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PHASE CONJUGATE MIRRORS
Article in Journal of Nonlinear Optical Physics & Materials · April 2012
DOI: 10.1142/S0218863501000425

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J. Nonlinear Optic. Phys. Mat. 2001.10:43-52. Downloaded from www.worldscientific.com by FLINDERS UNIVERSITY LIBRARY on 01/30/15. For personal use only.

May 8, 2001 16:14 WSPC/145-JNOPM 00042
Journal of Nonlinear Optical Physics & Materials Vol. 10, No. 1 (2001) 43–52 c World Scientiﬁc Publishing Company
PHASE CONJUGATE MIRRORS
HANS J. EICHLER and OLIVER MEHL∗ Technische Universita¨t Berlin, Optisches Institut, Straße des 17. Juni 135, D-10623 Berlin, Germany
∗E-mail : oliver.mehl@physik.tu-berlin.de
Received 18 May 2000 Phase conjugate mirrors are attractive devices to improve the beam quality of lasers. At ﬁrst, the fundamental properties of phase conjugate mirrors (PCMs) are summarized and a basic mathematical description is given. Degenerate four-wave mixing (DFWM) facilitates phase conjugation of weak signals and their ampliﬁcation at the same time, but requires additional pumping beams. In contrast, self pumped phase conjugation is achieved by stimulated Brillouin scattering (SBS) in appropriate media. Liquids and gases of high purity as well as solid materials like silica ﬁbers can be used with high eﬃciency. Solid-state laser systems with average output powers up to 500 W have been equipped with SBS phase conjugate mirrors to compensate for phase distortions in active media.
1. Introduction Phase conjugation is a nonlinear optical process which generates a light beam having the same wave fronts as an incoming light beam but opposite propagation direction, see Fig. 1. Therefore phase conjugation is called also wavefront reversal. A nonlinear optical device generating a phase conjugated wave is called a phase conjugator or phase conjugate mirror.
In Fig. 2, we consider the conjugation property of a PCM on a probe wave emanating from a point source. A diverging beam, after “reﬂection” from an ideal
Fig. 1. Wave front reﬂection at a conventional and a phase conjugate mirror. 43

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44 H. J. Eichler & O. Mehl

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Fig. 2. Beam propagation after reﬂection at a conventional mirror and a PCM, both illuminated by a point source.
PCM, gives rise to a converging conjugate wave that precisely retraces the path of the incident probe wave, and therefore propagates in a time-reversed sense back to the same initial point source.
A phase conjugator reﬂects light, mostly laser beams, if the incident power is high enough (self-pumped phase conjugator ) or if the nonlinear material in the phase conjugator is pumped by additional laser beams, e.g. two additional beams in a degenerate four-wave mixing arrangement. In principle phase conjugation could be achieved also by a deformable mirror which is controlled by a wave front sensor adapting the local mirror curvature to the incoming wave front. Instead of a deformable mirror also a 2-dimensional phase modulator could be used. However, deformable mirrors and other phase modulators are not applied up to now to solve practical problems requiring phase conjugation.

2. Basic Mathematical Description

The incoming wave Ein is given by Eq. (1) with frequency f , where the amplitude E0 and phase Φ are combined to the complex amplitude A. The complex conjugate is denoted by c.c.

Ein(x, y, z, t)

=

1 2

E0(x,

y,

z)e2πi(f

t+Φ(x,y,z))

+

c.c.

=

A(x, y, z)eiωt

+

c.c.

(1)

A(x, y, z)

=

1 2

E0(x,

y,

z)e2πiΦ(x,y,z)

.

(2)

The phase conjugated wave exhibits the same wave fronts, however the sign of the

phase Φ is inverted due to the inverted propagation direction. Thus, the phase

conjugated wave Epc can be written as Eq. (3).

Epc(x, y, z, t)

=

1 2

E0(x,

y,

z)e2πi(f

t−Φ(x,y,z))

+

c.c.

=

Apc(x, y, z)eiωt

+

c.c.

(3)

Apc(x, y, z)

=

1 2

E0(x,

y,

z)e−2πiΦ(x,y,z)

=

A∗(x, y, z) .

(4)

As can be seen Apc equals the complex conjugated A∗, what explains the term

phase conjugation. From Eqs. (1) and (3) we derive that the incident and phase

conjugated wave are also related to each other by

Ein(x, y, z, −t) = Epc(x, y, z, t) .

(5)

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Phase Conjugate Mirrors 45
Thus, the phase conjugate wave Epc propagates as if one would reverse the temporal evolution of the incident wave Ein. Therefore the term “time reversed replica” is sometimes used to describe the phase conjugate wave.
An ideal PCM also maintains the polarization state of an incident wave after phase conjugation. As an example, a probe wave that is right-handed circularly polarized (RHCP) will result in a RHCP reﬂected wave, after conjugation. This is in contrast to a conventional mirror, which reﬂects an incident RHCP ﬁeld to yield a left-handed circularly polarized (LHCP) wave.1
One should realize that an ideal phase conjugated wave exhibits the same frequency f as the incident wave and reveals the same polarization state. Often, real phase conjugators do not have these properties. However, if an PCM maintains the polarization state it is called a “vector phase conjugator ”.
The nonlinear optical process which comes closest to yielding an ideal phase conjugate wave is the backward-going, degenerate four-wave mixing interaction. Other classes of interaction (e.g. stimulated eﬀects) result in nonideal conjugate waves due to frequency shifts, nonconjugated ﬁeld polarization, etc. Although the application of stimulated eﬀects, especially stimulated Brillouin scattering (SBS), yields to nonideal phase conjugate mirrors they are used the most to solve practical problems requiring phase conjugation (e.g. compensation of phase distortions in high average power laser systems2).
3. Phase Conjugation by Degenerate Four-Wave Mixing Four-wave mixing can be understood as a real time holographic process, which facilitates phase conjugation. If the frequencies of the incoming wave, the two additionally required pump waves and the phase conjugated or reﬂected wave are equal the process is called degenerate four-wave mixing (DFWM), see Fig. 3.
Interference of the incoming wave Ein(x, y, z, t) with the pump wave P1(x, y, z, t) results in a spatially periodic intensity pattern which modulates the absorption coeﬃcient or refractive index of the optical material resulting in a dynamic or transient amplitude or phase grating. The other pump P2(x, y, z, t) is diﬀracted at this grating producing the phase conjugated wave. This corresponds to the conventional holographic process where the read-out wave is replaced by the second pump wave counterpropagating to the ﬁrst pump or reference wave.
Fig. 3. Setup for phase conjugation by four-wave mixing.

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46 H. J. Eichler & O. Mehl

Recording of a hologram is the ﬁrst step in phase conjugation and leads to a transmission function t in the hologram plane (variables will not be noted further more to simplify the readability):

t ∝ |P1 + Ein|2 = · · · = |P1|2 + P1Ei∗n + P1∗Ein + |Ein|2 .

(6)

During the read-out the phase conjugate wave can be generated. Therefore the
hologram is illuminated with a second pump wave P2, propagating in the opposite direction to P1. This is in contrast to standard holography. Since P2 precisely retraces the path of P1 in the opposite propagation direction, P2 equals P1∗. This means, that the two pump beams should be phase conjugated to each other, so that
their spatial phases cancel and do not inﬂuence the phases of the reﬂected beam.
In the hologram plane we obtain a ﬁeld strength distribution as follows:

P2t = P1∗t ∝ P1∗|P1|2 + |P1|2Ei∗n + (P1∗)2Ein + P1∗|Ein|2 .

(7)

The second term |P1|2Ei∗n corresponds to the phase conjugate wave of Ein. The other expressions lead to three additional waves which are not of interest here.

They can be suppressed in thick nonlinear media in case of Bragg diﬀraction.

Common dynamic grating materials for phase conjugation are:

• photorefractive crystals (BaTiO3, LiNbO3, . . .) • liquid crystals (molecular reorientation eﬀects) • laser crystals (spatial hole-burning, excited state absorption) • saturable absorbers • absorbing gases and liquids (thermal gratings) • semiconductors (Si, Ge, GaAs, . . .).

The disadvantage of phase conjugation by four-wave mixing is the requirement of two additional pump waves for the nonlinear medium. However, this facilitates ampliﬁcation of the phase conjugate wave in the nonlinear medium at the same time. Vector phase conjugation is not achieved by this simple DFWM scheme but requires polarization dependant interactions.

4. Self Pumped Phase Conjugation
Self pumped phase conjugation of continuous wave laser beams in the lower power range (mW to W) can be realized in FWM loop arrangements using photorefractive media (not discussed here). For pulsed lasers, self pumped phase conjugation is achieved by stimulated scattering. For practical application, stimulated Brillouin scattering3 in
• gases (SF6, Xe, C2F6, CH4, N2, . . .) under high pressure, • liquids (CS2, CCl4, Freon, GeCl4, acetone, methanol . . .), and • solids (bulk quartz glass, silica glass ﬁbers) is used.
Table 1 shows the Brillouin gain coeﬃcient g, the phonon lifetime τ for diﬀerent gaseous, liquid and solid state SBS media.

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Phase Conjugate Mirrors 47

Table 1. Brillouin gain coeﬃcient g and phonon lifetime τ for diﬀerent SBS media.

SBS Medium
SF6 (20 bar) Xe (50 bar) C2F6 (30 bar) CS2 CCl4 Acetone Quartz

Brillouin gain coeﬃcient g [cm/GW]
25 90 60 130 6 20 2.4

Phonon lifetime τ [ns]
15 33 10 5.2 0.6 2.1 5

A phase conjugate mirror consists simply of a gas or liquid cell or a ﬁber piece. The incoming wave is focused into the material where an oppositely traveling wave is generated initially by spontaneous scattering. This wave interferes with the incoming wave and induces a sound wave or another type of phase grating reﬂecting the incoming beam similarly as a dielectric multilayer mirror. The induced density variations have the frequency of the initial sound wave, which is ampliﬁed therefore and reinforces the backscattering.
The ampliﬁcation depends strongly on the extension of the interference area. Therefore the phase conjugated backscattered part dominates, leading to an exponential rise of the reﬂected phase conjugated signal. The wave fronts of the sound wave grating match the wave fronts of the incoming beam. Any disturbance of the incident wavefront will result in a self adapted mirror curvature with response times in the ns range.
For applications the “threshold”, reﬂectivity and conjugation ﬁdelity are the most important parameters that characterize the performance of a Brillouin scattering phase conjugate mirror. A sharply deﬁned threshold does not exist for the nonlinear SBS process. However, after exceeding a certain input energy a steep increase of reﬂectivity can be observed. Often this is called the energy threshold of the phase conjugate medium. For long pulses as compared to the phonon lifetime (typically several ns) the SBS is expected to become stationary. In this case the energy threshold can be substituted by a power threshold. Well above this threshold, the reﬂectivity is not stationary but exhibits statistical ﬂuctuations because SBS starts from noise.
It is important to emphasize that the power and not the intensity determines the “threshold”, in case of strongly monochromatic input waves. Slight focusing leads to lower intensity, but also to a longer Rayleigh length and a larger interaction area. Stronger focusing reduces the interaction length, but results in stronger refractive index modulation. Both eﬀects compensate each other if the interaction length is not limited by the coherence length.

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48 H. J. Eichler & O. Mehl

Practically, for most laser sources the coherence length is rather short. Here, the interaction length should be short compared to the coherence length. This requires adequate focusing of the beam into the SBS medium. Focal length and scattering material have to be chosen suitable to achieve a high SBS reﬂectivity and a good reproduction of the wave front. Side eﬀects in the material like absorption, optical breakdown or other scattering processes have to be avoided. Figure 4 shows the energy reﬂectivity of carbon disulﬁde CS2 as a function of the input power at 1 µm wavelength. Carbon disulﬁde shows one of the smallest power thresholds for liquids of about 18 kW. Applying gases as SBS media, the power thresholds are about one order of magnitude higher. A saturation of energy reﬂectivity close to 80% is a typical value for liquid SBS media, although reﬂectivities up to 96% had been demonstrated.4
For high power input pulses bulk solid state media like quartz are investigated as SBS media, too.5 To reduce the power threshold of SBS a waveguide geometry can be applied.6 The beam intensity inside the waveguide is high within a long interaction length resulting in low power thresholds. To avoid toxic liquids and gases under high pressure multimode silica ﬁbers can be used.7 The lower Brillouin gain of quartz glass compared to suitable SBS gases and liquids can be overcome using ﬁbers with lengths of several meters resulting in SBS thresholds down to 200 W peak power.8
The power threshold can be estimated from Eq. (8), where Aeﬀ is the eﬀective mode ﬁeld area inside the ﬁber core, Leﬀ the eﬀective interaction length, which depends on the coherence length, and g is the Brillouin gain coeﬃcient; for quartz g is about 2.4 cm/GW.9

Pth

=

21Aeﬀ Leﬀ g

.

(8)

Table 2 shows the power threshold, the maximum energy reﬂectivity, the far ﬁeld

ﬁdelity, the M 2-limit and an approximated power limit of ﬁber phase conjugators

Fig. 4. Commonly used carbon disulﬁde (CS2) shows an SBS threshold of about 18 kW (pulse peak power) under stationary conditions.

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Phase Conjugate Mirrors 49

Table 2. SBS threshold, max. reﬂectivity, far ﬁeld ﬁdelity, M 2-limit and power limit for diﬀerent ﬁber phase conjugators, coherence length 1.5 m. The reﬂectivity is corrected with respect to Fresnel and coupling losses.

LCore diameter SBS threshold Maximum

Far ﬁeld M 2-limit Power limit

(µm)

(kW)

reﬂectivity (%) ﬁdelity (%)

(kW)

200

17

80

93

63

160

100

6.4

80

91

31

40

50

2.0

88

70

16

10

25

0.3

86

—

8

2.5

with diﬀerent core diameters. The used quartz-quartz ﬁbers had a step-index geo-

metry and a numerical aperture of 0.22. They were investigated with a Nd:YAG

oscillator ampliﬁer system generating pulses of 30 ns (FWHM) pulses at 1.06 µm

wavelength. Regarding applications it is important to couple also spatially aberrated

beams into the ﬁber. The upper limit for the beam parameter product is given due

to the ﬁnite numerical aperture and the core diameter of the ﬁber. This can be expressed by a times diﬀraction limit value M 2. The upper power limit is approximated assuming a damage threshold above 500 MW/cm2 for ns pulses.

An important feature of a ﬁber phase conjugator is the threshold behavior for diﬀerent M 2-values of the incoming beam. In case of a ﬁber the SBS threshold is

nearly independent of the incoming beam quality. This is caused by mode conver-

sion inside the ﬁber resulting in homogeneous illumination and therefore in con-

stant SBS reﬂectivity. In case of a Brillouin cell the reﬂectivity depends on the far

ﬁeld distribution of the incoming beam. Here phase distortions result in amplitude

ﬂuctuations in the focal region. A comparison between a diﬀraction limited beam (M 2 = 1.0) and a highly distorted beam (M 2 = 10) showed an increase of the SBS

threshold of 300% in case of the Brillouin cell. For the ﬁber phase conjugator no remarkable changes of the power threshold were observed.10

Practically, the reproduction of the initial wave front is not perfect after phase

conjugation. To characterize the deviation with respect to the reference wave the term ﬁdelity is introduced.11

F=

| EsEp∗d2r|2 |Es|2d2r · |Ep|2d2r

.

(9)

The ﬁdelity equals unity in case of perfect wave front reproduction and is smaller

than unity for practical cases. To calculate the ﬁdelity, the electric ﬁeld distribution

of the incident signal Es and the phase conjugate wave Ep has to be known. The determination requires sophisticated measurement equipment. In contrast, the far

ﬁeld ﬁdelity can be determined with less eﬀort and is therefore often used. The

transmission through an aperture of the phase conjugate signal is compared with

the transmission of the input signal. The ratio is called far ﬁeld ﬁdelity, because

the aperture is placed in the focal plane of a focusing lens.

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May 8, 2001 16:14 WSPC/145-JNOPM 00042
50 H. J. Eichler & O. Mehl
5. Applications of SBS Phase Conjugation Phase conjugation generates a wave which retraces the incoming wave in a timereversed way. Thereby it is possible to eliminate phase distortions in optical systems. For example, in a solid state laser ampliﬁer, the incoming beam is not only ampliﬁed but suﬀers also from phase distortions due to thermal refractive index changes in the laser crystal. After passing this ampliﬁer crystal, the beam is reﬂected by a phase conjugator and passes the crystal a second time. Because the wave fronts are inverted with respect to the propagation direction, the refractive index changes reduce the phase distortions and after the second passage, these distortions disappear so that the beam quality of the incoming wave is reproduced.
Typically, phase conjugators are applied in Master Oscillator Power Ampliﬁer (MOPA) setups, where a nearly diﬀraction limited master oscillator beam is increased in power within an ampliﬁer arrangement, see Fig. 5. After the ﬁrst ampliﬁcation pass the beam quality is reduced due to thermally induced phase distortions. The spatial distorted beam enters the SBS mirror and becomes phase conjugated. The initial beam quality of the master oscillator can be roughly reproduced after the second ampliﬁcation pass. The ampliﬁed beam is extracted with an optical isolation, which consists in this case of a Faraday rotator and a polarizer.
Figure 6 shows a MOPA system producing up to 210 W average output power at 2 kHz average repetition rate (1.08 µm wavelength). The system is part of an advanced setup yielding to 520 W average output power.2 The oscillator beam has a nearly diﬀraction limited beam quality (M 2 < 1.2) which is already reduced in front of the ﬁrst ampliﬁer (M 2 ∼= 1.5). This results from optical components between oscillator and ampliﬁer which introduce phase distortions. After single pass ampliﬁcation the beam quality decreases to M 2 ∼= 5 due to phase distortions introduced by both pumped ampliﬁer rods at 6.5 kW pumping power for each ampliﬁer. After phase conjugation and double pass ampliﬁcation the initial beam quality can be nearly reproduced (M 2 < 1.9). Diﬀerences between the initial and ﬁnal beam quality are caused by a ﬁdelity smaller than unity and diﬀraction at several apertures in the ampliﬁer chain.
Fig. 5. Double pass scheme with phase conjugate mirror to compensate for phase distortions.

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May 8, 2001 16:14 WSPC/145-JNOPM 00042
Phase Conjugate Mirrors 51
Fig. 6. Master oscillator power ampliﬁer setup with phase conjugate mirror.
Fig. 7. Far ﬁeld intensity distributions of the oscillator beam, the distorted beam after single pass ampliﬁcation and the highly ampliﬁed beam after double pass ampliﬁcation with phase conjugation.
The performance of the phase conjugate mirror can be illustrated by far ﬁeld intensity proﬁles recorded at diﬀerent positions in the setup. In Fig. 7, the oscillator output beam exhibits a smooth Gaussian proﬁle corresponding to the nearly diﬀraction limited beam quality. After single pass ampliﬁcation the reduction of beam quality is conﬁrmed by a strongly aberrated far ﬁeld proﬁle. After phase conjugation and double pass ampliﬁcation the initial intensity distribution can be nearly reproduced. In this example the average power of the master oscillator beam (approx. 1 W) was increased to 130 W after double pass ampliﬁcation.
Presently, this is the most often frequent application of phase conjugation. In addition phase conjugators are useful as mirrors in laser oscillators replacing one of the conventional mirrors. Again, the phase conjugator eliminates phase distortions in the laser medium induced by optical or discharge pumping. References 1. D. M. Pepper, Opt. Eng. 21, 156 (1982). 2. H. J. Eichler and O. Mehl, “Multiampliﬁer arrangements with phase conjugation for
power-scaling of high-beam quality solid state lasers”, Solid State Lasers VIII, San Jos´e (California), SPIE Vol. 3613 (1999).

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May 8, 2001 16:14 WSPC/145-JNOPM 00042
52 H. J. Eichler & O. Mehl 3. W. Kaiser and M. Maier, “Stimulated Rayleigh, Brillouin and Raman Spectroscopy”, Laser Handbook, eds. F. T. Arecchi and E. O. Schulz-DuBois (North-Holland Publ. Co., 1972). 4. G. J. Crofts, M. J. Damzen and R. A. Lamb, J. Opt. Soc. Am. B8, 2282 (1991). 5. Yoshida et al., CLEO 1997, Technical Digest Series 11, 117 (1997). 6. S. Jackel et al., Nonlin. Opt. 11, 89 (1995). 7. H. J. Eichler, J. Kunde and B. Liu, Opt. Commun. 139, 327 (1997). 8. H. J. Eichler, A. Dehn, A. Haase, B. Liu, O. Mehl and S. Ru¨cknagel, “High repetition rate continuously pumped solid state lasers with phase conjugation”, Solid State Lasers VII, San Jose (California), SPIE Vol. 3265, 1998, pp. 200–210. 9. G. P. Agrawal, Nonlinear Fiber Optics (Academic Press, 1989).
10. H. J. Eichler, A. Haase, J. Kunde, B. Liu and O. Mehl, “Fiber phase-conjugator as reﬂecting mirror in a MOPA-arrangement”, Solid State Lasers VI, San Jose (California), SPIE Vol. 2986, 1997, pp. 46–54.
11. B. Ya. Zel’dovich and V. V. Shkunov, Sov. J. Quantum Electron. 7, 610 (1977).
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