thermal lens shaping in brewster gain media: a high-power, diode-pumped nd:gdvo4 laser

Thermal lens shaping in Brewster gain media: A high-power, diode-pumped Nd:GdVO4 laser

N.W. Rimington, S.L. Schieffer, and W. Andreas Schroeder,

University of Illinois at Chicago, Physics Department (m/c 273), 845 W. Taylor Street (rm. 2348), Chicago, IL 60607-7059

[email protected]

Brian K. Brickeen

Northrop Grumman Space Technologies, Cutting Edge Optronics, 20 Point West Blvd., St. Charles, MO 63301

Abstract: A straightforward method is presented for generating a stigmatic spherical thermal lens in laser-diode-pumped, Brewster-cut solid-state gain media by shaping the aspect ratio of the elliptical pumped region. Demonstration of this laser head design with Nd:GdVO4 as the gain medium yields a stable, efficient, high-power (>20W) diode-pumped laser at 1063nm. Analysis of the spatial mode characteristics of a 67cm-long symmetric resonator both confirms the radially symmetric nature of the pump-induced thermal lens and indicates that laser resonators incorporating this head design can readily generate a high spatial beam quality (M2 < 2).

©2004 Optical Society of America

OCIS codes: (140.3480) Lasers, diode-pumped; (140.3530) Lasers, neodymium ___________________________________________________________________________

References and Links

1. See, for example, R. Scheps, Introduction to laser diode-pumped solid state lasers, Tutorial Texts in Optical Engineering, vol. TT53 (International Society of Optical Engineering (SPIE), 2002).

2. W. Koechner, Solid-State Laser Engineering, 4th edition (Springer-Verlag, Berlin, 1996). 3. H. Zhang, J. Liu, J. Wang, C. Wang, L. Zhu, Z. Shao, X. Meng, X. Hu, M. Jiang, and Y.T. Chow,

“Characterization of the laser crystal Nd:GdVO4,” J. Opt. Soc. Am. B 19, 18-27 (2002). 4. Y.F. Chen, T.M. Huang, C.C. Liao, Y.P. Lan, and S.C. Wang, “Efficient high-power diode-end-pumped TEM00

Nd:YVO4 laser” IEEE Photon. Technol. Lett. 11, 1241-1243 (1999). 5. J. Liu, Z. Shao, H. Zhang, X. Meng, L. Zhu, and M. Jiang, “Diode-laser-array end-pumped 14.3W CW

Nd:GdVO4 solid-state laser at 1.06µm,” Appl. Phys. B 69, 241-243 (1999). 6. Y.F. Chen, Y.P. Lan, and S.C. Wang, “High-power diode-end-pumped Nd:YVO4 laser: thermally induced

fracture versus pump-wavelength sensitivity,” Appl. Phys. B 71, 827-830 (2000). 7. A. Giesen, H. Hügel, A. Voss, K. Wittig, U. Brauch, and H. Opower, “Scalable concept for diode-pumped high-

power solid-state-lasers,” Appl. Phys. B 58, 365-372 (1994). 8. B.A. Thompson, A. Minassian, and M.J. Damzen, “Operation of a 33-W, continuous-wave, self-adaptive, solid-

state laser oscillator,” J. Opt. Soc. Am. B 20, 857-862 (2003). 9. J.E. Bernard and A.J. Alcock, “High-efficiency diode-pumped Nd:YVO4 slab laser,” Opt. Lett. 18, 968-970

(1993). 10. C. Stewen, K. Contag, M. Larionov, A. Giesen, and H. Hügel, “A 1-kW CW thin disc laser,” IEEE J. Sel. Top.

Quantum. Electron. 6, 650-657 (2000). 11. Product information on Yb:YAG thin disk laser (Electronik Laser Systems GmbH, 2004),

http://www.versadisk.com/Products/vdisk.html. 12. S. Knoke, G. Hollemann, M. Nickel, and H. Voelckel, “Frequency doubled Nd:YVO4 thin disk laser with 30%

diode-to-green efficiency,” paper CThC2 in Technical Digest of the Conference on Lasers and Electro-Optics 2001 (Baltimore, MD), (Optical Society of America, Washington DC, 2001) p.388-389.

13. H.W. Kogelnik, E.P. Ippen, A. Dienes, and C.V. Shank, “Astigmatically compensated cavities for CW dye lasers,” IEEE J. Quantum. Electron. QE-8, 373-379 (1972).

14. M. Mehendale, T.R. Nelson, F.G. Omenetto, and W.A. Schroeder, “Thermal effects in laser pumped Kerr-lens modelocked Ti:sapphire lasers,” Opt. Commun. 136, 150-159 (1997).

15. A.E. Siegman, Lasers (University Science Books, Sausalito, CA, 1986).

#3970 - $15.00 US Received 3 March 2004; revised 24 March 2004; accepted 29 March 2004

(C) 2004 OSA 5 April 2004 / Vol. 12, No. 7 / OPTICS EXPRESS 1426

mailto:[email protected]

http://www.versadisk.com/Products/vdisk.html

16. L. Xu, G. Tempea, A. Poppe, M. Lenzner, Ch. Spielmann, F. Krausz, A. Stingl, and K. Ferencz, “High-power sub-10-fs Ti:sapphire oscillators,” Appl. Phys. B 65, 151-159 (1997).

17. R. Paschotta, J. Aus der Au, G.J. Spühler, F. Morier-Genoud, R. Hövel, M. Moser, S. Erhard, M. Karszewski, A. Giesen, and U. Keller, “Diode-pumped passively mode-locked lasers with high average power,” Appl. Phys. B 70, S25-S31 (2000).

18. Artic Silver 5, High-density Polysynthetic Silver Thermal Compound (Artic Silver, 2004), http://www.articsilver.com/as5.htm.

19. T. Jensen, V.G. Ostroumov, J.-P. Meyn, G. Huber, A.I. Zagumennyi, I.A. Shcherbakov, “Spectroscopic characterization and laser performance of diode-laser-pumped Nd:GdVO4,” Appl. Phys. B 58, 373-379 (1994).

20. Q. Fu, F. Seier, S.K. Gayen, and R.R. Alfano,”High-average-power kilohertz-repetition-rate sub-100-fs Ti:sapphire amplifier system,” Opt. Lett. 22, 712-714 (1997).

21. P.A. Studenikin, A.I. Zagumennyi, Yu.D. Zavaratsev, P.A. Popov, and I.A. Shcherbakov, “GdVO4 as a new medium for solid-state lasers: some optical and thermal properties of crystals doped with Nd3+, Tm3+, and Er3+ ions,” Quantum Electron. 25, 1162-1165 (1995).

22. P.K. Mukhopadhyay, A. Nautiyal, P.K. Gupta, K. Ranganathan, J. George, S.K. Sharma, and T.P.S. Nathan, “Experimental determination of the thermo-optic coefficient (dn/dT) and the effective stimulated emission cross-section (σe) of an a-axis cut 1.-at. % doped Nd:GdVO4 crystal at 1.06µm wavelength,” Appl. Phys. B 77, 81-87 (2003).

23. 808nm 40W CW laser diode array (Northrup Grumman Space Technologies, Cutting Edge Optronics, 2004), http://www.imclaser.com/pdf/808-CS-40W-single.pdf.

24. N. Hodgson and H. Weber, Optical Resonators (Springer, Berlin-Heidelberg, 1997). 25. W.A. Clarkson, “Thermal effects and their mitigation in end-pumped solid-state lasers,” J. Phys. D: Appl. Phys.

34, 2381-2395 (2001). ___________________________________________________________________________

1. Introduction

The directionality and spectral purity (i.e., brightness) of laser diode (LD) pump sources has revolutionized solid-state laser development [1,2]. In particular, many diode-pumped solid-state lasers producing multiwatt continuous-wave (cw) output power in the fundamental TEM00 spatial mode employ fiber-coupled LD pumping to provide the high efficiency generated by good spatial overlap between the pump radiation and the intracavity laser mode [3-5]. An optimized end-pumped Nd:YVO4 laser of this type has produced 25W of cw output power in the fundamental TEM00 mode at 1064nm [6]. Other efficient LD-pumped laser architectures have also been developed: for example, the thin disk geometry [7] as well as self-adaptive phase-conjugate oscillators [8] based on the grazing-incidence geometry [9]. While the former has been shown to be capable of generating kW-level cw output power using Yb:YAG as the gain medium [10], the latter ingeniously compensates for the strong pump-induced thermal lensing in Nd:YVO4 to produce 20W of cw TEM00-mode output. Several commercial devices based on fiber-coupled end-pumped and, more recently, thin disk [11,12] geometries are now available.

In this paper, we outline an alternative technique for obtaining high-power, low-divergence output from axially LD-pumped solid-state gain media. The method exploits the directionality and output asymmetry of LD arrays to generate a stigmatic spherical (i.e., radially symmetric) thermal lens in inherently astigmatic Brewster-cut laser crystals by shaping the aspect ratio of the elliptical pumped region. The rationale behind this straightforward method is described in Section 2. In Section 3, we propose a laser head design, which also avoids the use of dichroic or anti-reflection (AR) dielectric coatings, to test the concept using Nd:GdVO4 directly pumped by two 40W LDs in a near-longitudinal counter-propagating geometry. The cw performance of this high-power Nd:GdVO4 laser head in symmetric flat-flat resonators is described in Section 4. In particular, results of a spatial mode analysis are presented to verify that the design goal of shaping a stigmatic spherical thermal lens in the Brewster-cut gain medium has been achieved.

2. Design rationale

The use of Brewster-cut solid-state gain media in laser resonators has a number of well-known advantages: (i) the near-zero intracavity reflection loss from the gain medium



http://www.articsilver.com/as5.htm

http://www.imclaser.com/pdf/808-CS-40W-single.pdf

improves laser efficiency, (ii) the geometry strongly favors cavity oscillation in the linear π-polarization state (even if the gain medium is optically isotropic like Nd:YAG), and (iii) the optical damage threshold is generally higher for π-polarized radiation incident at Brewster’s angle than for normal incidence radiation (especially if an AR dielectric coating is used). However, the inherent astigmatism of the Brewster geometry will generally result in output beams with elliptical spatial profiles, unless optical compensation schemes (e.g., tilted focusing optics) are employed [13]. Below, we propose an alternative astigmatism compensation scheme for axially LD-pumped Brewster-cut solid-state gain media in which the pump-induced thermal lens is shaped to present, in effect, a stigmatic focusing element to the laser resonator.

Fig. 1. Thermal lens effects in the sagittal and tangential planes of a symmetrically longitudinally pumped, Brewster-cut solid-state laser gain medium of length l; shown are the bulk GRIN lens (shaded) generated by absorption absorption of pump radiation and heat conduction and the surface bowing with radii Rx and Ry due to thermal expansion near the crystal face. The employed coordinate system is also defined; x is the tangential direction, y is the sagittal direction, and z is the longitudinal (or propagation) direction.

Consider the longitudinally LD-pumped, Brewster-cut solid-state gain medium shown in

Fig. 1. The inherent radial asymmetry of the Brewster geometry will, in general, produce an astigmatic pump-induced thermal lens due to an elliptical temperature profile that, in the parabolic paraxial approximation, has the form

( )2221

0),( yBxATyxT TT +−= . (1)

Here, we have used the coordinate system defined in Fig. 1, so that T0 = T(x = 0, y = 0) is the peak axial temperature, and the values of AT and BT are determined primarily by the spatial pump beam profile and the details of thermal conduction in the tangential (x-z) and sagittal (y-z) planes, respectively. Normally, AT and BT are also functions of z (the axial co-ordinate) due to pump beam absorption (and possible self-induced focusing [14]) over the crystal length l. However, for the counter-propagating pump geometry employed for the Nd:GdVO4 laser described below, where the absorption-length product αl ≈ 2, AT and BT may be approximated as constants.



The spatial temperature profile of Eq. (1) generates three contributions to the overall thermal lens of the gain medium [2]: (i) an astigmatic gradient index (GRIN) lens through the bulk thermo-optic effect, (dn/dT); (ii) a refractive lens caused by bowing of the two faces of the gain medium due to thermal expansion; and (iii) a generally nonsymmetric lens produced by stress-induced changes in the refractive index. The stress contribution, which causes birefringence in Nd:YAG rods [2], is difficult to separate and quantify in birefringent gain media like Nd:GdVO4 and Nd:YVO4 that have a strong preferential laser emission polarized parallel to the crystal c-axis. Moreover, as shown later, this effect is expected to be insignificant for our pumping geometry. On the other hand, the thermal GRIN lens over the gain medium length l and the bowing of the crystal faces are both major contributors – albeit with a net thermal focal length fT >> l.

The optical effects of both the GRIN and refractive bowing contributions to the thermal lens in the Brewster geometry of Fig. 1 can be represented by ray transfer matrices (RTMs) [15]. For our case, where the GRIN lens’s perturbation to the wavefront is small upon propagation through the gain medium with refractive index n, the net RTM in the tangential plane (x) is

∆−

∆+γ−

∆

∆−

=

x

x

x

xx

x

x

x

x

x

Rn

l

R

nln

nR

l

n

l

Rn

l

DC

BA

222

2

2

32

12

1

, (2a)

and that in the sagittal plane (y) is

∆−

∆+γ−

∆

∆−

=

y

y

y

yy

y

y

y

y

ynR

l

Rl

nR

l

n

l

nR

l

DC

BA

12

1

22

2 . (2b)

In Eqs. (2), different GRIN lens coefficients γi and implicit positive bowing radii of curvature Ri (i = x or y) are assumed in the sagittal and tangential planes due to the elliptical thermal spatial profile of Eq. (1). The constants ∆y and ∆x are given by

BBy n θ−θ=∆ cossin and BB

yx θθ

∆=∆

cossin , (3)

where )(tan 1 nB−=θ is the Brewster (or polarization) angle.

It is clear from ABCD matrices of Eqs. (2) that in the ‘thin lens’ approximation (fT >> l), which is valid in our case, only the terms in the square brackets will contribute predominantly to the thermal lens. Consequently, since the focal length associated with a thin optical system described by an ABCD matrix is given by the element ratio –(A/C), the condition for a Brewster-cut gain medium to present a stigmatic thermal lens may be written as

α∆+

≈

α∆+

dnl

dT

dnnAdl

dT

dnB TxTTyT 22 2 . (4)



In obtaining Eq. (4), we have related the GRIN lens coefficients to the constants AT and BT

defined by Eq. (1):

=γdT

dnATx

2 and

=γdT

dnBTy

2 . In addition, we have computed the

values of Ri by assuming that only parts of the gain medium within a depth d of the surface contribute to the bowing through the thermal expansion coefficient αT. In a uniformly-pumped Nd:YAG rod, this distance is roughly equal to the rod radius [2]; that is, half of the spatial width of the pumped region. The corresponding distance in a ‘softer’ material like Nd:glass is approximately equal to the entire spatial width of the pumped region (i.e., the diameter for a uniformly-pumped rod). For the Nd-doped GdVO4 crystal, the characteristic expansion distance d is expected to lie between that of crystalline YAG and amorphous glass. This expansion distance must also be the same in both the tangential and sagittal planes, irrespective of the pumping geometry, in order to minimize the net internal stress and strain in the gain medium.

Equation (4) clearly indicates that, for a laser crystal with given dimensions and properties, there should always exist an elliptic parabolic temperature distribution (i.e., ratio AT/BT) within the thin lens approximation for which a Brewster-cut gain medium has a stigmatic thermal lens. Below we describe a general means of achieving this condition by manipulating the spatial pump beam profile in a laser-head geometry that restricts thermal conduction to one dimension [16,17]. The validity of this design approach is verified using results from a high-power (>10W), diode-pumped Nd:GdVO4 laser with high spatial beam quality.

3. The diode-pumped Nd:GdVO4 laser head

To affect the aspect ratio of the tangential-sagittal astigmatism of a thermal lens in a Brewster-cut solid-state laser gain medium, it is generally necessary to regulate the thermal conduction geometry and to closely control the spatial dimensions of the pumped region. The advent of highly directed pump radiation from LDs has made the latter control mechanism possible. To simplify the manipulation of the thermal lens, we have chosen to restrict the thermal conduction to one dimension (the sagittal (y) direction) so that the spatial extent and shape of the pump radiation in the perpendicular direction (the tangential (x) plane) solely determines the strength of the thermal lens in that dimension.

Fig. 2. Schematic of the diode-pumped Nd:GdVO4 laser head design: 40W, 808nm laser diode arrays (LD); f = 20mm spherical lens (L1); f = 10mm cylindrical lens (L2); 808nm half-wave plate (HWP).

The diode-pumped, Brewster-cut Nd:GdVO4 laser head that we have developed to

manipulate the thermal lens is depicted in Fig. 2. The 0.5at.%-doped, 3x5x10mm Nd:GdVO4 laser crystal is appropriately cut for Brewster-angled c-axis emission through its polished 3x10mm faces. To secure one-dimensional heat removal [16,17], only the largest 5x10mm top and bottom faces are conductively contacted to two water-cooled brass mounts, using

Intracavity laser beam

L2 HWP L1

L1 HWP L2

Nd:GdVO4 gain medium

LD LD



silver paste with a thermal conductivity of 11Wm-1K-1 [18]. The gain medium is pumped through both polished sides by two 40W LD bars whose outputs at 808nm are first partially fast-axis collimated in the sagittal plane by a cylindrical lens (f = 10mm) and then focused by a spherical lens (f = 20mm). To avoid the use of dichroic mirrors (or coatings) and to allow spatial separation from the intracavity laser beam (incident at Brewster’s angle, θB = 65.5º), the pump radiation is incident at angles of 15-45º on the gain medium (Fig. 3), which is located at the focal plane of the spherical pump lenses. Nonetheless, the resulting ~15º internal angular separation between the laser and counter-propagating pump beams in the tangential plane creates an efficient quasi-longitudinal pumping geometry over the pumped l ≈ 5mm Nd:GdVO4 crystal length, the ±600-700µm spatial walk-off being less than half the ~2mm tangential laser beam diameter encountered inside the gain medium of the operational laser (see Section 4). In addition, two half-wave plates are employed to ensure that the 808nm pump radiation from each 40W bar can be rotated into the s-polarization. The use of a pump polarization parallel to the a-axis of the 0.5at.% Nd-doped gain medium allows access to a lower α = 4cm-1 effective pump absorption coefficient [3,19], which (i) is beneficial for high-power diode-pumped Nd:GdVO4 lasers [5] and (ii) provides for a more favorable uniform thermal load along the crystal length [20] owing to the resulting αl ≈ 2 absorption condition for the counter-propagating pump beams.

The important design feature of the laser head is that the position of the cylindrical lens (L2) with respect to the LD controls the aspect ratio of the elliptical pump beams in the Nd:GdVO4 gain medium. Specifically, the position of the cylindrical lens determines the width of the pumped region in the sagittal plane, while that in the tangential plane is held constant by the static spherical lens (L1). This means that the strength of the pump-induced thermal lens in the sagittal plane can be manipulated independently to realize the condition for a stigmatic thermal lens defined by Eq. (4). For the Brewster-cut geometry of Fig. 2, the

relevant properties of Nd:GdVO4 (n = ne = 2.198 [21], ≈=dT

dn

dT

dn e 4x10-6K-1 [3,22] and

≈αT 1.6x10-6K-1, since αo = 1.5x10-6K-1 and αe = 7.3x10-6K-1 in the ordinary (a-axis) and extraordinary (c-axis) directions, respectively [3]) predict that Eq. (4) is satisfied for a ratio AT/BT ≈ 0.19; i.e., the thermal lens in the sagittal plane should be about five times stronger than that in the tangential plane. We note that the same calculation for Nd:YAG (n = 1.82,

=dT

dn7.3x10-6K-1, and αT = 7.9x10-6K-1 [2]) gives AT/BT ≈ 0.26, which can also be achieved

with the laser head design of Fig. 2. Figure 3 illustrates results of an exact ray tracing for the pump radiation from one 40W

LD array to the Brewster-cut Nd:GdVO4 gain medium through a canonical arrangement of the spherical (L1) and cylindrical (L2) pump optics. In the tangential plane (Fig. 3(a)), the pump spot size is determined solely by the focal length of L1 and by the slow-axis divergence of the 46 1x80µm individual semiconductor lasers comprising each 40W diode bar, as the gain medium is positioned at the focal plane of the two spherical lenses. Since the specified full-width divergence is 10° at 1/e2 irradiance (FW1/e2I) [23], a quasi-Gaussian pump beam with a FW1/e2I of 4-5mm results in the gain medium, as indicated in Fig. 3(a). This tangential pump spot size is not significantly affected by either the spherical aberrations of the lens L1 or the inherent astigmatism of the Brewster-oriented gain medium. As a result, the parabolic contribution AT to the tangential (x) direction of the elliptical temperature distribution (Eq. (1)) is expected to be characterized by the tangential pump spot size, since the thermal conduction is solely in the orthogonal sagittal direction. This is not true in the sagittal plane, where spherical aberrations, predominantly from the cylindrical lens L2, severely perturb the spatial shape of the pump beam. In fact, as shown in Fig. 3(b), pump rays near the specified fast-axis FW1/e2I of 40° [23] (i.e., ±20° from the optical axis) are brought to a focus several



millimetres before the central rays. The result is that a pump irradiance profile closer to a ‘top hat’ (or super-Gaussian) is produced in the gain medium. This means that the sagittal thermal lens for the pumped region between the two heat removal planes is more parabolic than in the absence of spherical aberration in the pump optics. The full-width of the sagittal pump spot size can be varied between about 0.7 and 1.5mm, depending on the axial position of the cylindrical lens. The exact value of the parabolic contribution BT to the sagittal (y) direction of the elliptical temperature distribution (Eq. (1)) is a function of this pump spot size and the 3mm height of the gain medium. We note that the ratio AT/BT will be independent of the pump power, provided that the thermal conductivity κ is not a strong function of the local Nd:GdVO4 crystal temperature.

(a)

Nd:GdVO4

L2 L1 gain medium

(b)

Fig. 3. Pump radiation ray tracing through the pump optics (L1 and L2) from one LD array into the 3x5x10 mm Nd:GdVO4 gain medium; (a) for 5 of the 46 emitters across the 1cm width of the LD bar in the tangential plane and (b) for the central LD bar emitter in the sagittal plane. For each depicted emitter five rays are shown; the central ray, two rays at half the 1/e2 irradiance divergence angle, and the two extreme rays at the 1/e2 irradiance divergence angle (±5° in the tangential plane and ±20° fast-axis divergence in the sagittal plane).

4. Laser performance and characterization

The performance of the diode-pumped, Brewster-cut Nd:GdVO4 laser head was assessed using simple plane-plane resonators of varying length with the gain medium (a positive thermal lens) positioned at the symmetric center of the cavity. Figure 4 shows the laser output power at 1063nm as a function of diode drive current (and summed diode pump power) for three different resonators, all with a near optimum 8% output coupling. At 32cm, the shortest cavity length, the 20W output power level at a diode current of 41A corresponds to an overall optical-to-optical efficiency of 32%, or, equivalently, a laser-output to absorbed-pump-power efficiency of ~41%, once reflective losses for the incident pump radiation have been accounted for. The initial optical-to-optical slope efficiency common to all resonators is



37(±2)%, which compares reasonably well with conventional fiber-coupled LD end-pumped geometries [3,5,19] after considering the diminished spatial overlap between the pump radiation and the intracavity laser mode. The reduction in output power for longer cavity lengths at high diode pump powers is due to the proximity of the confocal stability point for the symmetric resonators, which causes an increasing spatial mismatch between the diode-pumped region and the intracavity laser mode in the gain medium – specifically, the lowest-order TEM00 laser mode size exceeding the ~1mm pumped region in the sagittal plane (Fig. 3(b)). The position of this boundary, which is indicated by the solid black line in Fig. 4 and distinguishes stability regions I and II of the cavity, is evaluated using data for the power of the thermal lens in the Nd:GdVO4 crystal extracted from the analysis of the spatial properties of the laser output presented below. When operated well within stability region I, the diode-pumped Nd:GdVO4 laser has exceptional power stability (<1% power drift over one hour) and beam pointing instabilities significantly less than 100µrad, all without any protection (e.g., a housing) from the laboratory environment. Operation in stability region II, and particularly near the confocal ‘edge,’ is less stable, primarily due to observed fluctuations in the laser’s transverse mode structure.

15 20 25 30 35 40 45

0

5

10

15

20

67cm

77cm

84cm

32cm

Drive current (A)

46cm

Out

put p

ower

(W

)

57cm

10 20 30 40 50 60 70LD pump power (W)

Fig. 4. Symmetric laser cavity output powers as a function of LD pump power (drive current) for six symmetric laser cavity lengths between 32 and 84cm. The solid black line indicates the confocal resonator condition that separates cavity stability regions I and II (shaded).

The laser power data displayed in Fig. 4 was obtained under the circumstance that the

diode-pumped Nd:GdVO4 gain medium presents a radially symmetric thermal lens to the resonators; i.e., the condition defined by Eq. (4) is met. In practice, this condition is determined by finding the position of the cylindrical lens (L2) for which the fundamental TEM00 mode present at low output powers smoothly transitions into the TEM10* or ‘donut’ mode as the diode drive current is increased. The ability of the laser cavity to support this



mode is a strong indicator of radial symmetry in a cavity that contains an astigmatic Brewster-cut gain medium with a strongly preferred linearly polarized emission. If the cylindrical lenses are offset from this optimum position towards the LD arrays, which results in a larger sagittal pump spot size in the gain medium, the initial TEM00 mode transitions into a horizontal TEM10 Hermite-Gaussian spatial mode. Conversely, an offset towards the Nd:GdVO4 crystal produces a transition into the vertical TEM01 mode, due to the stronger thermal lens in the sagittal plane. The accuracy with which the cylindrical lenses have to be positioned to satisfy the condition of Eq. (4) we determined to be about ±0.1mm.

To verify that the temperature distribution in the Nd:GdVO4 gain medium does indeed satisfy Eq. (4), we analyzed the propagation characteristics of the laser beam emitted from the 67cm cavity. Figure 5 presents the results of using the knife-edge technique [24] to determine the M2 beam quality and embedded TEM00 focal mode size w0 at the 8% output coupler in both the tangential (x) and sagittal (y) directions. The data for w0 as a function of diode drive current (Fig. 5(a)) clearly show that the fundamental mode is indeed circular to within the roughly ±5% error of the measurement technique. The trend towards a smaller spot size at the output coupler as the strength of the thermal lens increases is expected for a symmetric laser resonator. The smallest spot size of ~350µm at 38A corresponds well to the confocal cavity condition where w0 = 337µm is expected, and it represents the point beyond which the laser output becomes distinctly more multimode and unstable.

18 20 22 24 26 28 30 32 34 36 38 400.8

1.0

1.2

1.4

1.6

1.8

2.0

2.2

2.4

M 2

wo

(mm

)

Current (A)

0.30

0.35

0.40

0.45

0.50

0.55

0.60

0.65

SagittalTangential

Fig. 5. The measured tangential (x) and sagittal (y) spatial mode characteristics of the 67cm-long symmetric laser cavity as a function of LD drive current; the embedded TEM00 mode radius w0 at the 8% output coupler (black) and the M2 beam quality in the x and y directions (red).

The values of 2xM and 2

yM shown in Fig. 5(b) indicate that the laser produces a high-

quality TEM00-mode output ( 1.1222 <= yx MMM ) up to a drive current of ~25A, where the

output power is 6.5W. Between 25 and 29A, the value of 2xM increases to ~1.8 while the



beam quality in the sagittal plane remains very high. In this region, the increase in 2xM is

due to some additional mode structure in the tangential plane outside the strong central circular TEM00 mode. This behavior is expected since (i) the ~1x5mm2 pumped region in the gain medium (Fig. 3) provides gain for low-power higher-order horizontal mode oscillation outside the ~2mm TEM00 mode width; and (ii) there are no mode-control apertures in the cavity. At higher drive currents, aberrations in the sagittal pump-induced thermal lens [25] and the smaller TEM00 mode size in the gain medium (<500µm) allow higher-order vertical

mode oscillation, causing the observed increase in 2yM . Nonetheless, throughout the first

stability region for this 67cm cavity length (i.e., up to the confocal edge at ~38A), the diode-pumped Nd:GdVO4 laser produces a low-divergence cw output with an overall M2 beam quality factor of less than 2. As the flat-flat cavity length is increased, the laser generates a higher spatial beam quality, but at a reduced output power (Fig. 4), owing to the larger TEM00 mode size that needs to be supported at longer thermal focal lengths of the gain medium (i.e., lower pump powers). On the other hand, as expected, the higher-power shorter resonators support higher-order spatial mode beams, although the measured M2 is only ~5 even for the 20W output power obtained for the 32cm cavity length.

16 18 20 22 24 26 28 30 32 34 36 38 40

SagittalTangential

1/f (

Dio

pter

s)

Current (A)

0.0

0.5

1.0

1.5

2.0

2.5

3.0

3.5

Fig. 6. The power of the pump-induced thermal lens in the Brewster-cut Nd:GdVO4 gain medium evaluated as a function of LD drive current for both the tangential (x) and sagittal (y) directions.

The embedded TEM00 spot sizes w0 measured at the output coupler (Fig. 5(a)) allow the

power of the thermal lens in the diode-pumped Nd:GdVO4 gain medium to be extracted as a function of the diode drive current (or pump power). The results of this calculation are shown in Fig. 6. As expected, the thermal focal power (1/fT) is a linear function of the pump power (i.e., LD drive current for the presented range), and zero focal power is consistent with the ~14A LD threshold current. This set of data is used to define the boundary (confocal condition) between the first and second stability regions for the symmetric resonators in Fig.



4; that is, for each cavity length L, the drive current corresponding to the condition fT = L/2 is found to allow the boundary (solid black line) to be plotted.

It is interesting to note that thermal focal powers for diode-pumped Nd:GdVO4 are expected to be significantly less than those for either Nd:YAG or Nd:YVO4 under similar αl ≈ 2 absorption conditions. Indeed, a preliminary experiment with a 3x5x10mm 0.9at.%-doped Nd:YAG crystal indicated the presence of a thermal lens with about twice the focusing power, despite the similar thermal conductivity of YAG and GdVO4 (κ = 11-12Wm-1K-1)

[2,3,22]. This is in agreement with both an approximately 50% larger value of dT

dn and a

substantially (~5x) greater thermal expansion coefficient αT [2]. For Nd:YVO4, the thermal lens is expected to be even stronger, mainly due to the significantly lower thermal conductivity of ~5Wm-1K-1 [3].

5. Summary

We have developed an efficient diode-pumped head for Brewster-cut solid-state laser crystals in which the aspect ratio of the elliptical pumped region can be manipulated to shape a radially symmetric (or spherical) thermal lens for a laser resonator, despite the inherent astigmatism of the Brewster crystal geometry. The near-longitudinal double-end-pumped design also removes the requirement for dichroic and AR dielectric coatings while exploiting the intrinsic elliptical output from 1cm-wide pump diode arrays to provide good pump-laser spatial mode matching in the gain medium. The effectiveness of this diode pumping scheme is demonstrated using Nd:GdVO4 – a laser crystal for which it appears to be well suited. The Nd:GdVO4 laser delivers over 20W of output power at 1063nm when pumped with more than 49W of 808nm radiation from the two utilized 40W-rated diode arrays. The laser has an initial optical-to-optical slope efficiency of 37(±2)%, which compares tolerably well with many collinear end-pumped geometries [3,5,19].

Analysis of the spatial mode characteristics of the output from a 67cm-long symmetric laser resonator (with the gain medium at the center) verified that the pump-induced thermal lens in the Brewster-cut Nd:GdVO4 crystal was indeed spherical to the flat-flat cavity. Moreover, the theoretical pumping arrangement required to meet this condition (defined by Eq. (4)) is consistent with the results of an exact ray tracing for the pump radiation emitted by the LDs. The beam analysis also showed that laser resonators incorporating this diode-pumped head design will be capable of generating outputs with a high spatial beam quality – the 67cm-long Nd:GdVO4 cavity produced stable laser output with M2 < 2 throughout stability region I without the use of an intracavity aperture.

The laser head design is also sufficiently flexible to incorporate other Brewster-cut solid-state gain media for which the realization of a stigmatic spherical thermal lens requires a different aspect ratio for the elliptical pumped region (Eq. (4)). We note that for Nd:YAG, little or no stress-induced depolarization [2] is expected because the heat conduction is orthogonal to the Brewster plane and hence to the laser polarization. Further, we note that the head design would, in principle, also allow the use of fiber-coupled LD pump sources, although probably at the expense of increased initial construction and operating costs. In such a case, only an appropriate set of pump optics would be required to shape the initially circular fiber output into the required elliptical aspect ratio in the gain medium.

Acknowledgments

The authors gratefully acknowledge the expert assistance of Kevin Lynch and the Machine Shop of the Physics Department at the University of Illinois at Chicago.



thermal lens shaping in brewster gain media: a high-power, diode-pumped nd:gdvo4 laser

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