Assessing environment and development outcomes in conservation landscapes

An approach to assessing the environmental outcomes and changes in peoples' livelihoods resulting from landscape-scale conservation interventions was developed for three locations in Africa. Simple sets of performance indicators were developed through participatory processes that included a variety of stakeholders. The selection of indicators was designed to reflect wider landscape processes, conservation objectives and as local peoples' preferred scenarios. This framework, combined with the use of social learning techniques, helped stakeholders develop greater understandings of landscape system dynamics and the linkages between livelihood and conservation objectives. Large scale conservation and development interventions should use these approaches to explore linkages and improve shared understanding of tradeoffs and synergies between livelihood and conservation initiatives. Such approaches provide the basis for negotiating and measuring the outcomes of conservation initiatives and for adapting these to changing perspectives and circumstances

Unified Electromagnetic-Electronic Design of Light Trapping Silicon Solar Cells

A three-dimensional unified electromagnetic-electronic model is developed in conjunction with a light trapping scheme in order to predict and maximize combined electron-photon harvesting in ultrathin crystalline silicon solar cells. The comparison between a bare and light trapping cell shows significant enhancement in photon absorption and electron collection. The model further demonstrates that in order to achieve high energy conversion efficiency, charge separation must be optimized through control of the doping profile and surface passivation. Despite having a larger number of surface defect states caused by the surface patterning in light trapping cells, we show that the higher charge carrier generation and collection in this design compensates the absorption and recombination losses and ultimately results in an increase in energy conversion efficiency. The fundamental physics behind this specific design approach is validated through its application to a 3 μm thick functional light trapping solar cell which shows 192% efficiency enhancement with respect to the bare cell of same thickness. Such a unified design approach will pave the path towards achieving the well-known Shockley-Queisser (SQ) limit for c-Si in thin-film (<30 μm) geometries