1.2 Population inversion

Absorption and Emission of radiation

Consider an atom or molecule with two energy levels,

E

i and

E

k

E

k Molecule in energy level

E

i

E

i A direct, radiative transition between these states would be associated with a photon of frequency ν :

h

ν = Δ

E

=

E

k

– E

i

Consider:

What are the possible radiative transitions?

What is the probability of a transition taking place?

How does the number of photons change with the transition?

Absorption and Emission of radiation

Three possible transitions: (a)“Induced absorption”: Molecule in

E

i absorbs a photon and is excited to

E

k

E

k

h

ν

E

i One less photon of energy

h

ν Probability of transition is: d

P

ik /d

t

d

P

ik

/d

t

=

B

ik

ρ

(ν)

is the probability per second of a molecule absorbing a photon

B

ik

ρ

(ν) is the Einstein coefficient of induced absorption is the spectral energy density (the number of photons of frequency ν per unit volume)

Absorption and Emission of radiation

(b) “Spontaneous emission”: Molecule in

E

k decays spontaneously to

E

i by emitting a photon in an arbitrary direction

E

k

h

ν

E

i One more photon of energy

h

ν (arbitrary phase & direction) Probability of transition is d

P

ki /d

t

d

P

ki

/d

t

=

A

ki is the probability per second of the excited molecule emitting a photon

A

ki is the Einstein coefficient of spontaneous emission (or the spontaneous transition probability) Spontaneous emission is not influenced by the presence of other photons in the medium

Absorption and Emission of radiation

(c) “Induced emission” (or “stimulated emission”): A photon of appropriate frequency induces the transition from

E

k to

E

i

h

ν

E

k

h

ν

E

i One more photon of energy

h

ν. The new photon has the same frequency, phase, and direction at the original photon Probability of transition is

d

P

ki

/dt =

B

ki d

P

ki /d

t

ρ

(ν)

is the probability per second of the excited molecule emitting a photon

B

ki is the Einstein coefficient of induced emission

Absorption and Emission of radiation

Relation between

B

ik

and

B

ki

:

The Einstein coefficients of induced absorption and emission are directly related through the degeneracy,

g

x , of each level

x

:

B

ik

= (

g

k

/

g

i

)

B

ki In the case where each level has the same degeneracy (

g

i =

g

k ), the Einstein coefficients of induced absorption and emission are identical – in other words, the probability of induced emission is the same as that of induced absorption How can we make practical use of induced emission?

Population inversion

Population inversion

A system with a population inversion is not in thermal equilibrium; populations of energy levels are not governed by the Boltzmann distribution IF we can alter the population distribution so that more molecules are in higher energy levels rather than lower energy levels, this is called population inversion.

With a population inversion, photons passing through the gain medium will be amplified (by induced emission) rather than attenuated (by induced absorption).

Population inversion

A resonator or cavity (produced by the two mirrors) is used to achieve selective feedback of some of the cavity modes in the cavity – that is, photons that travel on the axis between the mirrors are preferentially amplified over photons going in different directions:

Threshold condition

Threshold condition

The probability of stimulated absorption and emission depends on the populations of the upper and lower states. With

N

i molecules in level

E

i and

N

k molecules in level

E

k , the intensity after distance

z

is:

I = I

0

e

–α z

where

I

0 is the initial intensity and the absorption coefficient,

α

, is: Here σ

α =

[

N

i

–

(

g

k

/

g

i

)

N

k

] σ

is the absorption cross-section and is related to

B

ik When a population inversion exists (

N

k distance

z > N

i ) the intensity after is greater than the initial intensity (

I > I

0 ).

However, we also need to consider other photon losses in the cavity

Threshold condition

Photons may be lost in the cavity owing to transmission through the mirrors, scattering from surfaces and particles, diffraction losses, and absorption by other materials in the cavity. If all of these losses contribute to a loss coefficient, γ , then the intensity owing to cavity losses after a round trip in the cavity is

I = I

0

e

– γ

From above, if the cavity has length

L

, the round trip gain (considering only the population inversion) is then:

I = I

0

e

–

2α

L

To compensate for cavity losses, the threshold condition for amplification in the cavity is then:

Δ

N

= [(

g

k

/

g

i

)

N

k

–

N

i

] > (γ / 2σ

L

)

Generating a population inversion

“Pumping”: delivery of energy to produce a population inversion pump

E E

2 lasing 1 pump

E

3 rapid relaxation

E

lasing

E

1 2 Three-level system pump

E

4 rapid relaxation

E

3 lasing

E

2 rapid relaxation

E

1 Four-level system Two-level system Notes: A true two-level system cannot produce a population inversion Only

E

1 is populated at thermal equilibrium (

E

2 >>

E

1 ) A three-level system must be pumped harder than a four-level system – that is, more molecules must be pumped into the excited level to produce lasing Can we sustain a population inversion in a given laser?

Generating a population inversion

It is difficult to maintain a population inversion: Lasers that maintain a population inversion indefinitely produce continuous output – termed CW (for continuous wave) lasers Lasers that have a short-lived population inversion produce pulsed output – these are pulsed lasers Pulsed lasers may be of three types: “normal” pulsed lasers, Q- switched lasers, and mode-locked lasers Pumping can be achieved either: 1) optically – e.g., flashlamps (pulsed) or Hg arc lamps (CW operation) 2) electrically – e.g., electric discharge in a gas and in semiconductor lasers

Rate equations for a four-level laser

Box 3.1 (Telle)

Spectral characteristics of laser emission

The photon emitted between two levels is not perfectly monochromatic. The linewidth is affected inter alia by: Natural lifetime (usually gives narrow linewidth) Molecular motion (Doppler broadening) Collisions (Pressure broadening, solvent effects) This linewidth results in a gain profile for the laser: Only that part of the gain profile that is above the threshold can lase. The gain profile must be considered together with the cavity modes to determine the laser spectrum