Class 9 Science
Quick View
Ch- 3 Atoms and Molecules
Atoms
Ancient Greek philosophers - Democritus and Lucius, said that when
matter is divided and divided, after some time particles are found which cannot
be further divided. The democrats gave the name to this particle an atom.
According to English scientist John Dalton’s atomic theory, all matter,
whether an element, or a compound or a mixture is composed of small particles
called atoms.
Atoms are the smallest indivisible particles of an element that take part in chemical reaction.
The postulates of this theory may be stated as follows:
(i) All matter is made of very tiny particles called atoms.
(ii) Atoms are indivisible particles, which cannot be created or
destroyed in a chemical reaction.
(iii) Atoms of a given element are identical in mass and chemical
properties.
(iv) Atoms of different elements have different masses and chemical
properties.
(v) Atoms combine in the ratio of small whole numbers to form compounds.
(vi) The relative number and kinds of atoms are constant in a given
compound. Atoms are composed of fundamental or subatomic particles which are
protons, neutrons and electrons.
- Atoms
are composed of fundamental or subatomic particles which are protons,
neutrons and electrons.
- Protons
are positively charged particles, electrons are negatively
charged particles and neutrons are neutral in charge.
- Central
part of the atom called nucleus contains both protons and neutrons.
Electrons are present around the nucleus.
- Atoms
are very small in size. Atomic radius is measured in nano-metres.
1/109 m = 1 nm
1 m = 109 nm.
- Atoms normally exist in a combined form which gives us various forms of matter.
Two important laws of chemical combination given by Antoine L. Lavoisier and Joseph L. Proust as follows:
1.Law
of constant proportion - This law was stated by Proust as “In a chemical
substance the elements are always present in definite proportions by mass”.
Example- Water is a compound in which the ratio of the mass of
hydrogen to the mass of oxygen is always 1:8.
2H2O = 2H2 + O2
2H2 = 2 (2 x 1) = 4 ( atomic mass of hydrogen = 1)
O2 =16 x 2 = 32 (atomic mass of oxygen = 16)
Ratio of hydrogen and oxygen in 2 molecules of water
4 : 32 or 2 : 16 or 1: 8
1.Law of conservation of mass- Mass can neither be created nor destroyed in a chemical reaction.
Example: A + B → C + D
Reactants → Products
Mass of reactants = Mass of products
N2 + 3H2 = 2NH3
(2 X 14) + 3 x (1 x 2) = 2 ( 14 + 1 x 3 ) [ At. mass of N = 14
and H= 1]
28 + 6 = 2 x 17
34 = 34
Total mass of reactants= Total mass of products
The Modern day symbols of atom of different elements:
Dalton was the first scientist to use these symbols for elements.
Symbols of some elements are given from the first letter of the name and
a letter, appearing later in the name, some other symbols have been taken from
the names of elements in Latin.
Symbols for some elements:
|
Element |
Symbol |
Element |
Symbol |
|
Aluminium |
Al |
Iodine |
I |
|
Argon |
Ar |
Iron |
Fe |
|
Barium |
Ba |
Lead |
Pb |
|
Boron |
B |
Magnesium |
Mg |
|
Bromine |
Br |
Neon |
Ne |
|
Calcium |
Ca |
Nitrogen |
N |
|
Carbon |
C |
Oxygen |
O |
|
Chlorine |
Cl |
Potassium |
K |
|
Cobalt |
Co |
Silicone |
Si |
|
Copper |
Cu |
Silver |
Ag |
|
Fluorine |
F |
Sodium |
Na |
|
Gold |
Au |
Sulpher |
S |
|
Hydrogen |
H |
Uranium |
U |
Atomic number – The number of protons present in the nucleus of an atom is called its atomic number.
In an atom Number of protons = Number of
electrons.
Therefore,
Atomic number = Number of protons = Number of electrons
Molecules are a group of two or more atoms that are chemically bonded together by
the attractive forces.
Definition - Molecule is the smallest particle of an element or a compound
that is capable of an independent existence and shows all the properties of
that substance.
Example:
H2 is a 1 molecule of element hydrogen in which two atoms of
hydrogen combine together by the attractive forces.
H or 2H are not molecules; they are one or two atoms of hydrogen.
Similarly H2O is a 1 molecule of compound of water.
O2 is a molecule of oxygen consists of two atoms of oxygen
and it
is known as a diatomic molecule, O2.
O3 is a molecule of 3 atoms of oxygen which is known as
ozone.
- A
molecule is formed when two or more atoms bonded chemically.
- A
molecule of a compound has two or more elements.
The number of atoms constituting a molecule is known as its atomicity.
- Atomicity
of O2 is 2 and is called diatomic element,
- Atomicity
of O3 is 3, and atomicity of H2O is 3 (2 atoms
of hydrogen and 1 atom of oxygen) etc. and are called tri-atomic elements.
- 1
molecule of P4 phosphorus contains 4 atoms and is called
tetra-atomic.
- Sulfur
(S8) contains more than 4 atoms are called poly-atomic.
Compound is a substance that has two or more elements of different atoms in a fixed ratio.
Compounds are formed by the combination of two or more elements.
Example: CaCO3 is a compound of 1 atom of calcium, 1 atom of carbon
and 3 atoms of oxygen.
- A
compound is formed when different elements bonded chemically.
- All
compounds are molecules but all molecules are not compounds.
Compounds are composed of metals and non- metals in which metals are
positively charged particles and non- metals are negatively charged particles.
These charged particles are called ions.
Example: Common salt is a compound of sodium and chlorine, where sodium (metal)
is a positively charged particle and chlorine (non- metal) a negatively
charged particle. Sodium and chlorine are the ions. They are represented by Na+
and Cl-.
Example: Na+ is an
anion and is a Cl- cation.
Poly-atomic ion - A group of atoms
carrying a charge is known as a poly-atomic ion.
Example: Ammonium- NH4+, Nitrate- NO3-,
Sulphate- SO42-, Hydrogen carbonate- HCO3-.
Chemical formula of a compound is a symbolic representation of the
number of atoms and type of atoms of molecules.
Example: Chemical formula of compound sodium hydroxide is NaOH. This formula
represents that sodium hydroxide composed of one atom of sodium, one atom of
oxygen and one atom of hydrogen.
The combining capacity of an element with other is known as its
valency.
Valency of an element depends on the number of electrons present in the
outermost shell of their atoms.
In metals, number of electrons in outermost shell is less than 4 and
valency is equal to the number of electrons in the outermost shell of their
atoms.
Example: Valency of Na
Atomic number of Na = 11
Electronic configuration = 2, 8, 1 No. of electron in
outermost shell is 1.
Therefore valency = 1
In non-metals number of electrons is more than 4 and valency is equal to
eight minus the number of electrons in the outermost shell.
Example: Valency of Chlorine Cl
Atomic number of chlorine = 17
Electronic configuration = 2, 8, 7
Valency of Cl = 8 - 7 = 1
The rules for the writing a chemical formula:
- The
valencies or charges on the ion must balance.
- When
a compound consists of a metal and a non-metal, the symbol of the metal is
written first.
- The poly-atomic ion in the compound should be enclosed in the bracket.
Formula of simple compound
1. Formula of Calcium carbonate
Ca CO3
Valency +2 -2
( Exchanges of valency )
(Ca)2 (CO3)2
Molecular formula of calcium carbonate is CaCO3
2.
Formula of Water
H O
1 -2
(Exchanges of valency)
H2 O1
Molecular formula of water is H2O
The Molecular Mass
The molecular mass of a substance is the sum of the atomic masses of all the atoms in a molecule of the substance. It is expressed in atomic mass units (u).
Example:
Calculate the relative molecular mass of the water (H2O).
Solution: Water contains the
elements of hydrogen and oxygen.
Atomic mass of hydrogen = 1u,
Atomic mass of oxygen = 16 u
Therefore the molecular mass of water = 1 x 2 + 16 = 2 + 16 = 18 u.
To calculate the molecular mass of CaCO3
Calcium carbonate contains calcium Ca, Carbon C and oxygen O.
Atomic mass of Ca = 20 u
Atomic mass of C = 12 u
Atomic mass of O = 16 u
Therefore the molecular mass of CaCO3 = 40 + 12 + 16 x 3 = 40 + 12 + 48= 100
Formula Unit Mass
Example: Ions contained substance NaOH
Formula unit mass of NaOH
Atomic mass of Na = 23 u
Atomic mass of O = 16 u
Atomic mass of H = 1 u
Formula unit mass = 23 + 16 + 1 = 40 u
Mole
concept
1 mole of any substance = 6.022 x 1023.
6.022 x 1023 number is called Avogadro Constant.
Therefore the number of particles or atoms, or molecules or ions present
in 1 mole of any substance is 6.022 × 1023. This number is called
the Avogadro Constant or Avogadro Number.
Avogadro's number represented by N0.
It was named in honour of the Italian scientist Amedeo Avogadro.
The mass of 1 mole of a substance is equal to its relative atomic
or molecular mass in grams.
1 mole = 6.022 × 1023 number = Relative mass in grams.
Example:
The mass of 1 mole of NaOH = Molecular mass of NaOH = 23 + 16 + 1= 40 g.
[Molecular mass of Na = 23g, O = 16g , H = 1g ]
Mathematical expressions to find the mole:
Given mass = m
Molar mass = M
Number of moles = n
Given number of particles = N
Avogadro's number = N0
Then
I. Number of moles = Given mass in g / molar mass
Solution:
Molar mass of sodium Na (m) = 23 g
Given mass of sodium Na (M) = 69 g
Therefore
Number of moles = Given mass in g / molar mass = 69 / 23 = 3
Number of moles = 3 moles
II. Number of moles = Given number of particles/Avogadro's number
Example: Calculate the number of mole of 12.044 × 1023 particles of Mg.
Solution:
Given
Number of particles = 12.044 × 1023
Avogadro's number (1 mole) = 6.022 × 1023
Number of moles = N / N0= 12.044 × 1023 / 6.022 × 1023
Number of moles = 2
moles.
III. Calculate the mass of the followings:
(i) 0.5 mole of O2 gas
(ii) 0.5 mole of O atoms
(iii) 3.011 × 1023 number of O atoms
(iv) 6.022 × 1023 number of O2 molecules.
Solution:
(i) We have
1 Mole = Molar mass
Molar mass of O2= 2 X 16 = 32 g
Mass = Number of moles X Molar mass
Mass = n X M = 0.5 X 32 = 16 g.
(ii) 1 Mole = Molar mass
Molar mass of O= 16 g
Mass = Number of moles X Molar mass
Mass = n X M = 0.5 X 16 = 8 g.
(iii) Number of moles = Given number of particles/Avogadro's number
And N / N0= 3.011 × 1023 / 6.022 × 1023 = 1/2
Number of moles = 1/2 mole = 0.5 moles.
Molar mass of O = 16 g
Now mass = n X M = 0.5 X 16 = 8 g.
(iv) Number of moles = Given number of particles/Avogadro's number
N / N0= 3.011 × 1023 / 6.022 × 1023 = 1/2
Number of moles = 1/2 mole = 0.5 moles.
Molar mass of O2 = 16 X 2 = 32 g
Now mass = n X M = 0.5 X 32 = 16 g.
IV. Calculate the number of particles
in each of the following:
(i) 80 g of Ca atoms
(ii) 7 g N2 molecules
(iii) 0.1 moles of carbon atoms
Solution:
(i) Given mass of calcium Ca = 80 g
Molar mass of Ca = 40 g
Avogadro's number = 6.022 × 1023
Number of particles
N= Avogadro's number
X Given mass /
Number of particles N = (6.022 × 1023 x 80 g) / 40
Number of particles N = 6.022 × 1023 X 2 = 12.044 X 1023
(ii) Given mass of calcium Ca = 80 g
Molar mass of N = 7 g
Avogadro's number = 6.022 × 1023
Number of particles
N= Avogadro's number X Given mass /
Number of particles N = (6.022 × 1023 X 7) / 14
Number of particles N = (6.022 × 1023) /2 = 3.011 X 1023
(iii) Given number of mole of carbon (C) n = 0.1 mole
Avogadro's number= 6.022 × 1023
Number of particles N = Given number of moles × Avogadro’s number = n × N0
Number of particles N = 0.1 × 6.022 × 1023
Number of particles N = 0.6022 × 1023.
No comments:
Post a Comment