The present disclosure relates in general to high power continuous wave and pulsed lasers.
The benefits, features, and advantages of the present disclosure will become better understood with regard to the following description, and accompanying drawings.
High power continuous and pulsed lasers are required for many applications, such as but not limited to material processing, welding, and cutting. There are a number of problems with existing laser systems that are being scaled to power levels of 100's of kilowatts and even over 1 megawatt.
One problem with these existing laser systems is their excessive size, due to inefficient employment of volume which limits mobility. The maximum optical materials power density for many materials is in excess of 1 GW/cm2. Even if the average power 1 density is set at 10 MW/cm2, the total active lasing media cross section required for a 1 MW laser would be only 0.1 cm2.
Another problem with existing laser systems is that they require collecting and applying pump energy from a large number of pump sources. This calls for a pump combiner that efficiently produces, collects, transports and applies pump energy in a compact geometry.
Yet another problem is excessive parts count and complexity, which limits reliability and increases initial cost and maintenance costs. What is needed is an integrated configuration that can be mass produced at reasonable cost.
Still another problem is that multiple lasers must be operated in parallel to obtain total output power, which requires phase synchronization among outputs. This is difficult when lasers are spatially distant, since such a system requires phase coherence between many parallel sources.
Still another problem is extreme heat removal requirements due to overall efficiencies of about 25% and conventional thermal management approaches, which need low thermal resistance and sufficient heat transfer surface area
Still another problem is non-linear losses in the gain medium due to operation at high optical power densities, which reduces efficiency and leads to large mode area fibers. Such systems need an operating configuration that operates at low power density and single mode structure.
Still another problem is poor beam quality due to multi-mode configurations, which limits coherent adding and long distance propagation. A single transverse mode is desired to obtain a diffraction limited beam. 1. Slab Lasers—Slab lasers in which a thick slab of gain media is pumped with optical energy, either flash lamps or injection laser diode arrays
Several different technologies have been employed in the development of high power lasers. One such technology is slab lasers. Slab lasers can be operated in an oscillator mode or master oscillator power amplifier mode. The slab laser is limited by the removal of thermal energy from the slab. Slab lasers are efficient and rugged, but the crystal or ceramic slabs used as gain media have low thermal conductivity. The conversion efficiency of a slab laser is on the order of 50%, which means that the waste thermal energy that must be removed is approximately equal to the laser energy. The waste energy resident in the slab results in expansion, which affects the laser cavity such that the laser can be operated in an adiabatic mode. In addition, the output beam of a slab laser is naturally in a multi-transverse and longitudinal mode due to the dimensions of the slab and the optical cavity. Thus special optics are required to generate single transverse mode outputs necessary for good beam quality and long distance propagation. The optics employed to provide single transverse mode outputs do not efficiently use the volume of the gain media and thus reduce the overall efficiency. The average optical power density in a slab laser is low because the gain volume is not used efficiently. For example, the optical power damage threshold is on the order of 1 GW/cm2. Thus only 0.1 cm2 of gain material is required, but much larger volumes and thus much lower power densities are employed in state of the art slab lasers. It is important to note that non-linear effects like self-phase modulation, stimulated Raman scattering (SRS), and stimulated Brillouin scattering (SBS) also limit the power density that can be employed in a slab laser. In summary, slab lasers are hardware intensive, requiring many optical components and thermal components to operate the system which is further limited by thermal energy removal and obtaining the proper output mode structure for application.
Another laser technology is fiber lasers. A fiber laser is configured such that the core of the optical fiber is the gain medium and the cladding is used to apply the pump energy to the core all along the fiber. In a fiber laser, all the pump energy must be injected into the cladding at the input to the fiber and at the output of the fiber. The optical pump energy for a fiber laser is collected using a large number of optical elements from injection laser diodes, injected into transport fibers, and then coupled into the ends of the gain fiber. This complex system has progressed to provide very high power from a single fiber because of the difficulty of collecting and coupling the pump energy into the gain fiber. The requirement that all of the pump energy be injected at the ends of the gain fiber requires that the coupling system, which must concentrate the pump energy into a small area, is extremely difficult to design and build. Furthermore, the coupling system must be extremely efficient and handle extremely high powers.
Disk lasers are embodied in thin semiconductor or ceramic gain material disks that are pumped with optical energy. The disks are mounted on good heat sinks to extract the thermal energy from one side and illuminated with pump energy on the output side. Optical pump energy is focused on the disk to determine the size and transverse mode parameters of the output beam. Multiple disk assemblies are optically connected in series to provide an amplifier. The removal of thermal energy from the disk is the factor limiting the output power of each disk.
Electric or optically pumped gas or alkali vapor lasers employ either electrical discharge or optical energy as a pump source. The energy density produced by the pumping method is determined by the absorption characteristics of the gas and the gas density. Conventional gas lasers have relatively low energy density and thus are relatively large. The size is further increased by the size, volume, and rate of the required gas/vapor flow which requires large hardware and cooling systems. In some cases, the gas/vapor are very toxic to man and materials.
Chemical lasers employ exothermic reactions to provide the pump energy for the lasing medium. The advantage of chemical lasers is that the minimum electrical and optical pump energy is required. In the past, this type of laser was favored due to the electrical and optical power available. This type of laser employs materials that are toxic and must be cooled and recycled in order to avoid deleterious environmental and human hazards.
In reviewing each of these types of laser systems, shortcomings of each system become apparent. A major limitation of high power slab lasers is the removal of thermal energy from the optically pumped slabs of doped ceramic lasing mediums because of the very long thermal time constant. This limitation is addressed by employing very thin slabs and employing multi-pass beam paths to extract the gain energy or employing multiple slabs that are mechanically multiplexed to allow the slabs to cool. A second limitation of slab lasers is the formation of a high quality beam which requires a large number of optical components. Thus slab lasers require excessive hardware, which results in large initial cost as well as costly maintenance and alignment expense.
A major problem with very high power fiber lasers is related to cooling all the laser components, including the pump laser diodes, the collection optics, the transport optics, the coupling optics, and the gain fiber itself. Another limitation of high power fiber lasers is the requirement to operate each gain fiber at very high power density. This requirement is manifested through employing special cross section fibers or large mode area fibers in order to provide the volume of gain media necessary to operate at high power. However, employing a large diameter core allows off axis modes to absorb pump energy and to participate in the lasing process. Thus, in applications in which beam quality is important and a single transverse mode output is desired, it is necessary to prevent the off axis modes from propagating along the fiber. The gain of the off axis modes is reduced by coiling the gain fiber at a specific radius so that the off axis modes lose energy and the central, transverse on axis mode becomes dominant. Another limitation of fibers lasers is the non-linear power losses due to the high power at which the lasers are operated. The non-linear losses include Stimulated Brillouin Scattering (SBS), Stimulated Raman Scattering (SRS), and Self Phase Modulation (SPM), all of which result in energy loss from the desired output beam.
Optically pumped disk lasers, in which a thin solid state or ceramic gain media is pumped with optical energy, provide near single longitudinal mode outputs. The transverse size of the output beam is dependent upon the size of the spot illuminated by the pump energy. A major limitation of high power disk lasers is the requirement for complicated optical pump and output beam optics as well as thermal cooling systems. Thus disk lasers are hardware excessive that results in a large initial cost as well as costly maintenance, and alignment complexity and expense.
It may be seen that each of these existing systems exhibit important shortcomings for high power applications. A laser system that overcomes these shortcomings is thus highly desirable.
In various implementations, a high power laser has an output that is a matrix of individual phase controlled “pixels,” each pixel containing a number of low power, single transverse mode, phase coherent gain channel outputs. Each row of pixels is formed as an optical pump waveguide that is transverse or orthogonal to a number of parallel, longitudinal gain channels integrated within or adjacent to the transverse pump waveguide. Optical pump energy is produced and injected by a number of parallel, laser diode bars.
In various implementations, the systems and techniques described herein support the construction of a laser that is compact and portable.
In various implementations, the systems and techniques described herein support the elimination of complicated pump energy collection optics, transfer fibers, and coupling optics as used in parallel optical fiber lasers.
In various implementations, the systems and techniques described herein support the control of all laser parameters through design and fabrication methods.
In various implementations, the systems and techniques described herein support modifying and tuning each laser operation during the fabrication process using ion implantation or UV laser methods.
In various implementations, the systems and techniques described herein support the design and fabrication of a laser using photo-lithographic tools and techniques that may reduce cost.
In various implementations, the systems and techniques described herein support the generation of high power single transverse mode output beams without high power losses due to non-linear optical effects.
In various implementations, the systems and techniques described herein support the generation of a pixelated output matrix of beams with pixel phase control which eliminated deformable mirrors commonly used for phase conjugation.
In various implementations, the systems and techniques described herein support temperature control through integration of the laser pump waveguide and gain channels into the heat exchanger.
In various implementations, the systems and techniques described herein support a reduction in the part count and thus maintainability of a laser system when compared to multiple fiber lasers.
In various implementations, the systems and techniques described herein support phase coherence across a number of adjacent waveguide gain channels.
In various implementations, the systems and techniques described herein support laser line width control of integrated gain channel output wavelength.
In various implementations, the systems and techniques described herein support wavelength sensitive heating of gain channels absorbent materials during fabrication in order to reduce waveguide losses due to waveguide interface imperfections and gain channel material defect scattering.
In various implementations, the systems and techniques described herein support a single power supply to be used by more than one laser, one at a time, which facilitates multiple lasers per site.
It should be understood that the invention is not limited to the particular embodiments described, and that the terms used in describing the particular embodiments are for the purpose of describing those particular embodiments only, and are not intended to be limiting, since the scope of the present invention will be limited only by the claims.
The lasing media in the gain channels preferably has a sufficient absorption depth such the maximum output power per gain channel is sufficiently low to avoid all non-linear effects that lead to losses. For example, a gain channel output of desired length would be designed to absorb 20 Joules/second (J/s) and provide an output power of 10 J/second resulting in a 50% conversion efficiency. Note that this core power density is much less than those demonstrated in high power fiber lasers. This design criteria sets the thermal energy that must be removed from each gain channel at 10 J/s. Thermal management is important in these optical structures such that the pump waveguide is integrated into and sandwiched between two heat exchanger surfaces as illustrated in the following drawings.
The pump waveguide center (100) and integrated gain medium channels (101), illustrated in cross section of
The large number of parallel gain channels (101) within a pixel grouping (106) located within the pump waveguide (100) must be coherent in phase in order to efficiently form a beam and combine the output energy of all the beams. In various situations, this may be accomplished by designing a input signal distribution system (148), illustrated in
It may be necessary to further force coherence across the gain channels in one pixel as illustrated in
The output of the TPMWGL in the preferred embodiment requires extracting the optical waveguide energy from the single transverse mode beam in the square gain channel (101) using a micro-lens array or coupling the optical energy of each channel into a single mode optical fiber (154) as illustrated in
Fabrication of the pump waveguide structure is accomplished by depositing multiple layers of optical materials on one side of the heat exchanger (124) as illustrated in
At this point in the fabrication process where the initial deposition layers and gain channel have been completed (201), the system can be operated as a laser to add additional features like saturable absorber materials for phase coherence, Bragg mirror implants, adjust laser media volume or dimensions, and to trim and tune performance as required to certify the laser row quality before continuing. Note that the additional features can be accomplished using ion implants and UV laser ablation as well as other material modification methods.
Once all the gain channels within each pixel with the laser row have been certified or extinguished, the final set of layers (207) can be deposited and the top heat exchanger body bonded to the stack to form a row of laser pixels as illustrated in
In
Unless otherwise stated, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art.
Although any methods and materials similar or equivalent to those described herein can also be used in the practice or testing of the present invention, a limited number of the exemplary methods and materials are described herein. It will be apparent to those skilled in the art that many more modifications are possible without departing from the inventive concepts herein.
All terms used herein should be interpreted in the broadest possible manner consistent with the context. In particular, the terms “comprises” and “comprising” should be interpreted as referring to elements, components, or steps in a non-exclusive manner, indicating that the referenced elements, components, or steps may be present, or utilized, or combined with other elements, components, or steps that are not expressly referenced. When a Markush group or other grouping is used herein, all individual members of the group and all combinations and subcombinations possible of the group are intended to be individually included.
All references cited herein are hereby incorporated by reference to the extent that there is no inconsistency with the disclosure of this specification. The present invention has been described with reference to certain preferred and alternative embodiments that are intended to be exemplary only and not limiting to the full scope of the present invention, as set forth in the appended claims.
The foregoing description presents one or more embodiments of various systems and methods. It should be noted that these and any other embodiments are exemplary and are intended to be illustrative of the invention rather than limiting. While the invention is widely applicable to various types of technologies and techniques, a skilled person will recognize that it is impossible to include all of the possible embodiments and contexts of the invention in this disclosure.
Furthermore, those skilled in the art will recognize that boundaries between the functionality of the above described acts, steps, and other operations are merely illustrative. The functionality of several operations may be combined into a single operation, and/or the functionality of a single operation may be distributed in additional operations. Moreover, alternative embodiments may include multiple instances of a particular operation or may eliminate one or more operations, and the order of operations may be altered in various other embodiments. Those of skill in the art may implement the described functionality in varying ways for each particular application, but such implementation decisions should not be interpreted as causing a departure from the spirit or scope of the present invention.
As used herein, the term “based on” is used to describe one or more factors that affect a determination. This term does not foreclose additional factors that may affect the determination. That is, a determination may be based solely on the named factors or based in part on those factors. Consider the phrase “determine A based on B.” While B may be a factor that affects the determination of A, such a phrase does not foreclose the determination of A from also being based on C. In other instances, A may be determined based solely on B.
Some benefits and advantages that may be provided by some embodiments have been described above. These benefits or advantages, and any elements or limitations that may cause them to occur or to become more pronounced are not to be construed as critical, required, or essential features of any or all of the claims. While the foregoing description refers to particular embodiments, it should be understood that the embodiments are illustrative and that the scope of the invention is not limited to these embodiments. Many variations, modifications, additions, and improvements to the embodiments described above are possible.
This application is a continuation of International Application No. PCT/US2014/023931, titled “High Average Power Integrated Optical Waveguide Laser,” filed on Mar. 12, 2014, which claims the benefit of U.S. Provisional Application No. 61/778,064, titled “High Average Power Integrated Optical Waveguide Laser,” filed on Mar. 12, 2013. The aforementioned applications are hereby incorporated herein by reference in their entirety and for all purposes.
Number | Date | Country | |
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61778064 | Mar 2013 | US |
Number | Date | Country | |
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Parent | PCT/US2014/023931 | Mar 2014 | US |
Child | 14852553 | US |