Actividad fotocatalítica de L-Bi2MoO6 y H-Bi2MoO6 en la degradación de rodamina B por acción de luz visible

En el presente trabajo se evaluó a la actividad fotocatalítica del óxido semiconductor Bi2MoO6 por acción de luz visible en la degradación de rodamina B (RhB) en solución acuosa.

Foto-oxidación de bisfenol A bajo la acción de luz visible: el monitoreo de oxígeno disuelto como evidencia de la degradación

Propósito y Método del Estudio: El semiconductor más utilizado para su uso en fotocatálisis es el TiO2 debido a sus características como bajo costo, inocuidad y eficiencia fotocatalítica; alguno de los inconvenientes del uso de este material es su capacidad de activarse con radiación UV. En el presente trabajo se modificó al catalizador TiO2 con N a través del método de síntesis coloidal con el propósito de hacerlo fotoactivo bajo radiación visible; se sintetizaron catalizadores modificados a diferentes cantidades teóricas de nitrógeno, los cuales se caracterizaron morfológica y estructuralmente; posteriormente se evaluó la actividad fotocatalítica, bajo radiación visible con una solución de Bisfenol A realizando el seguimiento de la degradación fotocatalítica mediante espectroscopia UV-Vis y cromatografía de líquidos de alta resolución acoplado a espectrometría de masas (HPLC-MS). Contribuciones y Conclusiones: los resultados confirmaron que la incorporación de Nitrógeno al TiO2 provoca cambios en la cristalinidad, morfología y área superficial, así como en su actividad con radiación visible. La evolución fotocatalitica demostró que el catalizador modificado con 5% fue el que presento mayor eficiencia en la degradación de Bisfenol A.

Sonochemical synthesis of CuO nanostructures and their morphology dependent optical and visible light driven photocatalytic properties

A controlled synthesis of CuO nanostructures with various morphologies were successfully achieved by presence/absence of low frequency (42 kHz) ultrasound with two different methods. The size, shape and morphology of the CuO nanostructures were tailored by altering the ultrasound, mode of addition and solvent medium. The crystalline structure and molecular vibrational modes of the prepared nanostructures were analysed through X-ray diffraction and FTIR measurement, respectively which confirmed that the nanostructures were phase pure high-quality CuO with monoclinic crystal structure. The morphological evaluation and elemental composition analysis were done using TEM and EDS attached with SEM, respectively. Furthermore, we demonstrated that the prepared CuO nanostructures could be served as an effective photocatalyst towards the degradation of methyl orange (MO) under visible light irradiation. Among the various nanostructures, the spherical shape CuO nanostructures were found to have the better catalytic activities towards MO dye degradation. The catalytic degradation performance of MO in the presence of CuO nanostructures showed the following order: spherical\nanorod \layered oval \nanoleaf \triangular \shuttles structures. The influence of loading and reusability of catalyst revealed that the efficiency of visible light assisted degradation of MO was effectively enhanced and more than 95 % of degradation was achieved after 3 cycles

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