Overview of ytterbium based transparent ceramics for diode pumped high energy solid-state lasers Download: 786次
1 Introduction
High power diode pumped solid-state lasers have gained more attention in recent years due to their potential scientific and technological applications ranging from laser fusion research to industrial materials processing. In addition, efficient, high energy, pulsed laser systems operating at high pulse repetition rates (10 Hz and beyond) are the ideal pump sources for ultra-high intensity femtosecond petawatt-class lasers generating high-brightness secondary radiation (X-ray, gamma-ray) and particle (electron, proton, ion, muon) sources. These have potential applications for novel medical therapies, and in high-resolution radiography and advanced imaging for industrial and security sectors. The improvements in semiconductor technology result in high power semiconductor laser diodes with high efficiency and power over long life times. High power laser diodes coupled by coupling optics or optical fiber are efficient pump sources for solid-state lasers based on materials such as crystals, glasses or ceramics. Compactness, portability and high efficiency make diode pumped solid-state lasers more desirable for wide range of applications. Such high energy compact lasers generating an average output power exceeding 100 kW with pulse energy of 500 J were chosen for military purposes as a high energy laser weaponry due to the ease of mounting them on moving vehicle or even on an aircraft
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. Northrop Grumman demonstrated 105 kW output power by phase locking seven laser chain slabs (15 kW building blocks) pumped by high power laser diodes. In the field of plasma physics, laser–plasma interactions under high energy lasers can help scientists to understand relativistic plasma physics including compact particle accelerators and fast ignition of fusion targets. Extreme light infrastructure (ELI) will provide fs laser pulses with tens of joules of energy allowing generation of high energy density plasmas that are characterized by pressures above 1 Mbar (
Pa) or energy densities above
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. High-energy-class lasers with nanosecond pulses are in general limited to very low repetition rate in the order of few shots per minute or per hour, resulting in low average power. Such low average power lasers do not satisfy the requirements for advanced applications such as laser-driven inertial confinement fusion (ICF). Highly repetitive pulses
with multi-joule energy are important for several applications
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such as laser induced damage threshold (LIDT) of optics
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and in aerospace industries to improve the fatigue life of metals and alloys by laser shock peening (LSP) technique
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. With such wide application fields, several research groups around the world have been involved in prototyping high repetition high energy lasers. Bottlenecks to obtain high energy are laser gain media, pump sources and the cooling mechanism. A large size gain medium is necessary and such sizes can be easily made in glasses rather than crystalline form. The most common high energy laser based facilities such as National Ignition Facility (NIF) in USA, Shenguang-III in China, and Laser Mega Joule (LMJ) in France are based on Nd: glass
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. However, these facilities can generate single shot every few hours to provide necessary time for cooling the poor thermal conductive glass media. Danson
With continuous progress in transparent ceramic technology, lasers based on transparent ceramics have been popular over a couple of decades. This review article aims at bringing the recent progress in high energy lasers and the role of transparent ceramics to achieve high average power lasers. We also briefly discuss the impact of diode laser as a pump source and unique advantages of ytterbium ion with different hosts as active material. With a brief overview of several ongoing and upcoming high power laser projects globally, we have highlighted the recent demonstration of 1 kW average power from fully diode pumped solid-state lasers using Yb:Y Al O (here after Yb:YAG) transparent ceramics at cryogenic temperature in HiLASE Center, Czech Republic.
2 Diode as a pump source for solid-state lasers
Semiconductor laser diodes generating a continuous wave (CW) output power greater than 500 mW are termed as high power diode lasers (HPDLs). Because of their reliability, compactness and portability, high power laser diodes are widely used as a pump source for solid-state and fiber lasers. In addition to that one can lock the wavelength in these diodes using volume Bragg grating (VBG). Such wavelength stabilization along with narrow spectral bandwidth is very attractive for pumping solid-state lasers, especially to pump at specific wavelength such as the zero phonon line pumping of the gain medium [ 9 ] . Due to the improvements in semiconductor growth techniques such as metal organic chemical vapor deposition (MOCVD) and molecular beam epitaxy (MBE), semiconductor diode structures and laser cavity designs have been developed with variable atomic composition, doping concentration and precise atomic level layer thicknesses. Such refinements improve optical output power with significant electrical to optical power conversion efficiency (PCE) . Such higher efficiency reduces the heat load and the material’s internal losses. In a typical laser diode, optical emission takes place in one or more quantum wells of the p–n junction. Among the several semiconductor layers, the quantum wells have the lowest energy gap and highest refractive index which helps to confine the photons within the quantum wells whose thickness can vary between few nm to few . Output power from single emitter laser diode is improved by increasing the aperture/stripe width and by increasing the cavity length. Even though most practical laser diodes are available at near-IR (NIR) wavelength region between 800 and 980 nm, new materials also extend the wavelength region covering visible (400–780 nm) and mid-infrared region (1500–2300 nm). These laser diodes operate both in classical CW and also in quasi-continuous wave (QCW) emission modes. In CW mode, the laser diode is driven continuously with an electrical current and thus the laser emits continuously. The efficiency and performance of laser diodes under CW mode are generally limited by the generation of heat. In QCW mode, diode driver current is applied for short time intervals which significantly reduces the thermal load compared to CW mode operation. Because of smaller duty cycle, heat can be efficiently removed which helps to reduce the thermal effects and to achieve a high peak power [ 10 ] .
Continuous wave output power of more than 26 W with an output power facet density of
has been achieved at 940 nm using AlGaAs based broad-area single emitter laser diode with
aperture size and a cavity length of 5 mm
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. By combining several emitters, laser diode bars or diode stacks can generate higher power. A diode bar is a 1D array of several broad-area single emitters, whereas laser diode stack is a 2D array of several diode emitters arranged horizontally or vertically. Recently, at an injection current of 2 kA an output power of 2 kW (
, 10 Hz) has been achieved using GaAs based 1 cm laser diode bar with double quantum-well design. A peak efficiency of 68% was achieved at an operating temperature of 203 K with the emission wavelength centered at 944 nm
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. Multiple diode bars were used to generate multi kW laser power with high efficiency. JENOPTIK has demonstrated a pulse power of 4 kW using QCW diode stack containing eight QCW diode bars each generating 500 W (1 ms, 60 Hz) pulse power at 940 nm which is suitable for pumping Yb doped high energy lasers. Wolz
Due to larger emitter width, higher fill factor and emitter count, HPDLs result in an elliptical output beam with a near diffraction-limit along the fast axis ( -axis) and highly multimode along the slow axis ( -axis). Even though a better beam quality can be achieved by reducing the emitter count and fill factor (the ratio of sum of emitter widths to the total width of the diode bar), this can also reduce the overall power. Beam quality can be significantly improved by employing an array of cylindrical microlenses along both the propagation axes. By placing fast-axis collimation lens to individual emitters, beams can be collimated along the fast axis. Once coupled into fiber, the beam quality and brightness can be maintained. Due to this reason, laser diodes have been found to be good alternative pump sources for solid-state laser to generate laser with high spectral and spatial characteristics compared to flash lamps. In addition to that, laser diodes have narrow band emission and require lower maintenance. The first diode pumped solid-state laser was demonstrated using U:CaF at cryogenic liquid helium temperature [ 16 ] . The most common solid-state laser materials such as Nd:YAG and Yb:YAG can be efficiently pumped by laser diodes with emission spectra matching their absorption bands. Quantum-well laser diodes based on GaAs/AlGaAs are used for Nd based laser materials, whereas InGaAs/GaAs based laser diodes are used in Yb based materials because of the overlap between their absorption bands with the laser diode emission. The availability of high efficiency high power laser diodes leads to the implementation of successful and ongoing high energy laser projects such as POLARIS (Germany) [ 17 ] , LUCIA (France) [ 18 ] , PEnELOPE (Germany) [ 19 ] and HiLASE (Czechia) [ 20 ] . More details on such projects are discussed in the later sections.
3 Ytterbium based transparent ceramics for solid-state laser materials
Solid-state lasers producing high energy laser pulses at high repetition rates demand a large size gain media with extreme optical quality, high thermal conductivity and mechanical strength. Among several laser active ions, Yb
ion with two manifolds (
F
and
F
) and energy separation of about
is more desirable for high-energy-class lasers. Because of this simple electronic structure, it avoids unwanted thermal load due to nonlinear optical processes such as upconversion and excited state absorption (ESA), which are predominant with other common laser ions such as Nd
. This also allows doping high concentration of Yb
ion without any concentration quenching. Additionally, a low quantum defect, longer life time
and broad-band emission lines of Yb
help to generate high energy laser pulses with relatively short durations (
ps). However, Yb
ion also suffers from few drawbacks due to its quasi-three level nature of the ground state manifold (terminal laser level). At room temperature, the lower energy level gets thermally populated that causes reabsorption of laser wavelength reducing the population inversion and eventually increasing the laser threshold. The best way to avoid such thermal population is to operate the laser at cryogenic temperature. At cryogenic temperature, the Yb doped gain materials act as a four level laser medium, which reduces the reabsorption of laser wavelength. In addition, cryogenic cooling helps in improving the spectroscopic and thermo-optic properties of the laser gain medium. All these effects result in overall system laser performance. Fan
Solid-state lasers have been built with Yb
ion doped in glasses, single crystals and transparent ceramics. Yb doped glasses such phosphates, tellurites, fluorides and silicate glasses have been extensively studied for laser development because of their cost effectiveness and broad emission spectrum which is ideal for ultrashort lasers
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. Glasses require significant cooling for high average power lasers due to their poor thermal conductivity. Similarly, Yb ions have been doped in several crystalline materials for their potential laser applications. Using quasi-three level laser model, Brenier
Fig. 1. (a) Composite ceramic gain media used to achieve an output power of 520 W in microchip laser. (b) An output power of 520 W using YAG/Yb:YAG composite gain media. Reprinted with permission from Ref. [ 33 ].
Just above a couple of decades ago, Japanese scientists introduced the laser quality transparent ceramics into the solid-state laser domain which were earlier based only on single crystals and glasses. With controlled processing steps right from powder preparation followed by pressing, sintering and polishing, cubic materials without any secondary phase and porosity can be made transparent. For the fabrication of the earliest transparent YAG ceramics, two Japanese groups adapted different powder synthesis techniques to form YAG powders keeping the subsequent processing steps such as forming, pressing and sintering common. Ikesue
Takaichi
Over the years, Yb:YAG ceramics gained more attention in the laser community focused on high power generation. Yb:YAG ceramic rod was proposed in their conceptual design of GENBU laser in Japan aiming to generate 1 kJ laser pulses at a repetition rate of 100 Hz which are desirable for fusion energy reactor driver [ 34 ] . These lasers are diode pumped and the ceramics are operated in active mirror configuration. Recently, an average power of 1 kW has been achieved in HiLASE in diode pumped laser configuration using large aperture Yb:YAG ceramics. Specific details are discussed in the latter part of this article.
Other than YAG ceramics, ytterbium has also been explored in other host materials such as sesquioxides in transparent ceramic form. Yb:Y
O
ceramic 20 at.% was successfully developed and a successful laser oscillation with an efficiency of 32% was demonstrated even before Yb:YAG ceramic laser
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. This was followed by Yb:Lu
O
ceramic laser with an efficiency of 53%
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. Apart from better thermal conductivity, Yb doped sesquioxides have large value of nonlinear refractive index that can enhance Kerr-lens and phase modulation effects. Such nonlinear effects along with better thermal conductivity make sesquioxides suitable for the development of ultrashort lasers with high average power. Tokurakawa
4 High energy solid-state lasers
As mentioned in the introduction part, high efficiency nanosecond multi-joule class lasers with high repetition rates are becoming more and more attractive in the laser community compared to single-shot laser facilities. Diode pumped solid-state lasers generating nanosecond pulses with energy in tens of joules and more are highly demanding in a wide variety of application fields. The major challenges in achieving such high energy at several hertz high repetition rate are LIDT of the optics and gain media, thermal effects of the laser material due to the pumping process and the amplified spontaneous emission (ASE). Using a careful amplifier design including the size and shape of the gain medium, LIDT and ASE can be controlled. For instance, laser induced damage of optics can be avoided by increasing the pump spot size, whereas ASE can be suppressed using an edge-cladding absorbing layer around the gain media. Intensive works have been carried out to suppress thermal effects which result in the degradation of beam quality due to thermal distortions such as thermally induced birefringence [ 42 ] . Severe thermal gradients along the gain media can also result in thermally induced crack of the material, especially for the laser operating at high average power. Various laser amplifier configurations such as laser rod, zig-zag slab, active mirror slab, and face cooled multi-slab amplifiers have been investigated for efficient heat removal for such high average power lasers. In this section, we focus on the two most common amplifier configurations in practice for diode pumped high energy solid-state lasers: active mirror slab amplifier and multi-slab amplifier.
When introduced by General Electric Co. in the late 1960s, active mirror laser amplifiers did not have much success due to the dielectric coating issues on the gain media. Within few years, significant progress has been made on demonstration of high average power laser using active mirror amplifier (AMA). In AMA systems, the active mirror slab or disk has high aspect ratio with thickness in the order of mm to cm and a diameter of few centimeters. The pump beam is directed on the rear side of the slab which is coated with dichroic coatings having high transmission for the pump wavelength and high reflectivity for the laser beam. The front face of the slab is coated with maximum reflection for pump wavelength and a high transmission for the laser beam. AMA is a double-pass design that enables efficient energy extraction from the gain medium with twice power gain during each pass. Classically AMA laser was performed by flashlamp pumping with uniform transverse thermal distribution across the gain media and was cooled by direct contact of the coolant along the rear surface of the slab
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. A smooth thermal gradient reduces the thermal lensing effect. Brown
Diode pumped AMA systems generate high efficiency and excellent beam quality compared to flashlamp pumped systems. Nd:glass has been a common gain medium for AMA system but it suffers from poor thermal conductivity and low emission cross section that limit in achieving kW of average power. Crystalline gain media such as Nd:YAG and Yb:YAG also have been explored in AMA laser for high repetition rate high energy pulse generation but the power scaling is generally limited by the aperture dimension. Generation of nanosecond laser pulses with energy of 100 J requires a gain medium with an aperture size of more than 5 cm to survive the LIDT value of
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. Transparent ceramics offer unique advantages not only to make large aperture gain media but also have the potential to achieve composite gain media. Therefore, a combination of diode pump and transparent ceramics is attractive for high average power lasers in active mirror concept and its improved versions such as total-reflection active mirror or thin disc lasers. LUCIA laser is one of the most popular diode pumped solid-state lasers aiming to deliver high energy nanosecond laser pulses at a repetition rate of 10 Hz. It is also a part of the HiPER project which is dedicated to developing laser-driven inertial fusion energy sources
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. LUCIA laser consists of a cavity dumped master oscillator power amplifier (MOPA) followed by two pre-amplifier stages and a main amplifier stage. Pumped by 10 W laser diode, MOPA generates 0.5 nJ laser pulses at 10 Hz repetition rate using a 10% Yb:YAG single crystal disk (3.5 mm thick
25 mm diameter), whereas pre-amplifier stages use two 2% Yb:YAG single crystal disks (3 mm thick
30 mm diameter). After multiple passes in the pre-amplifier stages, laser pulse reaches 590 mJ of energy and enters the main power amplifier stage which is pumped by laser diode with an average power of 600 W. To avoid parasitic lasing (PL) due to ASE under such high power pumping, large diameter 2% Yb:YAG crystal (7 mm thick
60 mm diameter) was considered. Due to the difficulties in growing such a large diameter single crystal, an alternative solution using Cr
/Yb
:YAG composite ceramics (45 mm diameter) was found to generate same amount of laser energy. An energy of 14 J with more than 20% efficiency has been demonstrated using such composite ceramics. Schematic AMA concept used in LUCIA and the composite crystalline and ceramic media used to demonstrate an energy of 14 J are shown in Figures
Compared to this first generation composite ceramics with Cr layer (0.25 at.%) having a radial thickness of 5 mm, second generation transparent ceramics with 20 mm radial thickness of Cr layer ( at.%) shows higher gain [ 48 ] . An increase in thickness and a decrease in doping level of Cr layer reduce the thermal concentration and thermally induced stress along the Yb /Cr interface. Along with improvement in cooling system, LUCIA laser aims at generating laser pulses at 10 Hz.
Fig. 2. (a) Schematic of AMA concept used for LUCIA laser. (b) Crystalline and ceramic composites used in LUCIA laser to deliver an energy of 14 J. Reprinted with permission from Ref. [ 18 ].
Another laser geometry which provides efficient heat removal from the gain media and is ideal for high average power laser generation is multi-slab laser geometry. A slab laser allows effective cooling on both the faces by making direct contact with the coolant. Conventionally, a laser slab is cut at Brewster angle and the laser beam passes in zig-zag fashion within the slab by total internal reflection. In the first end pumped zig-zag slab laser, an average power of 150 W was achieved by Goodno
Similar projects such as PEnELOPE and POLARIS from Germany are fully diode pumped laser systems aiming at generating very high peak power in the order of terawatt. They adopted chirped pulse amplification (CPA) to amplify fs laser pulses by gain media based on glasses. PEnELOPE [ 19 ] is a direct diode pumped CPA laser system based on active mirror/multi-slab architecture to generate laser pulses of energy 150 J at 1 Hz repetition rate with a pulse duration of 120 fs. Gain media, including Yb doped glasses such as phosphate and fluoride phosphate and crystalline CaF were preferred because of their relatively lower refractive indices which enable an easy index matching and a better limiting aspect ratio. 5 mm thick Yb:CaF crystals of 5.5 cm and 11 cm with broad-band gain were chosen for two different multi-pass amplifier stages. The slabs are gas-cooled longitudinally to reduce thermally induced effects such as depolarization losses, stress induced birefringence and thermally induced stress [ 19 ] . Similarly, POLARIS project at Helmholtz-Institute Jena aims to achieve a peak power of 250 TW using gain media based on Yb doped fluoride phosphate glass and CaF single crystals. Pumped by 940 nm high power laser diode stacks, POLARIS currently generates laser pulses of energy 16.7 J with a pulse duration of 98 fs which corresponds to a peak power of 170 TW [ 17 ] .
The scalability of this multi-slab concept has been adopted by another high energy DPSSL called Diode Pumped Optical Laser for Experiments (DiPOLE) using transparent ceramics of Yb:YAG. Figure
Fig. 3. Multi-slab amplifier design adopted for DiPOLE laser systems. Reprinted with permission from Ref. [ 52 ].
Similarly, Cr
:YAG having strong absorption at 1030 nm was considered as the cladding layer for Yb:YAG. It was found in Cr
and Yb co-doped YAG crystal amplifier, that depletion of energy due to ASE could be significantly reduced with an optimum Cr
concentration which is dependent on the aperture size and Yb concentration in core laser rod
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53
]
. The main drawback of such co-doped materials is strong absorption of Cr
at 940 nm, the pump wavelength for Yb:YAG and affects the performance of laser. Magdalena
Fig. 4. One of the ceramic discs used in DiPOLE-10 to generate an energy of 10 J at 10 Hz.
5 Kilowatt class diode pumped solid-state laser in HiLASE using transparent ceramics
100 J HiLASE laser (also called DiPOLE100) consists of three components:
seed laser pulses, pre-amplifier stage delivering 10 J and finally cryogenic main amplifier delivering
laser pulses. The first component consists of seed source, regenerative pre-amplifier based on Yb:CaF
and multi-pass booster amplifier based on Yb:YAG crystal. More details on this first component can be found elsewhere
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. The 10 J amplifier is based on gas-cooled multi-slab laser system using Yb:YAG ceramic circular discs as mentioned above. Amplification is achieved by seven passes through the amplifier which increases energy extraction with less ASE losses. With further optimization, an efficiency of 27% was achieved for this 10 J pre-amplifier. The beam is sent for further amplification to 100 J in cryogenic main amplifier which is a scaled up version of 10 J pre-amplifier. Unlike circular ceramic discs in 10 J amplifier head, rectangular ceramic slabs are used for 100 J amplifier. It consists of 8.5 mm thick six rectangular Yb:YAG ceramic slabs with Cr
:YAG cladding layer. Yb doped core region in the slab is 100 mm wide, whereas cladding layer is 10 mm wide. Figure
Fig. 6. Output energy of 100 J against the pump energy. Reprinted with permission from Ref. [ 20 ].
The slabs are similarly cooled by passing high pressure He gas through the 2 mm slab gaps and the laser amplification is done at 150 K. The slabs are once again doped with different Yb concentrations in order to achieve uniform longitudinal absorption and heat load. Two center slabs are 1% Yb doped followed by 0.6% and 0.4% Yb doped slabs, whereas Cr
concentration for the cladding layer is chosen to provide an absorption coefficient of
at 1030 nm
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. Laser pulses with 105 J output energy at 10 Hz were achieved at an incident pump energy of 465 J with an optical to optical conversion efficiency of 22.5%. An average power of exceeding 1 kW was demonstrated for the first time in diode pumped solid-state laser scheme
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20
]
. Figure
6 Conclusions
Applications ranging from industrial to high-field research demand lasers operating at high average power. Diode pumped solid-state lasers are the potential contender for the development of efficient and compact laser systems for such applications. Demand for large aperture gain media and an efficient way of heat removal have been the limiting factors for generating high repetition pulses with energies ranging from tens of joules to kJ. With the advancement in ceramic technology, it is possible to engineer the laser gain media not only in terms of size but also in terms of composition and combination of layers such as composite ceramics. The crucial roles of ytterbium based materials, high power laser diodes and transparent ceramic gain media toward the recent progress in high energy lasers have been discussed. We also discussed two laser geometries in practice for high average power (HAP) lasers: active mirror and multi-slab amplifier concepts. Finally, recent achievement of kilowatt class laser operation in HiLASE using multi-slab large aperture Yb:YAG transparent ceramic clearly demonstrates a great potential for scaling this laser to the multi- level.
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Article Outline
Samuel Paul David, Venkatesan Jambunathan, Antonio Lucianetti, Tomas Mocek. Overview of ytterbium based transparent ceramics for diode pumped high energy solid-state lasers[J]. High Power Laser Science and Engineering, 2018, 6(4): 04000e62.