Structure of Atom
Atom is the smallest indivisible particle of
the matter. Atom is made of electron,
proton and neutrons.
|
PARTICLE |
ELECTRON |
PROTON |
|
NEUTRON |
|
|
|
|
|
|
|
Discovery |
Sir. J. J.
Thomson (1869) |
Goldstein
(1886) |
|
Chadwick
(1932) |
|
Nature of
charge |
Negative |
Positive |
|
Neutral |
|
Amount of |
1.6 x 10- |
1.6 x 10- |
|
0 |
|
charge |
19Coloumb |
19Coloumb |
|
|
|
Mass |
9.11 x
10-31kg |
1.672614 x
10-27kg |
|
1.67492
x10-27kg |
·
Electrons
were discovered using cathode ray discharge tube experiment.
·
Nucleus
was discovered by Rutherford in 1911.
·
Cathode
ray discharge tube experiment: A cathode ray discharge tube made
Of
glass is taken with two electrodes. At very low pressure and high voltage,
current starts flowing through a stream of particles moving in the tube from
cathode to anode. These rays were called cathode rays. When a perforated anode
was taken, the cathode rays struck the other end of the glass tube at the
fluorescent coating and a bright spot on the coating was developed.
Results:
(a)
Cathode rays consist of negatively charged electrons.
(b)
Cathode rays themselves are not visible but their behavior can be observed with
help of fluorescent or phosphorescent materials.
(c)
In absence of electrical or magnetic field cathode rays travel in straight
line.
(d) In presence of electrical or magnetic
field, behavior of cathode rays is similar to that shown by electrons e. The
characteristics of the cathode rays do not depend upon the material of the
electrodes and the nature of the gas present in the cathode ray tube.
·
Charge
to mass ratio of an electron was determined by Thomson. The charge to mass
ratio of an electron as 1.758820 x 1011 C kg-1
·
Charge
on an electron was determined by R A Millikan by using an oil drop experiment.
The value of the charge on an electron is -1.6 x 10-19C.
·
The
mass on an electron was determined by combining the results of Thomson’s
experiment and Millikan’s oil drop experiment. The mass of an electron was
determined to be 9.1094 x 10-31kg.
Discovery
of protons and canal rays:
Modified
cathode ray tube experiment was carried out which led to the discovery of
protons.
Characteristics
of positively charged particles:
(a) Charge
to mass ratio of particles depends on gas from which these originate.
(b) The
positively charged particles depend upon the nature of gas present in the
cathode ray discharge tube.
(c) Some of the positively charged particles carry
a multiple of fundamental of electrical charge.
(d) Behavior
of positively charged particles in electrical or magnetic field is opposite to
that observed for cathode rays.
·
Neutrons
were discovered by
James Chadwick by bombarding a thin sheet of beryllium by α- particles. They are electrically
neutral particles having a mass slightly greater than that of the protons.
·
Atomic number (Z): the number of protons present in the
nucleus (Moseley1913).
·
Mass
Number (A): Sum of
the number of protons and neutrons present in the nucleus.
Thomson
model of an atom:
This model
proposed that atom is considered as a uniform positively charged sphere and
electrons are embedded in it. An important feature of Thomson model of an atom
was that mass of atom is considered to be evenly spread over the atom. Thomson
model of atom is also called as Plum pudding, raisin pudding or watermelon
model Thomson model of atom was discarded because it could not explain certain
experimental results like the scattering of α- particles by thin metal foils.
Observations
from α- particles scattering experiment by Rutherford
(a) Most of the
α- particles
passed through gold foil un deflected
(b) A small
fraction of α- particles got
deflected through small angles
(c) Very few α- particles did not pass through foil
but suffered large deflection nearly180 degree.
Conclusions
Rutherford drew from α- particles scattering experiment:
(a)
Since most of the α-particles
passed through foil un deflected, it means most of the space in atom is empty.
(b)
Since some of the α-particles
are deflected to certain angles, it means that there is positively mass present
in atom.
(c)
Since only some of the α-particles
suffered large deflections, the positively charged mass must be occupying very
small space.
(d) Strong
deflections or even bouncing back of α-particles
from metal foil were due to direct collision with positively charged mass in
atom.
Rutherford’s
model of atom:
This
model explained that atom consists of nucleus which is concentrated in a very
small volume. The nucleus comprises of protons and neutrons. The electrons
revolve around the nucleus in fixed orbits. Electrons and nucleus are held
together by electrostatic forces of attraction.
Drawbacks of Rutherford’s model of atom:
a. According to
Rutherford’s model of atom, electrons which are negatively charged particles
revolve around the nucleus in fixed orbits. Thus,
b.
The electrons undergo acceleration. According to electromagnetic theory of
Maxwell, a charged particle undergoing acceleration should emit electromagnetic
radiation. Thus, an electron in an orbit should emit radiation. Thus, the orbit
should shrink. But this does not happen.
c. The model
does not give any information about how electrons are distributed around
nucleus and what are energies of these electrons.
Isotopes:
These are the atoms
of the same element having the same atomic number but different mass number.
e
g 1H1,1H2,1H3
Isobars:
Isobars are the atoms
of different elements having the same mass number but different atomic number.
e
g 18Ar40 , 20Ca40
Isoelectronic
species: These are
those species which have the same number of electrons.
Electromagnetic
radiations:
The
radiations which are associated with electrical and magnetic fields are called
electromagnetic radiations. When an electrically charged particle moves under
acceleration, alternating electrical and magnetic fields are produced and
transmitted. These fields are transmitted in the form of waves. These waves are
called electromagnetic waves or electromagnetic radiations.
Properties of electromagnetic radiations:
(a)
Oscillating electric and magnetic field are produced by oscillating charged
particles. These fields are perpendicular to each other and both are perpendicular
to the direction of propagation of the wave.
(b)
They do not need a medium to travel. That means they can even travel in vacuum.
Characteristics of electromagnetic radiations:
a.
Wavelength: It may be defined as the distance between two neighboring
crests or troughs of wave as shown. It is denoted by λ.
b.
Frequency (ν):
It may be defined as
the number of waves which pass through a particular point in one second.
c. Velocity
(v): It is defined as the distance travelled by a wave in one second. In vacuum
all types of electromagnetic radiations travel with the same velocity. Its
value is 3 X108m sec-1. It is denoted by v
d. Wave number:
Wave number is defined as the number of wavelengths per unit length.
Velocity
= frequency x wavelength c = νλ
Planck's
Quantum Theory-
·
The
radiant energy is emitted or absorbed not continuously but discontinuously in
the form of small discrete packets of energy called ‘quantum’. In case of light
, the quantum of energy is called a ‘photon’
·
The
energy of each quantum is directly proportional to the frequency of the
radiation, i.e. E α υ or E= hυ where h= Planck’s constant = 6.626 x
10-27 Js
·
Energy
is always emitted or absorbed as integral multiple of this quantum. E=nhυ Where n=1,2,3,4,.....
Black body:
An
ideal body, which emits and absorbs all frequencies, is called a black body.
The radiation emitted by such a body is called black body radiation.
Photoelectric effect:
The
phenomenon of ejection of electrons from the surface of metal when light of
suitable frequency strikes it is called photoelectric effect. The ejected
electrons are called photoelectrons.
Experimental results observed for the
experiment of Photoelectric effect-
·
When
beam of light falls on a metal surface electrons are ejected immediately.
·
Number
of electrons ejected is proportional to intensity or brightness of light.
·
Threshold frequency (vo): For each metal there is a
characteristic minimum frequency below which photoelectric effect is not
observed. This is called threshold frequency.
·
If
frequency of light is less than the threshold frequency there is no ejection of
electrons no matter how long it falls on surface or how high is its intensity.
Photoelectric work
function (Wo):
The
minimum energy required to eject electrons is called photoelectric work
function.
Wo=
hvo
Energy of the ejected electrons:
Dual
behavior of electromagnetic radiation- The light possesses both particle and
wave like properties, i.e., light has dual behavior. Whenever radiation
interacts with matter, it displays particle like properties. (Black body
radiation and photoelectric effect) Wave like properties are exhibited when it
propagates (interference an diffraction)
When
a white light is passed through a prism, it splits into a series of colored
bands known as spectrum.
Spectrum is of two
types: continuous and line
spectrum
(a)The spectrum
which consists of all the wavelengths is called continuous spectrum.
(b)A spectrum
in which only specific wavelengths are present is known as a line spectrum. It has bright lines with
dark spaces between them.
Electromagnetic
spectrum is a continuous spectrum. It consists of a range of electromagnetic
radiations arranged in the order of increasing wavelengths or decreasing
frequencies. It extends from radio waves to gamma rays.
Spectrum is also classified as emission and line
spectrum.
·
Emission spectrum:
The spectrum
of radiation emitted by a substance that has absorbed energy is called an
emission spectrum.
·
Absorption spectrum:
The
spectrum obtained when radiation is passed through a sample of material. The
sample absorbs radiation of certain wavelengths. The wavelengths which are
absorbed are missing and come as dark lines.
·
The
study of emission or absorption spectra is referred as spectroscopy.
Rydberg equation:
(R = Rydberg’s
constant = 109677 cm-1)
Bohr’s model for hydrogen atom:
(a)An electron in the hydrogen atom can
move around the nucleus in a circular path of fixed radius and energy. These
paths are called orbits or energy levels. These orbits are arranged
concentrically around the nucleus.
(b) As long as an electron remains in a
particular orbit, it does not lose or gain energy and its energy remains
constant.
(c)
When transition occurs between two stationary states that differ in energy, the
frequency of the radiation absorbed or emitted can be calculated.
(d)
An electron can move only in those orbits for which its angular momentum is an
integral multiple of h/2π
The radius of
the nth orbit is given byrn =52.9 pm x n2
Z
energy of
electron in nth orbit is :
Limitations of Bohr’s model of atom:
(a)
Bohr’s model failed to account for the finer details of the hydrogen spectrum.
(b)
Bohr’s model was also unable to explain spectrum of atoms containing more than
one electron.
Dual
behavior of matter:
De Broglie
proposed that matter exhibits dual behavior i.e. matter shows both particle and
wave nature. De Broglie’s relation is
Heisenberg’s
uncertainty principle:
It states that
it is impossible to determine simultaneously, the exact position and exact
momentum (or velocity) of an electron. The product of their uncertainties is
always equal to or greater than h/4π.
Heisenberg’s
uncertainty principle rules out the existence of definite paths or trajectories
of electrons and other similar particles.
Failure of Bohr’s model:
(a) It ignores the dual behavior of
matter.
(b) It contradicts Heisenberg’s uncertainty
principle.
Classical
mechanics is based on Newton’s laws of motion. It successfully describes the
motion of macroscopic particles but fails in the case of microscopic particles.
Reason:
Classical
mechanics ignores the concept of dual behavior of matter especially for
sub-atomic particles and the Heisenberg’s uncertainty principle.
Quantum mechanics:
It is
a theoretical science that deals with the study of the motions of the
microscopic objects that have both observable wave like and particle like
properties.
Quantum
mechanics is based on a fundamental equation which is called Schrodinger equation.
Schrodinger’s equation:
For a system
(such as an atom or a molecule whose energy does not change with time) the
Schrödinger equation is written as:
When
Schrödinger equation is solved for hydrogen atom, the solution gives the
possible energy levels the electron can occupy and the corresponding wave
function(s) of the electron associated with each energy level. Out of the
possible values, only certain solutions are permitted. Each permitted solution
is highly significant as it corresponds to a definite energy state. Thus, we
can say that energy is quantized.
ψ gives
us the amplitude of wave. The value of ψ has
no physical significance.
Ψ 2 gives us the
region in which the probability of finding an electron is maximum. It is called
probability density.
Orbital:
The
region of space around the nucleus where the probability of finding an electron
is maximum is called an orbital.
Quantum
numbers: There are a set of four quantum numbers which specify the energy,
size, shape and orientation of an orbital. To specify an orbital only three
quantum numbers are required while to specify an electron all four quantum
numbers are required.
Principal
quantum number (n):
It identifies
shell, determines sizes and energy of orbitals.
Azimuthal
quantum number (l): Azimuthal
quantum number. ‘l’ is also known as orbital angular momentum or subsidiary
quantum number. l. It identifies sub-shell, determines the shape of orbitals,
energy of orbitals in multi-electron atoms along with principal quantum number
and orbital angular momentum,
i.e.
The number of
orbitals in a sub shell = 2l + 1. For a given value of n, it can
have n values ranging from 0 to n-1. Total number of sub shells in a
particular shell is equal to the value of n.
Magnetic quantum number or Magnetic orbital quantum
number (ml): It gives information about the spatial
orientation of the orbital with respect to standard set of co-ordinate axis For
any sub-shell (defined by ‘l’ value) 2l+1 values of ml are possible. For each
value of l, ml = – l, – (l –1), – (l–2)... 0,1... (l – 2), (l–1), l
Electron spin quantum number (ms):
It
refers to orientation of the spin of the electron. It can have two values +1/2
and -1/2. +1/2 identifies the clock wise spin and -1/2 identifies the anti-
clockwise spin.
·
The
region where this probability density function reduces to zero is called nodal
surfaces or simply nodes.
·
Radial
nodes: Radial nodes occur when the probability density of wave function for the
electron is zero on a spherical surface of a particular radius. Number of
radial nodes = n – l – 1
·
Angular
nodes: Angular nodes occur when the probability density wave function for the
electron is zero along the directions specified by a particular angle. Number
of angular nodes = l
Total
number of nodes = n – 1
·
Degenerate orbitals: Orbitals having
the same energy are called degenerate orbitals. Shape of p and d-orbitals.
Shielding
effect or screening effect:
Due to the
presence of electrons in the inner shells, the electron in the outer shell will
not experience the full positive charge on the nucleus.
So, due to the
screening effect, the net positive charge experienced by the electron from the
nucleus is lowered and is known as effective nuclear charge. Effective nuclear
charge experienced by the orbital decreases with increase of azimuthal quantum
number (l).
Aufbau
Principle:
In the ground
state of the atoms, the orbitals are filled in order of their increasing
energies.
N+l rule- Orbitals with lower value of (n+l) have lower energy.
If two orbitals have the same value of (n+l) then orbital with lower value of n
will have lower energy.
The order in
which the orbitals are filled is as follows:
1s, 2s, 2p, 3s,
3p, 4s, 3d, 4p, 5s, 4d, 5p, 4f, 5d, 6p, 7s...
Pauli Exclusion Principle: No two electrons in an atom can have the same set of
four quantum numbers. Only two electrons may exist in the same orbital and
these electrons must have opposite spin.
Hund’s rule of maximum multiplicity:
Pairing
of electrons in the orbitals belonging to the same sub shell (p, d or f) does
not take place until each orbital belonging to that sub shell has got one
electron each i.e., it is singly occupied.
Electronic
configuration of atoms:
Arrangement of
electrons in different orbitals of an atom. The electronic configuration of
different atoms can be represented in two ways.
(a) s,p,d,......
notation.
(b) Orbital
diagram:, each orbital of the sub shell is represented by a box and the
electron is represented by an arrow (↑)
a positive spin or an arrow (↓)
a negative spin.
Stability of completely filled and half filled sub shells:
(a) Symmetrical distribution of electrons-
The completely filled or half filled sub-shells have symmetrical distribution
of electrons in them and are more stable.
(b) Exchange energy-The two
or more electrons with the same spin present in the degenerate orbitals of a
sub-shell can exchange their position and the energy released due to this
exchange is called exchange energy. The number of exchanges is maximum when the
subshell is either half filled or completely filled. As a result the exchange
energy is maximum and so is the stability.
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