63 research outputs found
Mechanisms of light energy harvesting in dendrimers and hyperbranched polymers
Since their earliest synthesis, much interest has arisen in the use of dendritic and structurally allied forms of polymer for light energy harvesting, especially as organic adjuncts for solar energy devices. With the facility to accommodate a proliferation of antenna chromophores, such materials can capture and channel light energy with a high degree of efficiency, each polymer unit potentially delivering the energy of one photon-or more, when optical nonlinearity is involved. To ensure the highest efficiency of operation, it is essential to understand the processes responsible for photon capture and channelling of the resulting electronic excitation. Highlighting the latest theoretical advances, this paper reviews the principal mechanisms, which prove to involve a complex interplay of structural, spectroscopic and electrodynamic properties. Designing materials with the capacity to capture and control light energy facilitates applications that now extend from solar energy to medical photonics. © 2011 by the authors; licensee MDPI, Basel, Switzerland
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Molecular designs toward improving organic photovoltaics
Organic photovoltaics (OPVs) that have been studied to date have poor power conversion efficiencies. This dissertation focuses on various molecular designs that could lead to both a fundamental understanding of photoinduced charge separation at a molecular level and also provide a solution to improve bulk properties of organic materials to overcome the poor efficiencies of OPV devices. The effect of molecular architectures on the efficiency of electron transfer, a primary step in OPVs functioning, is evaluated in this work. We have shown that even though dendrimer provides an interesting architecture for efficient electron transfer due to the presence of multiple peripheries around a single core, this architecture leads to trapping of charge at the dendritic core. This results in a decrease in the electron transfer efficiency in solution and also limits the possibility of charge transport to the electron in a photovoltaic device. Non-conjugated polymers containing conductive EDOT units at side chains were also designed and synthesized. The frontier energy levels of these polymers can be easily tuned by changing the conjugation lengths of side chain EDOT oligomers. Moreover, by incorporating crosslinkable units as co-side chains, the absorption bandwidth of these polymers can be manipulated as well
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PMSE 318-Heterogeneous electron transfer: A tool to probe the dendritic encapsulation at the periphery
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PMSE 318-Heterogeneous electron transfer: A tool to probe the dendritic encapsulation at the periphery
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Probing the periphery of dendrimers by heterogeneous electron transfer
The accessibility of the electroactive periphery was studied and compared for dendrimers and linear analogs by heterogeneous electron transfer using microelectrodes
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