Low phonon energy, Nd:LaF/sub 3/ channel waveguide lasers fabricated by molecular beam epitaxy

Bhutta, T.; Chardon, A.; Shepherd, D.P.; Daran, Emmanuelle; Serrano, C. M.; Muñoz‐Yagüe, A.

doi:10.1109/3.958380

Cited by 20 publications

(16 citation statements)

References 33 publications

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“…Although there are reports in the literature on MBE growth of waveguide films of complex ternary oxide materials such as LiNbO 3 [120] and BaTiO 3 [121], most of the work on dielectric waveguide layers to date has focused on hetero-epitaxial deposition of rare-earth doped fluoride waveguides, such as ZnF 2 , PbF 2 , [122] CaF 2 , [123] and LaF 3 [124][125][126][127]. They were grown on different dielectric and semiconductor substrates and their propagation loss was on the order of 1 dB·cm -1 [122,126,127].…”

Section: Molecular Beam Epitaxy (Mbe)mentioning

confidence: 99%

Section: Molecular Beam Epitaxy (Mbe)mentioning

confidence: 99%

“…They were grown on different dielectric and semiconductor substrates and their propagation loss was on the order of 1 dB·cm -1 [122,126,127]. Reports on waveguide lasers are limited to LaF 3 :Nd 3+ structures with slab and channel geometries [126,127]. The reasons behind this interest in implementing this method for growth of fluoride crystal layers rather than for their oxide counterparts are: (i) the fluoride molecules have a higher dissociation energy, and therefore can withstand the processes of evaporation and transport to the substrate without decomposing, and (ii) the combination of the low temperatures required for growth of fluoride layers and the inherently low growth rates of the MBE method ensures homogeneous distribution of the rare earth ions within the layers and thus minimization of clustering.…”

Section: Molecular Beam Epitaxy (Mbe)mentioning

confidence: 99%

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Optically pumped planar waveguide lasers, Part I: Fundamentals and fabrication techniques

Grivas

2011

Progress in Quantum Electronics

194

102

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Abstract:The tremendous interest in the field of waveguide lasers in the past two decades is largely attributed to the geometry of the gain medium, which provides the possibility to store optical energy on a very small dimension in the form of an optical mode. This allows for realization of sources with enhanced optical gain, low lasing threshold, and small footprint and opens up exciting possibilities in the area of integrated optics by facilitating their on-chip integration with different functionalities and highly compact photonic circuits. Moreover, this geometrical concept is compatible with high power diode pumping schemes as it provides exceptional thermal management, minimizing the impact of thermal loading on laser performance. The proliferation of techniques for fabrication and processing capable of producing high optical quality waveguides has greatly contributed to the growth of waveguide lasers from a topic of fundamental research to an area that encompasses a variety of practical applications. In this first part of the review on optically pumped waveguide lasers the properties that distinguish these sources from other classes of lasers will be discussed. Furthermore, the current state-of-the art in terms of fabrication tools used for producing waveguide lasers is reviewed from the aspects of the processes and the materials involved. 2 1.IntroductionOver the last two decades the field of solid-state planar waveguide lasers has experienced a steady growth, progressing from a laboratory curiosity to an area that demonstrates a broad spectrum of applications, from multiwavelength laser channel arrays for telecommunications to diode-pumped planar structures with multiwatt output powers for sensing and ranging applications. Waveguide lasers are by no means a new field and the first report on such a source dates back in 1961, when laser operation of a waveguide based on an active glass core rod embedded in a low refractive index cladding was demonstrated [1]. However research efforts in the years that followed this report focused primarily on the development of optically pumped laser sources based on high optical quality bulk dielectric laser media in the form of rods and slabs. The merits of the waveguide geometry and the associated optical confinement have been first highlighted in single mode glass optical fibers. Fibers have proven an enabling technology for realization of highly efficient amplifier and laser sources owing to their unrivalled low loss performance and ability to maintain a small spot size and hence high intensities over lengths that are orders of magnitude longer than would normally be allowed by diffraction, [2,3]. Er-doped fiber amplifiers (EDFAs) in particular have directly contributed to the enormous expansion of the optical communications networks that underpin today's internet infrastructure by allowing for signal regeneration and optical data transmission over long distances. The excellent performance of fiber lasers and amplifiers provided motivation and triggered a major techn...

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Section: Molecular Beam Epitaxy (Mbe)mentioning

confidence: 99%

Section: Molecular Beam Epitaxy (Mbe)mentioning

confidence: 99%

Section: Molecular Beam Epitaxy (Mbe)mentioning

confidence: 99%

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Optically pumped planar waveguide lasers, Part I: Fundamentals and fabrication techniques

Grivas

2011

Progress in Quantum Electronics

194

102

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“…In glass substrate, ultralow transition temperature in tellurite glasses, large crystallization tendency in gallate glasses, and poor acid resistibility in nonoxide glasses block the attempts in low phonon energy glass waveguide seriously. [15][16][17][18] In RE activators, illustrated by the case of S-band amplification of Tm 3+ , 3 H 4 → 3 F 4 transition is medisensitive to phonon energy and lower phonon energy hosts have to be employed to achieve the efficient emission. Meanwhile, exorbitant concentration doping of Tm 3+ should be avoided to reduce ͓ 3 H 4 , 3 H 6 ͔-͓ 3 F 4 , 3 F 4 ͔ cross-relaxation rate between Tm 3+ ions, which is necessary for maintaining S-band emission efficiency.…”

Section: Tm 3+ -Doped Ion-exchanged Aluminum Germanate Glass Waveguidmentioning

confidence: 99%

Tm 3 + -doped ion-exchanged aluminum germanate glass waveguide for S-band amplification

Yang

Pun

Lin

2009

Applied Physics Letters

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“…Crystalline fluoride thin films were first fabricated by molecular beam epitaxy (MBE) and were used as crystalline insulators in semiconductor/insulator/semiconductor heterostructures for integrated circuits and optoelectronic devices [2,3]. More recently, waveguide laser oscillation has been reported in crystalline rare-earth-doped fluoride layers fabricated by MBE [4,5] and liquid phase epitaxy (LPE) [6][7][8].…”

mentioning

confidence: 99%

Green, orange, and red Pr^3+∶YLiF_4 epitaxial waveguide lasers

et al. 2014

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Efficient guided laser oscillation in the visible spectral region is demonstrated with praseodymium-doped YLiF(4) layers grown by liquid phase epitaxy. By exciting Pr(3+) ions at 479.2 nm with an optically pumped semiconductor laser, maximum slope efficiencies of 40% at 639 nm and 32% at 604 nm are obtained in a cw regime. Green laser oscillation at 522.5 nm, in a quasi-cw regime, with an average output power of 66 mW, is demonstrated for the first time, to our knowledge, in a crystalline fluoride epitaxial waveguide. Furthermore, a record efficiency of 60% at 639 nm in the quasi-cw regime is reported.

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Low phonon energy, Nd:LaF/sub 3/ channel waveguide lasers fabricated by molecular beam epitaxy

Cited by 20 publications

References 33 publications

Optically pumped planar waveguide lasers, Part I: Fundamentals and fabrication techniques

Optically pumped planar waveguide lasers, Part I: Fundamentals and fabrication techniques

Tm 3 + -doped ion-exchanged aluminum germanate glass waveguide for S-band amplification

Green, orange, and red Pr^3+∶YLiF_4 epitaxial waveguide lasers

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