Sustainable hydrogen production for the greener environment by quantum dots-based efficient photocatalysts: A review

Nano-size photocatalysts exhibit multifunctional properties that opened the door for improved efficiency in energy, environment, and health care applications. Among the diversity of catalyst Quantum dots are a class of nanomaterials having a particle size between 2 and 10 nm, showing unique optoelectrical properties that are limited to some of the metal, metal oxide, metal chalcogenides, and carbon-based nanostructures. These unique characteristics arise from either pristine or binary/ternary composites where noble metal/metal oxide/metal chalcogenide/carbon quantum dots are anchored on the surface of semiconductor photocatalyst. It emphasized that properties, as well as performance of photocatalytic materials, are greatly influenced by the choice of synthesis methods and experimental conditions. Among the chemical methods, photo-deposition, precipitation, and chemical reduction, are the three most influential synthesis approaches. Further, two types of quantum dots namely metal based and carbon-based materials have been highlighted. Based on the optical, electrical and surface properties, quantum dots based photocatalysts have been divided into three categories namely (a) photocatalyst (b) co-catalyst and (c) photo-sensitizer. They showed enhanced photocatalytic performance for hydrogen production under visible/UV-visible light irradiation. Often, pristine metal chalcogenides as well as metal/metal oxide/carbon quantum dots attached to a semiconductor particle exhibit enhanced the photocatalytic activity for hydrogen production through absorption of visible light. Alternatively, noble metal quantum dots, which provide plenty of defects/active sites facilitate continuous hydrogen production. For instance, production of hydrogen in the presence of sacrificial agents using metal chalcogenides, metal oxides, and coinage metals based catalysts such as CdS/MoS₂ (99,000 μmol h^-1g^-1) TiO₂-Ni(OH)₂ (47,195 μmol h^-1g^-1) and Cu/Ag-TiO₂ nanotubes (56,167 μmol h^-1g^-1) have been reported. Among the carbon-based nanostructures, graphitic C₃N₄ and carbon quantum dots composites displayed enhanced hydrogen gas (116.1 μmol h^-1) production via overall water splitting. This review accounts recent findings on various chemical approaches used for quantum dots synthesis and their improved materials properties leading to enhanced hydrogen production particularly under visible light irradiation. Finally, the avenue to improve quantum efficiency further is proposed.

Abstract P6-07-13: Local relapse and survival

Aim: Local recurrence may precede distant relapse and death. Many factors which predict local recurrence also predict death. Few studies have investigated the contribution of local recurrence to mortality independent of prior prognostic factors such as nodal status. We wished to estimate the extent to which overall survival is affected specifically by local recurrence.

Methods: 114 of of 2945 patients aged 19 to 94 years (mean 58.3) who had either mastectomy or breast conservation for breast cancer between 1991 and 2011 subsequently suffered an ipsilateral local recurrence. We matched, with one exception (due to extreme young age), each patient who had a local recurrence with 2 controls matched for calendar year of presentation, age, nodal status, grade, and tumour size. A Cox regression analysis of survival from the first therapeutic operation was done on the case matched subset with local recurrence coded dichotomously and age coded continuously as the absolute deviation from the population mean (as both young and old age affect survival adversely) as predictors. To confirm independence of the effect of local recurrence on the hazard of death a further Cox regression analysis of survival as above was done for the whole series with local recurrence, Grade 3, >3 nodes involved, tumour diameter >40mm, coded dichotomously, and age coded as above as independent variables.

Results: The results of the analyses are given in the table below.

Wise pattern mastectomy with immediate breast reconstruction

A new technique of immediate breast reconstruction is presented. This technique uses a silicone implant placed in a subpectoral pocket, using de-epithelialised skin from the lower breast to augment the submuscular pocket, thus producing a compound myodermal flap. The technique is simple, and the resulting scar is cosmetically satisfactory; when combined with reduction mammoplasty on the opposite breast, this technique produces satisfactory breast symmetry.