Chapter 4Laser Dynamics (single-mode)Before we start to look into the dynamics of a multi-mode laser, we shouldrecall the technically important regimes of operation of a"single-mode" laser.The term"single-mode" is set in apostrophes, since it doesn't have to bereally single-mode. There can be several modes running, for example due tospatial holeburning, but in an incoherent fashion, so that only the averagepower of the beam matters. For a more detailed account on single-modelaser dynamics and Q-Switching the following references are recommended[1][3][16][4][5] 4.1Rate EquationsIn section 2.5, we derived for the interaction of a two-level atom with a laserfield propagating to the right the equations of motion (2.171) and (2.172),which are given here again:Nh010(4.1)A(z,t) =4T,E, (2, t) A(2,t),32aOt[A(z, t)2w-wo(4.2)ww(z,t)TIEswhere Ti is the energy relaxation rate, Ug the group velocity in the hostmaterial where the two level atoms are embedded, Es = I,Ti, the saturationfuence JJ/cm?, of the medium.and I, the saturation intensity according to127
Chapter 4 Laser Dynamics (single-mode) Before we start to look into the dynamics of a multi-mode laser, we should recall the technically important regimes of operation of a ”single-mode” laser. The term ”single-mode” is set in apostrophes, since it doesn’t have to be really single-mode. There can be several modes running, for example due to spatial holeburning, but in an incoherent fashion, so that only the average power of the beam matters. For a more detailed account on single-mode laser dynamics and Q-Switching the following references are recommended [1][3][16][4][5]. 4.1 Rate Equations In section 2.5, we derived for the interaction of a two-level atom with a laser field propagating to the right the equations of motion (2.171) and (2.172), which are given here again: µ ∂ ∂z + 1 vg ∂ ∂t¶ A(z, t) = N~ 4T2Es w (z, t) A(z, t), (4.1) w˙ = −w − w0 T1 + |A(z, t)| 2 Es w(z, t) (4.2) where T1 is the energy relaxation rate, vg the group velocity in the host material where the two level atoms are embedded, Es = IsT1, the saturation fluence [J/cm2] , of the medium.and Is the saturation intensity according to 127
128CHAPTER4.LASERDYNAMICS(SINGLE-MODE)Eq.(2.145)ME2TT,ZFIs :h2Ewhich relates the saturation intensity to the microscopic parameters of thetransition like longitudinal and transversal relaxation rates as well as thedipole moment of the transition.TN.I-hf'gAEffVN1VgFigure4.l:Rateequationsforthetwo-level atomIn many cases it is more convenient to normalize (4.1) and (4.2) to thepopulations in level e and g or 2 and 1, respectively, N2 and Ni, and thedensity of photons, nL, in the mode interacting with the atoms and travelingat the corresponding group velocity, g, see Fig. 4.1. The intensity I in amode propagating at group velocity ug with a mode volume V is related tothe numberof photons Nstored in themode with volumeVbyNL-1(4.3)I=hfL7-hfiniug,2*VUg2*where hfi is the photon energy. 2* = 2 for a linear laser resonator (thenonly half of the photons are going in one direction), and 2* = 1 for a ringlaser. In this first treatment we consider the case of space-independent rateequations, i.e. we assume that the laser is oscillating on a single mode andpumping and mode energy densities are uniform within the laser material.Withtheinteractioncrosssectiongdefined ashfi(4.4)a2*I,T
128 CHAPTER 4. LASER DYNAMICS (SINGLE-MODE) Eq.(2.145) Is = ⎡ ⎢ ⎣ 2T1T2ZF ~2 ¯ ¯ ¯ M ˆ E ¯ ¯ ¯ 2 ¯ ¯ ¯ ˆ E ¯ ¯ ¯ 2 ⎤ ⎥ ⎦ −1 , which relates the saturation intensity to the microscopic parameters of the transition like longitudinal and transversal relaxation rates as well as the dipole moment of the transition. Figure 4.1: Rate equations for the two-level atom In many cases it is more convenient to normalize (4.1) and (4.2) to the populations in level e and g or 2 and 1, respectively, N2 and N1, and the density of photons, nL, in the mode interacting with the atoms and traveling at the corresponding group velocity, vg, see Fig. 4.1. The intensity I in a mode propagating at group velocity vg with a mode volume V is related to the number of photons NL stored in the mode with volume V by I = hfL NL 2∗V vg = 1 2∗hfLnLvg, (4.3) where hfL is the photon energy. 2∗ = 2 for a linear laser resonator (then only half of the photons are going in one direction), and 2∗ = 1 for a ring laser. In this first treatment we consider the case of space-independent rate equations, i.e. we assume that the laser is oscillating on a single mode and pumping and mode energy densities are uniform within the laser material. With the interaction cross section σ defined as σ = hfL 2∗IsT1 , (4.4)
1294.1.RATEEQUATIONSand multiplying Eq. (??) with the number of atoms in the mode, we obtaind(Ma- M) --(=N) - (Na- ~) gn1 + R(4.5)dtT1Note, Ugnz is the photon flux, thus o is the stimulated emission cross sectionbetween theatoms and thephotons.Rpis thepumping rateintotheupperlaser level. A similar rate equation can be derived for the photon densitydnL++ 4agv [N (mL+ 1) - Ninl] .(4.6)nLdtL VgTpHere, Tp is the photon lifetime in the cavity or cavity decay time and theone in Eq(4.6) accounts for spontaneous emission which is equivalent tostimulated emission by one photon occupying the mode. V. is the volume ofthe active gain medium.For a laser cavity with a semi-transparent mirrorwith transmission T, producing a small power loss 2l = - ln(1 - T) ~ T (forsmall T)per round-trip in the cavity, the cavity decay time is Tp=21/Tr,if TR = 2*L/co is the roundtrip-time in linear cavity with optical length 2Lor a ring cavity with optical length L. The optical length L is the sum of theoptical length in the gain medium ngrouplg and the remaining free space cavitylength la.Internal losses can be treated in a similar way and contribute tothe cavity decay time. Note, the decay rate for the inversion in the absenceof a field, 1/Ti, is not only due to spontaneous emission, but is also a result ofnon radiative decay processes. See for example the four level system shownin Fig. 4.2. In the limit, where the populations in the third and first levelare zero, because of fast relaxation rates, i.e. T32, Tio → 0, we obtaindN2(4.7)N2gu.N2ni+RdtTLdnLeggN2 (nL+1).(4.8)dtntLVgTpwhere TL = T2r is the lifetime of the upper laser level. Experimentally, thephoton number and the inversion in a laser resonator are not
4.1. RATE EQUATIONS 129 and multiplying Eq. (??) with the number of atoms in the mode, we obtain d dt(N2 − N1) = −(N2 − N1) T1 − σ (N2 − N1) vgnL + Rp (4.5) Note, vgnL is the photon flux, thus σ is the stimulated emission cross section between the atoms and the photons. Rp is the pumping rate into the upper laser level. A similar rate equation can be derived for the photon density d dtnL = −nL τ p + lg L σvg Vg [N2 (nL + 1) − N1nL] . (4.6) Here, τ p is the photon lifetime in the cavity or cavity decay time and the one in Eq.(4.6) accounts for spontaneous emission which is equivalent to stimulated emission by one photon occupying the mode. Vg is the volume of the active gain medium. For a laser cavity with a semi-transparent mirror with transmission T, producing a small power loss 2l = − ln(1− T) ≈ T (for small T) per round-trip in the cavity, the cavity decay time is τ p = 2l/TR , if TR = 2∗L/c0 is the roundtrip-time in linear cavity with optical length 2L or a ring cavity with optical length L. The optical length L is the sum of the optical length in the gain medium ngroup g lg and the remaining free space cavity length la. Internal losses can be treated in a similar way and contribute to the cavity decay time. Note, the decay rate for the inversion in the absence of a field, 1/T1, is not only due to spontaneous emission, but is also a result of non radiative decay processes. See for example the four level system shown in Fig. 4.2. In the limit, where the populations in the third and first level are zero, because of fast relaxation rates, i.e. T32, T10 → 0, we obtain d dtN2 = −N2 τ L − σvgN2nL + Rp (4.7) d dtnL = −nL τ p + lg L σvg Vg N2 (nL + 1). (4.8) where τ L = T21 is the lifetime of the upper laser level. Experimentally, the photon number and the inversion in a laser resonator are not
130CHAPTER4.LASERDYNAMICS (SINGLE-MODE)N331322N2RP1211N1T1o0NoFigure 4.2: Vier-Niveau-Laservery convenient quantities, therefore, we normalize both equations to thelwaN,Trexperiencedbythelightandtheround-tripamplitudegaing=L21circulating intracavity power P=TAeffdgp9 - 90(4.9)dgEsatTLd12g(P+ Puac),(4.10)dtTRTpwithhfLEs(4.11)=IsAeffTL2*gPsatEsat/TL(4.12)=Puac(4.13)=hfLug/2*L=hfL/TR20,RpoTL(4.14)902Aeffcothe small signal round-trip gain of the laser.Note, the factor of two in frontof gain and loss is due to the fact, the g and I are gain and loss with respect toamplitude.Eq.(4.14) elucidates that the figure of merit that characterizes thesmall signal gain achievable with a certain laser material is the oTr-product
130 CHAPTER 4. LASER DYNAMICS (SINGLE-MODE) 3 0 1 2 N N N N 3 2 1 0 T T T 32 21 10 R p Figure 4.2: Vier-Niveau-Laser very convenient quantities, therefore, we normalize both equations to the round-trip amplitude gain g = lg L σvg 2Vg N2TR experienced by the light and the circulating intracavity power P = I · Aef f d dtg = −g − g0 τ L − gP Esat (4.9) d dtP = − 1 τ p P + 2g TR (P + Pvac), (4.10) with Es = IsAef f τ L = hfL 2∗σ (4.11) Psat = Esat/τ L (4.12) Pvac = hfLvg/2∗ L = hfL/TR (4.13) g0 = 2∗vgRp 2Aef f c0 στ L, (4.14) the small signal round-trip gain of the laser. Note, the factor of two in front of gain and loss is due to the fact, the g and l are gain and loss with respect to amplitude. Eq.(4.14) elucidates that the figure of merit that characterizes the small signal gain achievable with a certain laser material is the στ L-product
1314.1.RATEEQUATIONSWave-LinewidthCrossUpper-St.Refr.AfFWHM =SectionTypLaser MediumlengthLifetimeindex(THz)α (cm2)Xo(nm)TL (μs)n4.1·1019Nd3+:YAG1,0641,2000.210H1.821.3·10-19HNd3+:LSB1,062871.21.47 (ne)1.8.10-19Nd3+:YLF1,047450H0.3901.82 (ne)2.5.1019Nd3+:YVO4500.300H2.19 (ne)1,0644·10-203Nd3+ :glass1,054350H/I1.56·10-211,554H/I1.46Er3+:glass10,0002.10-20HRuby694.31,0000.061.763·1019HTi3+:Al,0331001.76660-11804.8.102080Cr3+:LiSAF67H1.4760-9601.3·102065Cr3+:LiCAF710-840170H1.43.3·10-20Cr3+:LiSGAF8880H1.4740-9301·10-131He-Ne632.80.7~10.00153·10-121Ar+515~10.070.00353·1018CO2H~110,6002,900,0000.0000603·10165H560-6400.00331.33Rhodamin-6G~10-1425H/l3-4450-30,000~0.002semiconductorsTable 4.1: Wavelength range, cross-section for stimulated emission, upper-state lifetime, linewidth, typ of lineshape (H-homogeneously broadened,I-inhomogeneously broadened) and index for some often used solid-statelaser materials, and in comparison with semiconductor and dye lasers