Absorption and Scattering PDF

Summary

These lecture notes cover absorption and scattering phenomena. The document details various concepts like absorption coefficient and cross-sections, molar absorption coefficient, spectrophotometry measurements, and the underlying principles of optical scattering. It includes diagrams and formulas.

Full Transcript

Absorption and
Scattering
Third session
 Absorption Coefficient.
To d a y ’s
Content Absorption Cross-Section

Molar Absorption Coefficient

Absorption Coefficient

Absorption Coefficient as a Probability

Spectrophotometry

Measuring Absorption Spectra
Transmittance and Absorbance

Spectroscopic Inversion.
 Optical Scattering.
To d a y ’s
Content The Physical Basis of
Scattering
Molecular Scattering Refractive
Index
Scattering Coefficient...
 For a photon of frequency the
Absorption likelihood of a transition from state a
coefficient to state b is often given in terms of
Absorption
the absorption cross-section,
Cross Section

The absorption cross-section is
the ratio of the power absorbed
by the molecule to the incident
power per unit area, so has
units of area.
 Absorption
Coefficient

Absorption
Cross-Section
 Absorption
Coefficient The description of the absorption of a single
molecule is not much use on its own in tissue
Absorption Molar optics, and it is necessary to move to a description
Coefficient of the absorption of bulk matter consisting of very
many molecules.

The molar absorption coefficient is obtained by
summing the absorption cross-sections of all the
molecules in one mole of ansubstance.
 is just NA mole One
Absorption molecules, where Avogadro’s
Coefficient constant NA= 6.022×10-23, so
Molar Absorption
:NA gives multiplying by
Coefficient
 As most biological media contain
Absorption any types of absorbers, eg. blood, lipids,
Coefficient water, melanin, the total absorption
coefficient of a material consisting of K
chromophores is the sum of the molar
absorption coefficients weighted by
their concentrations:
 the probability that a
Absorption
Coefficient as
photon will be absorbed while
a Probability travelling the distance is
 a plane wave of continuous
Absorption light irradiating a purely
Coefficient as
a Probability
absorbing, non-scattering
medium.

The intensity of the light will
decrease in the direction of
propagation as the light is
absorbed.
 The measurement of optical
Spectrophoto-
metry absorption spectra is known as
spectrophotometry.

Measuring the detected intensity can be
Absorption written as
Spectra

Io IL
Spectrophoto-
metry

Measuring
Absorption
Spectra
 Given a sample that contains
Spectroscopic
Inversion several known chromophores, it is
often possible to estimate the
concentrations of each constituent by
making measurements at multiple
wavelengths
 a sample containing a mixture
Spectroscopic
Inversion of three chromophores, a, b and
c,with specific extinction
coefficients
 Three measurements of the
Spectroscopic absorbance are made using a
Inversion spectrophotometer at
wavelengths
Spectroscopic
Inversion
Optical
Scattering
 In biological tissue the
scattering is often a dominant
characteristic, and explains
why skin, for example, is
opaque.
 Photon scattering can be
O p t i c a l divided into two classes:
Scattering
Elastic,in which energy is
conserved and so the scattered
light has the same frequency as
the incident light,

Inelastic, in which energy is lost
or gained and so the scattered
light has a different frequency
from the incident light.
 Elastic scattering is much
Optical Scattering more significant in most
biological tissues at visible
and NIR wavelengths.
 When the frequency does not
The Physical Basis excite any resonance in the
of Scattering
molecule then the oscillating
Molecular Scattering
dipole as it is a moving
charge will radiate an EM
wave as any accelerating
charge would.
Photon of equal energy to
the incoming photon will be
reradiated in a random
direction.
 Light travels at speed in the
The Physical
o f Basis
vacuum, and c/v at speed in
Scattering theglass
“why does the wave
Refractive seem to travel at a slower
Index speed in the glass”?
 The many scattered waves add
The Physical
o f Basis
together, and add to the original
Scattering incident wave, in such a way as
to result in a wave which is
Refractive phase shifted from the
Index original.
 the emergent wave moves
The Physical
of Basis through the medium with
Scattering speed c/n ,
Refractive
Index
 Because it appears to move
with a different speed, the light
The Physical appears to refract, and is bent
Basis on entering a medium with a
Scattering
different refractive index.
Refractive
Index
The Physical
o f Basis
Scattering

Refractive
Index
 microscopic scattering:
The Physical
o f Basis Macroscopic scattering
Scattering
the cause of scattering is
Refractive variations in the density of the
Index scatterers,
The refractive index will be
spatially varying and the light
will be refracted in various
directions:
 The key factor in determining
S c T h e
Physical Basis
whether a refractive
of Scattering index fluctuation will
scatter strongly is
Refractive the relationship between
Indexattering the size of the scatterer
the wavelength of the light
Coefficient
 Consider a collimated beam
Scattering
Coefficient
of light travelling in the z-
direction through a thin,
elastically scattering, non-
absorbing medium
 As the beam passes through
Scattering
coefficient
the medium, some of the
light will be scattered out of
the beam into different
directions and the intensity
of the beam will follow
an exponential decay,
where is called the scattering
coefficient.
 Probability that a photon will
Scattering
coefficient
be scattered while travelling the
short distance between.
The reduced scattering
coefficient is a lumped property
incorporating the scattering
coefficient µs and the anisotropy
g: µs' = µs(1 - g) [cm-1].
The mean free path is the
average distance traveled by a
moving particle (such as an
atom, a molecule, a photon)
between successive impacts
The purpose of µs' is to
describe the diffusion of
photons in a random walk of
step size of 1/µs' [cm] where
each step involves isotropic
scattering
cattering properties of tissue
include the scattering
coefficient (µs), which
describes the mean free path
between scattering events,
Reduced scattering coefficient can be defined as
inverse distance between effectively scattering
events, where photon loses all memory of its
initial direction.

This combined coefficient is very often used in
measurement tissue optical properties and is
fundamental parameter in diffusion theory.

Typical value of scattering coefficient is between
0.2 cm−1 and 400 cm−1. For g = 0.9 it gives us reduced scattering
coefficient between 0.02 cm−1 and 40 cm−1
 The diffusion of light remains almost the same
when varying µs and g yet keeping µs unchanged.
This explains why µa and µs

instead of µa, µs and g, are commonly used in
optical imaging. Light absorption and scattering
coefficients depend on the

optical properties of constituent particles and their
concentration. The g-factor measures how much
forward peaked is the

angular distribution of light when it is scattered
once by a particle in the medium, and is
independent of the concentration of the scatterers
The scattering mean free path is the
average distance between scattering
events (in biological tissues around
100 µm)

The transport mean free path can be
thought of as the mean distance after
which a photon’s direction becomes
random (in biological tissues around 1
mm)