OPTICAL PARAMETRIC AMPLIFICATION, OPTICAL PARAMETRIC GENERATION, AND OPTICAL PUMPING IN OPTICAL FIBERS SYSTEMS
Embodiments described herein include a system for producing ultrashort tunable pulses based on ultra broadband OPA or OPG in nonlinear materials. The system parameters such as the nonlinear material, pump wavelengths, quasi-phase matching periods, and temperatures can be selected to utilize the intrinsic dispersion relations for such material to produce bandwidth limited or nearly bandwidth limited pulse compression. Compact high average power sources of short optical pulses tunable in the wavelength range of 1800 to 2100 nm and after frequency doubling in the wavelength range of 900 to 1050 nm can be used as a pump for the ultra broadband OPA or OPG. In certain embodiments, these short pump pulses are obtained from an Er fiber oscillator at about 1550 nm, amplified in Er fiber, Raman-shifted to 1800 to 2100 nm, stretched in a fiber stretcher, and amplified in Tm-doped fiber.
This application is a continuation of U.S. patent application Ser. No. 13/714,840, filed Dec. 14, 2012, entitled “OPTICAL PARAMETRIC AMPLIFICATION, OPTICAL PARAMETRIC GENERATION, AND OPTICAL PUMPING IN OPTICAL FIBERS SYSTEMS,” which is a continuation of U.S. patent application Ser. No. 13/232,470, filed Sep. 14, 2011, entitled “OPTICAL PARAMETRIC AMPLIFICATION, OPTICAL PARAMETRIC GENERATION, AND OPTICAL PUMPING IN OPTICAL FIBERS SYSTEMS,” which is a continuation of U.S. patent application Ser. No. 11/091,015, filed Mar. 25, 2005, entitled “OPTICAL PARAMETRIC AMPLIFICATION, OPTICAL PARAMETRIC GENERATION, AND OPTICAL PUMPING IN OPTICAL FIBERS SYSTEMS,” now U.S. Pat. No. 8,040,929, which claims priority under 35 U.S.C. 119(e) to U.S. Provisional Patent Application No. 60/556,101, filed Mar. 25, 2004, entitled “ULTRABROADBAND SOURCES BASED ON FIBER LASER PUMPED OPTICAL PARAMETRIC GENERATION AND AMPLIFICATION IN PERIODICALLY-POLED MATERIALS” and to U.S. Provisional Patent Application No. 60/624,140, filed Nov. 1, 2004, entitled “A SOURCE OF SHORT OPTICAL PULSES BASED ON AMPLIFICATION IN TM-DOPED FIBER;” each of the aforementioned applications and patent is hereby incorporated by reference herein in its entirety.
BACKGROUNDCertain embodiments of the invention relate to apparatus and methods for converting optical pulses from compact fiber laser pulse sources into pulses having different wavelengths and having a large or increased bandwidth through the use of optical parametric amplifying media. Other embodiments of the invention relate to apparatus and methods for producing short optical pulses utilizing amplification in optical fibers operating in the infrared region beyond about 1700 nm.
Nonlinear optical elements may be employed to provide amplification in a process know as optical parametric amplification (OPA). In such a process, an intense coherent pump beam at a first wavelength interacts with the nonlinear optical element such as a nonlinear optical crystal to produce amplification. One or two output beams at respective second and third optical wavelengths exit the nonlinear optical element. These output beams are referred to as the signal and the idler. In optical parametric amplification, in addition to being pumped, the nonlinear optical element is seeded with radiation at the signal and possibly idler wavelengths.
The optical parametric amplification process obeys the conservation of energy principle ω1=ω2+ω3, where ωi is the pump frequency and ω2 and ω3 are the signal and idler frequencies. The individual values of ω2 and ω3 also satisfy the conservation of momentum condition, which for plane wave intersection is k1=k2+k3 where k1, k2, and k3 are the respective wavenumbers for ω1, ω2, and ω3. This later condition provides for phase-matching. Phase matching can be varied by changing an appropriate phase matching parameter of the nonlinear optical element such as the angle of propagation or the temperature.
If is no light is supplied to the nonlinear optical element at ω2 or ω3, the process is referred to as optical parametric generation (OPG). In OPG, seeding is provided by noise.
When ω2=ω3, the process is termed degenerate.
Parametric amplification can be incorporated in a resonant cavity that circulates the signal and/or the idler. In this geometry, the process is termed parametric oscillation. A parametric amplifier inside a resonant optical cavity yields a laser that can be used to generate a frequency-tunable coherent beam of light by pumping with a beam of fixed frequency. This laser is tuned by varying the phase matching properties of the nonlinear optical element.
Unique apparatus and methods of implementing optical parametric amplification and optical parametric generation are presented below.
SUMMARYOne embodiment of the invention comprises a pulsed light source based on optical parametric generation. This pulse light source comprises a pump laser and a nonlinear crystal. The pump laser is configured to output optical pulses having a pulse width of about 10 nanoseconds or less. The nonlinear crystal is selected from the group comprising periodically poled lithium-niobate, periodically poled KTP, periodically-twinned quartz, periodically poled RTA, periodically poled lithium tantalate, and periodically poled potassium niobate. The optical pulses from the pump laser pump the nonlinear crystal thereby producing optical parametric generation having a bandwidth of at least about 200 nanometers.
Another embodiment also comprises a pulsed light source based on optical parametric generation. This pulsed light source comprises a pump fiber laser and a nonlinear crystal selected from the group comprising periodically poled lithium-niobate, periodically poled KTP, periodically-poled quartz, periodically poled RTA, periodically poled lithium tantalate, periodically poled potassium niobate and orientation patterned GaAs. The pump fiber laser is configured to provide pump energy to the nonlinear crystal so as to produce spectral emission via optical parametric generation in a spectral range exceeding a width of about 100 nanometers (nm).
Another embodiment of the invention comprises a pulsed light source based on optical parametric amplification. This pulses light source comprises a fiber pump laser, a fiber continuum source, and a nonlinear crystal. The nonlinear crystal receives optical pulses from the fiber pump laser and optical pulses from the fiber continuum source. The optical pulses from the fiber continuum source are amplified by optical parametric amplification in the nonlinear crystal. The optical pulses from the fiber pump laser and the optical pulses from the fiber continuum source are substantially synchronized in time.
Another embodiment of the invention also comprises a pulsed light source based on optical parametric amplification. This pulses light source comprises a pump laser, a seed source, and a nonlinear crystal. The seed source comprises an optical continuum fiber. The nonlinear crystal receives optical pulses from the pump laser and optical pulses from the seed source. The optical pulses from the seed source are amplified by optical parametric amplification in the nonlinear crystal. The optical pulses from the pump laser and the optical pulses from the seed source are substantially synchronized in time.
Another embodiment of the invention also comprises a pulsed light source based on optical parametric amplification. The pulsed light source comprises a pump laser source, a seed source, and a nonlinear crystal. The nonlinear crystal receives optical pulses from the pump laser source and optical pulses from the seed source and produces spectral emission as a result of optical parametric amplification. This spectral emission has a spectral range exceeding a width of about 100 nm.
Another embodiment of the invention comprises an optical pulse source comprising a seed laser, a pulse stretcher, a Tm-doped fiber amplifier, and an output port. The seed laser is configured to emit optical seed pulses. The pulse stretcher is configured to stretch the seed pulses. The Tm-doped fiber amplifier is configured to amplify the stretched optical pulses. The output port outputs optical pulses amplified by the Tm-doped fiber amplifier. The optical pulses output from the output port have a pulse width of about 1 nanosecond or less and have a spectral content in a wavelength range extending from about 1600 to about 2400 nanometers.
Another embodiment of the invention comprises an optical pulse source comprising a Tm-doped fiber source, one or more nonlinear crystals, and an output port. The Tm-doped fiber source is configured to produce optical pulses. The one or more nonlinear crystals are disposed to receive the optical pulses. These one or more nonlinear crystals are configured for frequency up-conversion or down-conversion of the optical pulses. The output port outputs the optical pulses. These optical pulses output from the output port have a pulse width of about 1 nanosecond or less.
Another embodiment of the invention comprises an optical pulse source comprising means for producing optical seed pulses, means for stretching the seed pulses, means for amplifying the stretched optical pulses, and means for outputting the optical amplified pulses. The means for amplifying the stretched optical pulses comprises a Tm-doped fiber amplifier. The optical pulses output from the output port have a pulse width of about 1 nanosecond (ns) or less and have a spectral content in a wavelength range extending from about 1600 to about 2400 nanometers.
Another embodiment of the invention comprises an optical pulse source comprising means for producing optical pulses, means for frequency up-converting or frequency down-converting of the optical pulses, and means for outputting the optical pulses. The means for producing optical pulses comprises a Tm-doped fiber. The optical pulses output from the output port have a pulse width of about 1 nanosecond or less.
Another embodiment of the invention comprises a method of producing optical pulses comprising producing optical seed pulses, stretching the seed pulses, amplifying said stretched optical pulses, and outputting the amplified optical pulses. The stretched optical pulses are amplified using a Tm-doped fiber amplifier. The optical pulses output from the output port have a pulse width of about 1 nanosecond or less and have a spectral content in a wavelength range extending from about 1600 to about 2400 nanometers.
Another embodiment of the invention comprises a method of producing optical pulses comprising producing optical pulses, frequency up-converting or frequency down-converting of the optical pulses, and outputting the optical pulses. The optical pulses are produced using a Tm-doped fiber. The optical pulses output from the output port have a pulse width of about 1 nanosecond or less.
These and other embodiments of the present invention will also become readily apparent to those skilled in the art from the following detailed description of the preferred embodiments having reference to the attached figures, the invention not being limited to any particular embodiment(s) disclosed. Accordingly, the scope of the present invention is intended to be defined only by reference to the claims.
Various embodiments of the invention comprise optical parametric amplification (OPA) systems that output broad bandwidth, short optical pulses. Many of these systems operate at infrared wavelengths, between, e.g., about 1.9 to 2.1 microns or higher or lower. These optical parametric amplification systems are pumped by fiber amplifiers that produce broad bandwidth short pump pulses. In certain embodiments, for example, a moderate pulse energy (about 50 nJ or more) fiber laser system is used as a pump for an OPA system. This OPA system may comprise a periodically-poled material having periodic poling that provides quasi-phase matching (QPM). The effect of intrinsic dispersive properties of optical components in the OPA system such as optical fiber, which would otherwise produce pulse broadening, can be reduced by selection of appropriate combinations of pump wavelengths and the quasi-phase matching periods. Small-signal parametric gain bandwidths exceeding about 1000 nm can thereby be achieved. For example, pumping an OPA system comprising a periodically-poled lithium niobate (PPLN) that is pumped with wavelengths in the range of about 900-970 nm and selecting QPM periods appropriately allows for small-signal parametric gain bandwidths for the lithium niobate OPA exceeding about 1500-2000 nm centered at about 1.9 um.
Optical Parametric AmplificationAn OPA system may be operated close to the degeneracy point where the signal frequency is approximately equal to the idler frequency. This degeneracy condition can be established by appropriate phase matching. As described above, phase matching may be controlled by selecting a modulation period (in the case of quasi-phase matching) of the OPA material or selecting the angle and temperature (in the case of birefringent phase-matching). Selecting such parameters to establish the signal wavelength at about twice the pump wavelength results in large OPA bandwidths for amplification of the signal wave.
Tuning behavior of an OPA is often expressed as a dependence of the signal of signal wavelength, λs, on the pump wavelength, λp,
λs=λs(λp)
under the condition that the OPA process is phase-matched (birefringently or through QPM). At the degeneracy point, the first derivative vanishes (∂λp/∂λs=0). Accordingly, the OPA bandwidth is determined by the second derivative, ∂2λp/∂λs2.
Operating at the degeneracy point may lead to OPA gain bandwidths, for example, in the range of about 50-300 nm, depending on the material, device length and operating wavelengths. For instance, for OPA in 10-mm-long periodically-poled lithium niobate (PPLN) with QPM period of 18.9 the small signal gain at about 1550 nm has a bandwidth of about 44 nm when pumped at λp=780 nm.
As described above, phase-matching of OPA with QPM materials is governed by the energy and the momentum conservation equations,
1/λp=1/λs+1/λi (1)
1/Λ=np/λp−ns/λs−ni/λi, (2)
where λk is the wavelength, nk is the refractive index, A is the QPM period (subscript k corresponds to either p, s, i, which denotes pump, signal, and idler, respectively). For a given material and temperature (i.e. for a given material dispersion) these equations have four independent variables. For example, if QPM period is chosen, the tuning curve λs=λs (λk) is uniquely defined. As another example, establishing the degeneracy point as described above wherein λs=λi=2λk, uniquely defines the QPM period for each pump wavelength.
To find a regime for ultra broadband OPA gain, two conditions can be established in addition to those set forth in Eqs. (1) and (2):
∂λp/∂λs=0 (satisfied at the degeneracy point), and
∂2λp/∂λs2=0.
This set of these conditions uniquely identifies the QPM period and the interacting wavelengths. The result of such calculation is shown in
Additionally, in
As described in further detail below, parametric amplification can be used in a manner to provide several important advantages. Unlike quantum amplifiers that operate at specific wavelength bands defined by electron transitions in the gain material, QPM parametric amplifiers, which do not rely on such processes, and can have a gain peak (and gain bandwidth) engineered to be at the desired wavelength within the material's transparency window. See for example U.S. Pat. No. 6,181,463, entitled “Quasi-phase-matched Parametric Chirped Pulse Amplification Systems,” issued to Galvanauskas et al., which is incorporated herein by reference in its entirety. Accordingly, limitations on the gain bandwidth and pump wavelength, inherent in quantum amplifiers, can be removed by using quasi-phase-matched nonlinear materials. Moreover, as also discussed below, operating OPA in the regimes where special dispersion conditions exist results in ultra broadband gains approaching and exceeding an octave.
Additionally, parametric amplification systems are inherently simpler and more compact. Parametric amplification in a single stage can provide up to about 80 dB gain (the limit is imposed by the threshold for optical parametric generation (OPG)). Therefore, starting from about 10 pJ as a minimum energy obtainable with any fiber, laser diode or solid state oscillator, high pulse energies in the 1 mJ to 1 J range can be reached using only one or two amplification stages. Consequently, regenerative schemes and multi-pass schemes are not necessary.
In various preferred embodiments, the parametric gain as well as the maximum energy conversion from the pump into the signal in a parametric amplifier are sufficiently high (e.g., approximately 10 to 50%) to be useful. This energy conversion is determined by the peak intensity of the pump and the properties of the nonlinear crystal. Birefringent phase-matched crystals entail high peak intensities, which are substantially higher than those practically achievable with a pump pulse from a compact, diode-pumped source. As described below, however, using QPM materials such as PPLN, lower-intensity pumps for OPA can be used to achieve appreciable parametric gains. Further discussion of PPLN and related materials and their properties is provided in U.S. Pat. No. 5,815,307 entitled “Aperiodic Quasi-phasematching Gratings for Chirp Adjustments and Frequency Conversion of Ultra-short Pulses” issued to Arbore et al., U.S. Pat. No. 5,862,287 issued to Stock et al., U.S. Pat. No. 5,880,877 entitled “Apparatus and Methods for the Generation of High Power Femtosecond Pulses from a Fiber Amplifiers,” issued to Fermann et al., and Myers et al., “Quasi-phase-matched optical parametric oscillators in bulk periodically poled lithium niobate”, J. Opt. Soc. Am. B 22, 2102 (1995), which are each hereby incorporated herein by reference in their entirety.
Accordingly, practical advantages of various of the ultra broadband amplification schemes described herein are essentially determined by the advantageous properties of the nonlinear material used for OPA. Because a QPM parametric medium allows a reduction of required pump energies, a variety of system configurations producing amplified ultra broadband pulses becomes available for implementation. A variety of different system architectures are discussed below.
In another arm, a broadband continuum is generated in a continuum fiber 210. This continuum fiber 210 may comprise, for example, a fiber having nonlinear properties. Output from the continuum fiber 210 is passed through a filter 240 to filter out twice the center wavelength of the light generated by an OPA pump 200 located in a second arm. The filter 240 may pass long- and/or short-wavelength parts relative to twice the center wavelength of the OPA pump 200. This broadband continuum output comprises a seed pulse for seeding the OPA process.
Accordingly, the output from the continuum fiber 210 after being filtered by the filter 240 as well as the pump output from the OPA pump 200 are combined by a beamsplitter/coupler 250 and applied to the parametric amplifier 260. The beam splitter 250 thus combines high-energy narrow-bandwidth pump pulses from the OPA pump 200 and wide-bandwidth seed pulses from the continuum fiber 210. An amplified signal is produced by the parametric amplifier 260. This amplified signal is applied to the pulse compressor 270.
The various components may be coupled together by optical fiber or other types of waveguides. Free space propagation and bulk components may also be used.
The fiber laser 101 may be a mode-locked oscillator or a mode-locked oscillator followed by a one or more fiber amplifiers. The fiber laser 101 is constructed to deliver pulse energies and peak powers sufficient to produce a wide enough continuum in the continuum fiber 210, e.g., a few nanojoules (nJ). For additional background, see, U.S. Patent Publication 2004/0,213,302 entitled “Pulsed Laser Sources” filed by Fermann et al, which is incorporated herein by reference in its entirety. In various embodiments, the fiber laser 101 is an Er fiber laser that produces short optical pulses at about 1560 nm with the repetition rate of 20-100 megahertz (MHz). The laser 101 may produce linearly-polarized light as for example can be obtained by using polarization-maintaining (PM) components. The laser is optionally implemented as a master-oscillator-power-amplifier (MOPA) configuration. Such lasers are described in U.S. Patent Application No. 60/519,447, which is incorporated herein by reference in its entirety and are available from IMRA America, Ann Arbor Mich.
The output of the laser 101 is split into the two arms with a non-wavelength-selective beam splitter 220. The splitter 220 may have a 50/50 splitting ratio, however, other splitting ratios can also be used. The splitter 220 may comprise a fused fiber coupler. Optionally, a bulk splitter can be used, either in a fiber-coupled arrangement or by incorporating separate bulk optics to couple light in and out of the fibers.
The ultra broadband continuum in one arm is generated in the continuum fiber 210, which may comprise a micro-structured fiber or a conventional solid-core high-nonlinearity fiber. Optionally, two or more different nonlinear fiber types can be used sequentially as discussed in U.S. Patent Publication 2004/0,213,302 A1, which is incorporated herein by reference in its entirety. With such an approach, continuum generation can be optimized for different spectral parts, thereby resulting in stable operation over a wide ultra broadband spectrum.
Alternatively, the output from the splitter 220 can be split into two or more arms and different nonlinear fibers or sequences of nonlinear fibers in different arms can be used to optimize the continuum output for each individual arm. The optimization of the continuum output in each arm is particularly useful when creating ultra broadband continua or ultra-flat continua as well as low noise continua. Flat continua are preferred in most applications to reduce or avoid the occurrence of ‘spectral holes’. For example, in optical coherence tomography, spectral holes limit the optical resolution. Equally, in spectroscopy, spectral holes limit the signal/noise of a potential detection system in certain parts of the spectrum, which is undesired.
Spectral continua can be tailored for variety of operation modes. For example flat continua may be obtained by using an ultra-short input pulse (about 60 fs or less) or by concatenation of nonlinear fibers of different design as discussed above. See also U.S. patent Publication 2004/0,213,302 A1 and T. Hori et al., “Flatly broadened, wideband and low noise supercontinuum generation in highly nonlinear hybrid fiber”, Optics Express 12, No. 2, p. 317, 2004, each of which are incorporated herein by reference in their entirety.
As described above, low noise spectral continua may be generated by reducing or minimizing the width of the pulses injected into the nonlinear continuum fiber(s) 210. Additionally, in certain embodiments, fibers with a dispersion ≧0 fs2/m at least in the vicinity of the spectrum of the input pulses are used instead of the negative dispersion (soliton-supporting) highly nonlinear fibers. A negative dispersion value is referred to herein as soliton supporting, whereas positive dispersion is referred to as not soliton supporting. Accordingly, the fiber may have a slightly positive dispersion at least in a spectral range, e.g., of about 5 THz within the center of input pulse spectrum. For example, at a wavelength of about 1560 nm, a highly nonlinear fiber may have a dispersion ≧0 fs2/m in a spectral range from about 1540-1580 nm. Even outside this spectral range, the highly nonlinear fiber may be dispersion flattened and the dispersion does not drop to below about −100,000 fs2/m or not below about −50,000 fs2/m in the whole spectral region of interest.
Even in the presence of highly nonlinear fibers with negative dispersion, low noise spectral continua can be obtained by using the anti-Stokes part of the spectral continuum. The anti-Stokes part of the spectral continuum is generated mainly by coherent nonlinear processes such as self-phase modulation as well as self-steepening. In contrast, incoherent and inherently noisy nonlinear processes such as Raman scattering play only a minor role in the anti-Stokes part of the spectral continuum. Thus, the noise from Raman scattering can be substantially reduced by only using the anti-Stokes part of the continuum. The anti-Stokes part of the continuum is referred to as the spectral range with an optical frequency lower than the center frequency of the input pulses.
With continued reference to
The OPA pump 200 is disposed in the other arm of the splitter 220 to generate and provide the OPA pump beam. (As will be discussed below, the configuration comprising the fiber laser 101 and OPA pump 200 can be useful for applications other than pumping the OPA 260.) For increased gain to be achieved in the OPA 260, the pulse lengths of the pulse output from the continuum arm and the pulse output from the OPA pump arm can be matched to each other. The pulse length of the OPA pump arm output, for example, may be adjusted to be equal to (or somewhat exceed) the pulse length of the seed pulse output from the continuum arm.
The configuration shown in
As described above and shown in
The parametric amplifier 260 is preferably implemented with periodically-poled lithium niobate (PPLN) that has the quasi-phase matched (QPM) period and the operating temperature chosen appropriately to achieve ultra broadband OPA. Preferably, a Type I phase-matching configuration is used so that the interacting waves are polarized as extraordinary waves and interact with the largest element of the nonlinear susceptibility tensor. Alternatively, other polarization combinations can be used in a Type II configuration thereby utilizing different non-zero components of the nonlinear susceptibility tensor and different dispersion relations.
Alternatively, other QPM crystals can be used with appropriate polarizations, temperature and wavelengths choices. Examples of other QPM crystals include periodically-poled potassium titanyl phosphate (KTP), periodically-twinned quartz, periodically-poled rubidium titanyl arsenate (RTA), periodically-poled lithium tantalate, periodically-poled potassium niobate. Such nonlinear crystals can be configured to enable quasi-phase matched frequency conversion, optical parametric generation, amplification etc., as described herein.
Alternatively, instead of the bulk QPM crystal, an optical waveguide formed in a QPM material can be used for OPA; see for example U.S. Pat. No. 6,181,463 issued to Galvanauskas, et al. Using a nonlinear optical waveguide for OPA allows for substantial increase in the efficiency compared to bulk materials. The dispersive properties of such optical waveguide are generally noticeably different from that of the substrate bulk material and depend on the waveguide parameters. Hence to achieve the ultra broadband OPA regime, the selection of pump and signal wavelengths, temperature and QPM period is generally different from that for the substrate bulk material. The nonlinear waveguide guides both the pump wave and the ultra broadband continuum being amplified. In various preferred embodiments, each of the interacting waves stays predominantly in one mode in an interaction region in the nonlinear waveguide. Optionally, the waveguide OPA device can be pigtailed to allow for direct splicing with the rest of the fiber-based components which may comprise the entire system.
In various embodiments, the compressor 270 has enough bandwidth to support the bandwidth of the amplified pulses output from the OPA 260. The compressor 270 may be constructed using bulk diffraction gratings, fiber Bragg gratings, volume Bragg gratings, as described in U.S. Pat. No. 5,499,134 entitled “Optical Pulse Amplification Using Chirped Bragg Grating,” issued to Galvanauskas et al, which is also incorporated herein by reference in its entirety or photonic band-gap fiber, as described in Fermann et al., “All-fiber Chirped Pulse Amplification Systems” U.S. Patent Application No. 60/539,110, entitled “All-fiber Chirped Pulse Amplification Systems,” filed by Fermann et al, which is also incorporated herein by reference in its entirety. Optionally, because the OPA is generally not peak power limited, the compressor 270 can be placed anywhere before the OPA 260 and after the continuum fiber 210. Optionally, if ultra broadband amplified pulses need not be compressed for a particular application, the compressor 270 can be omitted altogether.
A wide range of configurations and designs are possible, in certain embodiments, for example, the fiber laser 101 may comprise an Er-doped fiber laser that outputs optical pulses at about 1.55 μm wavelength. These pulses may have a bandwidth of between about 2 and 40 nm and may be between about 30 and 500 femtoseconds (fs) in duration. The OPA pump 200 may comprise a frequency-doubled Tm-doped fiber amplifier that outputs optical pulses having the wavelength of between about 935 and 950 nm. These pulses may have a bandwidth of between about 1 and 30 nm and may be about 30 fs and 1000 picoseconds (ps) in duration. The continuum fiber 210 may output optical pulses in the range of about 1.1 to 2.5 μm. The pulses may have a bandwidth of between about 40 and 2000 nm and a pulse length between about 30 fs and 1000 ps duration. The optical filter 240 may filter out light at about 1900 nm. The optical pulses will remain between about 30 fs and 1000 ps in temporal duration. This filter may additionally remove light above or below 1900 nm. The QPM crystal 260 may output pulses having a similar spectrum as output by the optical filter 240, however, amplified in intensity. These pulses output by the QPM crystal 260 may be between about 30 fs and 1000 ps in duration. The compressor 270 compresses these pulses to between about 3 fs and 300 fs in length. Likewise, the outputs of the fiber laser 101, the OPA pump 200, and the QPM crystal 260 may be at least substantially or nearly bandwidth limited. Compressed optical pulses may be obtained wherein the pulse compression is about 10 times or less than the bandwidth limit, about 3 times or less than the bandwidth limit, or about 2 times than the bandwidth limit. As discussed more fully below, selection of appropriate dispersion of the respective components may be employed to provide such near bandwidth limited operation. Values outside these ranges are also possible and in some embodiments the pulses are not bandwidth limited.
Other designs of the optical parametric amplification system are possible. The components may operate at different wavelengths and the dispersion and other parameters may produce optical pulses having different temporal duration. Similarly, the bandwidth of the optical pulses may be different. In addition, components may be added, excluded, or arranged differently in other designs.
OPA PumpAs discussed above, the OPA pump 200 shown in
The description above with reference to the short pulse source 101 shown in
In the case of an Er-doped fiber laser 101, the laser outputs optical pulses at about 1.55 microns. These optical pulses may have a bandwidth between about 2 and 40 nm and maybe substantially bandwidth limited. Accordingly, the optical pulses may have a pulse duration of between about 30 and 500 femtoseconds in some embodiments. Values outside these ranges are also possible.
This short pulse source 101 produces optical pulses that seed an Er-doped fiber amplifier 102 and accordingly may be referred to as a short seed pulse source. The output of the laser 101 is directed to the Er-doped fiber amplifier 102 through an optical isolator (not shown separately). The Er-doped fiber amplifier 102 may operate in the nonlinear regime, i.e. with the B-integral exceeding unity, enabling higher-order soliton compression. Examples of such amplifiers are described in U.S. Pat. No. 6,014,249 entitled “Apparatus and Method for the Generation of High-power Femtosecond Pulses from a Fiber Amplifier,” issued to Fermann et al, which is incorporated herein by reference in its entirety. Accordingly, the optical pulses output from the Er-doped fiber amplifier may be substantially bandwidth limited and may have a duration of between about 30 and 500 fs in some embodiments. In some embodiments, values outside these ranges can also be used. The amplifier 102 may be implemented with polarization maintaining (PM) components. Optionally, the pulses output from the Er-doped fiber amplifier 102 have a spectral part that has its optical frequency slightly Raman shifted (about 10-50 nm) compared to the output of the fiber oscillator 101. Other types of optical amplifiers may also be used.
The output of the fiber amplifier 102 is injected into a Raman-shifting fiber 103. Optical coupling may be completed by fusion splicing of the respective fibers. At the end of such Raman fiber, the central frequency of the Raman soliton is substantially shifted to the longer wavelength; see, e.g., U.S. patent application Ser. No. 09/576,772, entitled “Modular, High Energy, Widely Tunable Ultrafast Fiber Source,” filed May 23, 2000 by Fermann et al, which is incorporated herein by reference in its entirety. The output wavelength can be tuned by changing the pulse energy input to the Raman shifting fiber, which in turn can be adjusted by changing the gain of the amplifier 102. Wavelength-tunable pulses can be obtained in the range of about 1600-2200 nm and beyond. In certain embodiments, the Raman shifter is implemented with a polarization maintaining (PM) fiber. The Raman soliton pulses may have a bandwidth of about 20 to 50 nm and the pulses are nearly-transform-limited with pulse lengths of 30 to 200 femtosecond (fs).
Elements 101, 102, and 103 form a seeder block 100 that produces nearly bandwidth limited tunable pulses in the wavelength range of about 1600-2200 nm. See also U.S. patent application Ser. No. 09/576,772, the contents of which are incorporated herein by reference.
The output of the Raman shifting fiber 103 at about 2 μm wavelength is injected to a fiber stretcher 104. In certain embodiments, this fiber stretcher 104 provides normal dispersion and has a length that produces chirped pulses with pulse length of about 6 picoseconds (ps) or shorter. Coupling may be made by fusion splicing of the fibers. To provide normal dispersion, a small core (large NA) fiber may be used for stretching. Other embodiments are also possible. Alternatively, the fiber stretcher 104 provides anomalous dispersion.
Alternatively, instead of the fiber stretcher 104, a chirped fiber Bragg grating (FBG) can be used for pulse stretching. Suitable arrangements can be used to couple light in and out of the FBG. The FBG has a low group delay ripple and may have a linear chirp. Optionally, a nonlinearly-chirped FBG can be used as described in U.S. application Ser. No. 09/576,772, and U.S. patent application Ser. No. 10/608,233 entitled “In-line, High Energy Fiber Chirped Pulse Amplification System,” filed by Fermann et al, both of which are incorporated herein by reference in their entirety.
The output of fiber stretcher 104 is injected into the fundamental mode of a fiber amplifier 105 comprising a thulium-doped (Tm-doped) fiber. Accordingly, optical pulses having wavelengths between about 1.55 and 2.1 microns are coupled from the fiber stretcher 104 into the Tm-doped fiber amplifier 105 which outputs similar wavelengths. Optical coupling can be performed by fusion splicing, a fiber coupler, or a bulk-optic imaging system. Other methods of optically coupling the fiber stretcher 104 and the fiber amplifier 105 may also be used. The amplifier fiber 105 may be a large-mode-area (LMA) fiber. To obtain a diffraction limited output, the fundamental mode in the LMA may be selectively excited and guided (see, e.g., U.S. Pat. No. 5,818,630 entitled “Single-mode Amplifier and Compressors Based on Multi-mode Fibers,” issued to M. E. Fermann et al. which is incorporated herein by reference in its entirety). The use of LMA fiber allows for high peak powers to be obtained at the output of the amplifier 105.
The Tm amplifier fiber may also comprise polarization maintaining fiber. In case of non-polarization maintaining fibers, appropriate polarization control elements like waveplates may be used prior to the fiber amplifier 105 or after the amplifier to prepare a polarization state appropriate for optimum frequency-doubling using a nonlinear crystal 108 (discussed more fully below). An LMA microstructured (holey) can also be used.
Also different dopants may be employed in different embodiments. For example, a holmium doped (Ho-doped) fiber amplifier can alternatively be used. The fiber can also be co-doped with other rare earths to enhance pump absorption as well. Still other designs are possible.
Tm-doped fibers (and in particular Tm-doped LMA fibers), however, have a number of advantages. The nonlinear parameter of Tm fiber is 2-4 times smaller, for example, than that of Er/Yb and Yb fibers, allowing for higher peak powers to be achieved. The reason for this is twofold. First, 1/λ scaling of the nonlinearity provides for reduced nonlinearity. Second, the mode area is larger in Tm than in Er/Yb and Yb for the same core size.
Thulium is also advantageous because the gain bandwidth of Tm fiber is about 100-300 nm and broader allowing to support sub-100 fs pulse amplification and/or tunable pulses. Tm-doped fiber has a high dispersion that may be about −20 to −100 ps2/km (anomalous). Such dispersion is about 2-4 times larger than that of typical Er/Yb fibers.
The quantum defect of Tm fiber pumped at about 790 nm and operating at about 2 μm is about 60%, much higher than that of Yb and Er fibers operating at about 1.1 μm and 1.5 μm, respectively, and pumped at 980 nm. However, utilizing cross-relaxation and energy transfer processes in heavily-doped Tm fibers, quantum efficiencies exceeding 100% may be achieved. See, for example, S. Jackson, Opt. Comm. 230 (2004) pp. 197-203. Hence, Tm doped silica fiber amplifiers can be efficient, with the efficiency performance approaching that of Yb and Er doped fibers.
In certain embodiments, the amplifier 105 is end-pumped with the output from a laser diode bar (not shown). Other configurations are possible. For example, similar pumping arrangements as described above for the Er fiber laser 101 can be also used for pumping Tm-doped fiber as well.
In certain embodiments, the Tm-doped fiber amplifier 105 is pumped at about 790 nm. Other pumping wavelengths, e.g., at about 1.1 μm and 1.5 can be used. Dual-wavelength pumping schemes (see, e.g., Gomes et al, Optics Letters, vol. 28, 2003, pp. 334-336, which is incorporated herein by reference in its entirety) involving two optical pumps at two different wavelengths can also be used to pump the Tm-doped fiber amplifier 105. The Tm fiber amplifier can also be co-doped with Yb in order to allow pumping at wavelength between 900-1050 nm.
In the embodiment shown in
At repetition rates of about 50-200 MHz, the pulses input to the amplifier 105 are stretched up to a few picoseconds to stay below the peak power limit to produce compressible amplified pulses. In various preferred embodiments, for example, the pulses output by the stretcher and input into the amplifier are between about 1 and 10 picoseconds in durations. The length of the stretcher fiber 104 is chosen to provide adequate dispersion for stretching the pulses input to the amplifier 105. The dispersion of the Tm-fiber (between about −80×10−3 ps2 and −300×10−3 ps2) is also to be factored into the overall system dispersion design to produce nearly bandwidth limited pulses at the output of the system. The elements affecting the system dispersion as described here are the stretcher fiber 104, coupling and mode-conversion optics, optional isolator(s), Tm fiber and any other transmission fiber as part of elements 104 and 105.
Fiber lasers and amplifiers are susceptible to optical feedback, so appropriate isolators (not shown) can be inserted between the oscillator and the fiber amplifier as well as between the amplifiers if more than one amplifier is used. In the embodiment shown in
Another advantage of seeding the Tm amplifier 105 with the Raman-shifted Er oscillator 101 is that the Raman shifted pulses are “clean.” For example, these pulses have a smooth spectral profile, without ripple. Such clean pulses can be amplified to higher energies before nonlinear effects in the amplifier 105 substantially deteriorate the amplified pulse quality (e.g., through self-phase-modulation).
The output of the Tm amplifier 105 is coupled to the chirped QPM frequency doubler 108 with the lens arrangement represented in
The chirped quasi-phase matched (QPM) frequency doubler 108 combines the functions of pulse compression and frequency doubling; (see, e.g., U.S. Pat. No. 5,867,304 entitled “Use of Aperiodic Quasi-phase-matched Gratings in Ultrashort Pulse Sources” issued to Galvanauskas et al. as well as U.S. Pat. No. 6,198,568 entitled “Use of Chirped Quasi-phase-matched Materials in Chirped Pulse Amplification,” issued to Galvanauskas et al., both of which are incorporated herein by reference.) The chirped QPM frequency doubler 108 shown in
In certain preferred embodiments, the chirp of the QPM frequency doubler 108 is such that the frequency doubler produces nearly bandwidth limited frequency doubled pulses. The bandwidth of the pulses may be, for example, between about 5 to 30 nm. In some embodiments, the chirp compensates any chirp accumulated prior to the frequency doubling stage. This accumulate chirp may include chirp due to fiber dispersion as well as due to self-phase-modulation (SPM) in the fiber amplifier(s). Accordingly, with smooth pulses as described here, the higher-order chirp due to SPM can be compensated as well with the appropriate nonlinearly-chirped QPM frequency doubler 108 to produce transform-limited or nearly transform-limited frequency-doubled pulses. If the pulse length generated in the continuum fiber 210, e.g., in
In various exemplary embodiment, the optical pulses at the output of the laser 101 may have a bandwidth between about 2 and 40 nm and a pulse duration of between about 30 and 500 femtoseconds in some embodiments. The optical pulses output from the Er-doped fiber amplifier 102 may be substantially bandwidth limited and may have a duration of between about 30 and 500 fs in some embodiments. The optical pulses output from the Raman shifter 103 may have a bandwidth of about 20-50 nm and the pulses are nearly-transform-limited with pulse lengths of 30 to 400 femtosecond (fs). The optical pulses output from the fiber stretcher 104 have a bandwidth of about 10-50 nm and the pulses are substantially stretched to pulse lengths of 1 to 15 picosecond. The optical pulses output from the Tm amplifier 105 have a bandwidth of about 10-50 nm and the pulses are substantially stretched to pulse lengths of 1 to 10 picosecond. The optical pulses output from the chirped QPM frequency doubler 108 have a bandwidth of about 5-50 nm and the pulses are nearly-transform-limited with pulse lengths of 30 to 200 femtosecond (fs). In some embodiments, the pulse may be compressed to less than or equal to 10 times the bandwidth limit, 3 times the bandwidth limit or 2 times the bandwidth limit. Values outside these ranges are also possible.
The chirped QPM doubler 108 may comprise a lithium niobate substrate. Optionally, other QPM materials can be used.
The small signal conversion efficiency in chirped PPLN assuming confocal focusing is about 100%/nJ×τc/τs, where τc and τs are the compressed and stretched pulse lengths, respectively (see, e.g., Imeshev et al., JOSA B, vol. 17, 2000, pp. 304-318). Assuming (conservatively) about 25 kW peak power of the amplified pulses, a stretched pulse length of about 8.5 ps, and a compressed pulse length of about 100 fs, the pulse energy output from the amplifier 105 is about 200 nJ. Accordingly, the small-signal doubling efficiency of chirped PPLN is about 1%/nJ which means that the conversion would be overdriven with about 200 nJ input pulses if confocal focusing is used. Overdriving the nonlinear conversion leads to back conversion limitations on the efficiency (see, e.g., Eimerl, IEEE JQE vol. 23, 1987, pp. 1361-1371, which is incorporate herein by reference in its entirety) and ultimately pulse quality deteriorations. Hence to achieve high quality frequency doubled pulses with overall conversion efficiency in the range about 25-50% and more, somewhat looser than confocal focusing may be used. With this approach, frequency converted pulses with pulse energies of about 50-100 nJ and average powers of about 250-1000 mW are generated.
Optionally, frequency-selective filter(s) can be used at the output of the system to separate frequency-doubled pulses from the remaining unconverted pulses. Particularly, if the embodiment shown in
The overall system tunability is achieved by changing the gain of the Er amplifier 102 and hence the pulse energy input to the Raman shifter 103. The phase-mating condition of the doubling crystal 108 is also appropriately adjusted. The latter can be done with temperature, angle-tuning and/or transverse translation of the QPM crystal 108. Discrete tuning with multi-grating QPM crystals is also possible. Continuous tuning with uniform-period PPLN gratings can be achieved with a fan-out grating arrangement; see, e.g., U.S. Pat. No. 6,359,914 entitled “Tunable Pulsed Narrow Bandwidth Light Source,” issued to Powers et al, which is incorporated by reference in its entirety. Continuously-tunable chirp is also possible; see, e.g., A. M. Schober, G. Imeshev, M. M. Fejer, “Tunable-chirp pulse compression in quasi-phase-matched second-harmonic generation” Optics Letters, Vol. 27, Issue 13, Page 1129, July 2002, which is also incorporated herein by reference in its entirety. In some embodiments, a suitably designed fan-out structure can be used to provide continuous period tuning of a chirped QPM grating. Alternatively, an appropriately designed fan-out structure can be used to provide continuous tuning of both period and chirp of a chirped QPM grating.
Alternatively, if the pulses are not stretched to the maximum practical group delay limit of the chirped QPM doubler 108 (for example, to about 8.5 ps for a chirped PPLN about 5 cm long, as discussed above), the tunability can be built into the chirped QPM doubler. For example, the chirped QPM doubler 108 can provide the necessary chirp for pulse compression but have the acceptance bandwidth exceeding that of the pulses. For example, if the stretched pulse length is about 3 ps and the pulse bandwidth is about 30 nm, the chirp that the QPM doubler 108 needs to supply is about 0.1 ps/nm and the corresponding crystal length is about 1.8 cm. Fabricating the QPM doubler 108 with the same chirp of 0.1 ps/nm, however, with a length of about 5 cm will provide the acceptance bandwidth of about 83 nm.
For some applications like two-photon microscopy, it is advantageous to have the laser system that can operate at high average powers (greater than about 500-1000 mW), with high repetition rates (greater than about 100-300 MHz), but with moderate pulse energies of few nanojoules (greater than about 2 nJ) to avoid damage to the sample. Obtaining such repetition rates from an environmentally stable and robust Er-doped fiber oscillator 101 can be difficult. To scale up the repetition rate from an environmentally stable Er-doped fiber oscillator 101 and provide average power, a time-division-multiplexing approach, as illustrated in
Such an arrangement can be cascaded to multiply the repetition rate by 4×, 8×, etc. With such cascaded arrangements, the insertion loss is also about 3 dB or slightly more because of the insertion loss of the components used and non-ideal splices. Alternatively, instead of the 50/50 splitters, 1×N splitters can be used to multiply the repetition rate by N. Such fused fiber coupler components are readily available. In certain embodiments, integrated optical waveguide couplers can be formed on planar substrates or other platforms that support lightwave circuits.
For applications requiring compressed pulses with pulse energies of few nano-Joules at a wavelength of about 2 μm, a particularly compact system can be constructed as shown in
In one embodiment, the Tm-doped amplifier fiber 105 has a substantial dispersion of about −85 ps2/km, so that approximately 2.5 meters of this fiber introduces a substantial group delay of about 2-3 ps across the bandwidth output from the Raman shifter 103. If the length of the fiber stretcher 104 is selected appropriately to provide dispersion approximately opposite to the dispersion of the Tm fiber amplifier, the ˜100 fs pulses injected to the fiber stretcher will be negatively stretched to about 2-3 ps after the fiber stretcher 104 and then amplified and simultaneously compressed close to about 100 fs in the Tm-doped fiber amplifier 105. To provide normal dispersion, a small core (large NA) fiber may be used as a fiber stretcher 104. Alternatively, a linearly- or nonlinearly-chirped FBG can be used in place of the fiber stretcher 104 as described above. Other designs are possible. The dispersion of the Tm-doped amplifier fiber 105 may, for example, range between about −80×10−3 ps2 and −300×10−3 ps2 in other embodiments. In certain embodiments, the dispersion of the stretcher is substantially equal (within about 90%) and opposite to the dispersion of the Tm-doped amplifiers so as to reduce the net dispersion and produce substantially bandwidth limited optical pulses. Accordingly, the dispersion of the stretcher may be between about −80×10−3 ps2 and −300×10−3 ps2 in certain embodiments. As described above, in some embodiments, the pulse may be compressed to less than or equal to 10 times the bandwidth limit, 3 times the bandwidth limit or 2 times the bandwidth limit. Values outside these ranges are also possible.
The arrangement shown in
In an exemplary embodiment, the fiber stretcher 104 comprises a length of silica fiber of about 140 cm with a numerical aperture (NA) of about 0.35 providing anomalous dispersion at about 1994 nm so that the pulses output from the fiber stretcher 104 have a pulse length of about 2.5 ps. The Tm amplifier 105 comprises a Tm-doped fiber having a length of about 2.5 meters and a core diameter of about 25 μm. The Tm amplifier 105 is end-pumped with up to about 26 W (coupled) power from the output of a fiber-coupled diode bar at about 790 nm. When seeded with between about 10-30 mW average power at about 1994 nm from the fiber stretcher 104, the amplifier 105 produces up to about 1.8 W average power at about 100 MHz repetition rate (about 18 nJ pulse energy), as shown in
Hence the system shown in
Further, operating the system in the regime where substantial spectral compression occurs in the Tm amplifier fiber 105 allows for even higher peak powers to be achieved. See, for example, U.S. Patent publication 2005-0041702 A1 entitled “High Energy Optical Fiber Amplifier for Picosecond-nanosecond Pulses for Advance Material Processing Applications,” which is incorporated herein by reference in its entirety. Spectral compression induces a decrease in signal bandwidth in the presence of self-phase modulation. For spectral compression to be effective in a Tm amplifier fiber 105 operating in the negative dispersion regime, negatively chirped pulses can be injected into the Tm fiber. In the configuration in
Moreover, in the 2 μm wavelength range, the peak Raman gain wavelength is red-shifted by nearly 200 nm from the peak of any signal wavelength amplified in Tm fiber. Hence, any Raman signal will have much less gain in Tm amplifier and more passive transmission loss that in general increases for longer wavelengths. Accordingly, stimulated Raman scattering can be effectively suppressed even in the presence of large peak power signals. Using spectral compression narrow band optical signals (with a bandwidth of about 0.1-20 nm) with peak power levels in excess of about 100 kW can thus be generated for pulses with a width of about 100 fs-1 ns.
Optionally, the output from the apparatus shown in
The output of the Tm amplifier 105 is coupled to the frequency doubler 108 with the lens arrangement represented in
The fiber stretcher 104 may or may not produce bandwidth limited pulses, for example, pulse lengths can range from about 1 ps to 1000 ps. Optionally, for example, if the embodiment shown in
In some embodiments, the frequency doubler 108 is implemented with PPLN whose length and QPM period are chosen to satisfy the phase-matching conditions for the conversion of the amplified pulses. Other QPM materials can also be used. Optionally, birefringently-phase-matched materials can be used. For pulses output from the amplifier 105 having lengths of about 100-200 fs and energies exceeding about 5-10 nJ, the doubling efficiency of about 25-50% can be obtained but is not limited to these ranges.
In one exemplary embodiment, up to about 1.8 W average power is obtained from the Tm amplifier 105, as discussed earlier for the embodiment shown in
Hence, the system shown in
The overall tunability of the system shown in
In an exemplary embodiment such as shown in
To produce compressed (e.g., bandwidth limited or nearly-bandwidth limited) tunable pulses with pulse energies exceeding about 200 nJ at about 2 μm wavelength from the Tm amplifier 105 and pulse energies exceeding about 100 nJ at about 1 μm wavelength from the QPM frequency doubler 108, the pulses input to the Tm amplifier 105 can be stretched to longer than about 5-20 ps to stay below the peak power limit of the amplifier. Compressing such long chirped pulses with a chirped QPM compressor, however, may be beyond the group delay limit available from a crystal of practical length. An exemplary embodiment for generation such compressed pulses output from the frequency doubler 108 at about 1 μm with pulse energies exceeding about 100 nJ is shown in
An optional pulse picker 110 is also inserted in the system shown in
In certain embodiments, the length of the fiber stretcher 104 is chosen to stretch pulses to pulse lengths greater than about 5 ps, and possible greater than about 20 ps. Values outside these ranges are possible. Alternatively, a linearly- or nonlinearly-chirped FBG can be used in place of the fiber stretcher 104 as described above.
To compensate for an additional insertion loss of the pulse picker and to increase the average power input to the Tm amplifier 105, an optional Tm-doped fiber pre-amplifier 111 may be disposed in the system before the amplifier 105 as shown in
In one embodiment, the pre-amplifier 111 is pumped by power not absorbed in the amplifier 105. Optionally, a small portion of light used for pumping amplifier 105 is split before the amplifier 105 and used to pump the pre-amplifier 111. In other embodiments, a separate pump source can be used to pump the pre-amplifier 111. The pre-amplifier 111 may be cladding pumped through the side of the fiber; see., e.g., L. Goldberg et al., Optics Letters, 24, 673 (1999), which is incorporated herein by reference in its entirety. Optionally, the pre-amplifier 111 comprises single-mode fiber core-pumped with a single-mode fiber-coupled laser diode. Dual-wavelength pumping schemes can also be used to pump the pre-amplifier 111, see, e.g., Gomes et al, Optics Letters, vol. 28, 2003, pp. 334-336, which is incorporated herein by reference in its entirety. Other configurations are possible as well.
The stretched amplified pulses output from the amplifier 105 are directed to the pulse compressor 112 which may a bulk diffraction grating arrangement with the optics suitable for operation at about 2 μm wavelength. Other pulse compressor designs may also be used. For example, a very compact compressor can be build using a bulk piece of dispersive material; see, e.g., U.S. Pat. No. 6,272,156, entitled “Apparatus for Ultrashort Pulse Transportation and Delivery,” issued to Reed et al, which is incorporated herein by reference in its entirety. Traversing light through such piece of material in a zigzag fashion allows accumulation of up to several picoseconds of group delay.
In certain embodiments, to achieve compressed pulses at about 2 μm wavelength with energies approaching 1 μJ and higher, pulses are stretched to about 10 ps-1 ns to stay below the peak power limit of the Tm amplifier 105. For such large stretching ratios, the third- and higher-order dispersion terms of the bulk grating compressor become non-negligible and may not be successfully compensated for with simple fiber stretchers or linearly-chirped fiber Bragg gratings resulting in compressed pulse quality deterioration. A nonlinearly-chirped FBGs, however, can be designed appropriately to compensate for third- and higher-order dispersion in the system, which can be used to achieve nearly bandwidth-limited pulses at the output of the compressor. See U.S. patent application Ser. No. 10/608,233, published as U.S. Patent Publication 2004/0263950, which is hereby incorporated herein by reference in its entirety.
A particularly compact compressor can be built using photonic bandgap fiber; see U.S. Provisional Patent Application No. 60/539,110, which is incorporated herein by reference in its entirety. Using photonic bandgap fiber as the compressor 112 (e.g., properly fabricated to have the bandgap at about 2 μm wavelength), a pulse energy exceeding about 100 nJ can be achieved at about 2 μm wavelength. Because the dispersion of such photonic bandgap fibers has large contributions of third- and higher-order terms, a dispersion tailored nonlinearly-chirped fiber grating may be used for stretching the pulses prior to amplification to obtain compressed pulses close to the bandwidth limit.
Alternatively, the compressor 112 can be implemented with a volume Bragg grating; see, e.g., U.S. Pat. No. 5,499,134, the contents of which are incorporated here by reference in their entirety. Still other configurations and designs not specifically recited herein are also possible.
The output of the pulse compressor 112 is coupled to the doubling crystal 108. Instead of the doubling crystal, any other nonlinear crystal may be incorporated as previously described with respect to
The overall system tunability as described with reference to
For example, in case where the compressor 112 is implemented using a bulk diffraction grating arrangement and the pulses are stretched to shorter than about 100 ps, the diffraction grating angle can be adjusted to achieve tunable outputs. In case the compressor 112 is implemented with a bulk diffraction grating arrangement and the pulses are stretched to longer than about 100 ps, the relative magnitude of second- and higher-order dispersion may change substantially when the wavelength is tuned over a broad band and the diffraction grating angle is adjusted accordingly. To somewhat compensate for such changes, the nonlinearly-chirped FBG 104 can be adjusted either by changing its temperature or by stretching.
In case the compressor 112 is implemented with the arrangement based on photonic bandgap fiber, the relative magnitude of second- and higher-order dispersion may change substantially when the wavelength is tuned over a broad band. To somewhat compensate for such changes, the nonlinearly-chirped FBG 104 can be adjusted either by changing its temperature or by stretching. Other approaches may also be employed for tuning.
Optionally, if the embodiment shown in
Optionally, if the compressed pulses with pulse energies greater than about 200 nJ are desired at about 2 the doubling crystal 108, lenses 107 and 109 can be omitted from the embodiment shown in
An alternative embodiment for generation of compressed pulses at about 1 μm wavelength with pulse energies exceeding about 100 nJ is shown in
Alternatively, in the embodiments shown in
A limitation with Tm fiber amplifiers is a possibility of cross relaxation; see, e.g., S. Jackson, Opt. Comm. 230 (2004) pp. 197-203, which is incorporated herein by reference in its entirety. Though cross relaxation can enable the construction of ultra-efficient Tm fiber lasers, cross relaxations can reduce the amount of achievable gain in Tm amplifiers and greatly reduce the efficiency of the amplifier. Because of the relatively strong absorption of the signal light in silica Tm amplifiers near 2 μm, the low gain of Tm amplifiers cannot be compensated by an increase in Tm amplifier length. In order to overcome the efficiency limitations of Tm amplifiers in the presence of cross relaxations, double-pass Tm amplifiers can thus be implemented, so that the input signal coupled through the same side of the fiber as the pump experiences gain during the first pass. Such double pass Tm amplifiers can be implemented, for example, in conjunction with the embodiments shown in
The construction of double-pass amplifiers is straightforward and can comprise the combination of a length of Tm amplifier with a Faraday rotator mirror and a polarization beam splitter. In an exemplary implementation, light is passed through the polarization beam splitter, coupled into the Tm amplifier and amplified, reflected by the Faraday rotator mirror, amplified again by the Tm amplifier and eventually extracted with its polarization state rotated by 90° by the polarization beam splitter. Alternatively, a non-polarization rotating mirror can be implemented and the polarization state can be rotated by 90° by adjusting the polarization state in the Tm amplifier by appropriate polarization controllers or additional waveplates inserted into the beam path anywhere between the polarization beam splitter and mirror. Equally, more than two passes can be implemented through such low gain Tm amplifiers using additional Faraday rotators, polarization beam splitters and polarization manipulating waveplates.
Instead of the Raman-shifted Er fiber laser seeder block 100 shown, for example, in
Referring back to
An alternative embodiment of the ultra broadband OPA that relies on the fiber gain at the OPA pump wavelength is shown in
As described above, in this exemplified embodiment, the fiber laser 101 may comprise an Er gain fiber. Alternatively, the fiber laser may comprise other sources such as Yb gain fiber; see, e.g., U.S. Patent Application 60/519,447 which is incorporated herein by reference in its entirety. In certain embodiments, the continuum is broad enough to provide a short-wavelength seed for the amplifier 230 and a long-wavelength part to be amplified in the OPA 260. The beam splitter 220 may comprise a fused fiber wavelength-division-multiplexing (WDM) coupler. Alternatively, bulk short- or long-pass dielectric filters can be used, either in a fiber-coupled arrangement or incorporating separate bulk optics to couple light in and out of the fibers.
The fiber amplifier 230 can be implemented in a single- or multiple-stage arrangement. The gain fiber may comprise single-mode small core or large-mode-area (LMA) fiber configured to obtain predominantly fundamental mode output; see, e.g., U.S. Pat. No. 5,627,848 issued to Fermann et al. entitled “Apparatus for producing femtosecond and picosecond pulses from mode-locked fiber lasers cladding pumped with broad area diode laser arrays,” which is incorporated herein by reference in its entirety. Alternatively, a LMA microstructured (holey) fiber can be used. The amplifier may comprise polarization-maintaining (PM) fiber. Alternatively, non-PM fiber can be used in a single-pass arrangement or in a double-pass configuration with a Faraday rotator mirror and a polarizing beam splitter. Optionally, the amplifier is preceded by polarization control elements such as bulk waveplates or their fiberoptic counterparts to facilitate coupling along a principal axis of the amplifier. The amplifier may be followed by polarization control elements such as bulk waveplates or their fiberoptic counterparts to prepare the polarization state appropriate for pumping the OPA.
In the exemplified embodiment where the OPA 260 comprises PPLN or other QPM nonlinear crystal that is to be pumped at about 930-970 nm to achieve the ultra broad OPA bandwidth, the fiber amplifier 230 may comprise a Nd-doped fiber utilizing a depressed cladding fiber design to avoid competition with the stronger 1060-1090 nm gain band.
Optionally, fiber amplifier 230 can be setup in a chirped pulse amplification (CPA) arrangement, incorporating a stretcher before the amplifier(s) and an optional compressor afterwards. The stretcher can be implemented with a length of transmission fiber or an FBG, as discussed above, for example, with reference to
In certain embodiments, the amplifier 230 can incorporate a band-pass filter at the input to further narrow the spectrum after the beam splitter 220. Other types of amplifiers and other configurations and designs are also possible.
An arrangement with a system using two sets of nonlinear fibers 210, 210 for continuum generation and amplification is shown in
In certain embodiments, the beam splitter 220 is predominantly non-wavelength selective across the bandwidth produced by the fiber laser 101. This beam splitter 220 may comprise a fused fiber coupler. Alternatively, bulk dielectric or metal-coated filters can be used for this purpose, either in a fiber-coupled arrangement or incorporating separate bulk optics to couple light in and out of the fibers.
Many of the element 101, 210, 230, 240, 250, 260 and 270 are described above in connection with
Optionally, more continuum fibers may be used in addition to 210 and/or 212 can be used to produce continuum. Additional continuum fibers enable separate tailoring or optimization, e.g., portions of the continuum for amplification in the OPA as well as the anti-Stokes part of the continuum used for seeding the amplifier 230.
Embodiments for the ultra broad bandwidth OPA described above allow appreciable parametric gains to be achieved with modest pump pulse energies, e.g., of about 10-200 nJ. Additionally, the OPA can also be pumped at specific wavelengths as dictated by the dispersive properties of the QPM crystals used for OPA. Chirped QPM crystals can also be used to engineer the OPA bandwidth; see, e.g., U.S. Pat. No. 6,208,458 “Quasi-phase-matched Parametric Chirped Pulse Amplification Systems,” issued to Galvanauskas, which is incorporated herein by reference in its entirety. For example, a chirped QPM crystal can be fabricated to provide an OPA bandwidth in excess of about 300 nm, for any pump wavelength, not limited by the intrinsic material dispersion. Compared to the uniform-grating QPM crystals, the use of chirped QPM crystals may utilize substantially higher pulse energies to achieve comparable parametric gains. These energy levels, however, are comparable or lower than the pulse energies required for pumping the ultra broadband OPA in BBO. Additionally, BBO needs to be pumped at a specific wavelength dictated by the dispersive properties.
In the embodiments described above, e.g., in reference to
As was discussed above, the use of QPM nonlinear materials for OPA generally allows for high parametric gains, exceeding 80 dB, when pumped by even low to moderate energy pulses (sub-nanojoules to tens of nanojoules) as available for example from fiber-based laser systems. Such high gains are enough to amplify quantum noise at the input of the optical parametric amplification (OPA) to macroscopic intensities, leading to optical parametric generation (OPG); see, e.g., A. Galvanauskas, M. A. Arbore, M. M. Fejer, M. E. Fermann, and D. Harter, “Fiber-laser-based femtosecond parametric generator in bulk periodically poled LiNbO3” Optics Letters 22, (1997) p. 105-107, which is incorporated herein by reference in its entirety. The use of OPG in QPM materials when pumped by short pulses form a fiber-based system allows for a particularly compact source of ultra broadband pulses with pulse lengths comparable to that of the pump.
Optical Parametric GenerationUltrabroadband OPA based on QPM materials as discussed herein, can also be used in the OPG configuration, i.e. using quantum noise as a seed for the ultra broadband OPA. As described above, the use of short optical pulses obtained from a fiber-based laser system for pumping such ultra broadband OPG allows for a particularly compact ultra broadband source.
Details regarding the fiber laser 101, amplifier 230, and optical parametric generator 260 are described above. When using a suitable active fiber media for producing pump pulses at the wavelengths satisfying the ultra broadband OPG conditions or when the chirped QPM crystal is used for OPG, the system is particularly compact. Other configurations are also possible.
The continuum is broad enough to provide adequate spectral intensity for seeding the amplifier 230 at the wavelength useful for pumping the ultra broadband OPG. Either the long- or a short-wavelength part of the continuum can be used for seeding the amplifier 230, depending on the wavelength of the fiber laser 101 relative to the wavelength required for pumping the ultra broadband OPG.
In certain embodiments, for example, the fiber laser 101 outputs optical pulses at about 1.55 μm, which are coupled into the continuum fiber 210. The continuum fiber 210 produces long and short wavelengths parts. The short wavelength part, referred to as the anti-Stokes wavelength at about 950 nm, is used to seed the fiber amplifier 230. Accordingly, these optical pulses at 950 nm are amplified and optically coupled into the QPM crystal 260 for pumping the OPG process.
Additional details regarding the fiber laser 101, continuum fiber 210, fiber amplifier 230, and QPM crystal 260 are described above. Other configuration may also be used.
As shown in
In certain embodiments, the fiber laser outputs optical pulses having a wavelength of 1.5 μm. These optical pulse are coupled into the Raman soliton fiber up shifts the wavelength of the optical pulses to about 2.0 μm. These optical pulses having wavelengths of about 2.0 μm seed the fiber amplifier 230 and are amplified. The amplified pulses are directed into the SHG frequency doubler 108, which outputs optical pulses having a wavelength of about 950 μm. These optical pulses at about 950 μm are directed into the QPM crystal for pumping the OPG process. Other designs and configurations are also possible.
Laser systems producing ultrashort optical pulses with high pulse energies are useful for a wide variety of applications. For example, fiber lasers and amplifiers are promising candidates for ultrafast pulse sources for advanced industrial applications due to their unique simplicity of construction. Other uses are possible. A wide variety of embodiments described herein may be advantageously employed in such applications.
Embodiments described herein include a system for producing ultrashort tunable pulses based on ultra broadband OPA or OPG in nonlinear materials. In some embodiments, these nonlinear materials are periodically poled. To achieve ultra broadband OPA or OPG, the system parameters such as nonlinear material, pump wavelengths, QPM periods and temperatures can be selected appropriately to utilize the intrinsic dispersion relations for such material. As described above, in certain embodiments low-energy seed pulses to the ultra broadband OPA or OPG can be obtained from continuum generated in highly nonlinear fiber in a fiber-based laser system. Moderate pulse energy pump pulses having, for example, about 500 nJ or less, possibly 100 nJ or less, for the OPA or OPG can be obtained from a fiber-based laser source. The pulse energies for pumping the OPA or OPG can further be lowered by the use of nonlinear waveguide materials. Chirped QPM devices can also be employed to achieve ultra broadband OPA or OPG. Pulses compression may result in the output of pulses from the system that are compressed to about 10 times or less than the bandwidth limit, about 3 times or less than the bandwidth limit, or about 2 times or less than the bandwidth limit.
In certain embodiments, compact high average power sources of short optical pulses tunable in the wavelength range of about 1800-2100 nm and after frequency doubling in the wavelength range of approximately 900-1050 nm can be used as a pump for the ultra broadband OPA or OPG. These sources, however, are also useful for a variety of applications, including but not limited to micromachining, spectroscopy, nonlinear frequency conversion and two-photon microscopy. For two-photon microscopy applications, short optical pulses at about 960 nm are of particular interest because a number of fluorophores have been developed for this range, see for example Chen and Periasamy, Microscopy Research and Technique vol. 63, pp. 72-80, 2004, which is incorporated herein by reference in its entirety. In embodiments of the invention, the system is based on fiber technology allowing for compact and robust implementation as is advantageous for, e.g., industrial applications.
In certain embodiments, the short optical pulses are obtained from an Er fiber oscillator at about 1550 nm, amplified in an Er fiber, Raman-shifted to about 1800 to 2100 nm, stretched in a fiber stretcher, and amplified in a Tm-doped fiber. To produce short pulses in the approximately 900 to 1050 nm wavelength range, the pulses are frequency-doubled with a chirped QPM doubler for nearly bandwidth-limited output. Tunability is achieved by changing the pulse energy input to the Raman-shifter fiber and adjusting the phase-matching conditions in the frequency doubling crystal.
The efficiency of Tm amplifiers can be increased or optimized by employing double pass or multi-pass amplification through the Tm amplifiers. Multi-pass Tm amplifiers are particularly useful for increasing the efficiency of Tm amplifiers in the presence of cross relations. In various embodiments, instead of the Raman-shifted Er fiber laser, a Tm mode-locked fiber laser (oscillator-only or master-oscillator-power-amplifier configurations) can be used for seeding the Tm fiber amplifier.
In certain embodiments, the average power may be increased using a high repetition rate fiber oscillator and further time-division multiplexing the pulses to achieve even higher repetition rate operation. Compact laser systems utilizing pulse compression in the Tm amplifier fiber are also possible. A chirped pulse amplification system can be implemented based on compression with a bulk compressor and optional frequency doubling. Compact chirped pulse amplification system may be implemented with pulse stretching before the Tm amplifier and with a nonlinearly-chirped fiber grating and compression with a photonic bandgap fiber compressor before or after the optional frequency doubling stage.
Such short-pulse systems based on amplification in Tm fibers can be used for gas sensing, two-photon microscopy and micro-machining. In addition, such short-pulse systems based on amplification in Tm fibers can be employed for nonlinear frequency conversion like harmonic generation, wide bandwidth optical parametric generation, and other nonlinear processes with QPM materials. Other applications are possible.
While the above detailed description has shown, described, and pointed out novel features of the invention as applied to various embodiments, it will be understood that various omissions, substitutions, and changes in the form and details of the structures or methods illustrated may be made by those skilled in the art without departing from the spirit of the invention. A wide range of design, configurations, arrangements and uses are possible. As will be recognized, the present invention may be embodied within a form that does not provide all of the features and benefits set forth herein, as some features may be used or practiced separately from others.
Claims
1. An optical pulse source comprising:
- a fiber based laser system comprising a seed laser configured to emit optical seed pulses;
- a pulse stretcher configured to stretch said seed pulses;
- a Tm fiber amplifier configured to amplify said stretched optical pulses, said Tm fiber amplifier comprising at least one doped fiber containing Tm;
- a pulse compressor disposed downstream from said at least one Tm fiber amplifier and arranged to compress pulses produced by said Tm fiber amplifier; and
- an output port configured to output optical pulses compressed with said pulse compressor.
2. The optical pulse source according to claim 1, wherein said seed laser comprises an Er laser.
3. The optical pulse source according to claim 1, wherein said seed laser comprises a mode-locked Er fiber oscillator.
4. The optical pulse source according to claim 3, wherein said fiber based laser system comprises a Raman shifter configured to generate Raman scattering within said fiber based laser system to shift a wavelength of a pulse generated with said mode-locked Er fiber oscillator to a longer wavelength in a range extending from about 1600 nm to about 2200 nanometers.
5. The optical pulse source according to claim 1, wherein said output optical pulses have wavelengths in a range from about 1600 nm to about 2200 nm and at least partially overlap with wavelengths of a Tm or Ho fiber gain spectrum.
6. The optical pulse source according to claim 1, wherein said Tm fiber amplifier operates at a laser wavelength of about 2 μm and has a gain-bandwidth of about 100 nm to 300 nm.
7. The optical pulse source according to claim 1, wherein said fiber based laser system is configured to generate frequency components via spectral broadening, said frequency components at least partially overlapping with a Tm or Ho fiber gain spectrum.
8. The optical pulse source according to claim 1, further comprising one or more nonlinear crystals for frequency conversion.
9. The optical pulse source according to claim 8, wherein said frequency conversion comprises frequency doubling.
10. The optical pulse source according to claim 8, wherein said one or more nonlinear crystals comprise periodically poled lithium-niobate, periodically poled KTP, periodically-twinned Quartz, periodically poled RTA, periodically poled lithium tantalate, periodically poled potassium niobate, or orientation patterned GaAs.
11. The optical pulse source according to claim 1, wherein said pulse compressor comprises a bulk grating compressor, a Bragg grating compressor, a large mode fiber, or a photonic crystal fiber compressor.
12. The optical pulse source according to claim 1, wherein said pulse compressor comprises a first nonlinear crystal, said first nonlinear crystal being periodically poled and chirped so as to substantially frequency double the optical pulses amplified by said Tm fiber amplifier.
13. The optical pulse source according to claim 1, wherein said Tm fiber amplifier is core pumped or cladding pumped.
14. An optical pulse source comprising:
- a fiber based laser system comprising a seed laser configured to emit optical seed pulses, said seed pulses emitted at a laser wavelength of about 2 μm;
- a pulse stretcher configured to stretch said optical seed pulses;
- a fiber amplifier configured to amplify said stretched optical seed pulses;
- a pulse compressor disposed downstream from said fiber amplifier and arranged to compress pulses produced by said fiber amplifier; and
- an output port configured to output optical pulses compressed with said pulse compressor,
- wherein said optical pulses output from said output port have a pulse width of about 1 nanosecond or less and have an output wavelength extending from about 1800 nanometers to about 2100 nanometers.
15. The optical pulse source according to claim 14, wherein said fiber amplifier comprises at least one fiber doped with Tm.
16. The optical pulse source according to claim 14, wherein said fiber amplifier comprises at least one fiber doped with Ho.
17. (canceled)
18. (canceled)
19. (canceled)
20. (canceled)
21. (canceled)
22. (canceled)
23. An optical pulse source comprising:
- a fiber based laser system comprising a seed laser configured to emit optical seed pulses;
- a positive dispersion pulse stretcher configured to stretch said seed pulses;
- a Tm fiber amplifier configured to amplify said stretched optical pulses, said Tm fiber amplifier comprising at least one doped fiber containing Tm;
- a dispersive pulse compressor arranged to compress pulses amplified by said Tm fiber amplifier, wherein said dispersive pulse compressor is configured to produce negative dispersion, and wherein said dispersive pulse compression occurs in either the Tm fiber amplifier or an additional negative dispersion fiber located downstream of said Tm fiber amplifier; and
- an output port configured to output optical pulses compressed with said dispersive pulse compressor.
24. The optical pulse source according to claim 23, further comprising an optical modulator configured as a pulse picker, said modulator disposed downstream from said seed laser.
Type: Application
Filed: Jun 24, 2015
Publication Date: Mar 3, 2016
Inventors: Gennady Imeshev (Irvine, CA), Martin E. Fermann (Dexter, MI)
Application Number: 14/749,330