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MOLES AND MOLAR CONCENTRATIONS
- Define the following terms
- Solution
A solution is a homogeneous mixture formed when a solute is dissolved in a solvent. In a solution, the solute particles are dispersed uniformly throughout the solvent. Solutions can be in various states, such as solid solutions (e.g., alloys), liquid solutions (e.g., sugar dissolved in water), or gaseous solutions (e.g., air).
- Solute
A solute refers to a substance that is dissolved in a solvent to form a solution. The solute is typically present in a smaller amount compared to the solvent. It can be a solid, liquid, or gas.
- Solvent
A solvent is a substance that dissolves the solute and forms a solution. It is usually a liquid, but it can also be a gas or a solid in some cases. The solvent is present in a larger quantity than the solute.
- Saturated solution
A saturated solution is a solution in which the solvent has dissolved the maximum amount of solute that it can under given conditions, such as temperature and pressure. At this point, any additional solute added will not dissolve, and instead, it will remain as undissolved particles. The concentration of the solute in a saturated solution is at its solubility limit.
2. Define
(a) Normality: A concentration unit (N); defined as the number of equivalents of solute per liter of solution (e.g., 1 M H2SO4= 2 N H2SO4)
(b) Molarity : The molarity of a solution is defined as the number of moles of solute per one liter of solution. Note that the unit of volume for molarity is liters, not milliliters or some other unit.
Also, note that one liter of solution contains both the solute and the solvent. Molarity, therefore, is a ratio between moles of solute and liters of solution. To prepare laboratory solutions, usually a given volume and molarity are required. To determine molarity, the formula weight or molar mass of the solute is needed.
(c ) ppm
Parts per million (PPM) is a unit of measurement used when expressing a very dilute concentration level of pollutants in the air, water and other fluids. For example, 1 PPM of ink in water means that in a million mass units of water there would be one mass unit of ink. Thus, PPM refers to one item in a million of anything of the same size. PPM is commonly used in measuring air, water and body fluids pollution. PPM is the mass ratio between a component and a solution. Mathematically, 1 PPM can be expressed as following:
1 PPM = 1 mg/kg
1 PPM = 1 mg/ltr
1 PPM = 0.0001 %
(d) Mass-volume percent solutions
Are also very common. These solutions are indicated by w/v% and are defined as the grams of solute per 100 milliliters of solution.
Example: 1 g of phenolphthalein in 100 mL of 95% ethyl alcohol is a 1 w/v% solution
(e) Decinormal Solution
The solution that contains 1/10th gram equivalent of solute in one liter of its solution is called decinormal solution.
2 Explain the relationship between Normality and molarity
The number of gram equivalent of solute present in in 1 litre of the solution is called normality. It is represented by N.
Normality=Number of gram equivalent of solute/volume of solution in litre
Normality (N) = Molarity × Basicity of acid
also, Normality (N) = Molarity × Acidity of base
- Normality Equation
The equation which is used to determine the strength of unknown solution is called normality equation.
Volume of acid × Normality of acid = Volume of Base × Normality of base
- If 5.00g of sodium chloride is dissolved in exactly 250 cm3of water in a calibrated volumetric flask,
(a) What is the concentration in g/dm3?
Volume = 250/1000 = 0.25 dm3
Concentration = mass / volume
= 5/0.25
= 20 g/dm3
- What is the molarity of the solution?
Ar(Na) = 23, Ar(Cl) = 35.5,
so Mr(NaCl) = 23 + 35.5 = 58.5
mole NaCl = 5.0/58.5 = 0.08547
volume = 250/1000 = 0.25 dm3
molarity = mol of solute / volume of solvent
Molarity = 0.08547/0.25
= 0.342 mol/dm3
c. Calculate the molar concentration of sulfuric acid from the following data. S.G=1.46
%H2SO4= 78%
RMM=98
Mass of solution = 1,000 mL x 1.46 g/mL = 1,460 g
Mass % = 78 X 1460
100
=1138g
Molar mass of Sulfuric acid = 98 g/mol
= mass x mass %
MMHCl
= 1138g
98 = 11.62M
Determine molarity of 37.2% hydrochloric acid (density 1.19 g/mL)
Mass of solution = 1,000 mL x 1.19 g/mL = 1,190
Mass % = 37.2 % = 0.372
Molar mass of hydrochloric acid = 36.4 g/mol
=mass x mass %
MMHCl
1,190 g x 0.372
= ————————
36.4 g/mol
= 12.1 moles
Molarity = moles/liters
= 12.1
moles/1 liter = 12.1 M
Calculate the the pH of 1×10−4M H2SO4 solution?
Sulphuric acid is a dibasic acid and hence gives two H+ atoms in it’s solution. Since, it is a strong acid it dissociates completely as:
H2SO4⇌2H++SO42−
[H+] = 2 X 0.0001M
Ph = −log(2 X 0.0001 )
=3.70
- 4g of sodium hydroxide pellets were disolved in 1 litre of distilled water . determine the concentration of the solution in
(i) moles per liter
(ii) Parts per million
- 20cm3 of the solution in (a) was titrated against 25cm3 of sodium hydroxide . determine the concentration of the hydroxide in moles per litre
- Calculate the amount of NaOH required to prepare 0.1Msolution in a 250ml volumetric flask (NaOH=40)
- Describe how solution in (c ) is prepared in the laboaratory
- Calculate the molarity of a solution containing 4.9g of sulphuric acid in 500cm3 solution (H=1, S=32,0=16)
- Calculate the mass of potassium carbonate required to prepare 0.1M solution in one litre volumetric flask(K=39,C=12,O=16)
- (a)Determine the molarity of a solution prepared by dissolving 3.15g of nitric acid in 250ml of water (H=1,N=14, O=16)
- 20cm3 of a 0.1M NaOH was neutralized by 8cm3 of dilute sulphuric acid . calculate the number of moles of the acid .
- (a)(i) Calculate the amount of KCl required to prepare 100ppm chloride ions solution in a 250ml volumetric flask (K=39, Cl=35.5)
(ii)Outline the procedure for laboratory preparation of dhloride ions solution in (a)(i)
- Calculate the amount of solution prepared in (a)(ii) above required to make 20ml of a 5ppm chloride ion solution
- Determine the number of moles present in 25ml of 0.05Msodium carbonate solution
- 95g of potassium bromide was dissolved in 400cm3of water.
(a) Calculate its molarity. [Ar‘s: K = 39, Br = 80]
moles = mass / formula mass, (KBr = 39 + 80 = 119)
mol KBr = 5.95/119 = 0.050 mol
400 cm3 = 400/1000 = 0.400 dm3
molarity = moles of solute / volume of solution
molarity of KBr solution = 0.050/0.400 = 0.125 mol/dm3
- (b) What is the concentration in grams per dm3?
Concentration = mass / volume, the volume = 400 / 1000 = 0.4 dm3
Concentration = 5.95 / 0.4 = 14.9 g/dm3
- What mass of sodium hydroxide (NaOH) is needed to make up 500 cm3 (0.500 dm3) of a 0.500 mol dm-3 (0.5M) solution? [Ar‘s: Na = 23, O = 16, H = 1]
1 mole of NaOH = 23 + 16 + 1 = 40g
molarity = moles / volume, so mol needed = molarity x volume in dm3
500 cm3 = 500/1000 = 0.50 dm3
mol NaOH needed = 0.500 x 0.500 = 0.250 mol NaOH
therefore mass = mol x formula mass
= 0.25 x 40 = 10g NaOH required
- How many moles of H2SO4are there in 250 cm3 of a 0.800 mol dm-3 (0.8M) sulphuric acid solution? What mass of acid is in this solution?
[Ar‘s: H = 1, S = 32, O = 16]
(a) molarity = moles / volume in dm3, rearranging equation for the sulfuric acid
mol H2SO4 = molarity H2SO4 x volume of H2SO4 in dm3
mol H2SO4 = 0.800 x 250/1000 = 0.200 mol H2SO4
(b) mass = moles x formula mass
formula mass of H2SO4 = 2 + 32 + (4×16) = 98
0.2 mol H2SO4 x 98 = 19.6g of H2SO4
- A solution of calcium sulphate (CaSO4) contained 0.500g dissolved in 2.00 dm3 of water. Calculate the concentration in (a) g/dm3, (b) g/cm3 and (c) mol/dm3.
(a) concentration = 0.500/2.00 = 0.250 g/dm3,
then since 1dm3 = 1000 cm3
(b) concentration = 0.250/1000 = 0.00025 g/cm3
(or from 0.500/2000)
(c) At. masses: Ca = 40, S = 32, O = 64,
formula mass CaSO4 = 40 + 32 + (4 x 16) = 136
moles CaSO4 = 0.5 / 136 = 0.00368 mol in 2.00 dm3 of water
concentration CaSO4 = 0.00368 / 2
- Describe how a sample of Zinc (II) carbonate can be prepared with Zinc oxide
- Describe how to prepare 250 mL of a 0.30 M NaCl solution.
A 0.30 M NaCl solution means that there is 0.30 mol NaCl in every liter of solution.
For example:
To make the solution we need to calculate the amount of NaCl to dissolve to make 250 mL of solution.
Start with 250 mL
13. Distinguish between a working solution and stock solution
A stock solution is a large volume of common reagent, such as hydrochloric acid or sodium hydroxide, at a standardized concentration. This term is commonly used in analytical chemistry for procedures such as titrations, where it is important that exact concentrations of solutions are used.
Working solutions are any dilutions that are made using the stock, generally into aqueous solution.
- Explain the limitation of using tap water in preparing potassium permanagenage standard solution
Any kind of chemical or biochemical experiment demands use of deionized or distilled water for preparing all solutions. Dionized water is highly prefered becouse it is almost completely free of all disolved ions unlike distilled water which may still be having some dissolved ions . Tap water is not used to prepare standard solutions for titration because of the impurities it contains which could interfere with the results. If you were titating with an acid, the results would be on the high side and if you were titrating with alkaline they would tend to be on the low side because of the minerals likely to be in the tap water.
- Outline the procedure for standardizing potassium thocyanate solution using 0.1M silver nitrate solution
Potassium thiocyanate solution has to be standardized, as it is not possible to prepare and dry KSCN pure enough so that it can be used as a standard substance for solution preparation. The easiest method if the standardization require standardized solution of silver nitrate. As KSCN solution is used for back titration of the excess of AgNO3, when we need to standardzie KSCN solution we usually have standardized silver nitrate solution ready.
Reaction taking place is
AgNO3 + KSCN → AgSCN↓ + KNO3
Procedure to follow:
- Pipette 25 mL aliquot of about 0.1M AgNO3solution into 250mL erlenmayer flask.
- Add 50 mL of distilled water.
- Add 1 mL of 10% FeNH4(SO4)2solution.
- Titrate with potassium thiocyanate till the first visible color change.
- Explain why iodine solution is prepared using potassium iodide solution
Molecular iodine is only slightly soluble in water. Adding potassium iodide to iodine in water rapidly converts the molecular iodine (I2) to the much more soluble triiodide ion (I3-).
An equimolar solution of iodine and potassium iodide is called Lugol’s solution. The iodine in Lugol’s solution is mostly in the form of triiodide ion, in equilibrium with molecular iodine. In short, potassium iodide is used to be able to attain much higher concentrations of iodine in aqueous solution without having to use organic solvents