1. Field of the Invention
This invention relates generally to fiber lasers and amplifiers. More specifically, it pertains to fiber optical isolators, which are used at high operating power in applications such as high power fiber lasers and amplifiers.
2. Discussion of the Related Art
This section is intended to introduce the reader to various aspects of art that may be related to various aspects of the present invention, which are described and claimed below. This discussion is believed to be helpful in providing the reader with background information to facilitate a better understanding of the various aspects of the present invention. Accordingly, it should be understood that these statements are to be read in this light, and not as admissions of prior art.
Optical isolators typically transmit light in the forward direction with relatively low insertion loss (typically <10% loss), however, backward propagating light may be attenuated by a factor of 1000 to 1,000,000, depending on the design of the isolator. For this reason, optical isolators are often used in fiber lasers and amplifiers to eliminate back reflections, because backward propagating light can damage optical components in the fiber laser and/or amplifier. Furthermore, backward propagating light passing through a gain medium is amplified such that it is more likely to damage components and may cause the laser or amplifier to become unstable.
To reduce the effect of backward light propagation, optical isolators can be placed between amplifier stages or at the output of an amplifier to block back reflections. Conventional optical isolators, however, are limited in their power tolerance. The highest power optical isolators currently available publicly are rated for power between 1 and 2 watts (“W”). This level of power tolerance simply may not be adequate for fiber amplifiers, which can have output powers as high as tens of watts. Isolators that could be used at higher power would be advantageous for higher power fiber amplifiers and lasers because it would enable the isolator to be placed at the output of the amplifier where it could provide greater protection against back reflections.
Certain aspects commensurate in scope with the disclosed embodiments are set forth below. It should be understood that these aspects are presented merely to provide the reader with a brief summary of certain aspects the invention might take and that these aspects are not intended to limit the scope of the invention. Indeed, the invention may encompass a variety of aspects that may not be set forth below.
There is provided a system and method for fabrication of an optical isolator. More specifically, there is provided a fiber optical isolator comprising a first isolator stage including a Faraday rotator configured to adjust the polarity of a light beam, and a heat sink coupled to the Faraday rotator and configured to dissipate heat generated in the Faraday rotator by a light beam.
Advantages of the invention may become apparent upon reading the following detailed description and upon reference to the drawings in which:
One or more specific embodiments of the present invention will be described below. In an effort to provide a concise description of these embodiments, not all features of an actual implementation are described in the specification. It should be appreciated that in the development of any such actual implementation, as in any engineering or design project, numerous implementation-specific decisions should be made to achieve the developers' specific goals, such as compliance with system-related and business-related constraints, which may vary from one implementation to another. Moreover, it should be appreciated that such a development effort might be complex and time consuming, but would nevertheless be a routine undertaking of design, fabrication, and manufacture for those of ordinary skill having the benefit of this disclosure.
The embodiments described below may be directed towards a method for improving the high power reliability of an optical isolator. More specifically, one or more of the embodiments described herein may be directed towards an optical isolator employing a Faraday rotator that is coupled to a heat sink to dissipate heat generated when light passes through the garnet in the Faraday rotator. Advantageously, heat sinking the garnet in the Faraday rotator reduces the likelihood of an index gradient forming by reducing the temperature rise in the garnet and, thus, causes isolation to decrease to a lesser extent as a function of power. In addition, another embodiment described herein is directed towards a method for aligning an optical isolator at a use power such that the alignment includes the effective lenses caused by the thermal lens effect. This process can reduce or minimize the insertion loss of the optical isolator at high power.
More specifically, one embodiment described herein provides a method for improving the high power reliability of fiber pigtailed optical isolators. One of the primary failure modes limiting the high power reliability of amplifiers is runaway thermal failure at the fiber ferrule due to absorption of light into the polymer materials in the ferrule and in the pigtail outside the ferrule. These failures are more likely to occur as more light is lost, because light is scattered or incident outside the core of the output fiber instead of coupled into it. Two failure mechanisms leading to increased light dissipated in the ferrule are scattering caused by optical damage at the fiber ferrule input face and thermal lensing in the garnet of the Faraday rotator. Thermal lensing occurs due to the Gaussian profile of the high power light incident on the garnet of the Faraday rotator. Due to the temperature dependent index of refraction of the garnet, an index gradient forms in the garnet. This gradient depends on both ambient temperature and on optical power of the laser. It leads to the formation of an effective optical lens, which results in the degradation of alignment (i.e., there is more light that is lost in the ferrule.) One or more of the embodiments described below relates to the mitigation of the thermal lens effect and, therefore, to the improvement of the high power reliability of fiber optical isolators.
Turning now to
The package 16 may include the isolator stages 18a and 18b. The isolator stages 18a and 18b may be configured to allow coherent light 20, such as light from a high power coherent source (e.g., a laser or amplifier), to pass through them in one direction (e.g., the direction from the input port 12 to the output port 14) while preventing or greatly reducing transmission of the light 20 in the opposite direction. In one embodiment, the coherent light 20 may be a laser with a wavelength of 1550 nanometers. It will be appreciated, however, that the dual isolator stages 18a and 18b, although typical, are merely exemplary. As such, in alternate embodiments, the optical isolator 10 may include a single isolator stage 18a or a plurality of suitable isolator stages 18a and 18b.
As illustrated in
As described above, the optical isolator 10 may be configured to operate at higher power levels than conventional optical isolators. More particularly, in one embodiment, the isolator stages 18a and 18b may be configured such that the temperature rise in the garnet caused by high power is reduced. For example,
When the light 20 enters the isolator stage 18, it passes through the polarizer 30, which is oriented parallel to the state of the light 20. In one embodiment, the polarizer 30 is a birefringent wedge polarizer configured to separate the random polarization state of the light 20 into two orthogonal polarization beams due to double refraction of a birefringent wedge. In alternate embodiments, other types of polarizers 30 may be employed in the optical isolator 10.
The Faraday rotator 36, in combination with the magnet 32, then rotates the polarization of the light 20 by forty-five degrees. In one embodiment, the Faraday rotator 36 may include a Bismuth doped yttrium-iron-garnet (“Bi-YIG”) material. It will be appreciated that in other embodiments the Faraday rotator could be based on other materials and that the basic principles governing high power reliability will apply to those materials.
After passing through the Faraday rotator 36, the light 20 passes into the analyzer 38. In one embodiment, the analyzer 38 includes a second birefringent wedge, which has its optical axis oriented at an angle of forty-five degrees relative to the optical axis of the polarizer 30. This orientation permits the light beams to be recombined angularly in the forward direction. Any light reflected off the polarizer 38 will end up passing back through the Faraday rotator 36, which will rotate the polarization another forty-five degrees. This additional rotation will increase the polarity of reflected beams to a total rotation of ninety degrees. When the ninety degree rotated beams reach the birefringent wedge type polarizer 30, they will be angularly separated into two separated beams and will not be coupled back to the input fiber.
Returning to the Faraday rotator 36, when the light 20 hits the Faraday rotator 36, the light 20 will transmit or transfer some amount of energy from itself to the materials of the Faraday rotator 36. More specifically, when the light 20 strikes the Faraday rotator 36, it will excite the atomic structure of the Faraday rotator 36 and cause the temperature of the Faraday rotator 36 to rise. This temperature increase in the Faraday rotator is more pronounced at higher power levels. For example, the light 20 with 10 watts of light power and a wavelength of 1550 nanometers could induce a temperature rise in the Faraday rotator 36 by as much as 60° C.
Increasing the temperature of the Faraday rotator, however, affects the properties of the Faraday rotator 36. More specifically, as the temperature of the Faraday rotator 36 increases, a thermal lensing effect is generated in the Faraday rotator 36. This thermal lens effect (also referred to more simply as a “thermal lens” or “thermal lensing”) causes increased insertion loss as the extra lens created displaces the focal point from the fiber core such that the coupling of the light into the core of the fiber pigtail is no longer optimized.
However to reduce the amount of thermal lensing, the isolator stage 18 may advantageously include the heat sink 34 to dissipate the heat generated in the Faraday rotator 36 by light from light 20. By “pulling” heat out of the Faraday rotator 36, the heat sink 34 reduces the temperature of the Faraday rotator 36 and, thus, reduces the thermal lensing effect. This may reduce the percentage of light dissipated in the fiber ferrule and, therefore, reduce the likelihood of failure of the optical isolator 10 at higher power levels. In one embodiment, the heat sink 34 may include gadolinium gallium garnet (also referred to as “GGG” or gadolinium gallium oxide). More specifically, in one embodiment, the heat sink 34 and the Faraday rotator 36 may be created by fabricating Bi-YIG material onto a GGG substrate. In alternate embodiments, however, any suitable material may be used as the heat sink 34.
In one embodiment, the effects of thermal lensing may be mitigated by aligning the optical isolator 10 for a particular target light power. More specifically, whereas conventional optical isolators are aligned to minimize insertion loss with lasers of one watt or less, the optical isolator 10 may be aligned to minimize insertion loss at higher power levels (e.g. two, four, six, eight, ten, or more watts). Accordingly,
As illustrated in
After the optical isolator 10 has been connected to the alignment laser 52 and the laser power detector 54, the alignment laser 52 may be activated or “turned on,” as indicated in block 66. When the alignment laser 52 is activated, the light 20 will proceed through the optical isolator 10, and the laser power detector 54 may measure the light power level exiting the optical isolator 10. By comparing the light power level of the light exiting the optical isolator 10 with the light power level of the alignment laser 52, the insertion loss from the optical isolator 10 may be determined, as indicated in block 68. For example, if the alignment laser 52 has a light power level of 10 W and the light power level of the light 20 exiting the optical isolator 10 is approximately 27% less than the power level of the alignment laser 52, the insertion loss from the optical isolator 10 may be approximately 1 dB. Similarly, if the power loss is approximately 5%, the insertion loss from the optical isolator will be approximately 0.2 dB, and so forth.
The technique 60 may also involve deciding whether the insertion loss from the optical isolator 10 is acceptable, as indicated in block 70. If the insertion loss is acceptable, the technique 60 may end. However, if the insertion loss is not acceptable, the technique 60 may continue. The insertion loss may not be acceptable for a variety of reasons. For example, the insertion loss may not be acceptable because the insertion loss is above a minimum insertion loss level determined theoretically or while aligning previous optical isolators 10. The determined insertion loss may also not be acceptable if the minimum insertion loss level is not known. For example, while aligning the optical isolator 10, a first execution of blocks 62-68 may yield an insertion loss of 0.4 dB. However, by adjusting the properties of the optical isolator 10, it may be possible to lower the insertion loss level, as described below. In such a case, the insertion loss level may not be acceptable until the properties of the optical isolator 10 have been sufficiently adjusted to determine an approximate range for the insertion loss at a particular laser light power level.
As described above, if the insertion loss level is not acceptable, the technique 60 may involve adjusting the properties of the optical isolator 10, as indicated in block 72. In one embodiment, adjusting the properties of the optical isolator 10 consists of optimizing the positions of the input and output fibers with respect to the collimating lenses such that the effects of the virtual lenses created by the thermal lens effect are compensated. After the properties of the optical isolator 10 have been adjusted, technique 60 will repeat blocks 62-72 until the optical isolator 10 is aligned to produce an insertion loss at an acceptable level. In one embodiment, the technique 60 is repeated until the insertion loss of the optical isolator 10 is approximately minimized for the laser light power of the alignment laser 52. For example, the technique 60 may be repeated until the insertion loss of the optical isolator 10 is less than or equal to 0.4 dB with a ten watt light power laser.
As stated above, the isolation of a conventional optical isolator will decrease as the light power increases due to thermal lenses. As such, adjusting the properties of the optical isolator may include adjusting the garnet thickness to increase and/or optimize the isolation at higher power levels. More specifically, the garnet thickness can be selected such that the Faraday rotation of the Faraday rotator 36 is greater than 45 degrees at lower power and approximately 45 degrees at a desired higher light power (e.g., 10 watts).
While the invention may be susceptible to various modifications and alternative forms, specific embodiments have been shown by way of example in the drawings and have been described in detail herein. However, it should be understood that the invention is not intended to be limited to the particular forms disclosed. Rather, the invention is to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the invention as defined by the following appended claims.
This invention was made with Government support. The Government has certain rights in this invention.
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