Unit-3a Lasers (Introduction to Laser Physics) PDF

Summary

This document provides an introduction to laser physics. It explores the fundamental principles behind laser operation, including light amplification by stimulated emission, the mechanisms of light absorption and emission, and the concept of population inversion. The document covers various laser types and their applications.

Full Transcript

Introduction to Laser Physics

Light Amplification by
Stimulated Emission of
Radiation (LASER)
Lasers are devices that generate intense, coherent beams of light
through the process of optical amplification. This presentation will explore
the fundamental principles underlying laser operation, including the
mechanisms of light absorption, spontaneous and stimulated emission,
and population inversion.

by Dr. Malay Udeshi
Laser Physics: Topics
Interaction of radiation with matter

Principle and Working of LASER
Time-line
1917 – A. Einstein postulates photons
Types of LASERS and stimulated emission
Application of LASERS
1954 – First microwave laser (MASER),
Townes, Shaw low, Prokhorov

1960 – First optical laser (Maiman)

1964 – Nobel Prize in Physics: Townes,
Prokhorov, Basov
Absorption of Light
1 Light Absorption 2 Excitation
When a photon of the The absorbed energy
appropriate energy excites the electron,
interacts with an atom or temporarily storing it in an
molecule, it can be unstable, higher-energy
absorbed, causing an state.
electron to transition to a
higher energy level.

3 Relaxation
The excited electron will eventually relax back to its ground
state, releasing the stored energy in the form of a new photon.

Interaction of Radiation with
Spontaneous Emission Photon Emission
As the electron transitions to a lower energy state, it
Excited State releases the excess energy in the form of a photon.
When an electron is in an excited state, it is unstable
and will eventually decay back to a lower energy level.
Randomness
The direction and timing of the spontaneous emission i
random, resulting in incoherent light.
Stimulated Emission
1 Incoming Photon
When a photon with the correct energy
interacts with an excited electron, it can
stimulate the electron to transition to a
lower energy state.

2 Photon Emission
The excited electron releases a new
photon that is identical in energy,
direction, and phase to the incoming
photon.
3 Amplification
The stimulated emission can lead to a
chain reaction, where multiple identical
photons are produced, resulting in optical
amplification.
Population Inversion

 The number of atoms present in the excited (or higher) state is greater than the number of
atoms present in the ground state (or lower) state is called population inversion.
Population Inversion
Population Inversion
 A mechanism where N2 > N1

 This is called POPULATION INVERSION

 Population inversion can be created by introducing a so call metastable centre where electrons can piled up to
achieve a situation where more N2 than N1
 It is not possible to achieve population inversion with a 2-state system.

 To create population inversion, a 3-state system is required.

Pumping
Phenomena of achieving Population inversion is called pumping. Energy into the lasing
medium, is pumped external energy source such as a flash lamp or another laser.
Population Inversion

Metastable States
The excited electrons must have a sufficiently long lifetime in the
metastable state to allow for the buildup of a population inversion.

Amplification
Once a population inversion is achieved, stimulated emission can
occur, leading to the amplification of light and the creation of a laser
beam.
Fast Fast
decay decay

slow
decay
Laser Cavity
Lasing Medium Mirrors Feedback
The lasing medium is the The laser cavity is formed The light bounces back
material in which the by two highly reflective and forth between the
population inversion is mirrors, which trap the mirrors, creating a
created and where the light within the medium feedback loop that selects
stimulated emission and allow for multiple and amplifies the desired
occurs, such as a gas, passes, increasing the laser wavelength.
solid, or liquid. amplification.
 Ruby Laser

Active Medium - Crystalline Substance - Al2O3

Three Main Parts of Ruby Laser

1) Ruby Rod - Al2O3 with 0.05% Chromium doping

2) Resonating Cavity - Ruby Rod 4 cm length and 0.5 cm diameter. Silver

3) Xenon Flash Pump - Pumping Source
Laser Beam Properties

Collimation Monochromaticity
Laser beams are highly Lasers produce light of a single,
collimated, meaning the light very narrow wavelength, making
waves are parallel and do not the light highly monochromatic.
diverge significantly over long
distances.

Coherence High Intensity
Laser light is also highly Lasers can produce very intense,
coherent, with the light waves in focused beams of light, with high
phase and synchronized. power densities.
Applications of Lasers
Medical Applications Industrial Applications Scientific Applications
Lasers are used in various medical Lasers are used for precision cutting, Lasers are essential tools in scientific
procedures, such as eye surgery, welding, and engraving in research, enabling techniques like
tumor removal, and hair removal. manufacturing and industrial spectroscopy, interferometry, and
processes. laser cooling.
Ruby Laser 1) Ruby Rod
1) Al2O3 +
0.05 wt% Cr
2) Mirrors
3) Xenon Flash
Tube – optical
pumping
Working of Ruby Laser Energy level ‘E’
is a metastable
Xe gas pumps the Cr atoms at the ground state
Cr atoms will be excited to level E1 and E2 state.
Atoms will stay
The excited atoms will undergo a non-radiative decay to energy level E
for finite time at
E
Thus a
population
inversion will be
there between
‘E’ and ‘E0’
Due to E2
atoms – Blue
laser is
generated
Due to E1
He-Ne Laser
The main advantage of gas lasers is that they can be operated continuously.
The gas lasers show exceptionally high monochromaticity and high stability of
frequency.
The output of the laser can be tuned to a certain available wavelength.
Hence, the gas lasers are widely used in industries
Helium–Neon Laser The first gas laser constructed by Javan in the laboratory is
the helium–neon laser as shown in Fig. 11.11. The two important parts of the
laser are as follows:
Active Medium

A mixture of Helium and Neon gases is used.
The He:Ne ratio is 10:1.
The mixture of gases is filled within the discharge tube

Gas Discharge Tube: Made up of Fused quartz tube with diameter of
11.5 cm and a length of 80.6 cm
A fully reflecting concave mirror is placed at one end of the discharge
tube and a partially reflecting concave mirror is placed at the other
end.
The population inversion for laser action is achieved by inelastic
atom–atom collisions. The collisions of the atoms are made using any
one of the
following methods given below.
(i) Direct current discharge
(ii) Alternate current discharge
(iii) Electrodeless high frequency discharge, and
(iv) High voltage pulses
Working of He-Ne Laser
The population inversion for laser action is achieved by inelastic atom–atom
collisions
an energetic electron interact with the ground state helium atom
As a result, helium atoms are excited to higher levels 1S0 and 3S1, known as
metastable state. The lifetime of these levels are relatively low. The collision
of the first kind is represented as Population inversion between

a) 3s and 2p – Laser – 6328 A
b) 3s and 3p – Laser – 3.39um
c) 2s and 2p – laser – 1.15 um

Two infrared lasers and 1 visible light laser
Is generated using He-Ne laser
Fiber Optics

Fiber optics is an overlap of science and technology
which deals with transmission of light waves into
optical fibers, their emission and detection

Optical cables are small in size and weight and are more efficient

for communication than metal cables

The principle behind the transmission of light waves in an optical
fiber is total internal reflection.
Two parts of the cable are important

Core
Cladding
it is the maximum angle of a ray hitting the fiber core which allows the incident light to be
guided by the core since total internal reflection can occur at the core–cladding boundary.

For larger incidence angles, there is no total internal reflection, and therefore there are
significant power losses at each reflection point.
Relation between Numerical aperture and
Incidence Angle