The Mole: Avogadro’s number
How much is: A dozen? A century? A mole?
Can you count a mole of pennies? If you could count 5 per second, it would take you 6.02 x 10 23 ÷ 5 pennies/second ÷ 60 sec/min ÷ 60 min/hr ÷ 24hrs/day ÷ 365 days/yr =
Can you spend a mole of dollars? If you could spend $1,000,000 every second it would take you 6.02 x 10 23 ÷ $1,000,000/sec ÷ 60 sec/min ÷ 60 min/hr ÷ 24hrs/day ÷ 365 days/yr =
When measuring amounts, you can count or you can mass them. If I want 2 dozen baseballs, I can count baseballs Or I can mass of baseballs.
Since we can’t count a mole of atoms, we MUST mass chemicals to measure moles 6.02 x 10 23 atoms of sulfur 32.07 grams of sulfur 6.02 x 10 23 atoms of carbon 12.01 grams of carbon
How do we measure moles? mole = number of particles equal to the number of atoms in 12 g of C-12 1 atom of C-12 weighs exactly 1 mole of C-12 weighs exactly The number of particles in 1 mole is called ____________ Number = 6.0221421 x 1023 1 mole of C atoms weighs and has atoms the average mass of a C atom is 12.01 amu
How do we measure moles? The atomic mass on your periodic table is the mass of a mole of atoms of that element. What is the mass of a mole of copper atoms? So, to count 6.02 x 1023 copper atoms, we mass out on the scale.
Mole and Mass Relationships Sulfur 32.06 g 1 mole Carbon 12.01 g
Find the mass of: A mole of silicon atoms 6.02 x 1023 atoms of nitrogen 6.02 x 1023 atoms of sodium 2 moles of sodium atoms
How many atoms are in: A mole of silicon 14.01 g of nitrogen 2 moles of sodium 45.98 g of sodium
How many things are in: A mole of footballs A mole of water 2 moles of pencils ½ mole of lead
Molar mass is the mass of one mole of a substance To find the molar mass of an element, look on the periodic table. To find the molar mass of a compound, add all the masses of its elements
Chemical Formulas as Conversion Factors 1 spider legs 1 chair legs 1 H2O molecule H atoms & O atom
Molar Mass of Compounds the relative weights of molecules can be calculated from atomic weights Formula Mass = 1 molecule of H2O since 1 mole of H2O contains 2 moles of H and 1 mole of O Molar Mass = 1 mole H2O
Find the molar mass of: Ammonium phosphate NH4+ PO43- (NH4)3PO4 = Carbon dioxide CO2
Find the molar mass of: Hydrogen gas H2 = Elemental hydrogen H
Find the molar mass of: Iron Fe = Iron (III) hydroxide Fe3+ OH-
Converting to and from moles. To convert between moles and particles, simply multiply or divide by Avogadro’s number. 2 mol x (6.02 x 1023 particles/mol) = 1.20 x 1024 particles 3.1 x 1024 particles x (1 mol/ 6.02 x 1023 particles) = 5.0 mol
Remember unit factors?
Converting to and from moles. Converting between moles and mass requires the molar mass of the substance from the periodic table. Element: Ag = g/mol Ionic compound: CaCl2 = g/mol Covalent compound: NO2 = g/mol Always keep at least two decimal place on all values taken from the periodic table.
Converting to and from moles. To convert from moles to grams, multiply by molar mass: 0.500 mol H2O x (18.0g/mol) = 9.00g H2O To convert from grams to moles, divide by molar mass: 54g H2O x (1mol/18.0g) = 3.0 mol H2O
Converting to and from moles. For gases, use the fact that at STP, 1 mol of any gas has a volume of Liters. What is STP? Standard Temperature = K or °C Standard Pressure = atmosphere = mm Hg (barometric) = kPa.
Converting to and from moles. To go from moles to volume, multiply by 22.4L. 3.00 mol x (22.4L/mol) = of gas To go from volume to moles, divide by 22.4L 44.8L x (1mol/22.4L) = moles of gas
Converting to and from moles. A convenient tool for making these conversions is called a “mole map.” With the mole at the center, we can put all of the aforementioned calculations together into one simple picture.
The Mole Map Gas Volume @ STP # Particles Mole Mass
Percent Composition Percentage of each element in a compound By mass Can be determined from the of the compound the experimental mass analysis of the compound the total mass of The percentages may not always total to 100% due to
What percentage of water is Oxygen? Formula of the compound Mass of the compound Mass of each element
Mass Percent as a Conversion Factor the mass percent tells you the mass of a constituent element in 100 g of the compound the fact that NaCl is 39% Na by mass means that 100 g of NaCl contains 39 g Na this can be used as a conversion factor 100. g NaCl 39.0 g Na
Empirical Formulas The simplest, whole-number ratio of atoms in a molecule is called the can be determined from percent composition or combining masses The Molecular Formula is a multiple of the Empirical Formula % A mass A (g) moles A 100g MMA % B mass B (g) moles B 100g MMB moles A moles B
Empirical Formulas Hydrogen Peroxide Molecular Formula = H2O2 Empirical Formula = HO
Benzene Molecular Formula = Empirical Formula = Glucose Molecular Formula = Empirical Formula =
Finding an Empirical Formula convert the skip if already grams convert use molar mass of each element divide all by round or multiply all mole ratios by number to make all whole numbers if ratio ?.5, multiply all by 2; if ratio ?.33 or ?.67, multiply all by 3, etc. skip if already whole numbers
Determine the empirical formula of a compound containing 80 Determine the empirical formula of a compound containing 80.0 grams of carbon and 20.0 grams hydrogen.
Grams to moles
Divide by smallest
Write Empirical Formula
Example: A laboratory analysis of aspirin determined the following mass percent composition. Find the empirical formula. C = 60.00% H = 4.48% O = 35.53%
All these molecules have the same Empirical Formula All these molecules have the same Empirical Formula. How are the molecules different? Name Molecular Formula Empirical glyceraldehyde C3H6O3 CH2O erythrose C4H8O4 arabinose C5H10O5 glucose C6H12O6
Molecular Formulas The molecular formula is a multiple of To determine the molecular formula you need to know and the of the compound
What is the molecular formula for ethane if it has a molar mass of 30 What is the molecular formula for ethane if it has a molar mass of 30.0 g/mol? CH3= g/mol Molecular formula =
Determine the Molecular Formula of Cadinene if it has a molar mass of 204 g and an empirical formula of C5H8
Ask a chemist, they always have Ask a chemist, they always have Solutions
Solutes and Solvents Solution: Solute: Solvent: Solution: Solute: Solvent: (usually found in the largest amounts) If the solvent is water, then it is called an
Solubility Why does sugar “disappear” in your iced tea? Why does sugar “disappear” in your iced tea? How do fish breathe underwater? Why does soda go flat faster when left out than when it is refrigerated? It is all based on solubility!
Solubility Example: iced tea Solute Solvent
States and Solutions Solutions can be any state of matter Solid-solid: Solutions can be any state of matter Solid-solid: Solid-liquid: Liquid-liquid: Liquid-gas: Gas-gas:
How Things Dissolve Need to find/ create “__________” in water for the dissolving substance to move Get _______________ between water molecules and molecules of the solute
Why some coffee is so strong it can “Put hair on your chest.” “Strong’ coffee has more coffee dissolved in a given amount (say 1 pot) than “weak” coffee. Strong coffee = concentrated Weak coffee = dilute Concentration:
Molarity (M) M = moles of solute Most common way to express concentration Molarity is the number of ____________ of solute dissolved in each __________of solution Formula M = moles of solute liters of solution Dependent on _______________ The higher the molarity the stronger the concentration
Practice Problems 1. What is the molarity when 6.0 moles of glucose is dissolved in water to make 3.0 L of solution. 2. How many moles of sodium chloride are there in 500 mL of 4.0 M solution? 3. What is the volume of 3.0 M solution that contains 15 moles of glucose?
How does something so strong become so weak? The answer is dilution. The more dilute something is, the lower the concentration (it’s weaker). To accomplish this, add more solvent How do we know how much to add? M 1V1 = M 2V2 Typically start with a highly concentrated solution and dilute down to what you need
Figure 15. 8: Process of making 500 mL of a 1 Figure 15.8: Process of making 500 mL of a 1.00 M acetic acid solution.
End of Chapter