Air Spheres Research Articles

Modified spontaneous emission of europium complex nanoclusters embedded in colloidal silica spheres

Europium complex nanoclusters were encapsulated inside silica colloidal spheres by a wet-chemical method. The hybrid spheres were characterized to possess a core-shell structure by transmission electron microscopy. The spheres present strong characteristic emissions of Eu 3+ ions, and the fluorescence decay time decreases when the spheres are dispersed in two dielectric polymers. Temperature-dependent decay dynamics indicates that europium complex in sphere-polymer systems display higher spontaneous emission rate compared with free hybrid spheres in air. Our results are suggestive for optimizing the luminescence quantum yield of lanthanide complexes, and also provide a promising probe to investigate modified spontaneous emission in photonic crystals.

Mechanical evaluation of a respiratory device

This article aims to characterize the mechanical behaviour of the Flutter VRP 1, a respiratory physiotherapy device designed to aid sputum clearance of the airways of patients. The device resembles a smoking pipe with a conical cavity containing a stainless steel sphere which floats up and down while the patient comes with a forced expiration through it. The sphere's oscillatory movement is function of the air flow rate and angular orientation of the device. When the sphere's oscillatory frequency matches the natural frequency of the patient's chestwall + abdomen system, it will produce resonance which, in turn, will enhance sputum clearance. A dynamical model of the Flutter was formulated and an experimental setup was assembled in order to study the oscillatory frequency of the sphere under different conditions of air flow rate, fluid pressure, angular orientation and sphere's material and weight. Interesting results presented by this article point to eventual mechanical optimization of the device and show information that could be beneficial to the professional of the respiratory physiotherapy.

Fabrication of a three-dimensional terahertz photonic crystal using monosized spherical particles

Three-dimensional artificial crystals with periodicity corresponding to terahertz wave lengths were fabricated by self-assembling monosized metal spherical particles. The metal crystals were weakly sintered to utilize them as templates. The metal templates were inverted to air spheres crystal embedded in dielectric resin though infiltration and etching. The resulting resin inverted crystals clearly presented the photonic stop gaps within terahertz wave region and the frequencies of the gaps were confirmed to agree well with calculation by plane wave expansion method.

Bragg attenuation length in metallo-dielectric photonic band gap materials

We analyze the ability of the Bragg reflector model to account for the properties of metallo-dielectric photonic crystals. We perform mm-wave transmission measurements on photonic structure consisting of conducting spheres in air and compare our results to the model predictions. In particular, we verify the universal relation between the Bragg attenuation length and the width of the photonic stopband, which is predicted by the Bragg reflector model.

Homogeneity of Oxide Air-Sphere Crystals from Millimeter to 100-nm Length Scales: A Probe for Macroporous Photonic Crystal Formation

We study the homogeneity of photonic air-sphere crystals made of oxides. This important class of macroporous materials is prepared via liquid precursor infiltration of opal templates and subsequent removal of the template by calcination. We have synthesized highly ordered structures of macropores in a solid backbone consisting of two consecutively infiltrated materials: the oxide pairs zirconia/titania (ZrO2/TiO2) and alumina/titania (Al2O3/TiO2). The ordered arrangement of the air spheres was confirmed by scanning electron microscopy. To determine the spatial distribution of the materials, energy-dispersive spectroscopy was used. It was observed that there are variations in the distribution of oxide materials throughout the sample on length scales ranging from 1 mm to 100 nm. We propose that the spatial variations originate from the reaction process where the precursors hydrolyze and possibly also from the densification that occurs in the calcination step. Since many light emitters are quenched on semic...

Effect of particle fluidization intensity on floating and sinking of objects in a gas-solid fluidized bed

Abstract The floating and sinking of different density spheres in a gas-solid fluidized bed was investigated by changing the superficial air velocity, bed height, particle diameter and sphere diameter. Vertical shaking of the fluidized bed surface was observed under these experimental conditions to evaluate particle fluidization intensity. Those observations were compared with the results of sphere floating and sinking. Small spheres of diameter = 4:76 mm tended to drift in the fluidized bed without floating or sinking with increasing superficial air velocity. However, the spheres easily floated and sank when the bed height or particle diameter was small even if the superficial air velocity was relatively large. Vertical shaking decreased with decreasing superficial air velocity, bed height and particle diameter. Spheres floated and sank according to the density difference when the vertical shaking was less than 1 cm. These results indicate that optimum conditions to reduce particle fluidization intensity should be employed to obtain steady floating and sinking of objects in practice.

Speed of sound in periodic elastic composites.

We consider the low-frequency limit (homogenization) for propagation of sound waves in periodic elastic medium (phononic crystals). Exact analytical formulas for the speed of sound propagating in a three-dimensional periodic arrangement of liquid and gas or in a two-dimensional arrangement of solids are derived. We apply our formulas to the well-known phenomenon of the drop of the speed of sound in mixtures. For air bubbles in water we obtain a perfect agreement with the recent results of coherent potential approximation obtained by Phys. Rev. Lett. 84, 6050 (2000)] if the filling of air bubbles is far from close packing. When air spheres almost touch each other, the approximation gives 10 times lower speed of sound than the exact theory does.

Piezoelectric–mechanical–acoustic couplings from a PZT-actuated vibrating beam and its sound radiation

This paper presents a finite element modelling of flexural actuation of an aluminium cantilever beam by two thin plates made of piezoelectric PZT-ceramic material. An analytical study describes the actuators as flexural wave-source into the beam that once excited radiates sound waves into the surrounding air. FEM-calculations of piezoelectric–mechanical–acoustic aspects correlated together are then conducted with ANSYS that has been chosen for its coupled-field modelling capabilities. As the PZT-plates are polarised in their thickness direction but operate in the plane dimension, their input material properties are orthotropic and characterised by the three, stiffness, dielectric and piezoelectric, matrices. The finite element analysis takes into account a physical adhesive bonding between actuators and beam, as well as beam damping conditions. Sound radiation of the vibrating beam is calculated within an air sphere surrounding the beam and in contact with it by a fluid–structure interaction zone. Results are given in the form of spatial distributions of sound pressure and frequency response functions. A complete calculation example is also given for the sixth flexural vibration eigenmode at 1550 Hz of the beam. Validation of the numerical results is conducted through measurements for both piezoelectric–mechanical and mechanical–acoustic couplings.

Exploring for 3D photonic bandgap structures in the 11 f.c.c. space groups.

The promise of photonic crystals and their potential applications has attracted considerable attention towards the establishment of periodic dielectric structures that in addition to possessing robust complete bandgaps, can be easily fabricated with current techniques. A number of theoretical structures have been proposed. To date, the best complete photonic bandgap structure is that of diamond networks having Fd3m symmetry (2-3 gap). The only other known complete bandgap in a face-centred-cubic (f.c.c.) lattice structure is that of air spheres in a dielectric matrix (8-9 gap; the so called 'inverse-opal' structure). Importantly, there is no systematic approach to discovering champion photonic crystal structures. Here we propose a level-set approach based on crystallography to systematically examine for photonic bandgap structures and illustrate this approach by applying it to the 11 f.c.c. groups. This approach gives us an insight into the effects of symmetry and connectivity. We classify the F-space groups into four fundamental geometries on the basis of the connectivity of high-symmetry Wyckoff sites. Three of the fundamental geometries studied display complete bandgaps--including two: the F-RD structure with Fm3m symmetry and a group 216 structure with F43m symmetry that have not been reported previously. By using this systematic approach we were able to open gaps between the 2-3, 5-6 and 8-9 bands in the f.c.c. systems.

Fluid Dynamic Behaviour of Two‐ and Three‐Phase Airlift Reactors

AbstractThis work deals with two‐ and three‐phase airlift systems, employing ambient air, tap water and plastic spheres. The dependency of the main parameters (gas and liquid hold‐ups, liquid circulation rate) on the only external factor, the gas flow rate was investigated. Liquid circulation rate was correlated by a pressure balance which lead to the experimental determination of an overall friction coefficient. A digital camera was used was used, in the second part of the investigation, to determine bubble hold‐up and bubble size distribution. Gas flow rate in the downcomer could be inferred and a tentative correlation with the flow condition prevailing in the riser was suggested.

Synthesis of (Pb,La)(Zr,Ti)O3 Inverse Opal Photonic Crystals

(Pb,La)(Zr,Ti)O3 (PLZT) inverse opal photonic crystals were synthesized by a sol‐gel process with synthetic opal templates of monodisperse submicrometer polystyrene spheres. This process involves infiltration of precursors into the interstices of the opal template, followed by hydrolytic condensation of the precursors and removal of the polystyrene opal combined with crystallization of PLZT perovskite by calcination at a final temperature of 750°C. By this method, PLZT inverse opal photonic crystals with a periodical structure of 280 nm center‐to‐center distance between the air spheres are prepared from opal templates of polystyrene microspheres with a mean diameter of 400 nm. The PLZT inverse opals reflect yellow‐green light strongly.

Structural Color and the Lotus Effect

The study of biological microstructure is one of the most important research areas in biomimicry.[1–3] Microstructure plays many important roles in living things.[2,3] For example, the charming blue color of the Morpho sulkowskyi butterfly originates from light diffraction and scattering, which results from the ordered microstructure of its scales. This form of color is usually known as structural color, which is utilized by animals both for protection and as a warning. Today, the study of structural color has been extended from biology to optics.[4–6] As well as affecting coloration, microstructure also plays an important role in self-cleaning.[2, 7] For the butterfly, the specific nanostructure enhances the hydrophobicity of its wings, which allows droplets of water to be dispersed more easily. During this process, dust particles on the surface of the wings are removed. This phenomenon is known as the “lotus effect”, which is not only very useful for natural species, but also for materials applications, such as for decoration where a natural force might be used to clean a surface. It would be interesting to discover whether it is possible to design a material that incorporates both structural color and the lotus effect, thus mimicking the wings of a butterfly. Such a material should be of great biological and technological importance. In this paper, we will show one approach to fabricating such a biomimetic decorative material by taking advantage of a nanostructured inverse opal surface. Inverse opal is a solid material that consists of a threedimensional network.[6,8–10] Orderedmonodisperse air spheres throughout the network contribute to an optical stop band, the position of which can be tuned by careful control of the periodicity of the air spheres. Colors can be observed by the naked eye when the stop band falls in the visible region. As a consequence of its unique optical properties, inverse opal has been regarded as a new-generation decorative material, in addition to its application as a photonic crystalline material.[6,11] Recently, we realized that inverse opal might also be incorporated into the design of a hydrophobic material. The solid material network of inverse opal contributes a rough surface composed of well-ordered meshes. According to the Cassie–Baxter law, the intrinsic wettability of the solid material can be greatly reduced.[12] Such a decorative material, which exhibits both structural color and the lotus effect, would be environmentally friendly and energy-efficient. For practical applications, a convenient method of fabricating a uniform inverse opal film over a large area is required. In addition, the rough inverse opal surface needs to be further optimized to imbue the surface with superhydrophobic character. We describe here the development of a dipping method that can be used to meet these criteria, and which can derive uniform inverse opal films with a nanostructured surface. The procedure for the fabrication is as follows: First, submicron-sized monodisperse polystyrene spheres and nanosized particles were ultrasonically dispersed into deionised water. A glass substrate was then immersed into the solution and withdrawn at a constant speed. It is known that a mixture of spheres with different sizes cannot be used to fabricate colloidal crystals with long-range structural order by such a deposition method,[13–15] as phase separation occurs, or an amorphous structure is formed. In our experiment, we found that this conclusion is only partially correct. A structure with long-range order can be derived when the ratio of the diameters of the spheres falls into a particular regime. Figure 1a shows an image of a structure composed of monodisperse spheres, while Figure 1b–d displays three images of structures composed of spheres of two sizes, with diameter ratios of 0.94, 0.34, and 0.07, respectively. The structure formed by the spheres of varying size depends on the diameter ratio. A structure with long-range order can be observed in films composed of monodisperse spheres, however, such order is absent in films composed of spheres of two sizes, where the diameter ratio is larger than 0.15. Usually, the particles form a structure with discernible separation when the ratio between the two types of sphere is larger than 0.5 (Figure 1b), while the domains formed by different types of particles are separated when the ratio is smaller than this value (Figure 1c). When the diameter ratio between the [7] W. P. Rothwell, W. Shen, J. H. Lunsford, J. Am. Chem. Soc. 1984, 106, 2452 – 2453. [8] Each unit cell of CHA contains 36 T sites and three cages. The HSAPO-34 used has one Si, five P, and six Al atoms per cage. [9] J. F. Haw, P. W. Goguen, T. Xu, T. W. Skloss, W. Song, Z. Wang, Angew. Chem. 1998, 110, 993 – 995; Angew. Chem. Int. Ed. 1998, 37, 948 – 949.

Complete three-dimensional band gap in macroporous silicon photonic crystals

The prospect of obtaining a complete three-dimensional band gap in macroporous silicon photonic crystals is investigated theoretically. Band structure calculations indicate that a modified form of the simple cubic lattice of air spheres in silicon exhibits a complete band gap, with a bandwidth of up to 4%. It is further shown that this quasispherical crystal may be fabricated using standard etching procedures. These results provide a practical route to obtaining large-scale, high-quality, silicon photonic crystals with a complete band gap.

Angle-resolved reflectivity of single-domain photonic crystals: effects of disorder.

Angle-resolved reflectivity has been measured from single-domain photonic crystals consisting of air spheres in a TiO2 backbone. Monochromatic beams are focused to a 10 microm spot, and kept on the rotation axis with a precision better than 10 microm. We report high reflectivity up to 94% and surface domains as large as 200 microm, with a mosaic spread of +/-3 degrees. The maximum reflectivity at normal incidence agrees well with theoretical calculations in the scalar-wave approximation, extended to include an extinction length due to diffuse scattering, that is obtained from independent experiments. The angle-resolved stop bands compare favorably with previous measurements using coarse beams as well as with prior theoretical calculations. Inhomogeneous broadening introduced by coarse beams in previous measurements is found to be small. Our results can only be understood if we assume multiple Bragg diffraction from more than one family of planes simultaneously to take place.

Tuning the Optical Properties of Inverse Opal Photonic Crystals by Deformation

Simple uniaxial elongation of the air spheres in polymer inverse opal is used to tune the material’s stop band. Stretching causes the distance between the (111) planes parallel to the film surface to decrease, resulting in a shift of the stop band to shorter wavelength. This is coupled with a shift to longer wavelength of the stop band associated with periodicity in the stretching direction. The Figure shows the resulting elongated air voids.

Tunable three-dimensional photonic crystals using semiconductors with varying free-carrier densities

We show from theoretical calculations that three-dimensional photonic crystals constructed with close-packed air spheres in a semiconductor matrix can exhibit a complete photonic band gap (CPBG) in the near-infrared range. The CPBG is easily tunable by using the free-carrier density dependence of plasma frequencies of semiconductors. The frequency of the defect mode created by inserting a slab of semiconductor into inverted opals is also found to be tunable by changing the density of free carriers of the semiconductor.

Large-scale ordered macroporous SiO2 thin films by a template-directed method

Ordered three-dimensional macroporous SiO2 films were fabricated by colloidal crystal templating. Scanning electron microscope measurements showed that the size of the air sphere replicates that of the initial polystyrene spheres, and that the porous sample exhibits long-range order. Optical measurements show that the macroporous sample exhibits the behavior of a photonic band gap, indicating crystalline order in the sample. Fourier-transform infrared measurements revealed that a strong network of Si–O–Si bonds have been formed throughout the voids of the template before the solidification of the gel. It is proposed that this network hinders the large volume shrinkage during the subsequent heat treatment, and thus high-quality large-scale ordered macroporous films can be obtained.

Effect of cohesive interparticle force on the flow characteristics of granular material

The transition from free-flowing to “stick–slip” or cohesive flow in particulate solids was studied using two systems: glass spheres in humidity-controlled air and iron spheres within a magnetic field. The flow characteristics of glass spheres in the range 25–3000 μm were studied as a function of relative humidity (RH) using a rotating inclined cup apparatus. It was found that there is a critical relative humidity at which the spheres undergo the transition from free-flowing to stick–slip behaviour, and this critical humidity increases with increasing particle size. Atomic Force Microscope (AFM) measurements suggest that this transition is due to the system achieving a certain critical level of cohesive interparticle force and not due to an abrupt rise in this force. Similar experiments were performed using iron spheres in a magnetic field, thus allowing the interparticle (magnetic) cohesive force to be controlled. The results confirmed the above finding and suggested that the transition from free-flowing to stick–slip behaviour occurs at a critical ratio of interparticle force to particle weight.

Acoustic properties of colloidal crystals

We present a systematic study of the frequency band structure of acoustic waves in crystals consisting of nonoverlapping solid spheres in a fluid. We consider colloidal crystals consisting of polystyrene spheres in water, and an opal consisting of close-packed silica spheres in air. The opal exhibits an omnidirectional frequency gap of considerable width; the colloidal crystals do not. The physical origin of the bands are discussed for each case in some detail. We present also results on the transmittance of finite slabs of the above crystals.

Observation of coupled plasmon-polariton modes of plasmon waveguides for electromagnetic energy transport below the diffraction limit

AbstractWe study the influence of optical near-field interactions on the dipole surface plasmon resonance of Au nanoparticles in closely spaced particle arrays using finite-difference timedomain simulations. In particular, the resonance energies of the collective plasmon-polariton modes are determined for longitudinal and transverse polarization for different particle array lengths and inter-particle spacings of 50 nm Au spheres in air. The obtained results are set in context with recent publications suggesting the possibility to use ordered arrays of closely spaced noble metal nanoparticles as plasmon waveguides for electromagnetic energy below the diffraction limit of light.