During the last decades, the growing urbanization and industrialization result in a significant need for energy. However, since feasible renewable energy sources should be further developed to replace the current energy source, the release of greenhouse gases and their climate change consequences are difficult to overcome. For that reason, the development of renewable energy sources has been attracting growing research efforts. Recently, perovskites gathered great interest owing to their outstanding optical and electrical properties. For instance, their high absorption coefficient and superior charge mobility.
This thesis comprises six scientific articles about perovskites. On one hand, 3 works study the optical phenomena that occur within the material in order to achieve a better understanding. The deep knowledge of these optical phenomena's at the individual level (isolated crystals) enable the modulation and tuning of their synthesis and morphology to match specific applications.
On another hand, perovskites have been implemented in several devices for their application in three research fields: photocatalysis, sensors, and photovoltaic. For the first time, this nanomaterial was successfully employed for obtaining hydrogen carrying out the reaction in the vapor phase. Likewise, several perovskite compositions have been used for decorating graphene and detect trace levels of Volatile Organic Compounds (VOC) as benzene and toluene. And finally, it has been developed a strategy to insert organic molecules in the perovskite structure, resulting in an enhanced photoresponse in the visible range.
Therefore, perovskites have been successfully implemented in several applications, becoming a promising material and easily adaptable to the different requirements needed in each field of study.
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