Mole Concept

In the language of chemistry Mole is one of the seven SI units of measurement and it  is expressed as mol. It  represents  amount of the substance containing Avogadro’s number of particles .These particles may be electrons,protons,atoms,molecules etc.The term Avogadro's number represents unimaginably huge number and that number is  6.022×10²³ .The beauty of this concept lies in the fact that mole is the only unit which is used to express both number and quantity of a substance at the same time.To put it simply if we know the number of moles of a substance we can very precisely tell about amount & number of particles contained in that amount of the substance. Isn't it amazing ?.

Let us try to explore how do we do that.For example one mole of sodium means we have 23 gram of sodium metal and  6.022×10²³ number of  sodium atoms. Similarly one mole of hydrogen reveals that one gram of hydrogen contains 6.022×10²³ atoms of hydrogen.However one mole of both these elements  means Avogadro's number of atoms but on the other hand  there would be a lot of difference so far as their masses are concerned.

In order to dive deep into this concept of moles first we have to get acquainted  with  masses of these atoms.All  atoms of elements have two kinds of masses :

1) Absolute mass

2) Relative mass

Let us take the example of carbon atom whose atomic number is six and mass number is 12.In this example the actual mass of single carbon atom is  1.99×10^-23 g. Where as its relative mass is 12 u.Now we know this without doubt that through some sophisticated  & technical methods like spectroscopy and complex calculations we have figured out  negligible masses of these tiny atoms but questions arises which method is used to calculate the relative masses of these atoms.

As these atoms are terribly small and in the beginning of 20th century due to the lack of sophisticated technology chemists of that time devised a scale in which they took 12 gram of carbon element and divided this amount with Avogadro's number  6.022×10²³ .In this way they got the weight of one carbon atom which comes out to be 1.99×10^-23 g.Then the later value was divided with number 12 to get new number 1.66×10^-24 g.

This value was used as a unit to frame a scale which is known as amu scale. On this scale this value1.66×10^-24 g. has been assigned one unit. Later on this unit was brought into practice by the chemists in order to compare the atomic masses of all other atoms.For example on amu scale  one atom of sodium weighs 23 u which simply means one atom of sodium is 23 times heavier than one amu. Similarly the relative atomic mass of Aluminum atom is 27 u, which means one atom of this element is 27 times heavier than one amu on the atomic mass unit scale.

Let us try to define few terms related to mole concept then we will discuss the numerical aspect of Mole concept:

ATOMIC MASS

The atomic mass unit scale is used to express atomic and molecular masses. Which is called amu or simply u.The atomic mass of carbon isotope-12 is taken as reference for defining atomic masses of elements. 

WHAT IS ONE AMU ?

One amu or simply u is  the mass  equal to one-twelfth of the mass of an atom of carbon-12 isotope.Atomic mass of an element indicates the number of times one atom of that element is heavier than one amu.E.g. atomic mass of sodium is 23 amu which means one atom of sodium element is 23 times heavier than one amu.

TYPES OF ATOMIC MASSES

Atomic masses are of two types:

1. Actual Atomic mass.

2. Relative Atomic mass .

WHAT IS ACTUAL  MASS ?

The mass of one atom of an element or one molecule of an element or a  compound is known as actual mass or absolute mass.
E.g. Actual mass of one  carbon atom  is :- 1.99×10^-23 g.

 ACTUAL MASS OF 1 AMU

Actual mass of one amu that is mass of 1/12th the mass of an atom of carbon-12 isotope.It can be calculated as follow:

            1.99×10^-23 g/12 = 1.66×10^-24 g.

 

RELATIVE ATOMIC MASS

It is the average relative mass of an atom as compared to one amu (1/12th the mass of one atom of carbon-12).E.g. Relative atomic mass of oxygen can be calculated as follow:

 

RELATIVE MOLECULAR MASS

It is the average relatives mass of one  molecule of a substance as compared to one amu or  1/12th the mass of one atom of carbon-12. 

E.g., Molecular mass of methane, (CH4) 

= (12.011 u) + 4 (1.008 u) = 16.043 u.

Similarly, molecular mass of water (H2O):

 =2 atomic mass of hydrogen + 1 atomic mass of oxygen

 = 2 (1.008 u) + (16.00 u) = 18.02 u.

Molecular mass of glucose (C6H12O6):

 = 6(12.011 u) + 12(1.008 u) + 6(16.00 u)

 = (72.066 u) + (12.096 u) + (96.00 u) 

= 180.162 u

GRAM ATOMIC MASS

The relative atomic mass of an element expressed in grams is called gram atomic mass. It is also called gram atom.

E.g. relative atomic mass of Oxygen  is  16 amu And its gram atomic mass is 16 gram.  Similarly
Nitrogen = 14 g
Sodium = 23 g

GRAM MOLECULAR MASS

The molecular mass of a substance expressed in grams is called gram molecular mass. It is also known as gram molecule.

E.g. Water(H2O ) = 18 g
Methane(CH4) = 16 g
Glucose(C6H12O6) = 180 g
Sulphuric acid(H2SO4) = 98 g

FORMULA MASS

Some substances such as sodium chloride do not contain discrete molecules as their constituent units. In such compounds, positive (sodium) and negative (chloride) entities are arranged in a three-dimensional structure. The formula such as NaCl is used to calculate the formula mass instead of molecular mass .Because in the solid-state sodium chloride does not exist as a single entity.
Thus, formula mass of sodium chloride :
= atomic mass of sodium + atomic mass of chlorine
 = 23.0 u + 35.5 u = 58.5 u.

GRAM FORMULA MASS

The formula mass of an ionic compound expressed in grams is known as gram formula mass.
E.g. NaCl = 58.5 g
  Na2CO3 = 106 g
The formula mass of an ionic compound expressed in grams is known as gram formula mass.
E.g. NaCl = 58.5 g
  Na2CO3 = 106 g

MOLE

It is defined as amount of the substance containing Avogadro’s number of particles .(electrons, atoms, molecules etc).

MOLAR MASS

The mass of one mole of any substance is called its molar mass. It is equal to gram atomic mass or gram molecular mass . 

E.g. Sodium = 23 g and 

Water(H2O ) = 18 g

AVOGADRO’S NUMBER

The number of particles present in one mole of any substance is called Avogadro’s number or Avogadro’s constant. It is equal to 6.022×1023.

MOLAR VOLUME

The volume occupied by one mole of any gas at STP is known as molar volume. It is equal to 22.4L.The mass of this volume of gas is equal to its molecular mass.

For example one mole of carbon dioxide gas will occupy 22.4 liter of volume at STP and mass of this volume of gas will be 44 gram

 

 Numerically in order to find out the number of moles we use following three formulae which are quiet interesting when we play with them to solve numerical problem related to mole concept:

I) CALCULATION OF NUMBER OF MOLES FROM MASS OF SUBSTANCE

a) From the atomic mass of an element:

 

b) From the molecular mass of a compound:

 

II) FROM THE NUMBER OF PARTICLES OF A SUBSTANCE

 

 

III FROM THE VOLUME OF GAS

 

 

 

Loschmidt number :-number of molecules present in one centimeter cube of a gas at STP is known as Loschmidt number 

NUMERICALS ON MOLES

1) Calculation of actual mass

1.  actual mass of 1 amu. (1.66 × 10^-24 g )
2.  Calculate actual mass of an atom of  Ag. (1.79 × 10^-22 g )
3. one molecule of oxygen. (5.31 × 10^-23 g )
4. one molecule of water . (2.99 × 10^-23 g )
5.  and one molecule of carbon dioxide. (7.31 × 10^-23 g )
6.  Calculate actual mass of an atom of  C-12. (1.99 × 10^-23 g )

2) Calculation of moles from mass:

1. 5 g of C .(0.42 mol)
   
2. 15 g of Al.(0.56 mol)
   
3. 0.9 g of Fe. (0.0161)
   

3) Calculation of moles from number:

How many moles are there in :

1. 1.02× 10²³   molecules of CO₂ (0.166 mol)
   
2. 12.044 × 10²³   C  atoms (2 mol )
   
3. 6.022 × 10²³   molecules of H₂SO₄ .(1 mol)
   
4. 1.5× 10²³  atoms of sodium .(0.25 mol)
   
5. 1.673 × 10²¹   molecules of water.(0.00272 mol)
   

4) Calculation from volume of gas at STP :

Calculate number of moles in:

1) 70,000 L of ammonia at STP. (3125 mol )

2) 11200 L of hydrogen gass at STP . (500 mol )

3) 11.2 L of sulphur dioxide gas at STP. (0.5 mol )

4) 5.6 L of carbon dioxide gas at STP . (0.25 mol )

5) From moles to mass and number

1)Cal mass and number of atoms in 54 moles of He. (216 gram & 3.252 × 10²⁵  )

2) number of molecules in one drop of water having mass 0.05 g.(1.67 × 10²¹ )

3)calculate mass of 4.5 moles  of C-12. (54 gram)

 

6) Calculation of moles using ideal gas equation

IDEAL GAS EQUATION

PV = nRT

Here P = pressure in atm

V = volume in centimeter cube or Liter

n = number of moles

R = gas constant

T = temperature in K

NUMERICAL

 

1) Using Ideal gas equation calculate the number of  molecules of ammonia in 350 cm³ volume at 273 K and 2 atmospheric pressure.

 

     Value of R =  0.0821 L atm K^-1mol^-1

     Value of R =  82.1 cm³  atm K^-1mol^-1

Ans :-  1.88× 10²² molecules

 

2) Using Ideal gas equation calculate the moles of oxygen in 35 cm³ volume at 6 degree Celsius temperature  and 1.5 atmospheric pressure.

 

        Value of R =  0.0821 L atm K^-1mol^-1

        Value of R =  82.1 cm³  atm K^-1mol^-1

 

Ans :-  2.29 × 10^-3 mol

 

3) Using Ideal gas equation calculate the number of  moles of a gas having volume  42 cm³ volume at 27 degree Celsius temperature and  1140 mm of Hg pressure.

 

     Value of R =  0.0821 L atm K^-1mol^-1

     Value of R =  82.1 cm³  atm K^-1mol^-1

 

Ans :-  2.56 × 10^-3 mol

 

4) Calculate volume, radius and diameter of one molecule of water .Density of water is 1 g/cm³ .

 

Sol :- 1) Find the volume of one molecule of water :-

 

Volume occupied by one mol of water that is 18 gram of water is :

   d  =  m/v 

   v  = m/d   

   v = 18g/1 g/cm³     

   v =  18 cm³

 

Hence Volume occupied by one molecule  of water 

 

    = 18 cm³/6.022 × 10²³  

   =  2.99 × 10^-23cm³

 

2) Find the radius of one molecules of water :-

 

Water molecule has  spherical shape hence volume of a sphere is given by:  

= 4/3×πr³

Hence      2.99 × 10^-23cm³    =   4/3×πr³

                  r³ = 3 × 7  ×  2.99 × 10^-23cm³/4  ×  22

                 r³ =  7.133 × 10²⁴cm³

                 r  = ( 7.133 × 10²⁴cm³)^1/3

                 r =1.925 × 10^-8 cm

 

3) Find the diameter of one molecule of water :-

 

    Diameter = 2  ×  r

                   = 2  ×  1.925 × 10^-8 cm

                   = 3.85 × 10^-8 cm

TABLE OF ELEMENTS WITH ATOMIC MASSES

AT.NO	SYMBOL	ELEMENT	AT. MASS
1	H	Hydrogen	1.008
2	He	Helium	4.0026
3	Li	Lithium	6.94
4	Be	Beryllium	9.0122
5	B	Boron	10.81
6	C	Carbon	12.011
7	N	Nitrogen	14.007
8	O	Oxygen	15.999
9	F	Fluorine	18.998
10	Ne	Neon	20.18
11	Na	Sodium	22.99
12	Mg	Magnesium	24.305
13	Al	Aluminium	26.982
14	Si	Silicon	28.085
15	P	Phosphorus	30.974
16	S	Sulfur	32.06
17	Cl	Chlorine	35.45
18	Ar	Argon	39.948
19	K	Potassium	39.098
20	Ca	Calcium	40.078
21	Sc	Scandium	44.956
22	Ti	Titanium	47.867
23	V	Vanadium	50.942
24	Cr	Chromium	51.996
25	Mn	Manganese	54.938
26	Fe	Iron	55.845
27	Co	Cobalt	58.933
28	Ni	Nickel	58.693
29	Cu	Copper	63.546
30	Zn	Zinc	65.38

 

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