Informatics Educational Institutions & Programs

Round-trip gain refers to the laser physics, and laser cavities (or laser resonators). It is gain, integrated along a ray, which makes a round-trip in the cavity.

At the continuous-wave operation, the round-trip gain exactly compensates both the output coupling of the cavity and its background loss.^{[clarification needed]}

Round-trip gain in geometric optics

Generally, the Round-trip gain may depend on the frequency, on the position and tilt of the ray, and even on the polarization of light. Usually, we may assume that at some moment of time, at reasonable frequency of operation, the gain $<img src="https://wikimedia.org/api/rest_v1/media/math/render/svg/d51c69be11044075dfa6d5a527b72bc94a6543ca" class="mwe-math-fallback-image-inline mw-invert" aria-hidden="true" style="vertical-align: -0.838ex; width:10.438ex; height:2.843ex;" alt="{\displaystyle ~G(x,y,z)~}">$ is function of the Cartesian coordinates $<img src="https://wikimedia.org/api/rest_v1/media/math/render/svg/f5d01d47148f6e2063a236987f91b991e885ffb6" class="mwe-math-fallback-image-inline mw-invert" aria-hidden="true" style="vertical-align: -0.338ex; width:2.491ex; height:1.676ex;" alt="{\displaystyle ~x~}">$ , $<img src="https://wikimedia.org/api/rest_v1/media/math/render/svg/7ff7fedfae906c9584c67b50c9b1172fe63f3952" class="mwe-math-fallback-image-inline mw-invert" aria-hidden="true" style="vertical-align: -0.671ex; width:2.317ex; height:2.009ex;" alt="{\displaystyle ~y~}">$ , and $<img src="https://wikimedia.org/api/rest_v1/media/math/render/svg/70e682393943fc5050b362b38b28ece8c41cc360" class="mwe-math-fallback-image-inline mw-invert" aria-hidden="true" style="vertical-align: -0.338ex; width:2.249ex; height:1.676ex;" alt="{\displaystyle ~z~}">$ . Then, assuming that the geometrical optics is applicable the round-trip gain $<img src="https://wikimedia.org/api/rest_v1/media/math/render/svg/7baacef0b0cf33ec0d65ddda283ea254e7e26cbb" class="mwe-math-fallback-image-inline mw-invert" aria-hidden="true" style="vertical-align: -0.671ex; width:2.277ex; height:2.009ex;" alt="{\displaystyle ~g~}">$ can be expressed as follows:

<img src="https://wikimedia.org/api/rest_v1/media/math/render/svg/df48fe1787d6ad5e7cff7567c3ef4976222c698e" class="mwe-math-fallback-image-inline mw-invert" aria-hidden="true" style="vertical-align: -2.338ex; width:29.454ex; height:5.676ex;" alt="{\displaystyle ~g=\int G(x(a),y(a),z(a))~{\rm {d}}a~}">

,

where $<img src="https://wikimedia.org/api/rest_v1/media/math/render/svg/bd1e0bd119dc10f8345006e6b53a342f1060bc46" class="mwe-math-fallback-image-inline mw-invert" aria-hidden="true" style="vertical-align: -0.338ex; width:2.391ex; height:1.676ex;" alt="{\displaystyle ~a~}">$ is path along the ray, parametrized with functions $<img src="https://wikimedia.org/api/rest_v1/media/math/render/svg/3778152d430a85915b2e3862b615ffa7e5e8121b" class="mwe-math-fallback-image-inline mw-invert" aria-hidden="true" style="vertical-align: -0.838ex; width:5.53ex; height:2.843ex;" alt="{\displaystyle ~x(a)~}">$ , $<img src="https://wikimedia.org/api/rest_v1/media/math/render/svg/86d67950e3878ba9aadf321c274b942c78677922" class="mwe-math-fallback-image-inline mw-invert" aria-hidden="true" style="vertical-align: -0.838ex; width:5.356ex; height:2.843ex;" alt="{\displaystyle ~y(a)~}">$ , $<img src="https://wikimedia.org/api/rest_v1/media/math/render/svg/3035f21d4ad19cf278d7eae635ff09419c88464a" class="mwe-math-fallback-image-inline mw-invert" aria-hidden="true" style="vertical-align: -0.838ex; width:5.289ex; height:2.843ex;" alt="{\displaystyle ~z(a)~}">$ ; the integration is performed along the whole ray, which is supposed to form the closed loop.

In simple models, the flat-top distribution of pump and gain $<img src="https://wikimedia.org/api/rest_v1/media/math/render/svg/bbd404b86c834dff5810a792f61b54370da93ff0" class="mwe-math-fallback-image-inline mw-invert" aria-hidden="true" style="vertical-align: -0.338ex; width:2.988ex; height:2.176ex;" alt="{\displaystyle ~G~}">$ is assumed to be constant. In the case of simplest cavity, the round-trip gain $<img src="https://wikimedia.org/api/rest_v1/media/math/render/svg/a67cec74a1c3e9fe19db873fcdb8e831a487f4d4" class="mwe-math-fallback-image-inline mw-invert" aria-hidden="true" style="vertical-align: -0.671ex; width:9.704ex; height:2.509ex;" alt="{\displaystyle ~g=2Gh~}">$ , where $<img src="https://wikimedia.org/api/rest_v1/media/math/render/svg/83d610d404dcf2aed9029c2fb232747a87879165" class="mwe-math-fallback-image-inline mw-invert" aria-hidden="true" style="vertical-align: -0.338ex; width:2.5ex; height:2.176ex;" alt="{\displaystyle ~h~}">$ is length of the cavity; the laser light is supposed to go forward and back, this leads to the coefficient 2 in the estimate.

In the steady-state continuous wave operation of a laser, the round-trip gain is determined by the reflectivity of the mirrors (in the case of stable cavity) and the magnification coefficient in the case of unstable resonator (unstable cavity).

Coupling parameter

The coupling parameter $<img src="https://wikimedia.org/api/rest_v1/media/math/render/svg/6c656edf3a0b2bca62a5321900d9ebbb3e0a3ce7" class="mwe-math-fallback-image-inline mw-invert" aria-hidden="true" style="vertical-align: -0.338ex; width:2.252ex; height:2.176ex;" alt="{\displaystyle ~\theta ~}">$ of a laser resonator determines, what part of the energy of the laser field in the cavity goes out at each round-trip. This output can be determined by the transmitivity of the output coupler, or the magnification coefficient in the case of unstable cavity.^[1]

Round-trip loss (background loss)

The background loss, of the round-trip loss $<img src="https://wikimedia.org/api/rest_v1/media/math/render/svg/40d015fc2ada48c756c32b203284b03e5a2aff9a" class="mwe-math-fallback-image-inline mw-invert" aria-hidden="true" style="vertical-align: -0.671ex; width:2.493ex; height:2.509ex;" alt="{\displaystyle ~\beta ~}">$ determines, what part of the energy of the laser field becomes unusable at each round-trip; it can be absorbed or scattered.

At the self-pulsation, the gain is late to respond the variation of number of photons in the cavity. Within the simple model, the round-trip loss and the output coupling determine the damping parameters of the equivalent oscillator Toda.^[2]^[3]

At the steady-state operation, the round-trip gain $<img src="https://wikimedia.org/api/rest_v1/media/math/render/svg/7baacef0b0cf33ec0d65ddda283ea254e7e26cbb" class="mwe-math-fallback-image-inline mw-invert" aria-hidden="true" style="vertical-align: -0.671ex; width:2.277ex; height:2.009ex;" alt="{\displaystyle ~g~}">$ exactly compensate both, the output coupling and losses:

<img src="https://wikimedia.org/api/rest_v1/media/math/render/svg/52da55b4ba7e38be30b8f14e88cd122261b3bc2f" class="mwe-math-fallback-image-inline mw-invert" aria-hidden="true" style="vertical-align: -0.838ex; width:23.943ex; height:2.843ex;" alt="{\displaystyle ~\exp(g)~(1-\beta -\theta )=1~}">

.

Assuming, that the gain is small ( $<img src="https://wikimedia.org/api/rest_v1/media/math/render/svg/7b74334283243f6db7493d69761f92678bc3b8dd" class="mwe-math-fallback-image-inline mw-invert" aria-hidden="true" style="vertical-align: -0.671ex; width:7.634ex; height:2.509ex;" alt="{\displaystyle ~g~\ll 1~}">$ ), this relation can be written as follows:

<img src="https://wikimedia.org/api/rest_v1/media/math/render/svg/45da91c62a04723906e54107dabf7fcefac5f306" class="mwe-math-fallback-image-inline mw-invert" aria-hidden="true" style="vertical-align: -0.671ex; width:10.639ex; height:2.509ex;" alt="{\displaystyle ~g=\beta +\theta ~}">

Such as relation is used in analytic estimates of the performance of lasers.^[4] In particular, the round-trip loss $<img src="https://wikimedia.org/api/rest_v1/media/math/render/svg/40d015fc2ada48c756c32b203284b03e5a2aff9a" class="mwe-math-fallback-image-inline mw-invert" aria-hidden="true" style="vertical-align: -0.671ex; width:2.493ex; height:2.509ex;" alt="{\displaystyle ~\beta ~}">$ may be one of important parameters which limit the output power of a disk laser; at the power scaling, the gain $<img src="https://wikimedia.org/api/rest_v1/media/math/render/svg/bbd404b86c834dff5810a792f61b54370da93ff0" class="mwe-math-fallback-image-inline mw-invert" aria-hidden="true" style="vertical-align: -0.338ex; width:2.988ex; height:2.176ex;" alt="{\displaystyle ~G~}">$ should be decreased (in order to avoid the exponential growth of the amplified spontaneous emission), and the round-trip gain $<img src="https://wikimedia.org/api/rest_v1/media/math/render/svg/7baacef0b0cf33ec0d65ddda283ea254e7e26cbb" class="mwe-math-fallback-image-inline mw-invert" aria-hidden="true" style="vertical-align: -0.671ex; width:2.277ex; height:2.009ex;" alt="{\displaystyle ~g~}">$ should remain larger than the background loss $<img src="https://wikimedia.org/api/rest_v1/media/math/render/svg/40d015fc2ada48c756c32b203284b03e5a2aff9a" class="mwe-math-fallback-image-inline mw-invert" aria-hidden="true" style="vertical-align: -0.671ex; width:2.493ex; height:2.509ex;" alt="{\displaystyle ~\beta ~}">$ ; this requires to increase of the thickness of the slab of the gain medium; at certain thickness, the overheating prevents the efficient operation.^[5]

For the analysis of processes in active medium, the sum $<img src="https://wikimedia.org/api/rest_v1/media/math/render/svg/8b981c17265e1d9b77eaec8c66101ede6379fbe0" class="mwe-math-fallback-image-inline mw-invert" aria-hidden="true" style="vertical-align: -0.671ex; width:6.424ex; height:2.509ex;" alt="{\displaystyle ~\beta +\theta ~}">$ can be also called "loss".^[1] This notation leads to confusions as soon as one is interested, which part of the energy is absorbed and scattered, and which part of such a "loss" is actually wanted and useful output of the laser.

References

^ ^a ^b A.E.Siegman (1986). Lasers. University Science Books. ISBN 978-0-935702-11-8. Archived from the original on 2016-12-06. Retrieved 2007-05-24.
^ G.L.Oppo; A.Politi (1985). "Toda potential in laser equations". Zeitschrift für Physik B. 59 (1): 111–115. Bibcode:1985ZPhyB..59..111O. doi:10.1007/BF01325388. ISSN 0722-3277. S2CID 119657810.
^ D. Kouznetsov; J.-F. Bisson; J. Li; K. Ueda (2007). "Self-pulsing laser as oscillator Toda: Approximation through elementary functions". Journal of Physics A. 40 (9): 1–18. Bibcode:2007JPhA...40.2107K. CiteSeerX 10.1.1.535.5379. doi:10.1088/1751-8113/40/9/016. S2CID 53330023.
^ D. Kouznetsov; J.-F. Bisson; K. Takaichi; K. Ueda (2005). "Single-mode solid-state laser with short wide unstable cavity". Journal of the Optical Society of America B. 22 (8): 1605–1619. Bibcode:2005JOSAB..22.1605K. doi:10.1364/JOSAB.22.001605.
^ D. Kouznetsov; J.-F. Bisson; J. Dong; K. Ueda (2006). "Surface loss limit of the power scaling of a thin-disk laser". Journal of the Optical Society of America B. 23 (6): 1074–1082. Bibcode:2006JOSAB..23.1074K. doi:10.1364/JOSAB.23.001074. Retrieved 2007-01-26.; [1]^{[permanent dead link]}

[siegman-1] A.E.Siegman (1986). Lasers. University Science Books. ISBN 978-0-935702-11-8. Archived from the original on 2016-12-06. Retrieved 2007-05-24.

[oppo-2] G.L.Oppo; A.Politi (1985). "Toda potential in laser equations". Zeitschrift für Physik B. 59 (1): 111–115. Bibcode:1985ZPhyB..59..111O. doi:10.1007/BF01325388. ISSN 0722-3277. S2CID 119657810.

[kouz-3] D. Kouznetsov; J.-F. Bisson; J. Li; K. Ueda (2007). "Self-pulsing laser as oscillator Toda: Approximation through elementary functions". Journal of Physics A. 40 (9): 1–18. Bibcode:2007JPhA...40.2107K. CiteSeerX 10.1.1.535.5379. doi:10.1088/1751-8113/40/9/016. S2CID 53330023.

[uns-4] D. Kouznetsov; J.-F. Bisson; K. Takaichi; K. Ueda (2005). "Single-mode solid-state laser with short wide unstable cavity". Journal of the Optical Society of America B. 22 (8): 1605–1619. Bibcode:2005JOSAB..22.1605K. doi:10.1364/JOSAB.22.001605.

[kouz06-5] D. Kouznetsov; J.-F. Bisson; J. Dong; K. Ueda (2006). "Surface loss limit of the power scaling of a thin-disk laser". Journal of the Optical Society of America B. 23 (6): 1074–1082. Bibcode:2006JOSAB..23.1074K. doi:10.1364/JOSAB.23.001074. Retrieved 2007-01-26.; [1]^{[permanent dead link]}

[1]

[2]

[3]

[4]

[5]