Identification of the feature genes involved in cytokine release syndrome in COVID-19

With PV Thermal panels sunlight is converted into electricity and heat simultaneously. Per unit area the total efficiency of a PVT panel is higher than the sum of the efficiencies of separate PV panels and solar thermal collectors. During the last 20 years research into PVT techniques and concepts has been widespread, but rather scattered. This reflects the number of possible PVT concepts and the accompanying research and development problems, for which it is the general goal to optimise both electrical and thermal efficiency of a device simultaneously. The aspects that can be optimised are, amongst others, the spectral characteristics of the PV cell, its solar absorption and the internal heat transfer between cells and heat-collecting system. Another important level of optimisation is for the PVT device geometry and the integration into a system. The electricity and heat demand and the temperature level of the heat determine the choice for a certain system set-up. With an optimal design, PVT systems can supply buildings with 100% renewable electricity and heat in a more cost-effective manner than separate PV and solar thermal systems and thus contribute to the long-term international targets on implementation of renewable energy in the built environment.

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Detailed analysis of the energy yield of systems with covered sheet-and-tube PVT collectors

Santbergen

et al. 2010

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Modeling the thermal absorption factor of photovoltaic/thermal combi-panels

Santbergen¹,

Zolingen²

2006

Energy Conversion and Management

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Gettering in polycrystalline silicon solar cells

Verhoef

Michiels

Roorda

et al. 1990

Materials Science and Engineering: B

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Combined impurity gettering and defect passivation in polycrystalline silicon solar cells

Verhoef

Michiels

Sinke

et al. 1990

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Polycrystalline silicon wafers have been subjected to annealing (700 °C, 1 h) and to a hydrogen plasma (350 °C, 30 min) during the processing of solar cells. The annealing treatment enhances the bulk minority-carrier recombination lifetime by 19%, presumably by impurity gettering. The plasma treatment improves the lifetime by 26%; hydrogen passivation accounts for at least 2/3 of this improvement. Gettering and passivation are found to be complementary: application of both treatments results in a 43% increase in lifetime compared to standard.

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R.J.C. van Zolingen

PV thermal systems: PV panels supplying renewable electricity and heat

Detailed analysis of the energy yield of systems with covered sheet-and-tube PVT collectors

Modeling the thermal absorption factor of photovoltaic/thermal combi-panels

Gettering in polycrystalline silicon solar cells

Combined impurity gettering and defect passivation in polycrystalline silicon solar cells

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