Nickel-assisted growth and selective doping of spinel-like gallium oxide nanocrystals in germano-silicate glasses for infrared broadband light emission

Сигаев, В. Н.; Golubev, N. V.; Ignat’eva, E. S.; Savinkov, V. I.; Campione, Marcello; Lorenzi, Roberto; Meinardi, Francesco; Палеари, А.

doi:10.1088/0957-4484/23/1/015708

Cited by 40 publications

(46 citation statements)

References 34 publications

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“…This trend has been also observed in germanate-based materials for which the authors have shown by optical absorption measurements that Ni ions are fully embedded in the crystalline phase. [ 53 ] No emission in the near-infrared could be obtained in our glass material, even for a 980 nm excitation, as previously reported for several glass systems. [ 48,54,55 ] In the glass ceramic, the emission observed at around 1300 nm for a similar excitation corresponds to octahedral coordinated Ni 2+ ions ( 3 T 2 → 3 A 2 transition).…”

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confidence: 86%

“…[ 48,54,55 ] In the glass ceramic, the emission observed at around 1300 nm for a similar excitation corresponds to octahedral coordinated Ni 2+ ions ( 3 T 2 → 3 A 2 transition). [53][54][55] The Ni 2+ luminescence emission around 1300 nm in the octahedral site has already been reported. [ 48,54,55 ] In Figure 4 b, the emission maximum is located at 1325 nm.…”

Section: Full Paper Full Paper Full Papermentioning

confidence: 81%

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Tuneable Nanostructuring of Highly Transparent Zinc Gallogermanate Glasses and Glass‐Ceramics

Chenu

Véron

Genevois

et al. 2014

Advanced Optical Materials

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routes [ 9,10 ] have been recently reported. Technical challenges remain to produce these transparent ceramic materials (complicated and time-consuming procedures to avoid porosity, [ 11 ] limited compositions, segregation of doping agents, etc.). Many of these obstacles can be avoided via the use of glass-ceramic technology. [ 12 ] Therefore, the development of transparent glassceramics is of great interest for many promising optical applications [ 13 ] (solar concentrators, [ 14 ] optical memory media, [ 15 ] telescope mirrors, [ 16 ] amplifi ers, [ 17 ] electrooptical devices [ 18 ] ). Unlike single crystals and polycrystalline sintered ceramics, glass-ceramic materials offer considerable advantages such as a wider range of accessible chemical compositions, fabrication of complex shapes, and largescale production by fast and cost-effi cient glass-forming processes. The absence of porosity, control of the microstructure, and high transparency allow a large variety of optical glass-ceramics to be designed and commercialized.Glass-ceramic technology is generally based on the controlled crystallization of glass. [ 12 ] According to the Rayleigh-GansDebye [ 19 ] and Hendy theories, [ 20 ] the retention of transparency during glass crystallization typically requires a homogeneous distribution of nanoscale crystals in the glass-ceramic material to minimize light scattering. Nucleating agents (such as ZrO 2 and TiO 2 ) are thus often added in the parent glass to produce, by heat treatment, uniformly dispersed nanocrystals. [ 21 ] Nevertheless, a few exceptions with large crystal sizes (β-quartz- [ 16 ] and Na 2 O-CaO-SiO 2 -based glass-ceramics [ 22 ] ) have been reported, and their transparency is directly linked to a very small refractive index difference between the amorphous and crystalline phases. Much attention has been devoted to transparent silicate glass-ceramics, which often present low thermal expansion, thermal stability, and high transparency in both visible and near-infrared ranges. [ 12,16 ] However, silicatebased glass-ceramics present a high phonon energy, which considerably limits their transparency in the infrared range and therefore their applications in this domain. The development of oxyfl uoride [23][24][25][26] and chalcogenide [ 27,28 ] glass-ceramics has extended the transparency toward the infrared range. These materials offer a real alternative allowing access to applications in telecommunications [ 25,26,29 ] (up-conversion devices, waveguide amplifi ers), although their poor chemical durability and complex fabrication (synthesis under a controlled New nanostructured gallogermanate-based glass materials exhibiting high transparency in the visible and infrared regions are fabricated by conventional melt-quenching. These materials can accommodate wide oxide compositions and present nanoscale phase separation, in the form of droplets well separated from the germanate matrix. The size of the nanostructures can be tailored depending on the composition. A single heat treatment then allows select...

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Section: Full Paper Full Paper Full Papersupporting

confidence: 86%

Section: Full Paper Full Paper Full Papermentioning

confidence: 81%

Tuneable Nanostructuring of Highly Transparent Zinc Gallogermanate Glasses and Glass‐Ceramics

Chenu

Véron

Genevois

et al. 2014

Advanced Optical Materials

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“…Particularly, no data are available on the intrinsic properties of g-Ga 2 O 3 NCs in glass, since the only studies on embedded variants were essentially aimed at obtaining convenient hosts for IR-emitting ions, such as Ni 2+ and Cr 4+ . 15,17,34 As a result, the data in Fig. 2 constitute the rst quantitative insight into the absorption edge of g-Ga 2 O 3 as a nanophase in a solid matrix.…”

Section: Resultsmentioning

confidence: 80%

“…Doping the investigated glass with Ni 2+ ions gives rise, in fact, to full incorporation of Ni 2+ into g-Ga 2 O 3 NCs upon nanocrystallization, as we found in a previous work by registering the changes of Ni 2+ crystal eld absorption and IR luminescence. 15 The selective doping of NCs with Ni 2+ ions gives a tool for lowering N A by means of heterovalent cations with oxidation state smaller than Ga 3+ . Bearing in mind that acceptors consist of (V O , V Ga ) 0 complexes -and that the presence of native V Ga is somewhat related to the oxygen deciency determined by the synthesis conditions -we expect that Ni 2+ ions could lower the number of Ga 3+ vacancies required by charge neutrality at a xed oxygen defectiveness.…”

Section: W(r)mentioning

confidence: 99%

“…[15][16][17] At present, however, data on light emission properties of nanosized Ga oxides are only available for nanopowders and nanowires, or NCs in colloidal solutions. 14,[18][19][20][21][22][23][24][25] A large fraction of those results regard the b-Ga 2 O 3 phase, 4,6,7,[10][11][12][13][14]22 whereas only a few studies concern the metastable polymorph g-Ga 2 O 3 .…”

Section: Introductionmentioning

confidence: 99%

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Light-emitting Ga-oxide nanocrystals in glass: a new paradigm for low-cost and robust UV-to-visible solar-blind converters and UV emitters

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Recent Advances in Hybrid Optical Materials: Integrating Nanoparticles within a Glass Matrix

Wei

Ebendorff‐Heidepriem

Zhao

2019

Advanced Optical Materials

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Glass containing optically active nanoparticles have been manufactured for centuries. However, only in the early 1900s, the invention of ultramicroscope and development of Mie theory paved the way to discovering the occurrence of nanoparticles in glass and their special role in imparting unique optical properties to glass. This groundbreaking insight inspired scientists to extensively research such nanoparticles‐in‐glass hybrid optical materials, which led to a series of fundamental breakthroughs (e.g., invention of glass ceramics, discovery of quantum dots) and commercial successes (e.g., photosensitive glass, photochromic glass, dichromic polarizer). Over the past decades, a new wave of research in this area has been initiated by opportunities of incorporating a large variety of synthetic nanoparticles in glass, which promises the development of advanced functional devices for lighting, display, smart window, data storage, and sensing applications. Recent development of various approaches of fabricating nanoparticles‐in‐glass hybrid optical materials and postmodifying nanoparticles that are embedded in glass is reviewed. The state‐of‐the‐art techniques relevant to controlling the dispersion, distribution, orientation, and nanostructure of nanoparticles in glass, as well as manipulating the macroscopic performance of the hybrid materials are discussed. Examples of applications with promising pathway to commercially viable devices based on hybrid optical materials are outlined.

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Nickel-assisted growth and selective doping of spinel-like gallium oxide nanocrystals in germano-silicate glasses for infrared broadband light emission

Cited by 40 publications

References 34 publications

Tuneable Nanostructuring of Highly Transparent Zinc Gallogermanate Glasses and Glass‐Ceramics

Tuneable Nanostructuring of Highly Transparent Zinc Gallogermanate Glasses and Glass‐Ceramics

Light-emitting Ga-oxide nanocrystals in glass: a new paradigm for low-cost and robust UV-to-visible solar-blind converters and UV emitters

Recent Advances in Hybrid Optical Materials: Integrating Nanoparticles within a Glass Matrix

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