Post on 20-Jan-2018
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Chapter 9Threshold Requirements
Looking at Loss again
Lasermedium
R1 R2
d
Loss/length =α1
Gain/length =−αorκ
I
I e-(α1+αd
IR2 e-(α1+αdIR2R1 e-2(α1+αd
All self-sustaining oscillators require gain to exceed losses
α = h νr B/c (n1-n2) = -κ
Gain Threshold
R2R1 e2(κ -α1d ≥ 1 Eq 9.1
Rewrite this as:
κ ≥ α1 - ln[R2R1]/2dCavity stuffAtom stuff
Cavity LifetimeLets make another defn so we can simplify: ‘ cavity lifetime’
(also called cold cavity lifetime or photon lifetime). This is the time the intensity decreases to 1/e of its starting value when there is no gain in the cavity
In one round trip intensity decreases by R2R1 e2(κ -α1d
which takes 2d/c seconds (assumed cavity and gain material length are the same) Assume intensity decrease can be approx. described as e-t/tc where tc is cold cavity lifetime
tc = 2dc (2α1 d - ln [R1R2])
Eq 9.3
Population Difference Threshold
n2-n1 ≥8πνr
2 tsp
c3 g(νr) tc
Since achieving n2>n1 is really hard, what should a smart person do?
ExampleRuby rod from before except lets use a 5cm long rod Between two 90% reflectivity mirrors
From Eq. 9.3 we get tc = 2.8ns, and therefore we find by substitution into Eq. 9.4 that:
n2-n1 ≥ 2 x 1023 m-3
Typical Cr atom densities in ruby (about 1% replacement of Al)
are around 1.6 x 1025 m-3.
Resonator Transfer Function in presence of gain
1
0
2
1
0
What happens after lots of round trips?
Go to Phet Simulation
Talking about GainAlso, Talk about two level situation
Chapter 10Pumping Processes and Rate Equations
Two Level AtomNarrow Band Radiation at νr with density u, hit some atoms.
Rabs = n1c3A g(νr) u(T)/(8 π h νr3)
= n1 W12
E1
E2
n1
n2 u(T)
Rem = n2c3A g(νr) u(T)/(8 π h νr3)
= n2 W21
N.B. W12 = W21
n1 = W21 (n2-n1) + A n2.
W12 n1
W21 n2A n2
Solution for 2 level system
n2/n1 = W21/(W21 + A)
Cannot possibly work!
Three Level AtomNarrow Band Radiation at νp with density u.
E1
E3
n1 = W31 (n3-n1) + A31 n3 + A21 n2 + W21 (n2-n1) .
W13 n1
W31 n3A31 n3
A32 n3
hvp A21 n2 W21 n2
W12 n1
Three Level Solution
ΔnN
=W31-A21
W31+A21
1
1+ W12 3W31+2A32
A32 (W31+A21)
Below threshold essentially no laser light: W12 = 0
In this case pop difference, and hence gain, are indep. of W12
⇒ Intensity depends exponentially on distance
Lets look at saturation in more detail in 4 level laser
Example: pump power for RubyAt threshold:
ΔnN
≈W31-A21
W31+A21≈ 0
PD is nearly zero
No. of pumped atoms/sec/volume ~ W31 n1
Power (per unit volume) will be:
P = W31 n1 h νp = A21 N/2 h νp
For Ruby, A21 =1/τ = 1/(3ms), N ~ 1.6 x 1019 cm-3
Pump wavelength ~ 480nm (frequency ~ 6 x 1014 Hz)
P = 1100 Wcm-3
Electrical thresholds are about 16 times higher than this
Four Level Atom
E1
E4
n1 = W41 (n4-n1) + A41 n4 + A21 n2.
W14 n1
W41 n4A41 n4
A43 n4
hvpA21 n2 W32 n3
E3
A21 n2E2
W23 n2hvL
Smart: avoid using the ground state for one of the laser levels If A21 > A43 then get PI for smallest pumping intensities
Four level solution
ΔnN
=W31-A21
W31+A21
1
1+ W12 3W31+2A32
A32 (W31+A21)
ΔnN
= W41
W41+A32
1
1+ W32 2W41+ A21
A21 (W41+A32)
Viz. 3 level:
Small signal behaviour (below and near threshold)
Nd:YAG exampleNB. 2 errors in notes p. 125 - should be N ~ 6 x 1025 m-3 (0.5% doping) p. 124 - should be Gain coeff/m on vertical axis of Fig 10.3
λ ~ 1064nm, Δν ~ 195 GHz, τ ~ 230µsN ~ 6 x 1025 m-3 , n0 ~ 1.82, νp ~ 400 THz
R1 ~ 100%, R2 ~ 80%, l ~ 7cm α1 = 0
Δn ~ 2.5 x 1021 m-3
W41 ~ 0.2 s-1
P ~ W41 n1 h vp ~ W41 N h vp ~ 3.2 W/cm3
Gain dependence on output
0.01 1 100 100000
0.25
0.5
0.75
1
1.25
1.5
W320.01 1 100 10000
Intensity (W/cm )2
W41 ~ 0.2 s-1
W41 ~ 0.4 s-1
W41 ~ 0.1 s-1
Threshold
No. of photons in mode
100
101
102
103
104
105
106
107
108
109
1010
Photon Number
0.12 3 4 5 6 7 8 9
12 3 4 5
Pump Intensity (as ratio with threshold)
Power vs Current in LDs
2.52.01.51.0 Pump Intensity (as ratio with threshold)
Line BroadeningChapter 11: Not for examination
Radiation from a bunch of excited atoms0.5
0.0
-0.5
Intensity (a.u)
2000150010005000 Time
τFWHM = 1/(2 π
τ)
Collisions40
30
20
10
0
Intensity (a.u)
1400120010008006004002000 Time (fs)
Doppler Broadening1.0
0.8
0.6
0.4
0.2
0.0
Intensity (a.u)