Abstract
This paper presents short wavelength operation of tunable thulium-doped mode-locked lasers with sweep ranges of 1702 to 1764 nm and 1788 to 1831 nm. This operation is realized by a combination of the partial amplified spontaneous emission suppression method, the bidirectional pumping mechanism and the nonlinear polarization rotation (NPR) technique. Lasing at emission bands lower than the 1800 nm wavelength in thulium-doped fiber lasers is achieved using mode confinement loss in a specially designed photonic crystal fiber (PCF). The enlargement of the first outer ring air holes around the core region of the PCF attenuates emissions above the cut-off wavelength and dominates the active region. This amplified spontaneous emission (ASE) suppression using our presented PCF is applied to a mode-locked laser cavity and is demonstrated to be a simple and compact solution to widely tunable all-fiber lasers.
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Introduction
Interest in fiber lasers emitting in the wavelength range of 1700 to 2100 nm has been escalating in recent fiber laser related research. This eye-safe1 wavelength region has various applications, such as light detection and ranging (LIDAR) systems2, biomedical science3, optical sensing4, and industrial machining5. This attention is also related to the exploration of promising transmission capacity beyond the conventional 1550 nm region6. Recent studies focused on achieving optimum signal transmission in the range of 1700 to 1900 nm. For such a case, hollow-core photonics band-gap fibers (HC-PBGFs) are proposed7,8. These fibers are able to overcome the capacity limit of traditional systems due to their ultra-low non-linearity and near-vacuum latency. Additionally, 1700 nm is the optimum wavelength for brain related studies9,10 in terms of tissue penetration when both tissue scattering and absorption are considered. This spectral window is promising for multi-photon nonlinear optical imaging of the brain. The sensitivity and the penetration level at 1700 nm are also high for ultrahigh-resolution optical coherence tomography (UHR-OCT)10. Peak absorption is observed at approximately 1720 nm for human tissues with lipids where the water absorption is exceeded by the fat absorption. Such phenomena would contribute to the treatment of different types of skin where the tissues with lipids can be selectively targeted9.
The numerous applications at the 1700 to 2100 nm region have driven researchers to focus on thulium-doped fibers (TDFs)7,8,9,10,11,12,13,14,15. TDFs have recently been fabricated, which generate gain in a broad wavelength range. Such fibers successfully enhanced the operation of optical amplifiers, continuous-wave fiber lasers and super luminescent sources in the 1700–2100 nm range that peaks at approximately 1900 nm6,16. Although the invention of these fibers broadened the achievable emission region, lasing at a wide tunable range remains an important challenge. To achieve such a wide tunable range, the gain bandwidth of lasing emission has to be broadened, and the center wavelength has to be tunable16,17.
To shift the center-wavelength in fiber amplifiers, methods such as the formation of an artificial spectral filter comprising a tapered fiber18, a fiber Bragg Grating (FBGs)19, and a multimode fiber20, have been proposed. Another recommended method to shift the range of amplification and the operating wavelength of the lasers is the amplified spontaneous emission (ASE) suppression method21,22,23,24,25. This method is made possible by suppressing the unwanted ASE spectrum for the improvement of gain of the transmission window. A S-band EDFA has been obtained by suppressing the C-band ASE using depressed cladding fiber (W fibers) with a variation of the refractive index26. In the case of TDFs, to achieve a fiber laser operating below 1800 nm with lasing extended to as short as 1710 nm, a piece of holmium-doped fiber (HDF) is placed between a two stage thulium-doped fiber amplifier (TDFA). The HDF acts as an absorber of wavelengths that are above 1800 nm and are from the ASE generated from the TDF during amplification27. In 2014, Yamada also demonstrated TDFL as a good candidate for gain amplification at 1700 nm28, when terbium is doped in the TDF cladding as the unwanted emission absorber. This condition contributes to the suppression of the 1800 to 2000 nm emission region. ASE Suppression based on photonic crystal fibers (PCFs) is the other novel method that has been proposed. In 2009, Varshney presented a single mode S-band erbium-doped PCF fiber amplifier based on concentric dual-core PCF structures. A complete suppression of ASE in the C-band region results in amplification gain in the S-band region24. For TDFA, to enhance the performance of a S-band fiber laser, thulium-doped photonic crystal fiber (TDPCF) was demonstrated21. The proposed method was based on 800 nm and 2000 nm band ASE suppression provided by the PCF’s unique geometric structure.
This paper reports an all-fiber tunable thulium-doped mode-locked laser with the two wide tunable ranges of 1702 to 1764 nm and 1788 to 1831 nm. This is achieved with a combination of partial ASE suppression and the nonlinear polarization rotation (NPR) technique. The ASE suppression is induced by a specially designed PCF in the laser cavity and indicates the extinction of the longer wavelengths after passing through the PCF. Two PCFs, namely, PCF (1) and PCF (2), are designed and applied to the mode-locked fiber laser setup to achieve desirable wavelength lasing.
Results and Discussion
PCF design for ASE suppression
Different structural specifications of PCFs lead to different transmission characteristics29,30. To design a PCF for filtering purposes the PCF’s structural characteristics are classified into four geometrical properties: lattice constant Λ, core diameter D, inner air hole ring diameter d′ that surrounds the core, and the outer ring air hole diameter d. It is important to highlight the parameters d′ and d since their ratio will influence the low-pass filter’s cut-off wavelength. In the proposed model, the air hole diameter in the inner ring is adjusted to achieve a long cut-off wavelength31. To reach the desired cut-off wavelength, d′/Λ is varied from 0.30 to 0.55 and d/Λ is varied from 0.25 to 0.40, in the simulation. The constants Λ and D for both of the PCFs fabricated in this study are similar and are equal to 3.2 μm. PCF (1) has an inner hole ring diameter d′ of 2.5 μm and an outer ring diameter d of 1.1 μm while for PCF (2) the inner hole ring diameter d′ is 1.9 μm and the outer ring diameter d is 0.7 μm. The fabrication process is conducted in such a manner that the first layer of a different capillary diameter is followed by seven layers stacked together. Stacking is done hexagonally across a central rod which is fabricated using MCVD method. The inset of Fig. 1(a) shows the electron microscope image of the end face of PCF (1). The fabrication process exploited the classical stack and draw method, whereby the various capillary sizes of the first layer and the following seven layers were stacked hexagonally around a central rod that was fabricated via MCVD. Subsequent application of intra-air hole overpressure enabled control of the air hole dimensions in the final course of the drawing stage from the cane to the fiber.
The graphs in Fig. 1(a) represent the refractive index of cladding and the fundamental mode of PCF (1) and PCF (2) as a function of wavelength. The intersection of these two parameters represents the long cut-off wavelength of the PCF. When the core effective refractive index is smaller than the cladding refractive index, the relationship between d′ and the core effective refractive index becomes noticeable at the corresponding wavelength. Therefore, when going beyond the long cut-off wavelength, the electromagnetic intensity moves toward the fiber cladding and hence contributes to a higher loss in the fiber. For PCF (1), the extinction occurs beyond 1850 nm while for PCF (2) it occurs beyond 1750 nm. Figure 1(b) shows the E-field graph of the PCF (1) at 1850 and 1750 nm and of the PCF (2) at 1750 and 1650 nm. This figure illustrates that at wavelengths shorter than the cut-off, the electric field operates in guided mode at the central core, while at wavelengths longer than the cut-off, the electric field again radiates inside the cladding region leading to higher loss. The experimental transmission spectral response of the PCFs and the results of modeled transmission spectra using the V-FEM method are shown in Fig. 2. The modeled transmission spectra comprise five rings of air holes are calculated based on the confinement loss32. To experimentally study the spectral response, 1.0 m of PCF is set up and a white light source with −58 dBm of power is injected into it. As observed from the fundamental mode and cladding effective refractive index variation graph in Fig. 1, there was a high loss of 15 dBm for wavelengths longer than 1850 nm for PCF (1) and 1750 nm for PCF (2). With reference to Fig. 2, a total of 1.68 dB of loss was measured at 1560 nm. Based on the total measured, the modeled PCF, and splice losses, the 0.65 dB extra loss is probably due to the overlapping losses between the PCF and SMF. It can be clearly seen that when using the same design parameters, both experimental and numerical results are in agreement.
ASE suppressed TDFA
To elucidate the ASE suppression mechanism in a fiber laser, ASE suppression results of a TDFA are presented in this section. The configuration of the TDFA setup is presented in the methods section. The red curve in Fig. 3(a) shows the ASE spectrum of a standard single stage TDFA, while the blue and black curves represent the ASE spectrum of a TDFA for PCF (1) and PCF (2), respectively. In this case, the amplifier is forward pumped by a 788 nm laser with 181 mW of power. The generation of a broadband amplification region for the TDFA occurred at 1650–2100 nm. Figure 3(a) shows that there is a significant ASE suppression beyond the cut-off wavelength which is in agreement with the loss spectrum of Fig. 2. The amplification band of PCF (1) is shifted from 1700 to 1740 nm, and for PCF (2) from 1800 to 1820 nm due to the extinction of the longer wavelengths after passing through the PCF. To show the ASE suppression mechanism in a laser cavity, an experimental setup of a dual stage TDFA was completed, as shown in methods section. In the dual stage setup, the forward and the backward 788 nm laser power remained fixed at 100 mW at each stage. The ASE experimental results of the single stage TDFA without a PCF and the single and the dual stage TDFAs with PCF (2) are represented by red, blue and black curves, respectively, in Fig. 3(b). In comparison with the ASE spectrum of the single stage TDFA with a PCF (black curve in Fig. 3(b)), a higher ASE peak power at 1740 nm can be observed in the dual stage TDFA (black curve in Fig. 3(b)).
The broadening of the gain bandwidth is the main factor to achieve a wide tunable range. The bidirectional pumping method is adopted to widen the gain bandwidth of a TDF. Figure 3(c) shows an estimated gain bandwidth where the black and the red curves represent the bidirectional and the forward pumping schemes. It also shows ASE suppression of a TDF using PCF(2), where the green curve represents the bidirectional pumping, while the blue curve shows the forward one.
ASE suppressed tunable mode-locked fiber laser
The output spectra of the mode-locked ring laser (see the methods section) developed with just TDFL, TDFL + PCF (1), and TDFL + PCF (2) are shown in Figs 4, 5 and 6, respectively. The power of the forward pump is set at 181 mW, while for the backward pump it is set at 255 mW. The soliton effect contributes to peak sidebands of the output pulse32, whereas water absorption contributes to the dip of the spectra33. The emission wavelength can be manipulated by tuning the polarization controller. The laser emits at a fixed peak position at any fixed state of the cavity polarization because the nonlinear polarization evolution prohibits the periodic spectral filters, which affect the entire range of the emission spectrum34,35.
Figure 4 shows the tunable lasing range of a normal TDFL without ASE suppression that falls in the 1848–1920 nm wavelength range. The 30 m PCF length in the cavity is used to shorten the periodicity of the modulated transmission, thus to increase the number of peaks in the wavelength range of laser emission. Figures 5 and 6 show that the tunable lasing range shifted to 1788–1831 nm and to 1702–1764 nm when PCF (1) and PCF (2) are added to the setup, respectively. The shift in the ASE peak power is because of the ASE suppression at longer wavelengths. Due to the 2–1 cross-relaxation process of the thulium ions, the conversion efficiency when lasing at 1800 nm is high. The relatively low efficiency observed at wavelengths lower than 1780 nm is due to the overlap between the emission and the absorption of the cross-sectional area, which leads to a low thulium inversion.
A nominal pulse train of the laser for the TDFL without a PCF at 1920 nm, TDFL + PCF (1) at 1810 nm and TDFL + PCF (2) at 1730 nm is shown in Fig. 7(a–c), respectively. The autocorrelator trace of the laser pulse using the function fitting measurement is shown in the inset of the figures. For TDFL + PCF (1), the pulse full-width at half-maximum (FWHM) is measured to be 2.52 ps and the laser repetition rate in this case is 3.4 MHz. The measured pulse FWHM and the laser repetition rate for TDFL + PCF (2), is 2.55 ps and 3.2 MHz, respectively. A higher reputation rate of 14.3 MHz is observed for the TDFL without a PCF. This could be the result of the high length of the cavity related PCFs. For the TDFL without a PCF the pulse FWHM is approximately 3.31 ps.
Conclusions
Two tunable ranges of a thulium doped mode-locked all-fiber laser are achieved. Based on the partial ASE suppression mechanism using two fabricated PCFs in conjunction with the NPR method, the emission band of the laser is shifted to shorter wavelengths. The intersection of the effective refractive index and the cladding refractive index for PCF (1) and PCF (2), which corresponds to the long cut-off wavelength, occurs at 1850 and 1750 nm, respectively. These intersections are due to the larger size of the air holes in the inner ring that surrounds the central core. For PCF (1), the tunable lasing range shifted to 1788–1831 nm, whereas for PCF (2) the emission spectrum shifted to the 1702–1764 nm range. The collected data could be further utilized in other simulations and experimental work for tunable thulium-doped mode-locked fiber lasers.
Methods
Suppressed band thulium-doped fiber optic amplifier system setup
Figure 8 shows the configuration and measurement setup of a dual stage suppressed band thulium-doped fiber amplifier. The TDFA is characterized after the first stage and after the second stage. The architecture of the single stage TDFA consists of a TDF, a wavelength division multiplexing (WDM) coupler, a PCF, a pump laser and, an optical isolator. The TDF concentration is 2150 ppm with 27.00 dB/m of core absorption at the 788 nm wavelength. The numerical aperture (NA) and core diameter are 0.15 and 9.0 μm, respectively. The TDF length is optimized at 2.0 m while the PCF length is fixed at 1.0 m. The WDM coupler is used to combine the input signal with the pump. The optical isolator is placed after the signal to ensure a unidirectional operation of the optical amplifier. Two continuous wave (CW) tunable titanium-sapphire lasers are used as the pumps for the forward and backward pumping configurations. The operational wavelength of the laser is fixed at the TDF peak absorption of 788 nm. A Yokogawa AQ6375 optical spectrum analyzer (OSA) is used to measure the amplified spontaneous emission (ASE) spectrum.
Tunable mode-locked fiber laser system setup
The system setup for the tunable mode-locked fiber laser is shown in Fig. 9. This setup consists of an optimized 2.5 m of the same TDF as the amplifiers. The TDF is bi-directionally pumped by two CW tunable titanium-sapphire lasers operating at 788 nm via two WDM couplers. The polarization dependent isolator sandwiched between the two polarization controllers serves as the mode locker, which induces the NPR mechanism. At the output 95:5 coupler, 5% of the power is channeled as the cavity output and the rest propagates in the cavity. A long length of PCF (30 m) in the cavity is used to shorten the periodicity of the modulated transmission, thus increasing the number of peaks in the wavelength range of laser emission. However, a longer PCF would lead to more transmission loss and affect the mode-locking threshold. The dispersion coefficients of the TDF and the PCF at 1790 nm are −72 and approximately −65.2 ps 2/km, respectively.
References
Yang, L.-M., Wan, P., Protopopov, V. & Liu, J. 2 um Femtosecond Fiber Laser At Low Repetition Rate and High Pulse Energy. Opt. Express 20, 5683, https://doi.org/10.1364/OE.20.005683 (2012).
Luo, J. et al. Mid-IR supercontinuum pumped by femtosecond pulses from Thulium doped all-fiber amplifier. Opt. Express 24, 13939–13945, https://doi.org/10.1364/OE.24.013939 (2016).
Kawagoe, H. et al. Development of a high power supercontinuum source in the 17 μm wavelength region for highly penetrative ultrahigh-resolution optical coherence tomography. Biomed. Opt. Express 5, 932, https://doi.org/10.1364/BOE.5.000932 (2014).
Killinger, D. K. & Menyuk, N. Laser remote sensing of the atmosphere. Sci. (New York, NY) 235, 37–45, https://doi.org/10.1126/science.235.4784.37 (1987).
Hoult, T. Lasers in the 2 um SWIR spectral regime and their Applications. In CLEO: 2015, ATu4M.1, https://doi.org/10.1364/CLEOAT.2015.ATu4M.1 (OSA, Washington, DC, 2015).
Fatehi, H. et al. Analytical model for broadband Thulium-bismuth-doped fiber amplifier. IEEE J. Quantum Electron. 48, 1052–1058, https://doi.org/10.1109/JQE.2012.2199739 (2012).
Smith, C. M. et al. Low-loss hollow-core silica/air photonic bandgap fibre. Nat. 424, 657–9, https://doi.org/10.1038/nature01849 (2003).
Poletti, F. et al. Hollow Core Photonic Bandgap fibers for Telecommunications: Opportunities and Potential Issues. Soc. 11–13, https://doi.org/10.1364/OFC.2012.OTh1H.3 (2012).
Polder, K. D., Harrison, A., Eubanks, L. E. & Bruce, S. 1,927-nm fractional Thulium fiber laser for the treatment of nonfacial photodamage: A pilot study. Dermatol. Surg. 37, 342–348, https://doi.org/10.1111/j.1524-4725.2011.01884.x (2011).
Horton, N. G. et al. In vivo three-photon microscopy of subcortical structures within an intact mouse brain. Nat. Photonics 7, 205–209, https://doi.org/10.1038/nphoton.2012.336 (2013).
Chambers, P., Austin, E. A. D. & Dakin, J. P. Theoretical analysis of a methane gas detection system, using the complementary source modulation method of correlation spectroscopy. Meas. Sci. Technol. 15, 1629 (2004).
Phillips, M. W. Thulium-Doped Fiber Amplifier Development for Power Scaling the 2 Micron Coherent Laser Absorption Instrument for ASCENDS. Lockheed Martin Coherent Technol. Louisville, CO, Tech. Rep (2011).
Chernysheva, M. et al. High Power Q-Switched Thulium Doped Fibre Laser using Carbon Nanotube Polymer Composite Saturable Absorber. Sci. Reports 6, 24220, https://doi.org/10.1038/srep24220 (2016).
Soltanian, M. R. K. et al. A Stable Dual-wavelength Thulium-doped Fiber Laser at 1.9 μm Using Photonic Crystal Fiber. Sci. Reports 5, 14537, https://doi.org/10.1038/srep14537 (2015).
Wang, J. et al. 152 fs nanotube-mode-locked Thulium-doped all-fiber laser. Sci. Reports 6, 28885, https://doi.org/10.1038/srep28885 (2016).
Emami, S. D. et al. Gain-shift induced by dopant concentration ratio in a Thulium-bismuth doped fiber amplifier. Opt. Express 22, 7075–7086, https://doi.org/10.1364/OE.22.007075 (2014).
Emami, S. D. Thulium-doped Fiber Amplifier, Numerical and Experimental Approach. Lasers and electro-optics research and technology series (2011).
Harun, S. W., Lim, K. S. & Ahmad, H. Filtering characteristic of the microfiber loop resonator embedded in low refractive index polymer. In 2010 International Conference on Enabling Science and Nanotechnology (ESciNano), 1, https://doi.org/10.1109/ESCINANO.2010.5701026 (2010).
Tay, C. M. et al. A high-resolution tunable fiber Bragg grating filter. Microw. Opt. Technol. Lett. 42, 89–92, https://doi.org/10.1002/mop.20217 (2004).
Antonio-Lopez, J. E., Castillo-Guzman, A., May-Arrioja, D. A., Selvas-Aguilar, R. & Likamwa, P. Tunable multimode-interference bandpass fiber filter. Opt. letters 35, 324–326, https://doi.org/10.1364/OL.35.000324 (2010).
Emami, S. D., Muhammad, A. R., Harun, S. W., Ahmad, H. & Abdul Rashid, H. A. S-band Thulium-doped fiber amplifier enhancement using ASE suppression. In Conference on Optical Fiber Communication, Technical Digest Series, https://doi.org/10.1109/OFC.2014.6886890 (2014).
Emami, S. D. et al. New design of a Thulium-aluminum-doped fiber amplifier based on macro-bending approach. J. Light. Technol. 30, 3263–3272, https://doi.org/10.1109/JLT.2012.2217477 (2012).
Emami, S. D. et al. Micro-bending based optical band-pass filter and its application in S-band Thulium-doped fiber amplifier. Opt. express 20, 29784–97, https://doi.org/10.1364/OE.20.029784 (2012).
Varshney, S. K., Saitoh, K., Koshiba, M., Pal, B. P. & Sinha, R. K. Design of S-Band Erbium-Doped Concentric Dual-Core Photonic Crystal Fiber Amplifiers With ASE Suppression. J. Light. Technol. 27, 1725–1733, https://doi.org/10.1109/JLT.2009.2021991 (2009).
Rosolem, J. B., Juriollo, A. A. & Romero, M. A. S band EDFA using standard erbium doped fiber, 1450 nm pumping and single stage ASE filtering. In OFC/NFOEC 2008 - 2008 Conference on Optical Fiber Communication/National Fiber Optic Engineers Conference, https://doi.org/10.1109/OFC.2008.4528644 (2008).
Vincetti, L. et al. Numerical modeling of S-Band EDFA based on distributed fiber loss. J. Light. Technol. 26, 2168–2174, https://doi.org/10.1109/JLT.2008.923221 (2008).
Li, Z. et al. 90 nm gain extension towards 1.7 ??m for diode-pumped silica-based Thulium-doped fiber amplifiers. In European Conference on Optical Communication, ECOC, https://doi.org/10.1109/ECOC.2014.6964109 (2014).
Yamada, M., Ono, H. & Ono, J. 1.7 μm band optical fiber amplifier. In Optical Fiber Communication Conference, Tu2D.3, https://doi.org/10.1364/OFC.2014.Tu2D.3 (Optical Society of America, 2014).
Russell, P. Photonic Crystal Fibers. Sci. 299, 358–362, https://doi.org/10.1126/science.1079280 (2003).
Fogli, F., Saccomandi, L., Bassi, P., Bellanca, G. & Trillo, S. Full vectorial BPM modeling of Index-Guiding Photonic Crystal Fibers and Couplers. Opt. express 10, 54–59, https://doi.org/10.1364/OE.10.000054 (2002).
Varshney, S. K. et al. Strategies for realizing photonic crystal fiber bandpass filters. Opt. express 16, 9459–9467, https://doi.org/10.1364/OE.16.009459 (2008).
Kelly, S. Characteristic sideband instability of periodically amplified average soliton. Electron. Lett. 28, 806, https://doi.org/10.1049/el:19920508 (1992).
Sobon, G. et al. All-polarization maintaining, graphene-based femtosecond Tm-doped all-fiber laser. Opt. Express 23, 9339, https://doi.org/10.1364/OE.23.009339 (2015).
Wang, Y. et al. Tunable and switchable dual-wavelength mode-locked Tmˆ3+-doped fiber laser based on a fiber taper. Opt. Express 24, 15299, https://doi.org/10.1364/OE.24.015299 (2016).
Wu, Z. et al. Switchable Thulium-doped fiber laser from polarization rotation vector to scalar soliton. Sci. Reports 6, 34844, https://doi.org/10.1038/srep34844 (2016).
Acknowledgements
This work was supported by Iranian National Elites Foundation. We would like to thank for the financial support.
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S.D.E. conceived the ideas, and performed design and modeling of the PCF. H.A.A. contributed to PCF fabrication and fiber characterization. S.D.E. and H.J.U. performed the part of experiment, and M.M.D. and A.S.A. contributed to the scientific discussion and considerably improved the manuscript presentation. S.D.E., H.A.A., M.M.D., and A.S.A. analyzed the results and wrote the manuscript. All authors reviewed the manuscript.
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Emami, S.D., Dashtabi, M.M., Lee, H.J. et al. 1700 nm and 1800 nm band tunable thulium doped mode-locked fiber lasers. Sci Rep 7, 12747 (2017). https://doi.org/10.1038/s41598-017-13200-x
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DOI: https://doi.org/10.1038/s41598-017-13200-x
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