I. Moura scite author profile

Semiconductor quantum dot (QD) assemblies are promising systems for light harvesting and energy conversion and transfer, as they have a superior photostability compared to classical dyes and their absorption and emission properties can be tuned during synthesis. Here, we investigate excitonic energy transfer in self-assembled dentrite-type fractal structures consisting of QDs by microscopically mapping their fluorescence spectra and lifetimes. The behaviors of CdSe/ZnS and CdTe QD assemblies are compared; in particular, the energy transfer probability is found to be stronger in CdTe-based structures, scaling with their radiation quantum yield. Our results indicate Förster-type energy transfer in both systems, although with a higher efficiency in CdTe. The energy transfer is caused by near-field (nonradiative) dipole–dipole coupling between the individual QDs within a dendrite, with the excitation migrating from the edges to the center of the structure. The experimental findings are supported by theoretical modeling results obtained by using master equations for exciton migration/decay kinetics in diffusion-limited fractal aggregates composed of identical particles.

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Bioplastics from agro-wastes for food packaging applications

Moura

Sá

Abreu

et al. 2017

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Biodegradability assessment of aliphatic polyesters‐based blends using standard methods

Moura

Machado

Duarte

et al. 2010

J of Applied Polymer Sci

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Important information concerning polymer's final fate in the environment can be achieved in biodegradation studies. In this context, the focus of this study was to evaluate the biodegradability of blends containing aliphatic polyesters using standard methods. Blends of high-density polyethylene, biodegradable polymer, and polyethylene modified with maleic anhydride (used as compatibilizer) were prepared in a corotating twin-screw extruder. Biodegradable polymers used were poly(lactic acid) (PLA), poly(e-caprolactone) (PCL), and Mater-Bi (thermoplastic starch with PLA or PCL). Biodegradation tests were carried out using two standard methods: (i) ISO 14851 (1999), biochemical oxygen demand in a closed respirometer and (ii) ASTM G 22-76, microbial growth of test microorganisms. Both biodegradability tests suggested that the blend containing PCL is more biodegradable than the one containing PLA. Addition of starch increased the biodegradability of the PLA blend. The biodegradability of the blends evaluated in this study by the biochemical oxygen demand method ranged from 22% (PLA 60) to 52% for corn starch/PCL 30/70 (% wt) (SPCL 70). Therefore, the blends may not be considered ''readily biodegradable'' according to the OECD standard.

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I. Moura

Characterization of EVA/PLA Blends When Exposed to Different Environments

Synthesis of EVA-g-PLA copolymers using transesterification reactions

Energy Transfer via Exciton Transport in Quantum Dot Based Self-Assembled Fractal Structures

Bioplastics from agro-wastes for food packaging applications

Biodegradability assessment of aliphatic polyesters‐based blends using standard methods

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