The present invention relates to an ultrafast fiber laser system operative to controllably switch pulse duration at exceptionally high speed on the fly to perform different material processing tasks at higher productions speeds and reduces cost.
Pulse duration of a laser is a critical parameter for optimum laser machining. Different materials often require widely disparate pulse durations for best machining quality and processing speed. As a result, laser processing of inhomogeneous, composite or multi-material or multi-layered components often requires multiple lasers operating at different pulse durations with prohibitively high cost. In addition, different desired types of micro-processing (such as drilling, trenching, marking, engraving, cutting, ablation, scribing, etc.) may also require a range of optimum pulse durations. It is advantageous to be able to perform multiple types of processing on the same component in order to reduce setup time and cost.
Ultrafast lasers, including among others solid state and fiber lasers, is a generic term for picosecond and femtosecond lasers which are widely used in laser processing of various materials. The pulse width of ultrafast lasers shorter than picoseconds is typically used for industrial applications, while longer pulses are used for commercial and industrial applications because of the high output power and high reliability. Such ultrashort pulse widths suppress heat diffusion to the surroundings of processed regions, which significantly reduces the formation of a heat-affected zone and enables ultrahigh precision micro- and nano-fabrication of a variety of materials. Owing to the ultrashort pulse width, the peak intensity of ultrafast lasers require heat treating at 103 104 W/cm2, welding and cladding at 105-106 W/cm2, and material removal 107-109 W/cm2 for drilling, cutting, and milling. This level of high peak intensities creates nonlinear issues in the small diameter fiber core decreasing the quality of light and limiting its output power.
Numerous techniques have been developed to minimize undesirable consequences of high peak intensities in high power lasers including fiber laser. One of the known techniques is a chirped pulse amplification (CPA). Utilizing this technique, the extracted pulse energy is typically higher than that obtained by direct amplification. The CPA is based on chromatic dispersion and can be introduced with light propagating in optical materials including optical fibers via materials dispersion. It can also be introduced via angular dispersion in gratings or prisms. Chromatic dispersion in Bragg grating components uses the principle of interference in order to reflect different wavelengths of light at different locations in the grating. The convenience of Bragg reflectors is that the dispersion can be tailored or designed to the requirements such as dispersion compensation of other components.
Each light pulse guided through an optical media has a temporal shape that depends on its frequency content. For a pulse without a chirp the wider its frequency spectrum, the shorter the temporal width of the pulse. The chromatic dispersion or chirp is a temporal spreading over the wavelength spectrum. The pulse chirp is a foundation of CPA since the broader the pulse, the lower the peak intensity, the higher the threshold for nonlinear effects and, therefore, the greater the pulse amplification.
Thus, in CPA laser systems, the ultrashort pulses are first stretched in time using dispersion which leads a sufficiently reduced intensity enabling the subsequent amplification of the stretched pulses. In the final stage of CPA systems, a downstream dispersive element or compressor carries out the temporal compression of optically amplified pulses. Recompressing the higher pulse energy amplified pulses results in significantly higher peak powers at the system's output.
Many industrial applications of CPA laser systems require transform limited pulses which can be achieved by designing the zero or close to zero overall dispersion between various dispersive components in the laser system. The transform limit (or Fourier transform limit) is the lower limit for the pulse duration which is possible for a given optical spectrum of pulse. In other words, the transform-limited pulse has no chirp. If other than transform limited pulses are required, the components affecting the overall dispersion of the laser system should be properly adjusted to prevent full or zero compensation between these components.
An exemplary CPA fiber laser system includes a stretcher, such as a chirped fiber Bragg grating (CFBG), used to stretch optical pulses from an ultrafast optical laser seed. The system also includes a compressor, for example a chirped volume Bragg grating (CVBG), used to compress optical pulses after amplification. The pulses can be increased in size by one of two methods after the pulse compressor. In accordance with one method, the optical spectral width of the optical pulses can be adjusted by decreasing the spectral width of the CFBG. The other method is to use mismatched dispersion between the CFBG and CVBG to create chirped optical pulses.
Fine tuning of the pulse duration and pulse shape can be accomplished by a pulse shaper. One example of the pulse shaper such as an CFBG is disclosed in U.S. Provisional Patent applications 62/782,071 and 62/864,834. The tuning of the CFBG by increasing or decreasing the pulse duration is limited by the optical bandwidth and the amount of dispersion tunability. It was demonstrated that such a pulse can be tuned from <1 ps to 25 ps using the CFBG. However, the speed of tuning was limited to 20 seconds due to the design of the shaper (heating different portions of the CFBG). Faster pulse shapers, such as moveable gratings, are available. However, a movable grating is bulky and its tunability is slower than that of acousto-optical pulse shapers such as a commercially available Dazzler.
It is therefore desirable to use a single laser source that can switch pulse duration on the fly to reduce setup time, complexity and cost of the laser system.
A further need exists for a compact industrial grade laser configuration with fast switching between pulse durations for different laser processing applications at high speed.
This invention addresses the issue of fast switching between femtosecond (fs), picosecond (ps) and nanosecond (ns) pulse lasers in a single laser configuration utilizing a chirped pulse amplification (CPA) technique.
The inventive chirp pulse amplification (CPA) laser system in its basic configuration includes an ultrafast seed laser which outputs a train of ultrafast pulses along a light path coupled into a pulse duration switch assembly. The latter is operative to split each pulse into two or more replicas which have pulse temporal and spectral contents modified so that only one of the replicas continues propagation along the path. The guided replica is then amplified and again temporally treated in a downstream dispersion element so that the CPA system outputs high energy pulses in a fs ns duration range.
The pulse duration switch assembly is configured with at least one beam splitter guiding two replicas with respective power fractions of the split pulse along respective replica paths. The replicas each interact with an upstream dispersive element modifying the temporal content of the replica. In addition, spectral filters may be applied to respective replica paths so as to change the spectral content of the replica. Alternatively, a single upstream dispersive element can be used for modulating a pulse duration and spectral pulse width of each replica.
To have the desired duration of the pulses at the output of the CPA system, two optical switches are coupled into respective replica paths and individually controlled so that one of the replicas is blocked from a further propagation. Any of high speed acousto-optic modulator (AOM), electro-optic modulator (EOM), MEMS-based switch and others can be readily incorporated in the inventive structure.
The individual control of optical switches allows both of them to be switched simultaneously to the “on” position. This may be useful for industrial applications requiring a sequential irradiation of the surface to be processed by two pulses with different pulse durations. For example, a ps or ns pulse initially heats the irradiated surface such that a subsequent fs pulse, which is incident on the heated surface, forms a hole. The sequential irradiation by different pulses is accomplished by increasing the optical path length of one of the replica paths. This structural feature may be used with all of the examples of the inventive CPA system disclosed above. If, however, only a single pulse is required, both replica paths may have a uniform optical length.
In the inventive CPA laser system, the upstream dispersive elements apply respective chirps to the replicas. The upstream dispersive elements are selected from a FBG, CFBG, length of fiber, bulk optics, prisms etc., and located along respective replica paths upstream or downstream from respective optical pulse switches.
By tailoring the chromatic dispersion of the upstream and downstream dispersive elements one can generate pulse durations in a femtosecond-nanosecond range. For example, a femtosecond laser can be configured by using a positive dispersion CFBG pulse stretcher and a nearly matched negative dispersion CVBG pulse compressor or vice versa. A more mismatched CFBG and CVBG pair can be used in picosecond lasers. For the nanosecond case, the CFBG can have the same sign of dispersion as the CVBG, i.e., positive or negative dispersion, to stretch the pulses further after amplification. A typical CFBG can stretch the pulse to a 0.5-1 ns range. A VBG with the same dispersion sign would end up stretching the pulses to 1-2 ns.
The CPA laser system as disclosed above is configured with at least one beam coupler in optical communication with downstream ends of respective replica paths. Functionally, the beam coupler guides the selected replica towards the downstream end of the CPA system. The beam splitter and beam coupler each can be a bulk optic component or fiber-based component, wherein the bulk optic component includes a dielectric coated optic, while the fiber-based component is a directional fused fiber coupler.
The CPA laser system as disclosed above may additionally have at least one more beam splitter and at least one second beam coupler defining therebetween a third replica path for a third replica with spectral and pulse duration contents which are different from those of the other replicas. The third replica path is structurally analogous to the above disclosed two replica paths and includes a third upstream dispersive element and third optical switch. Optionally, a third spectral filter can be applied to the third replica path.
The above and other features of the inventive system will become more readily apparent from the following specific description which is accompanied by the following drawings, in which:
In the figures, each identical or nearly identical component that is illustrated in various figures is represented by a like numeral. For purposes of clarity, not every component may be labeled in every figure.
The inventive laser system is based on a chirped pulse amplification laser technique and includes a high speed pulse duration switch assembly which is operative to pass one or more pulse replicas with the desired duration while blocking or delaying the output with the other pulse durations. In the inventive laser system, the pulse duration is set by a proper dispersion management and, optionally, controllable adjustment of the spectral width of dispersive elements such as a stretcher and compressor which are further referred to as upstream and downstream dispersion elements, respectively. Several schematics illustrating the inventive concepts is discussed hereinbelow.
Referring to
As illustrated in
The amplified pulses are further coupled into a downstream dispersive component 20 tuned to provide amplified pulse replicas 36 with the desired duration. The desired pulse duration may be as low as 5 fs and as long as a few ns, whereas the high peak power range extends between a few hundred watts and a few MWs.
Optionally, CPA laser system 10 may be configured with a frequency conversion unit downstream from dispersion element or compressor 20. The frequency conversion unit may include a second harmonic generator (SHG) 24 (
An isolator 15 preventing propagation of back-reflected light can be installed in any of the schematics shown in respective figures referred to above. Furthermore, if transform limited pulses are desired at the output of system 10, a multiphoton intrapulse interference phase scan (MIIPS) shaper, can be incorporated in any of the discussed configurations of system 10 after downstream dispersion element 20. The operation of MIIPS pulse shaper is disclosed in PCT/US2018/025152 fully incorporated herein by reference.
Referring specifically to
The schematic of
The relative position of upstream dispersive element 32′, 32″ and optical switch 34′, 34″ applied to each replica path can vary. The switches 34′, 34″ are coupled to respective outputs of upstream dispersive elements 32′ and 32″.
Ultrashort pulses emitted from seed laser 12 (
The dispersion has different positive and negative signs. In a medium with the positive dispersion, the higher frequency components of the pulse travel slower than the lower frequency components, and the pulse becomes positively-chirped or up-chirped, increasing in frequency with time. In a medium with negative dispersion, the higher frequency components travel faster than the lower ones, and the pulse becomes negatively chirped or down-chirped, decreasing in frequency with time. Dispersive gratings provide large stretching factors and by using diffraction gratings, ultrashort optical pulses can be stretched to more than 1000 times.
Structurally, upstream fiber dispersion element 32′, 32″ may include any of prism, bulk optic, length of fiber, volume Bragg grating (VBG), uniform fiber Bragg grating (FBG) or chirped FBG (CFBG) configurations. The FBG is a periodic structure that resonates at one Bragg wavelength. In contrast, the Bragg wavelength varies along the grating in the CFBG, since each portion of the latter reflects a different spectrum. Thus, the key characteristic of the CFBG is the fact that the overall spectrum depends on the temperature/strain recorded in each section of CFBG as opposed to the strain or temperature applied on the whole grating length of FBG.
The downstream dispersion element 20 (
The optical switch 34′, 34″ is used to shut off the optical power for any of the undesired replica paths thus allowing only one replica with the desired pulse duration to propagate towards downstream dispersive element 20. The optical switch may have different configurations. For example, it can be a MEMs based switch, electro-optic switch such as lithium niobate modulator, or an acousto-optic switch such as an AOM. The specific configuration of optical switch 34′, 34″ depends on various factors. The key consideration for selecting the desired switch, however, is a switching time which should be fast as possible. The AOM is perhaps the fastest switching device. In the tested configurations of CPA laser system 10, a minimal switching time of a fiber coupled AOM was determined to be in a 20-30 ns range. This time interval is believed to be a record time which is so important in micro-processing of multi-layer or multi-material parts such as semi wafers, PCBs, Flex Circuits that require optimally different pulse durations. The speed at which inventive CPA system 10 is operative to switch pulse durations is one of the key advantages of this invention—essentially it is able to offer the functionality of multiple lasers in one single laser. The switching operation is controlled by standard electronics 15 with appropriate speed are required to switch on and off optical switches 34′ and 34″.
As mentioned above, it is also possible to have multiple pulses at the output of CPA system 10 with different pulse durations by utilizing differently configured upstream dispersion elements 32′ and 32″ and using both switches 34′ and 34″ which both can be switched to the “on” state. The pulse separation at the output of switch assembly 14 can be controlled by introducing a delay fiber loop 22 increasing the optical length of one of replica paths while keeping the optical length of other(s) replica paths intact. All optical paths may be configured with respective delay loops 22 dimensioned to provide the replica paths with respective optical lengths which differ from one another. It would allow creating a burst of pulses with different pulse durations or same pulse duration that are reconfigurable in real time. For example, one can operate the seed in the burst mode such as to keep n number of pulses in each optical path, then switch the seed to n−1 pulse burst, n−2 pulse burst, etc.
The optical paths are combined into a single optical path by using a beam combiner 38. The beam combiner can be an optical component configured similarly to beam splitter 28. For bulk optics this may be a dielectric coated optic. For fiber based system, a directional fused fiber coupler can be incorporated in CPA system 10. Differently configured beam splitter and combiner components may be implemented in every schematic shown in
Turning specifically to
Referring specifically to
Revisiting
The booster 18 can be selected from a variety of configurations including fiber, rare earth ion-doped yttrium aluminum garnet (YAG), disk and other amplifier configurations. Regardless of the configuration, booster 18 should provide the replica or replicas incident thereupon with a high gain. Peak powers reaching MW levels are particularly beneficial for CPA system 10 provided with frequency conversion stages. Exemplary configurations of fiber booster 18 are disclosed in U.S. Pat. Nos. 7,848,368, 8,068,705, 8,081,667 and/or 9,667,023, whereas the YAG configuration is disclosed in US Patent Application Publication 201662428628 all incorporated herein by reference.
While the principles of the invention have been described herein, it is to be understood by those skilled in the art that this description is made only by way of example and not as a limitation as to the scope of the invention. Other embodiments are contemplated within the scope of the present invention in addition to the exemplary embodiments shown and described herein. Modifications and substitutions by one of ordinary skill in the art are considered to be within the scope of the present invention, which is not to be limited except by the following claims.
Filing Document | Filing Date | Country | Kind |
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PCT/US20/41341 | 7/9/2020 | WO |
Number | Date | Country | |
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62871878 | Jul 2019 | US |