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Molarity and Molality are terms used to express the concentration of a solution. The quantity of the solute in the solution determines its concentration. Molarity or molar concentration is the number of moles of solute per liter of solution. Molality, on the other hand, is the number of moles of solute in one kilogram of solvent. Molarity and Molality are used to quantitatively express the strength of the solution whether it is concentrated or dilute.
- Molarity is concentration expressed in terms of moles per unit volume.
- Molality is concentration expressed in terms of moles per unit mass.
The relation between Molarity (M) and Molality (m) is given by
| \(m = \frac{1000M}{1000 \rho - MM'}\) |
Where
- ρ is the density of the solution (mg/mL).
- M1 is the molecular weight of the solute.
Key Terms: Molarity, Molality, Concentration of a Solution, Solute, Solvent, Solution, Mole, Density, Mass
What is Molarity?
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Molarity, also known as molar concentration, is defined as the number of moles of the solute in 1 l (liter) of solution. It is denoted using M (capital m). The formula can be given as:
\(Molarity= \frac {moles\, of \,solute}{liters\, of\,solution}\)
- Molarity quantifies the amount of solute (the substance being dissolved) in relation to the volume of the solution.
- Molarity provides insights into how densely packed the solute particles are within the solution.
Molarity
Solute, Solvent, and Solution
The solution is a liquid-state mixture comprising two components, i.e. a solute and a solvent.
- A solute is a component of a mixture present in small quantities. It is the substance being dissolved within the solution.
- A solvent is a component present in large quantities. It is responsible for dissolving the solute.
Mole
A mole is the standard unit to express the number of atoms and molecules of a substance present. For example, 12 gm of Carbon 12 represents one mole.
What is Molality?
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Molality is defined as the number of moles of solute present in 1 kg (kilogram) of solvent. It is denoted using m (small m).
\(Molality=\frac{moles \,of \,solute}{kg\, of \,solution}\)
Unlike molarity, which relates the number of moles to the volume of the entire solution, molality specifically considers the mass of the solvent. Molality is useful in certain situations, such as in colligative properties of solutions, where it becomes a crucial factor in determining the changes in properties like boiling point elevation and freezing point depression.
Molality
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Relation Between Molarity and Molality
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Molarity and Molality relation plays a crucial role in concentration determination. The following derivation illustrates the relation between molarity and molality.
- Mass of given solute: W
- Weight of solvent: W’
- Volume of solution: V
- Molar mass of solute: M’
- Molality: m
- Molarity: M
Let the number of moles be represented as X,
Therefore,
\(X= \frac{mass\ of\ solute\ taken}{molar\ mass\ of\ solute\ } = \frac{W}{M'}\) ……….……… (1)
Molarity can then be expressed as,
\(M= \frac{W}{M'} * \frac{1000}{V} = \frac {W*1000}{M' * V}\)……………. (2)
Molality can be expressed as,
\(m=\frac{W}{M'} * \frac {1000}{W'} = \frac {W*1000}{M'*W'}\)……………. (3)
Density,
d = \(\frac {mass\ of\ solute\ and\ solvent}{volume}= \frac{W+W'}{V}\) --- (4)
From (2),
\(V= \frac{W*1000}{M'*m}\)
From (3),
\(W'= \frac {W*1000}{M'*m}\)
Hence,
\(W+W' = W+ \frac {W*1000}{M'*m}\)
\(= \frac {W*1000}{M'} [\frac{M'}{1000}+\frac{1}{m}]\)…………. (5)
By dividing (5) by (2) we get,
\(d= (\frac{M'}{1000}+\frac{1}{m})*M \)
\(\frac{d}{M}=\frac{M'}{1000}+\frac{1}{m}\)
\(\frac{1}{m}=\frac{d}{M}-\frac{M'}{1000}\)
This is the relation between the Molarity and Molality of a solution. The molarity and morality relation formula emphasizes the interdependence of molarity, molality, and density in characterizing a solution. The relation helps in chemical analysis, especially when dealing with concentration-dependent reactions.
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Solved ExampleQues. Consider a solution where the molarity (M) is 0.5 M, the molar mass of the solute (M') is 30 g/mol, and the density (ρ) is 1.2 g/mL. Calculate the molality (m) through the molarity morality relation. Solution: Relation: \(m = \frac{1000M}{1000 \rho - MM'} \) Substitute the given values: \(m = \frac{500}{1200 - 15} \) \(m = \frac{500}{1185} \) \(m \approx 0.422 \, \text{mol/kg} \) For the given solution with a molarity of 0.5 M, a molar mass of the solute of 30 g/mol, and a density of 1.2 g/mL, the calculated molality is approximately 0.422 mol/kg. Ques. How molarity and molality are impacted with temperature? Ans. The impact of temperature on molarity and molality lies in their dependence on volume and mass, respectively. As temperature changes, Volume can fluctuate, affecting molarity. In contrast, molality, which relies on the mass of the solvent, is not influenced by temperature, making it more stable measure of concentration under varying thermal conditions. |
Difference Between Molarity and Molality
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Molarity and Molality are two interrelated terms in the concentration of a solution. Tabulated below are the differences between molarity and morality:
| Molarity | Molality |
|---|---|
| Molarity is the number of moles of the solute in one litre of a solution. | Molality is the number of moles of solute present in 1 kilogram of solvent. |
| It is represented by the symbol ‘M’. | It is represented by the symbol ‘m’. |
| Molarity Formula =\(\frac {moles \,of \,solute}{volume \,of \,solvent \,in \,liters}\) | Molality Formula = \(\frac{moles\, of \,solute}{weight \,of \,solvent \,in \,kg}\) |
| It is the ratio of moles to the volume of solution in liters. | It is the ratio of miles to weight of solvent in kgs. |
| Relation between Molarity and Molality: \(M= \frac {1000d}{[\frac{1000}{m}+M^1]}\) | |
Important Topics for JEE MainAs per JEE Main 2024 Session 1, important subtopics included in the relation between molarity and molality are as follows:
Some memory based important questions asked in JEE Main 2024 Session 1 include: 1. Calculate the molarity of a solution having a density of 1.5 g/ml, percentage of (w/w) of solute as 36%, and molecular weight of solute 36 g/mol? 2. If a 250 mL solution of CH3COONa of molarity 0.35 M is to be prepared, what is the mass of CH3COONa required in grams? Round off the answer to the nearest integer. |
Things to Remember
- Molarity and Molality are terms used to express the composition and concentration of a solution.
- In a solution, the solute is the component present in small quantities.
- In a solution, the solvent is the component present in large quantities.
- The solute and solvent mixture forms the solution.
- Molarity is defined as the number of moles of the solute per liter of the solution. It is denoted by M.
- Molality is defined as the number of moles of the solute per kg of the solvent. It is denoted by m.
- The relation between molarity and molality is given by \(M= \frac {1000d}{[\frac{1000}{m}+M^1]}\).
- Concentration expressed in molarity and molality finds application in the study of solution properties with respect to vapor pressure and temperature changes.
Previous Year Questions
- The number of water molecules is maximum in… [NEET 2015]
- 1.0 g of magnesium is burnt with 0.56 g… [NEET 2014]
- The temperature of 32∘C is equivalent to… [MHT CET 2019]
- Which of the following compound has all four types… [BITSAT 2016]
- Complete combustion of 1.80g of an oxygen-containing compound… [JEE Main 2021]
- 25.3g of sodium carbonate, Na2CO3 is dissolved in enough water… [NEET 2010]
- 6.02×1020 molecules of urea are present in… [NEET 2013]
- A mixture of 2.3g formic acid and 4.5g oxalic acid is treated… [NEET 2018]
- A mixture of gases contains H2 and O2 gases in the ratio of 1:4… [NEET 2015]
- An element, X has the following isotopic composition… [NEET 2007]
Sample Questions
Ques. What is Molarity? (1 Mark)
Ans. Molarity is a measure of the concentration of a solution. It is defined as the number of moles of solute present in one liter of the solution. Molarity is expressed in units of moles per liter (mol/L).
Ques. Explain the steps to determine the molality of the solution using the given molarity. (3 marks)
Ans. To determine the molality (m) of a solution with known molarity (M), the following steps are performed:
- Determine the density (ρ): Measure the mass and volume of a known quantity of the solution. Calculate the density using the formula density = mass/volume.
- Use the relation formula: Substitute the known values of molarity (M), density (ρ), and molar mass of solute (M′) into the relation formula to find the molality (m).
m = 1000M/{1000ρ – MM’}
These steps allow you to determine the molality of the solution based on the given molarity and experimentally determined density.
Ques. What is the molality of a sodium sulfate solution having 138 gm of sodium sulfate ions per kg of water (solvent)? (3 Marks)
a. 16
b. 8
c. 6
d. 12
Ans. (c) 6
Explanation: Given that
- Weight of sodium ions given = 138 gm
- Molecular mass of sodium = 23 gm
- Number of moles of sodium ion = 138/23 = 6 moles
- Weight of solvent given = 1 kg
Hence,
Molality = number of moles of sodium ion/ weight of solvent in kg
= 6/1
= 6 m
Ques. What is the molarity of a solution containing 50 gm of NaCl in 500 gm of a solution having a density of 0.936 gm/cm3: (3 Marks)
Ans. Density = Mass/volume
Volume = Mass/density
= 500/0.936 = 534.18 ml of solution
Molarity = number of moles of solute/ volume of solution in l
\(=\frac{50}{58.44}* \frac {1000}{534.18}\)
=1.60 M
Ques. Which is more preferred- molarity or molality? (2 Marks)
Ans. Molarity is the number of moles of solute present in 1 liter of the solution. Molality is the number of moles of solute in 1 kg of solvent. This clearly indicates molarity is a function of the volume of the solution.
- A change in the temperature of the system can hence affect the molarity of the solution.
- Molality is a function of the mass of the solution and thus has no effect on a change in temperature.
- This independence of molality on temperature makes it a more preferred choice for expressing solution concentrations.
Ques. Differentiate in terms of concentration: 1M vs 1m. (2 Marks)
Ans. 1M means 1 mole of solute in 1L of solution. Here, we may note that the solution is a mixture of both solute and solvent.
1m means 1 mole of solute in 1kg of solution. Here, the solution is 1L of solvent.
This implies that the quantity of solvent is more in 1m of the solution when compared to 1M of the solution (for the same 1 mole of solute). Thus the concentration of 1M solutions is greater than 1m of solution with the same number of moles of the solute.
Ques. Define the Normality of a solution. (2 Marks)
Ans. Normality is expressed as the gram equivalent of solute per liter of solution. It is another way of calculating the concentration of a solution like the molarity and molality. The S.I. unit is eq/L and is denoted by N. It can be calculated by the formula:
N = Weight of Solute in gm. / Equivalent Weight × Volume in ltr.
Ques. The mole fraction of water in a sulphuric acid solution is 0.85. Calculate the molality of the solution. (4 Marks)
Ans. Mole fraction of water in solution = 0.85-mole fraction H2SO4 in solution =1−0.85=0.15.
If n1 is the number of moles of water and n2 is the number of moles of H2SO4 in the solution, then:
Mole fraction of H2SO4 = \(\frac{n_2}{n_1 + n_2}\) = 0.15
The molality of the H2SO4 solution means the number of moles of H2SO4 present in 1000 of H2O.
Therefore, we have, w1=1000
g or n1 = 1000/18 = 55.55, n2=1
n2/55.55+n2 = 0.15
n2 = 0.15n2 + 8.3325
or Molality (n2) = 9.8 m
Ques. The density of the 3M solution of NaCl is 1.25 g mL−1. Calculate the molality of the solution. (5 Marks)
Ans. The volume of the solution is 1000 ml.
∴ Moles of NaCl=3 moles
∴ Mass of NaCl=3×(23+35.5)g
=175.5 g=0.1755 kg
∴ Density = Mass of solution/Volume of solution
∴ Mass of solution = 1.26×1000
=1260 g = 1.26 kg
∴ Mass of solvent = Mass of solution- Mass of NaCl
=1.26−0.1755
=1.0845 kg
∴ Molality = Moles of NaCl/Mass of solvent (kg)
=1.08453
∴ Molality = 2.766 m
Ques. Calculate the mole fraction of ethylene glycol (C2H6O2) in a solution containing 20% of C2H6O2 by mass. (5 Marks)
Ans. Let us assume that we have 100 g of solution.
Then the mass of C2H6O2 in this solution will be 20 g (20% of 100 g). Similarly, the mass of water in this solution will be 80 g.
Molar mass of C2H6O2
=2x12 + 6x1 + 2x16 = 24+6+32 = 62 g mol-1
Molar mass of H2O = 2x1+16 = 18 g mol-1
Moles of ethylene glycol = (20g)/(62g\mol(-1)) = 0.322 mol
Moles of water = (80g)/(18g\mol(-1)) = 4.44 mol
Now, mole fraction can be calculated as follows: X(glycol)=(ng)/(ng+nw)
=(0.322)/(0.322+4.444) = 0.068
Molarity (M): The number of moles of solute dissolved in one liter of solution is called the molarity of the solute.
Ques. Calculate the molality of 2.5 g of ethanoic acid (CH3COOH) in 75 g of benzene. (2 Marks)
Moles of C2H4O2 = (2.5g)/(60g\mol(-1))=0.0417 mol
Mass of benzene in kg = (75 g)/(1000 g\ kg(–1)) = 75 xx 10(–3) kg
Molality of C2H4O2 =(0.0417 mol)/(75x10(-3)kg)=0.556 mol kg-1
Ques. A sulfuric acid solution containing 571.4 g of H2SO4 per liter of the solution has a density of 1.329 g/cm3. Calculate the molality of H2SO4 in this solution. (3 Marks)
Ans. 1 L of solution = 1000 mL = 1000 cm3
1.329 g/cm3 times 1000 cm3 = 1329 g (the mass of the entire solution)
1329 g minus 571.4 g = 757.6 g = 0.7576 kg (the mass of water in the solution)
571.4 g / 98.0768 g/mol = 5.826 mol of H2SO4
5.826 mol / 0.7576 kg = 7.690 m
Ques. What is the mass of a sample of 0.449 molal KBr that contains 2.92 kg of water? (3 Marks)
Ans. 1) Molality = moles solute divided by kilograms solute:
0.449 mol/kg = x / 2.92 kg
x = 1.31108 mol of KBr
2) Moles times molar mass equals grams:
(1.31108 mol) (119.0023 g/mol) = 156 g KBr
3) Adding them up:
156 g KBr + 2920 g water = 3076 g total
Ques. What is the molality of NaCl in an aqueous solution in which the mole fraction of NaCl is 0.100? (2 Marks)
Ans. A mole fraction of 0.100 for NaCl means the mole fraction of water is 0.900.
Let us assume a solution is presently made up of 0.100 moles of NaCl and 0.900 moles of water.
- Mass of water present \(\rightarrow \) (0.900 mol) (18.015 g/mol) = 16.2135 g
- Molality of solution \(\rightarrow \) 0.100 mol / 0.0162135 kg = 6.1677 m
Ques. Calculate the molality of a solution containing 16.5 g of naphthalene (C10H8) in 54.3 g of benzene (C6H6). (2 Marks)
Ans. Molality = moles of naphthalene/kilograms of benzene
(16.5 g / 128.1732 g/mol) / 0.0543 kg = 2.37 m
Ques. A solution of hydrogen peroxide is 15.2% by mass. What is the molarity of the solution? Assume that the solution has a density of 1.01g/mL. (4 Marks)
Ans. Let’s assume that we have 1.00L of this solution. Hydrogen peroxide has a molecular formula of H2O2.
Use the given density to find the mass of the solution.
1.00L⋅1000mL/1L⋅1.01g/mL=1010g
Next, find the mass of the hydrogen peroxide present in the solution.
1010g(0.152)=153.52g
Convert the mass of hydrogen peroxide into moles of hydrogen peroxide.
153.52g of H2O2⋅1 mole H2O2/31.04g H2O2=4.95 moles of H2O2
Molarity=moles of solute/liters of solution
Since we have 1.00L of the solution, the molarity is 4.95M.
Ques. How many milliliters of a 5.0MCuSO4 solution is needed to prepare 0.350L of 0.500MCuSO4? (2 Marks)
Ans. 35mL of 5.0MCuSO4 solution is needed to prepare 0.350L of 0.500MCuSO4.
We can use the formula M1V1 = M2V2
Thus, (5.00M1)(V1)=(0.350M2)(0.500L)
V1=0.035L=35mL
Ques. How many ml of water are needed to dilute 65ml 7M KCl to 2M? (2 Marks)
Ans. Minitial \(\times\) Vinitial = Mfinal \(\times\) Vfinal
- Minitial = 7M
- Vinitial = 65ml
- Mfinal = 2M
- Vfinal =?
Solve for Vfinal since we are looking for the final volume of water needed to dilute the existing solution:
Vfinal = Minitial \(\times\) Vinitial/Mfinal
=7M \(\times\) 65ml/2M = 227.5ml
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