ZnO nanorods prepared via ablation of Zn with millisecond laser in liquid media

ZnO nanomaterials with controlled size, shape and surface chemistry are required for applications in diverse areas, such as optoelectronics, photocatalysis, biomedicine and so on. Here, we report on ZnO nanostructures with rod-like and spherical shapes prepared via laser ablation in liquid using a laser with millisecond-long pulses. By changing laser parameters (such as pulse width and peak power), the size or aspect ratio of such nanostructures could be tuned. The surface chemistry and defects of the products were also strongly affected by applied laser conditions. The preparation of different structures is explained by the intense heating of liquid media caused by millisecond-long pulses and secondary irradiation of already-formed nanostructures.

Studies on betanin natural dye incorporated ZnO composites at nano and micro scale for photonic device applications

Green energy and Green technology are the most of the quoted terms in the context of modern science and technology. Technology which is close to nature is the necessity of the modern world which is haunted by global warming and climatic alterations. Proper utilization of solar energy is one of the goals of Green Energy Movement. The present thesis deals with the work carried out in the eld of nanotechnology and its possible use in various applications (employing natural dyes) like solar cells. Unlike arti cial dyes, the natural dyes are available, easy to prepare, low in cost, non-toxic, environmentally friendly and fully biodegradable. Looking to the 21st century, the nano/micro sciences will be a chief contributor to scienti c and technological developments. As nanotechnology progresses and complex nanosystems are fabricated, a growing impetus is being given to the development of multi-functional and size-dependent materials. The control of the morphology, from the nano to the micrometer scales, associated with the incorporation of several functionalities can yield entirely new smart hybrid materials. They are special class of materials which provide a new method for the improvement of the environmental stability of the material with interesting optical properties and opening a land of opportunities for applications in the eld of photonics. Zinc oxide (ZnO) is one such multipurpose material that has been explored for applications in sensing, environmental monitoring, and bio-medical systems and communications technology. Understanding the growth mechanism and tailoring their morphology is essential for the use of ZnO crystals as nano/micro electromechanical systems and also as building blocks of other nanosystems.

Purificación de aire mediante oxidación fotocatalítica de gases contaminantes NOₓ: estudio de los fotocatalizadores TiO₂ y ZnO

Los óxidos de nitrógeno (NOx) son gases contaminantes que afectan al medio ambiente al ser responsables de la formación de smog fotoquímico, lluvia ácida, ozono troposférico, reducción de la capa de ozono, además de participar en el efecto invernadero en la forma de N2O. Adicionalmente, la exposición a estos gases provoca daños a la salud de los seres humanos. Una propuesta tecnológica para abordar esta problemática ambiental es su eliminación mediante un proceso fotooxidativo, lo cual requiere del empleo de óxidos semiconductores con alta actividad fotocatalítica. En el presente trabajo de investigación se valoró el alcance de la tecnología de fotocatálisis heterogénea para la purificación de aire por eliminación de gases tipo NOx. Para este propósito, en una primera parte del trabajo se construyó un reactor fotocatalítico de acuerdo a la norma internacional ISO 22197-1 con el fin de realizar las pruebas fotocatalíticas en condiciones estándar a las establecidas por la regulación internacional y dar así consistencia a los resultados obtenidos. La segunda parte del trabajo consistió en la síntesis y caracterización de los óxidos semiconductores TiO2 y ZnO por el método sol-gel para lo cual en cada caso se aplicó un diseño de experimentos con el fin de encontrar las condiciones experimentales que permitieran la obtención del mejor fotocatalizador de cada sistema en base a sus propiedades fisicoquímicas. La actividad fotocatalítica de las muestras de TiO2 y ZnO se determinó en la reacción de fotooxidación de óxido nítrico (NO) en aire bajo radiación UV. Los mejores fotocatalizadores fueron seleccionados para pruebas de desempeño variando las condiciones experimentales de la reacción fotocatalítica como el caudal volumétrico que entró al reactor, la irradiancia y la cantidad de humedad presente en el medio de reacción, evaluando además el efecto de diversas variables experimentales de la reacción fotocatalítica en sus respectivos valores. Asimismo, el seguimiento de los productos de reacción confirmó la presencia iones nitrato (NO3-) como producto mayoritario de la fotooxidación de NO, lo que dota al proceso de eliminación de NO de un carácter sustentable. En una tercera parte del trabajo se probó la actividad fotocatalítica del fotocatalizador TiO2 cuando fue incorporado en un prototipo de material de construcción. El desempeño fue probado bajo condiciones simuladas y reales de exposición a la intemperie. Los resultados obtenidos indicaron la potencial aplicación de los materiales para el desarrollo comercial de productos fotocatalíticos. En la parte final del trabajo se presentan resultados obtenidos con óxidos semiconductores alternos a los convencionales como Bi2Mo3O12 y TiO2/WO3 cuyo principal propósito fue el de desarrollar fotocatalizadores cuya activación fuera mediante absorción en la porción visible del espectro solar.

Microstructure, vibrational and visible emission properties of low frequency ultrasound (42 kHz) assisted ZnO nanostructures

Size and shape tuneable ZnO nanostructures were prepared by a low frequency ultrasound (42 kHz) route using various organic solvents as the reaction media. The crystalline nature, lattice parameters and microstructural parameters such as microstrain, stress and energy density of the prepared ZnO nanostructures were revealed through X-ray diffraction (XRD) analysis. The organic solvents influenced the size and morphology of the ZnO nanostructures, and interesting morphological changes involving a spherical to triangular shaped transition were observed. The visible emission properties and lattice vibrational characteristics of the nanostructures were drastically modified by the changes in size and shape. Raman spectral measurements revealed the presence of multiphonon processes in the ZnO nanostructures. The intensity of the visible emission band was found to vary with the size and morphology of the structures. The strongest visible emission band corresponded to the structure with the largest surface/volume ratio and could be attributed to surface oxygen vacancies. The control over the size and morphology of ZnO nanostructures has been presented as a means of determining the intensity of the visible emission band

Direct synthesis of β-ketophosphonates and vinyl phosphonates from alkenes or alkynes catalyzed by CuNPs/ZnO

Copper nanoparticles (CuNPs) supported on ZnO have been shown to effectively catalyze the direct synthesis of β-ketophosphonates from alkenes or alkynes, and that of vinyl phosphonates from alkynes and diethylphosphite, under air and in the absence of any additive or ligand. When using alkynes as starting materials, the selectivity proved to be dependent on the nature of the alkyne. Thus, alkynes conjugated with an aromatic ring or a carbon–carbon double bond gave β-ketophosphonates as the main reaction products, whereas aliphatic alkynes or alkynes conjugated with a carbonyl group led to the formation of the corresponding vinyl phosphonates.

Light polarization sensitive photodetectors with m- and r-plane homoepitaxial ZnO/ZnMgO quantum wells

Homoepitaxial ZnO/(Zn,Mg)O multiple quantum wells (MQWs) grown with m- and r-plane orientations are used to demonstrate Schottky photodiodes sensitive to the polarization state of light. In both orientations, the spectral photoresponse of the MQW photodiodes shows a sharp excitonic absorption edge at 3.48 eV with a very low Urbach tail, allowing the observation of the absorption from the A, B and C excitonic transitions. The absorption edge energy is shifted by ∼30 and ∼15 meV for the m- and r-plane MQW photodiodes, respectively, in full agreement with the calculated polarization of the A, B, and C excitonic transitions. The best figures of merit are obtained for the m-plane photodiodes, which present a quantum efficiency of ∼11%, and a specific detectivity D* of ∼6.4 × 1010 cm Hz1/2/W. In these photodiodes, the absorption polarization sensitivity contrast between the two orthogonal in-plane axes yields a maximum value of (R⊥/R||)max ∼ 9.9 with a narrow bandwidth of ∼33 meV.

Development of antibacterial ZnO-loaded cotton fabric based on in situ fabrication

A method provided for the deposition of nanostructured ZnO on cotton fabric to introduce antibacterial functionality was presented in this article. This strategy enabled fabric to be coated with inorganic-based functional materials through in situ synthesis of nanoparticles using ultrasonic irradiation. The amino-terminated silicon sol (AEAPTS) was employed to generate nanostructured ZnO, and the mechanism of the ultrasound-assisted coating was proposed. Antibacterial activities, UV protection and other properties of ZnO-loaded cotton characterized by SEM, FTIR, XRD and TGA were investigated. The results indicated that ZnO-loaded cotton exhibited excellent UV protective property, efficient antibacterial activities, well water-resistant effect, together with moderate cytotoxicity against L929 and lower tensile strength. The developed method provides not only a facile way for in situ synthesis of ZnO on textile but also the production of antibacterial materials for healthcare applications.

Nanowires of metal oxides for gas sensing applications

Nanowires of different metal oxides (SnO2, ZnO) have been grown by evaporation-condensation process. Their chemical composition has been investigated by using XPS. The standard XPS quantification through main photoelectron peaks, modified Auger parameter and valence band spectra were examined for the accurate determination of oxidation state of metals in the nanowires. Morphological investigation has been conducted by acquiring and analyzing the SEM images. For the simulation of working conditions of sensor, the samples were annealed in ultra high vacuum (UHV) up to 500°C and XPS analysis repeated after this treatment. Finally, the nanowires of SnO 2 have were used to produce a novel gas sensor based on Pt/oxide/SiC structure and operating as Schottky diode. Copyright © 2008 John Wiley & Sons, Ltd.