Tapered Amplifiers For Amplification of Seed Sources or for External Cavity Laser Setups 750 nm to 1070 nm COHERENT.COM DILAS.COM
Welcome DILAS Semiconductor is now part of Coherent Inc. With operations in Germany, North America and China, Coherent DILAS develops and manufactures high-power semiconductor laser components, modules and turnkey diode laser systems for distributions worldwide. Setting the standard for performance and reliability, Coherent DILAS high-power, high brightness product portfolio offers a wide selection of configurations, powers, and wavelengths from 405 nm to 2300 nm. Our core technology consists of clean room based process lines for GaAs, InP and GaSb based diode lasers including in-house epi designs grown by MBE (Molecular Beam Epitaxy) and MOCVD (Metalorganic Vapor Phase Epitaxy) and a patented facet coating technology. We offer bare chips, single emitters and laser bars based on tapered, broad-area or customized designs. Our diode lasers in the lower mid-infrared (1.85 µm to >2 µm) wavelength regimes are being used globally in the fields of medical treatment, materials processing, spectroscopy, and metrology. For more information visit www.dilas.com www.coherent.com. Coherent DILAS Semiconductor Business Unit, Freiburg, Germany
The Tapered Laser Concept Diode lasers with tapered design combine a nearly diffraction limited beam quality with output powers which have previously only been available for diode lasers with broad-area design. They can be used either as stand-alone highbrightness diode lasers or as an amplifier within a MOPA (Master Oscillator Power Amplifier) or ECL (External Cavity Laser) configuration. In comparison to pure single-mode or broad-area laser, laser systems based on tapered amplifiers offer not only high power and nearly diffraction limited beam quality, but also tunability and extremely narrow linewidth. To achieve these characteristics, the lateral design of the diode laser consists of two components monolithically integrated on one chip. High beam quality is made possible via an index-guided ridge-waveguide. In contrast, high output power requires a gain-guided broad pumped area with an output facet width of several 100 micrometer, which leads in summary to a taper section. The beam quality depends on the beam waist and the far field of the laser. In vertical direction the beam quality of a diode laser is typically diffraction limited caused by the used semiconductor layer sequence. tapersection ridgesection output facet Because of the tapered geometry, the minimal lateral rear facet beam waist in the focus depends only on the width of the ridge waveguide section. In comparison to broad-area lasers with identical output power this leads to a beam width reduced by a factor of 20 to 30. The lateral far field is given by the taper angle. By stretching the length of the taper section the output facet will be broadened and the output power can be increased up to several watts. The minimal beam width, the far field and therefore the beam quality does not change. The ridge-waveguide and taper sections are processed cost-effective by using standard diode laser processing steps like optical lithography and a mixture of dry and wet chemical etching. The structure consists of a taper angle of 4 together with different taper section lengths according to the used power level. The ridge width is typically 3 µm. The ridge height is chosen appropriately for the propagating wave to fill the taper angle. Cavity-spoiling groves on both sides of the ridge section suppress undesired Fabry-Perot modes. More than 20 years ago, tuneable diode laser systems based on tapered amplifiers have been developed for the first time. Coherent DILAS Semiconductor has introduced its first commercial tapered amplifier for amplifying seed lasers in 2001. A few years later external cavity systems based on tapered amplifiers have been added. Nowadays tapered amplifiers are used worldwide in powerful multi-watt commercial and scientific systems in the fields of spectroscopy or metrology.
Tapered Amplifiers Tapered Amplifiers used in MOPA Configuration MOPA setups are used for the amplification of an existing seed laser. The seed power typically ranging between 10 mw and 50 mw can be amplified up to nearly diffraction limited power values of several watts. A typical setup (1) consists of a seed laser, e.g. a grating stabilized ridge laser or a DFB laser, an optical isolator to avoid back-reflections between seed laser and tapered amplifier, a half wave plate to adjust the polarization between seed laser and tapered amplifier, and a focusing lens in front of the rear facet of the tapered amplifier. The waveguide of the ridge-section of the tapered amplifier acts as a slit to capture the light of the seed laser. Then the light will be amplified in the tapered section without losing its spectral or spatial quality. For the quality of the MOPA setup it is essential that both facets of the tapered amplifier are highly antireflection coated with values of less than 1% to avoid laser action of the amplifier chip itself. Tapered Amplifiers used in External Cavity Setups Tapered amplifiers can be also used in external resonator laser configuration to combine tuneable nearly diffraction limited output powers of several watts with small spectral line widths and high side mode suppression ratios. No additional seed laser and extra electronics is needed which makes it attractive for applications were cost plays an important role. seed-laser (e.g. DFB-laser) optical isolator collimation lens tapered amplifier Light For example a typical external cavity setup (2) in Littrow configuration consists of a tapered amplifier with a collimating lens in front of the rear facet, a half wave plate to correct the polarisation and an external grating. The first order of the dispersed light is reflected back into the ridge side of the tapered amplifier. The waveguide acts as a slit to capture a small part of the light at the lasing wavelength which is used to seed the ridge section and then amplified in the tapered section. (1) (2) external grating Littrow configuration rear facet collimation lens tapered amplifier output facet The front side is coated such that a small amount of the light is reflected back to provide oscillation. In comparison to tapered amplifiers in MOPA configuration the front facets are provided with an anti-reflection coating in the range of 1% to protect the chips from back reflections. Characteristics ffdifferent amplifiers between 750 nm and 1070 nm available ffamplification of seed laser up to 4W ffhighly antireflection coatings of <1% ffnearly diffraction limited behaviour, typ. M 2 < ffase suppression >40 db fftypically 20 nm to 40 nm tuning range Applications fflaser cooling and trapping, Bose-Einstein condensation ffmetrology, Raman spectroscopy, interferometry ffabsorption spectroscopy of atoms, molecules and ions fffrequency doubling
Specifications Detailed datasheets for each wavelength can be downloaded at www.dilas.com www.coherent.com. Power Class and M 2 Product Type TA- / TAL- Usable Wavelength Range Packaging 0850-3000 845 nm to 865 nm P = 3W M 2 <1.7 0860-3000 853 nm to 870 nm 0890-3000 878 nm to 903 nm 0920-3000 900 nm to 935 nm P = 2W M 2 <1.7 P = 1W M 2 <1.6 0976-3000 965 nm to 985 nm 0765-2000 763 nm to 770 nm 0780-2000 776 nm to 793 nm 0785-2000 779 nm to 790 nm 0850-2000 845 nm to 865 nm 0870-2000 865 nm to 880 nm 0890-2000 884 nm to 898 nm 0920-2000 910 nm to 930 nm 0950-2000 935 nm to 965 nm 0976-2000 965 nm to 990 nm 1010-2000 1000 nm to 1025 nm 1060-2000 1037 nm to 1068 nm 0765-1000 750 nm to 775 nm 0780-1000 765 nm to 790 nm 0785-1000 770 nm to 800 nm 0800-0500 790 nm to 810 nm 0920-1000 895 nm to 935 nm C-mount, DHP-I or DHP-F
Example Measurement Data The charts presented only describe typical measurement data examples. All modules are characterised individually, the results being contained in the documentation included. The display options are subject to alteration by Coherent DILAS Semiconductor. The charts show P(I) and U(I) characteristics and the amplifier output spectrum without external feedback. The intensity distribution at the amplifier output facet (for MOPA) or for the minimal beam waist (ECL) in the slow axis with seed power are shown in the third chart for each wavelength. M 2 has been measured using a commercial BeamScope in accordance to ISO 11146. Tapered Amplifier used in MOPA Configuration output power with seed laser (W) intensity without seed laser (db) 4 3 2 1 0 0 1 2 3 4 5-50 -55-60 -65-70 T = 20 C P seed = 20mW current (A) λ = 860nm -75 820 840 860 880 900 wavelength (nm) voltage (V) output power with seed laser (W) intensity without seed laser (db) 5 4 3 2 1 0 0 1 2 3 4 5 6-50 -60-70 -80 T = 20 C P seed = 20mW current (A) λ = 976nm 940 960 980 1000 1020 wavelength (nm) 2.5 voltage (V) beam waist at 3W with seed laser (normalized) M 2 = 1.3-200 -100 0 100 200 beam position beam waist at 4W with seed laser (normalized) M 2 = 1.2-500 -400-300 -200-100 0 100 200 300 400 500 beam position Tapered Amplifier used in External Cavity Configuration output power with grating (W) 0 1 2 3 4-50 T = 20 C grating: 630 lines/mm current (A) 2.5 voltage (V) output power with grating (W) 2.5-40 T = 20 C grating: 630 lines/mm 0 1 2 3 4 current (A) 2.5 voltage (V) intensity without grating (db) -55-60 λ = 765nm -65 740 750 760 770 780 wavelength (nm) intensity without grating (db) -50-60 λ = 1060nm -70 1000 1020 1040 1060 1080 1100 wavelength (nm) beam waist at 2W with grating (normalized) M 2 = 1.3-500 -400-300 -200-100 0 100 200 300 400 500 beam position beam waist at 2W with grating (normalized) M 2 = 1.2-500 -400-300 -200-100 0 100 200 300 400 500 beam position
Safety This is a laser class IV product according to IEC - Standard International Commission (Publication 825, 1993). The laser light emitted from this laser diode is invisible and/or visible and is harmful to the human eye. The safety regulations for eye and personnel protection included in the IEC Standard must be observed to avoid any harm to operating personnel. Avoid direct exposure and looking into the laser diode, into the collimated beam or into the fiber when it is linked to the module. Operation and Handling Diode lasers are extremely sensitive to over-voltage. Take extreme precaution to avoid electrostatic charges. Precautions against spiking during switching on and off the power supply must be assured. Correct polarity of power supply must be assured. During handling, personnel has to wear wrist straps. Grounded work surfaces and additional antistatic techniques are mandatory during handling. Device failure and safety hazard are caused by operation in excess of maximum ratings. Exceeding output power and temperature specification will result in accelerated device aging. DANGER INVISIBLE LASER RADIATION AVOID EYE OR SKIN EXPOSURE TO DIRECT OR SCATTERED RADIATION DIODE LASER > 1 W MAX OUTPUT at 765-1080 nm CLASS IV LASER PRODUCT
Imprint DILAS Diodenlaser GmbH Galileo-Galilei-Strasse 10 55129 Mainz Germany Copyrights All rights reserved. Pictures are copyright protected by the DILAS Diodenlaser GmbH. The use of these illustrations requires an explicit permission. Please note: Specifications are subject to change without further notice. Main Phone +49 (0) 6131-9226-0 Main Fax +49 (0) 6131-9226-257 Sales Phone +49 (0) 6131-9226-202 Sales Fax +49 (0) 6131-9226-253 COHERENT.COM DILAS.COM DI-062017