1. The Mole
The following provides an overview of moles and the skills necessary for performing mole conversions

2. Definition of a Mole
A dozen is a number that has been given a name. The same can be said for a mole. The only difference is that the number defined as a mole is very, very, very, very, very, very, very ,very, very, very, very, very, very, very, very, very, very, big!!!
1 mole = 6.02 x 1023
(602,000,000,000,000,000,000,000)
Avogadro’s Number

3. Is A Mole Really That Big?
If an atom were the size of a marble and one mole of marbles were spread over the surface of the Earth, our planet would be covered by a 50 mi-thick layer.

4. Is A Mole Really That Big?
A new supercomputer can count all of the people in the United States in one-quarter of a second, but it would take almost two million years for it to count one mole of people at the same rate.

5. Is A Mole Really That Big?
If you made $40,000 (4,000,000 pennies) every second at your job that you had been working at since the formation of earth 4.5 billion years ago, you would not yet have earned Avogadro’s number of pennies.

6. So How is a Mole Helpful?
Scientists obviously can’t mass quantities of chemicals in amu because an amu is far too small. When scientists work with a substance like H2O, they can’t deal with single molecules – we can’t see or mass 2 atoms of hydrogen and one atom of oxygen. Scientists obviously have to work with much larger quantities. To solve this problem, scientists use the mole. To be useful the mole has to be somehow related to amu. Officially, the mole (symbol mol) is the SI term for the amount of substance containing as many elementary particles as there are atoms in kg of carbon-12 (which is about 6.02 x 1023atoms)

7. Where do you find how much a mole of something weighs?
The atomic mass given on the periodic table is not only the mass of one atom of that element, but it is also the mass (in grams) of 1 mole of the atoms of that element. Therefore, since the mass of one carbon atom is 12 amu, the mass of one mole of Carbon atoms would be 12 grams. When dealing with a molecule or compound you simply calculate the molecular/formula mass using the periodic table, and this (like with atoms) is not only the mass of one molecule/compound, but it is also the mass (in grams) of 1 mole of the molecule/compound. Therefore, since the mass of one molecule of ozone (O3) is 48 amu, the mass of one mole of ozone molecules would be 48 grams.

8. How much does it weigh? 1 mole of Oxygen 1 mole of Sodium
You may want to use your periodic table!
1 mole of Oxygen
1 mole of Sodium
2 moles of Carbon
3 moles of Hydrogen
1 mole of H2O
16 grams
23 grams
24 grams
3 grams
18 grams

9. Mole Map This map is to help you navigate mole problems Moles
Atoms, Molecules,
Particles,
Etc.
Mass (Grams)
Excuse me, how do I get to Atoms?
If you use the map, you won’t get lost!!!
Just start at grams, go straight through moles and you will get to atoms.

10. Sample One Step Problem
Calculate the mass of 7.5 moles of Carbon.
Use the “map” to help figure it out
Moles
Atoms, Molecules,
Particles,
Etc.
Mass (Grams)
What is the starting point in this problem?
What is the final destination in this problem?
How many steps/fractions will it take you to get there?

11. Calculate the mass of 7.5 moles of Carbon.
One Step Problem
Calculate the mass of 7.5 moles of Carbon.
7.5 moles of C  grams of C
(7.5 moles of C)
(1)
grams of C
(____________)
( ) 12
= 90 grams of C 1
mole of C
Explanation
#4 –Since you are aware that it is
necessary to travel to grams you can
simply place that unit on the top of the
fraction. To determine the mass of a
mole of carbon you use the periodic table.
In this case, one mole of carbon has a
mass of 12 grams. You plug these numbers
into the fraction, letting the units guide
you. You have now transitioned from
moles to grams.
#5 –Now that you have arrived at your
final destination (grams) you can simply
cancel all other diagonal units.
#6 –Finally, multiply across the top,
multiply across the bottom, and divide the
product of the top by the product of the bottom. This will give you the final answer, which in this case is 90 grams of C.
#3 –Multiply between fractions and
make sure the bottom unit of the new fraction is the same as the top unit of the previous fraction. In this case the unit is “mole of carbon.”
#2 –Place your starting point over
one. In this case you will be placing
7.5 moles of carbon over one.
#1 –Since you have already found the
starting point, final destination, and the
number of steps it will take, you should
now write down a little reminder of
all of this information.
Use Periodic table
Use 1 Mole = 6.02x1023

12. Sample Two Step Problem
How many atoms are in 45.8 grams of Na?
Use the “map” to help figure it out
Moles
Atoms, Molecules,
Particles,
Etc.
Mass (Grams)
What is the starting point in this problem?
What is the final destination in this problem?
How many steps/fractions will it take you to get there?

13. How many atoms are in 45.8 grams of Na?
Two Step Problem
How many atoms are in 45.8 grams of Na?
45.8 grams  atoms of Na
(45.8 grams of Na)
(1)
mole of Na
(_____________)
( ) 1
(________________)
( )
6.02x1023
atoms of Na 23
grams of Na 1
mole of Na
= x 1024 atoms of Na
Explanation
#4 –Since you are aware that it is
necessary to travel to atoms, according to the “Mole Map,” you must stop at moles first. Therefore you should place that unit on the top of the fraction. To determine the mass of a mole of sodium you use the periodic table. In this case, one mole of sodium has a mass of 23 grams. You plug these numbers into the fraction, letting the units guide you. You have now transitioned from grams to moles.
#6 –Since you are at moles, it is now possible for you to travel to atoms; therefore you should place that unit on
the top of the fraction. To determine the number of atoms in a mole of sodium you simply use 1 mole = 6.02x You plug these numbers into the fraction, letting the units guide you. You have now transitioned from moles to atoms.
#8 –Finally, multiply across the top,
multiply across the bottom, and divide the
product of the top by the product of the bottom. This will give you the final answer, which in this case is 1.20x1024 atoms of sodium.
#7 –Now that you have arrived at your
final destination (atoms) you can simply
cancel all other diagonal units.
#3 –Multiply between fractions and
make sure the bottom unit of the new fraction is the same as the top unit of the previous fraction. In this case the unit is “grams of sodium.”
#1 –Since you have already found the
starting point, final destination, and the
number of steps it will take, you should
now write down a little reminder of
all of this information.
#2 –Place your starting point over
one. In this case you will be placing
45.8 grams of sodium over one.
#5 –Now that you have arrived at moles it will be necessary to continue your travels to atoms since moles is not your final destination. Once again, you need to multiply between fractions and make sure the bottom unit of the new fraction is the same as the top unit of the previous fraction. In this case the unit is “mole of sodium.”
Use Periodic table
Use 1 Mole = 6.02x1023

14. Sample Problem That Requires Some Prep Work Before Converting
Calculate the mass of two moles of the compound Ca(NO3)2.
What is different about this problem when compared to the others?
Ca(NO3)2 - it is not an atom
You should calculate the molar mass using your periodic
table prior to using your map and subsequently converting
Ca = 40g x 1 = 40 g/mol
N = 14g x 2 = 28 g/mol
O = 16g x 6 = 96 g/mol
1 mole of Ca(NO3)2 = 164 g
Now that you know the molar mass of Ca(NO3)2
you can use your map and convert

15. Sample Problem That Requires Some Prep Work Before Converting
Calculate the mass of two moles of the compound Ca(NO3)2.
Use the “map” to help figure it out
Moles
Atoms, Molecules,
Particles,
Etc.
Mass (Grams)
What is the starting point in this problem?
What is the final destination in this problem?
How many steps/fractions will it take you to get there?

16. Continuation of Problem After Prep Work is Complete
Calculate the mass of two moles of the compound Ca(NO3)2.
2 moles of Ca(NO3)2  grams of Ca(NO3)2
1 mole of Ca(NO3)2 = 164 g
(2 moles of Ca(NO3)2)
(1)
grams of Ca(NO3)2
(__________________)
( )
164 1
mole of Ca(NO3)2
= 328 grams of Ca(NO3)2
Explanation
#5 –Now that you have arrived at your
final destination (grams) you can simply
cancel all other diagonal units.
#6 –Finally, multiply across the top,
multiply across the bottom, and divide the
product of the top by the product of the bottom. This will give you the final
answer, which in this case is 328 grams of Ca(NO3)2..
#4 –Since you are aware that it is
necessary to travel to grams you can
simply place that unit on the top of the
fraction. To determine the mass of a
mole of Ca(NO3)2 you have already used your periodic table and you calculated a mass of 164 grams. You plug these numbers into the fraction, letting the
units guide you. You have now transitioned from moles to grams.
#3 –Multiply between fractions and
make sure the bottom unit of the new fraction is the same as the top unit of the previous fraction. In this case the unit is “mole of Ca(NO3)2.”
#1 –Since you have already done some
preliminary work and determined the
mass of a mole of Ca(NO3)2, found the
starting point, final destination, and the
number of steps it will take, you should
now write down a little reminder of
all of this information.
#2 –Place your starting point over
one. In this case you will be placing
2 moles of Ca(NO3)2 over one.
Use Periodic table
Use 1 Mole = 6.02x1023