notes: 16.1-16.2 – solutions and concentration
TRANSCRIPT
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NOTES: 16.1-16.2 – Solutions and Concentration
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Solutions – a REVIEW:● SOLUTION – a homogeneous
mixture of pure substances
● the SOLVENT is the medium in which the SOLUTES are dissolved. (The solvent is usually the most abundant substance.)
● Example: Solution: Salt WaterSolute: SaltSolvent: Water
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The process of dissolution is favored by:
● A decrease in the energy of the system (exothermic)
● An increase in the disorder of the system (entropy)
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Liquids Dissolving in Liquids
● Liquids that are soluble in one another (“mix”) are MISCIBLE.
-“LIKE dissolves LIKE”
● POLAR liquids are generally soluble in other POLAR liquids.
● NONPOLAR liquids are generally soluble in other NONPOLAR liquids.
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Liquids Dissolving in Liquids
● Liquids that are insoluble in one another (do not mix) are IMMISCIBLE.
● Example: oil and water
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Factors affecting RATE of dissolution:
● Surface area / particle size Greater surface area, faster it dissolves
● Temperature Most solids dissolve faster @ higher temps
● Agitation Stirring / shaking will speed up rate of dissolution
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SATURATION:
● Unsaturated solution – is able to dissolve more solute
● Saturated solution – has dissolved the maximum amount of solute
● Supersaturated solution – has dissolved excess solute (at a higher temperature); (solid crystals generally form when this solution is cooled)
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SOLUBILITY
● SOLUBILITY = the AMOUNT of solute that will dissolve in a given amount of solvent
**Key difference between this and the RATE of dissolving!!
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Factors Affecting SOLUBILITY:
● The nature of the solute and solvent: different substances have different solubilities
● Temperature: many solids substances become more soluble as the temp of a solvent increases;
however, gases are less soluble in liquids at higher temps.
● Pressure: Only affects the solubility of gases. As pressure increases, the solubility of gases increases.
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SOLUBILITY CURVES:● shows how the
solubility of a particular substance in a particular solvent changes as temperature changes.
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HENRY’S LAW:
● at a given temperature the solubility (S) of a gas is directly proportional to the pressure (P) or S1/P1 = S2/P2
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Henry’s Law EXAMPLE:If the solubility of a gas in water is 0.77 g/L at 3.5 atm of
pressure, what is its solubility (in g/L) at 1.0 atm of
pressure? (the temp. is held constant at 25°C)
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Henry’s Law EXAMPLE:If the solubility of a gas in water is 0.77 g/L at 3.5 atm of
pressure, what is its solubility (in g/L) at 1.0 atm of
pressure? (the temp. is held constant at 25°C)
S1/P1 = S2/P2
0.77 g/L = S2
3.5 atm 1.0 atm
S2 = 0.22 g/L
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Concentration of Solution
● CONCENTRATION refers to the amount of solute dissolved in a solution.
● a DILUTE solution is one that contains a low concentration of solute
● a CONCENTRATED solution contains a high concentration of solute
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MOLARITY
nsol' L
solute mol(M)Molarity
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MOLARITY example #1:
What is the molarity of a 2.0 L solution
containing 4.0 mol NaCl?
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MOLARITY example #1:
What is the molarity of a 2.0 L solution
containing 4.0 mol NaCl?
MOLARITY = mol solute / L solution
= 4.0 mol NaCl / 2.0 L
= 2.0 mol/L
or 2.0 M NaCl
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MOLARITY example #2:
A salt solution contains 0.90 g of NaCl in
100.0 mL of solution. What is the molarity
of the solution?
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MOLARITY example #2:
A salt solution contains 0.90 g of NaCl in
100.0 mL of solution. What is the molarity
of the solution?
mol NaCl = 0.90 g x 1 mol = 0.0154 mol
58.5 g
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MOLARITY example #2:
A salt solution contains 0.90 g of NaCl in
100.0 mL of solution. What is the molarity
of the solution?
MOLARITY = 0.0154 mol / 0.100 L
= 0.154 mol / L
or 0.154 M NaCl
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MOLARITY example #3:
How many moles of solute are present in
1.5 L of 0.24 M Na2SO4?
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MOLARITY example #3:
How many moles of solute are present in
1.5 L of 0.24 M Na2SO4?
1.5 L x 0.24 mol = 0.36 mol Na2SO4
1 L
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MOLARITY BY DILUTION
● When you dilute a solution, you can use this equation:
2211 VMVM
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DILUTION example #1:
How many liters of 5.0 M CuSO4 would be
needed to prepare 0.1 L of 0.5 M CuSO4?
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DILUTION example #1:
How many liters of 5.0 M CuSO4 would be
needed to prepare 0.1 L of 0.5 M CuSO4?
(5.0 M) (V1) = (0.5 M) (0.1 L)
V1 = 0.01 L
or 10. mL
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DILUTION example #2:
How many milliliters of a stock solution of
2.00 M MgSO4 would you need to prepare
100.0 mL of 0.400 M MgSO4?
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DILUTION example #2:
How many milliliters of a stock solution of
2.00 M MgSO4 would you need to prepare
100.0 mL of 0.400 M MgSO4?
(2.00 M) (V1) = (0.400 M) (100.0 mL)
V1 = 20.0 mL
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Example #3: Describe how you would prepare 2.50 L of 0.665 M Na2SO4 solution starting with:a) solid Na2SO4
b) 5.00 M Na2SO4
L 2.50
xM 665.0
nsol' L
solute mol(M)Molarity
mol 1.6625x
g236mol 1
g 1.142SONa mol 6625.1 42
Dissolve 236 g of Na2SO4 in enough water
to create 2.50 Lof solution.
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Example #3: Describe how you would prepare 2.50 L of 0.665 M Na2SO4 solution starting with:a) solid Na2SO4
b) 5.00 M Na2SO4
L) M)(2.50 665.0()M)(V (5.00 1
mL 333 L 333.0V1
2211 VMVM
Add 0.333 L of Na2SO4 to 2.17 L of water.
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PERCENT SOLUTIONS:
● If both the solute and the solvent are liquids, the concentration of the solute can be expressed as a PERCENT BY VOLUME:
% (v/v) = volume of solute x 100%
solution volume
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Percent by Vol. example #1
What is the percent volume of acetone in
water if 25 mL of acetone is added to 75
mL of water?
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Percent by Vol. example #1
What is the percent volume of acetone in
water if 25 mL of acetone is added to 75
mL of water?
% v/v = solute vol. / solution vol.
= 25 mL / (75 + 25 mL)
= 25 mL / 100 mL
= 0.25 x 100%
= 25% acetone (v/v)
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Percent by Vol. example #2:What is the percent by volume of ethanol
(C2H5OH) in the final solution when 85 mL
of ethanol is diluted to a volume of 250 mL
with water?
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Percent by Vol. example #2:What is the percent by volume of ethanol
(C2H5OH) in the final solution when 85 mL
of ethanol is diluted to a volume of 250 mL
with water?
% (v/v) = 85 mL / 250 mL
= 34% ethanol (v/v)
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MASS PERCENT:
● If a solid solute is dissolved into a liquid, the concentration of the solute can be expressed as a PERCENT BY MASS:
% (m/v) = mass of solute (g) x 100%
solution volume (mL)
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Mass % example #1:
What is the % (m/v) of a 100 mL aqueous
solution containing 10 g of NaCl?
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Mass % example #1:
What is the % (m/v) of a 100 mL aqueous
solution containing 10 g of NaCl?
% (m/v) = mass solute / vol. solution
= 10 g NaCl / 100 mL
= 0.10 x 100%
= 10% NaCl (m/v)
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Mass % example #2:
What is the percent of NaCl in a solution
made by dissolving 24 g of NaCl in water
to a final volume of 174 mL?
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Mass % example #2:
What is the percent of NaCl in a solution
made by dissolving 24 g of NaCl in water
to a final volume of 174 mL?
% (m/v) = mass solute / vol. solution
= 24 g NaCl / 174 mL
= 0.138 x 100%
= 13.8% NaCl (m/v)