TiO2@Silica nanoparticles in a random laser: Strong relationship of silica shell thickness on scattering medium properties and random laser performance

Jiménez‐Villar, Ernesto; Mestre, Valdeci; Oliveira, Paulo César de; Faustino, Wagner M.; Silva, D. S.; Sá, Gilberto F. de

doi:10.1063/1.4865092

Cited by 38 publications

(23 citation statements)

References 26 publications

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“…We attribute this effect to the following causes: (i) the presence of agglomerates of smaller particles (smaller than wavelength), such that the space between scattering surfaces is smaller than one wavelength. This should favor the near‐field coupling, which decreases the effective scattering strength . (ii) The agglomerates made of smaller particles should behave approximately like a bigger particle with a lower effective scattering cross‐section (lower effective refractive index).…”

Section: Absorption Measurements and Transport Mean Free Path Calculamentioning

confidence: 99%

“…On the contrary, a random laser composed by a homogeneous scattering medium with short transport mean free path would be pumped only from the front side of the sample, reducing considerably the volume and intensity of pumping and, consequently, its efficiency. A promising method called fraction of absorbed pumping (FAP) was used to study the absorption and diffusion processes in the samples, which allowed us to determine that the absorbance increases appreciably with the introduction of smaller grains between the big particles.…”

Section: Introductionmentioning

confidence: 99%

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Polydispersed Powders (Nd³⁺:YVO₄) for Ultra Efficient Random Lasers

Wetter

Giehl

Butzbach

et al. 2017

Part & Part Syst Charact

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inherent cost advantages become attractive for the large majority of applications.In order to overcome the problems of random lasers associated to nondirectional output and lack of efficiency, the main approach has been to choose lowdimensional random lasers. 1D fiber random lasers are well suited for this purpose and have achieved up to several watts of continuous output. [10] 2D distributed feedback (DFB) lasers have demonstrated highly efficient and directional output in the microjoule range. [11] These low-dimensional random lasers are generally quite large (like in the case of random fiber lasers) and require sophisticated production methods that are in stark contrast to the simplicity and practicality of the 3D random laser production.Noginov and co-workers have studied the dependence of random laser emission in neodymium doped powders (Nd 0.5 La 0.5 Al 3 (BO 3 ) 4 ) on the particle size, the powder volume density, and the pump spot size. [12,13] Best reported efficiency was below half a percent. An impediment for increasing the efficiency is the surface reflectivity of the compacted powders. The bulk reflection coefficient of Nd 0.5 La 0.5 Al 3 (BO 3 ) 4 at λ = 532 nm for medium to high powder density is ≈0.7. [13] Using a fiber-coupled random laser, where the pump fiber terminates deep inside the scattering medium in order to deliver the pump energy directly into the gain volume without reflection loss at the surface, Noginov et al. achieved a higher efficiency of ≈0.7%. [14] Azkargorta et al. achieved 20% and 42% slope efficiencies with respect to pump power using Nd: yttrium aluminium garnet (YAG) and Nd 3 Ga 5 O 12 crystal powders. [15,16] The stimulated random laser (RL) emission of these rare earth doped powder pellets comes in the form of a Lambertian emission with a linewidth that decreases around laser threshold and becomes much smaller than typical amplified spontaneous emission (ASE). [17] Output power also shows a typical laser threshold and slope efficiency. As we have shown for yttrium vanadate doped with neodymium (Nd:YVO 4 ), the emission decay after a pump pulse follows two different exponentials corresponding to a fast laser emission decay of a few microseconds and a slower fluorescence emission decay which is shorter than the intrinsic decay time, which should amount to 73 µs for 1.33 mol% neodymium doping concentration, because of upconversion. [18] We therefore expected some decrease in laser efficiency due to energy transfer upconversion.Random lasers hold the potential for cheap, coherent light sources that can be miniaturized and molded into any shape with several other added benefits such as speckle-free imaging; however, they require improvements specifically in terms of efficiency. This paper details for the first time a strategy for increasing the efficiency of a random laser that consists in using smaller particles, trapped between large particles to serve as absorption and gain centers whereas the large particles control mainly the light diffusion into the sample. Measurements...

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Section: Absorption Measurements and Transport Mean Free Path Calculamentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Polydispersed Powders (Nd³⁺:YVO₄) for Ultra Efficient Random Lasers

Wetter

Giehl

Butzbach

et al. 2017

Part & Part Syst Charact

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“…In spite of the promising characteristics of dye-based RLs, the dye photodegradation, enhanced due to the presence of the scatterers is a drawback for the basic investigation and practical application of these systems [21,23]. The most used scatterer particles material is TiO 2 in the rutile phase due to its high refractive index (~ 2.6 at 632.8 nm) that implies a large index contrast with the dye solution.…”

Section: Introductionmentioning

confidence: 99%

“…Then, a photocatalytic process is started leading to fast dye degradation [24]. Attempts to minimize the photodegradation were made using scatterer particles based on materials with large energy bandgap [21][22][23]. Indeed, silica particles, which have energy bandgap of ~ 5.0 eV and refractive index of ~ 1.7 in the visible range, have been used and lower photodegradation was observed [21][22][23].…”

Section: Introductionmentioning

confidence: 99%

“…Attempts to minimize the photodegradation were made using scatterer particles based on materials with large energy bandgap [21][22][23]. Indeed, silica particles, which have energy bandgap of ~ 5.0 eV and refractive index of ~ 1.7 in the visible range, have been used and lower photodegradation was observed [21][22][23]. However, two other important points neglected by most of researchers are the particles precipitation and the chemical bonding between the particles and the cuvette walls that contribute to reduce the efficiency and lifetime of the RLs.…”

Section: Introductionmentioning

confidence: 99%

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Observation of photonic paramagnetic to spin-glass transition in a specially designed TiO_2 particle-based dye-colloidal random laser

et al. 2016

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By using specially designed nanoparticles scatterers which prevents photodegradation of the dye, we present clear demonstration of replica symmetry break and a photonic paramagnetic to spin-glass phase transition in a random laser operating in the incoherent feedback regime based on ethanol solution of Rhodamine 6G and amorphous TiO 2 nanoparticles. PACS number(s): 42.55. Zz, 42.55.Mv, 75.50.Lk. 3

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