Nanoparticle doping for high power fiber lasers at eye-safer wavelengths

Baker, Colin; Friebele, E. J.; Burdett, Ashley; Rhonehouse, Daniel L.; Fontana, Jake; Kim, Woohong; Bowman, S. R.; Shaw, L. Brandon; Sanghera, Jasbinder S.; Zhang, Jun; Pattnaik, R.; Dubinskii, Mark; Ballato, John; Kucera, Courtney; Vargas, Amber L.; Hemming, Alexander; Simakov, Nikita; Haub, John

doi:10.1364/oe.25.013903

Cited by 64 publications

(31 citation statements)

References 18 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Despite the novel composition of the incorporated nanocrystals the results do not significantly differ from those achieved with fibers doped with now widely used aluminum oxide nanocrystals. More than a decade of intense research in the world-leading laboratories has led to the preparation of aluminum oxide nanocrystals doped fibers exhibiting lifetimes ranging from 10.3 to 11.8 ms [6,20] and laser slope efficiency ranging from 8% to 75%. It should be pointed out that the reported results were achieved for a monolithic Fabry-Perot fiber laser setup, the slope efficiency of which is usually higher.…”

Section: Discussionmentioning

confidence: 99%

“…This novel method started a glamour career; it has attracted huge attention of the researchers [6,16,17] and has rapidly found its place in industry [18,19]. It has been generally accepted that the nanoparticle doping significantly improves properties of active optical fibers [16,20,21] in comparison with the traditional solution doping method [11]. A homogeneous distribution of nanoparticles inside the fiber core suppresses optical losses.…”

mentioning

confidence: 99%

See 1 more Smart Citation

YAG Ceramic Nanocrystals Implementation into MCVD Technology of Active Optical Fibers

et al. 2018

View full text Add to dashboard Cite

Nanoparticle doping is an alternative approach the conventional solution doping method allowing the preparation of active optical fibers with improved optical and structural properties. The combination of the nanoparticle doping with MCVD process has brought new technological challenges. We present the preparation of fiber lasers doped with Er-doped yttrium aluminum garnet (Er:YAG) nanocrystals. These nanocrystals, prepared by a hydrothermal reaction, were analyzed by several structural methods to determine the mean nanocrystal size and an effective hydrodynamic radius. The nanocrystals were incorporated into silica frits with various porosity made by the conventional MCVD process. The Er:YAG-doped silica frits were processed into preforms, which were drawn into optical fibers. We studied the effect of the nanocrystal size and frit's porosity on the final structural and optical properties of prepared preforms and optical fibers. Selected optical fibers were tested as an active medium in a fiber ring laser setup and the characteristics of the laser were determined. Optimal laser properties were achieved for the fiber length of 7 m. The slope efficiency of the fiber laser was about 42%. Presented method can be simply extended to the deposition of other ceramic nanomaterials.fiber laser materials, such as high thermal stability, improved luminescence, etc. [7]. Recent progress in nanotechnologies has brought a completely novel powerful tool to this field.Rare-earth doped glass has been used as basic material in active fiber core. Tick [8] suggested to replace glass in the fiber core with glass-ceramic material to improve the active fiber properties. This innovative approach started a new research field of glass-ceramic and nanoparticle doped fibers [9,10]. However, the prepared fibers exhibited quite high background losses in comparison with conventional glass fibers [6,[11][12][13][14]. The nanoparticle doping of alumina nanoparticles, for the first time presented at 20th Annual Meeting of the IEEE Lasers and Electro-Optics Society in 2007 [15], has brought the major breakthrough in the field of nanoparticle doped active optical fibers. It was demonstrated that the nanoparticle doping is fully competitive with the conventional solution doping method. This novel method started a glamour career; it has attracted huge attention of the researchers [6,16,17] and has rapidly found its place in industry [18,19]. It has been generally accepted that the nanoparticle doping significantly improves properties of active optical fibers [16,20,21] in comparison with the traditional solution doping method [11]. A homogeneous distribution of nanoparticles inside the fiber core suppresses optical losses. The nanoparticle structure and their composition can improve luminescence properties of the incorporated rare-earth element which determines the operating wavelength of the fiber laser [1,6,17].A number of advanced methods and materials have been studied to produce active fibers suitable for fiber lasers. Besides the nanoparticle do...

show abstract

Section: Discussionmentioning

confidence: 99%

mentioning

confidence: 99%

YAG Ceramic Nanocrystals Implementation into MCVD Technology of Active Optical Fibers

et al. 2018

View full text Add to dashboard Cite

show abstract

“…This new nanoparticle doping MCVD-process was implemented to fabricate REE-doped fibers. Use of erbium-doped nanoparticles allows one to control better Er 3+ local environment, decreasing the probability of the pair-formation and up-conversion level, providing longer luminescence lifetimes; achieving high homogeneity of the dopant along the fiber length erbium-doped fibers; and reducing light attenuation level in the fiber [176][177][178][179]. This approach also works for other REEs [179,180].…”

Section: Glass-ceramics Fibersmentioning

confidence: 99%

“…Use of erbium-doped nanoparticles allows one to control better Er 3+ local environment, decreasing the probability of the pair-formation and up-conversion level, providing longer luminescence lifetimes; achieving high homogeneity of the dopant along the fiber length erbium-doped fibers; and reducing light attenuation level in the fiber [176][177][178][179]. This approach also works for other REEs [179,180]. Fibers have been prepared by adding other NPs, such as REE-doped Y 3 Al 5 O 12 (YAG) [181] and LaF 3 [182,183] nanocrystals.…”

Section: Glass-ceramics Fibersmentioning

confidence: 99%

Nano-Structured Optical Fibers Made of Glass-Ceramics, and Phase Separated and Metallic Particle-Containing Glasses

Veber

Vermillac

et al. 2019

Fibers

View full text Add to dashboard Cite

For years, scientists have been looking for different techniques to make glasses perfect: fully amorphous and ideally homogeneous. Meanwhile, recent advances in the development of particle-containing glasses (PCG), defined in this paper as glass-ceramics, glasses doped with metallic nanoparticles, and phase-separated glasses show that these "imperfect" glasses can result in better optical materials if particles of desired chemistry, size, and shape are present in the glass. It has been shown that PCGs can be used for the fabrication of nanostructured fibers-a novel class of media for fiber optics. These unique optical fibers are able to outperform their traditional glass counterparts in terms of available emission spectral range, quantum efficiency, non-linear properties, fabricated sensors sensitivity, and other parameters. Being rather special, nanostructured fibers require new, unconventional solutions on the materials used, fabrication, and characterization techniques, limiting the use of these novel materials. This work overviews practical aspects and progress in the fabrication and characterization methods of the particle-containing glasses with particular attention to nanostructured fibers made of these materials. A review of the recent achievements shows that current technologies allow producing high-optical quality PCG-fibers of different types, and the unique optical properties of these nanostructured fibers make them prospective for applications in lasers, optical communications, medicine, lighting, and other areas of science and industry.Made of glass, optical fibers inherited all positive and negative properties of this material. Glasses are easy and inexpensive to produce on any scale and in any shape, they can possess high chemical stability and mechanical strength, and have high transparency. However, they could hardly compete, for example, with crystalline materials in thermal conductivity, or rare-earth elements' absorption, emission cross-sections, and available transparency range. Recent advances in glass science showed that properties of this material can be significantly improved if some additional phases are formed or impregnated in the glass. In particular, advances have been achieved in the development of particle-containing glasses: glass-ceramic materials, glasses doped with metallic nanoparticles, and phase-separated glasses. To date, these particle-containing glasses have become quite common and actively used in case of the bulk materials, but are still rather new for fiber optics.The purpose of this review is to summarize recent advances in the fabrication of structured fibers made of particle-containing glasses, their potential benefits, their actual properties, and their potential applications. The review covers three types of particle-containing glasses (PCG): crystalline dielectric particles, i.e., glass-ceramics; metallic nanoparticles (MeNPs); and dielectric amorphous particles, i.e., phase-separated glasses.First, we consider properties of the PCG bulk materials, their potenti...

show abstract

“…Both erbium and holmium doped fiber are high energy laser and both are safe to eye at atmospheric transmission window (Colin et al 2017) [11]. But operating EDFA at wavelength>1600nm is difficult due to decreasing emission so alternative rare earth dopant at 2µm wavelength is investigated.…”

Section: Doped Fibermentioning

confidence: 99%

Design and Performance Analysis of Holmium-Doped Fiber Amplifier Operating at 2µm band

2018

IJMTER

View full text Add to dashboard Cite

This paper investigates the dense WDM system in thespectral region doped fiber amplifier pumped at 1950nm high gain can beutilized inremote sensing, scientific and defence different pumping powers and HDF length is almost constant (flat) at 10W pump power amplified, with 39dBm of output power 2012nm. The performance evaluation of the system is done by analysing the rate(BER), quality factor, extinction ratio and eye BER8.94E-31, high value of Q-factor 11.95dB, highest ER value is 18dB. gain and high power amplifier.

show abstract

Nanoparticle doping for high power fiber lasers at eye-safer wavelengths

Cited by 64 publications

References 18 publications

YAG Ceramic Nanocrystals Implementation into MCVD Technology of Active Optical Fibers

YAG Ceramic Nanocrystals Implementation into MCVD Technology of Active Optical Fibers

Nano-Structured Optical Fibers Made of Glass-Ceramics, and Phase Separated and Metallic Particle-Containing Glasses

Design and Performance Analysis of Holmium-Doped Fiber Amplifier Operating at 2µm band

Contact Info

Product

Resources

About