. Convert the grams of each element to moles of each element.
3. Divide each mole amount by the smallest mole amount.
4. If your answers are within .1 of whole number, round up or down and these numbers become your subscripts.
5. If your answers are not within .1 of a whole number, you must find the smallest number that you can multiply by all the mol amounts you have just calculated to get them to be all whole numbers or within .1 of a whole number.

Example 13

A sample of a brown gas, a major air pollutant, is found to contain 2.34 g N and 5.34g O. Determine a formula for this substance.

Example 14

A compound has the following percent composition: 31.9%K, 29.0 % Cl and 39.1%O. What is the empirical formula?

Extra Practice if needed!

A substance has the following composition by mass: 60.80 % Na ; 28.60 % B ; 10.60 % H. What is the empirical formula of the substance?

Molecular Formula

• Empirical means the lowest ratio, molecular means the actual ratio of the molecule that exists.
• To calculate, you need the molar mass of the molecular formula and the empirical formula’s mass(you will probably have to calculate this
• Steps to calculate the molecular formula:

1. Divide the Molecular formula mass by the empirical formula mass to get a whole number.
2. Multiply the whole number(factor) to the subscripts of the empirical formula

Example 15

A compound has an empirical formula of NO2. The colorless liquid, used in rocket engines has a molar mass of 92.0 g/mole. What is the molecular formula of this substance?

Calculating Empirical Formulas from Combustion Analysis

How to:

Use the mass of CO2 to covert to moles of CO2 to moles of C to grams of C.

Use the mass of H2O and convert to moles of H2O to mole H to g H

Subtract the combined mass of C and Hfrom the mass of the sample to get the mass of oxygen. Convert it to moles.

Simplify the mole ratios of C, H and O to get the empirical formula

Example 16: Calculate the empirical formula for the combustion of 11.5 g ethanol. 22.0 g CO2 and 13.5 g H2O are produced in the reaction.

Chemical Equations

• Sentences that describe what happens in a chemical reaction

• Reactants are the starting substances found on the left of an equation
• Products are the new substances created which are found on the right of an equation
• Reactants  Products

(yields)

• Law of Conservation of Mass: Matter can neither be created nor destroyed, just changed in form.

• Equations should be balanced in order to satisfy the law of conservation of mass- same number of each kind of atom on both sides of the equation must exist

__ CH4 + __ O2  __ CO2 + __ H2O

1 C 1

4 H 2

2 O 3

Important Abbreviations : (s) solid(l) liquid (g) gas (aq) aqueous

heat ∆ catalyst

  

Hints for balancing:

1. Never start with hydrogen or oxygen
2. Treat polyatomic ions as chunks not separate atoms
3. Do not put a coefficient of 1 down until the end when all atoms are balanced
4. If you have an odd number of atoms on one side and an even number of those atoms of the other, place a 2 as a coefficient next to the chemical formula with the odd numbers to make it even.

Examples 17

1. __ Ca(OH) 2 + __ H3PO4  __ H2O + __ Ca3(PO4) 2

1. __ Cr + __ S8  __ Cr2S 3

1. __ KClO 3  ___ KCl + __ O 2

1. Translate this and then balance: Solid iron(III) sulfide reacts with gaseous hydrogen chloride to form solid iron(III) chloride and hydrogen sulfide gas

Meaning of the coefficients in a Chemical Equation

• Used to describe a reaction in moles, and particles (molecules, formula units and atoms) but not grams. For example: 2 H2 + O2 2 H2O would be interpreted as 2 molecules of hydrogen react with 1 molecule of water to produce 2 molecules of water OR 2 moles of hydrogen react with 1 mole of oxygen to produce 2 moles of water!
• A Mole Ratio is the conversion factor between 2 different amounts in a balanced chemical equation

2 KClO 3  2 KCl + 3 O 2 Possible Mole Ratios could be:

• Stoichiometry: Given an amount of either reactant or product, you can determine the other quantities in a reaction using dimensional analysis

Steps to solve problems

1. Write balanced chemical equation

2. Convert quantities of known substances into moles

3. Use coefficients in balanced equation to calculate the number of moles of the

sought quantity

4. Convert moles of sought quantity into desired units

• Use conversion factors of [molar mass (grams) = 1 mole] and the balanced chemical equation mole ratio [? Mol A = ? Mol B]

4 types of problems

1. mole –mole: 1 step process using a mole ratio to convert from moles of

substance A to moles of substance B

2. mole-mass: 2 step process using a mole ratio to convert from moles of

substance A to moles of substance B and then the molar mass

conversion factor to convert between moles of B to grams of B

3. mass-mole: 2 step process using the molar mass conversion factor to convert

from mass of A to moles of A and then the mole ratio to convert

from moles A to moles of B

4. mass-mass: 3 step process using the molar mass conversion factor to convert

from mass of A to moles of A, then a mole ratio used to convert

from moles A to moles of B, then a molar mass conversion factor

to convert between moles of B to mass of B

Example 18

(Mole To Mol) How many moles of sulfur trioxide can be produced if 8.1 moles of oxygen react with sulfur. 2S + 3 O2 2 SO3

Example 19

(Mass To Mole) One way of producing oxygen O2 involves the decomposition of potassium chlorate into potassium chloride and oxygen gas. A 25.5 g sample of potassium chlorate is decomposed. How many moles of O2 are produced?

2 KClO 3  2 KCl + 3 O 2

Example 20

(Mass to Mass)If 209 g of methanol are used up in the combustion, what mass of water is produced?

2CH3OH + 3O2 2CO2 + 4H2O

Limiting Reagent

• Limiting reagent is the reactant that determines the amount of product formed ( it is the one you run out of first)

Excess ReagentThe reactant that you don’t run out of.

• How to tell if the problem you are working is a limiting reagent: IF 2 AMOUNTS OF REACTANT ARE GIVEN TO YOU IN THE PROBLEM!

Steps to determine the LR(limiting reagent)

1. Pick A Product
2. Try ALL the reactants
3. The lowest answer will be the correct answer
4. The reactant that gives the lowest answer will be the limiting reactant

Once you determine the LR, you should only start with it!

To find the amount of Y and Z

A + B  X + Y + Z Let’s say B is the LR!

There is no need to use A to find Y and Z

It will give you the wrong answer – a lot of extra work for nothing

Example 21

10.0g of aluminum reacts with 35.0 grams of chlorine gas to produce aluminum chloride. Which reactant is limiting, which is in excess, and how much product is produced?

2 Al + 3 Cl2 2 AlCl3

Shortcut to Finding Limiting Reagent

1. Take each reactant amount and convert to moles. If already in moles move to the next

step.

2. Divide each mole amount by the coefficient of that substance from the balanced

chemical equation.

3. Whichever is the smallest number will identify the limiting reagent (LR)

4. Use the original amount of the reactant from the problem to begin your conversion

process to determine either how much excess reagent you have left over or how much

product you will form.

Example 22:

In one process, 124.0 g of Al are reacted with 601.0 g of Fe2O3, calculate the mass of Al2O3 formed. 2Al + Fe2O3  Al2O3 + 2Fe

Finding Excess Reagent Practice

Example 23 : 10.0g of aluminum reacts with 35.0 grams of chlorine gas
2 Al + 3 Cl2 2 AlCl3

•We found that chlorine is the limiting reactant, and 43.8 g of aluminum chloride are produced. How much excess reagent in left over?

Percent Yield

• Percent Yield is the ratio in percent of amount of product you produced in the lab compared to the amount of product that you should of produced if the reaction went to completion and no problems arose in the lab
• Must always use the LR to determine the amount of product produced
• Theoretical yield- is the amount you would produce if everything went perfect; use the balanced chemical equation for this one
• Actual Yield is the actual amount you make in lab under imperfect condition.
• % yield = Actual/Theoretical x 100% OR
• % yield = what you got/what you should of got x 100%

Example 24

Aluminum burns in bromine producing aluminum bromide. In a lab, 6.0 g of aluminum reacts with excess bromine. 50.3 grams of aluminum bromide are produced. What are the three types of yield? 2 Al + 3 Br2 2 AlBr3