Unified Electromagnetic-Electronic Design of Light Trapping Silicon Solar Cells

159

We demonstrate through precise numerical simulations the possibility of flexible, thin-film solar cells, consisting of crystalline silicon, to achieve power conversion efficiency of 31%. Our optimized photonic crystal architecture consists of a 15 μm thick cell patterned with inverted micro-pyramids with lattice spacing comparable to the wavelength of near-infrared light, enabling strong wave-interference based light trapping and absorption. Unlike previous photonic crystal designs, photogenerated charge carrier flow is guided to a grid of interdigitated back contacts with optimized geometry to minimize Auger recombination losses due to lateral current flow. Front and back surface fields provided by optimized Gaussian doping profiles are shown to play a vital role in enhancing surface passivation. We carefully delineate the drop in power conversion efficiency when surface recombination velocities exceed 100 cm/s and the doping profiles deviate from prescribed values. These results are obtained by exact numerical simulation of Maxwell’s wave equations for light propagation throughout the cell architecture and a state-of-the-art model for charge carrier transport and Auger recombination.

Section: Introductionmentioning

confidence: 99%

Beyond 30% Conversion Efficiency in Silicon Solar Cells: A Numerical Demonstration

Bhattacharya

John

2019

159

“…predicts that electrical micro-renewable energy systems such as solar PV could provide 30–40% of the United Kingdom’s electricity needs by 2050 4 . Currently, research in the area of photovoltaics is focused primarily on new technologies such as third generation PV 5 , optimising efficiencies and applications of solar cells by unconventional means 6–14 .…”

Section: Introductionmentioning

confidence: 99%

Assessment of the energy recovery potential of waste Photovoltaic (PV) modules

Farrell

Osman

Zhang

et al. 2019

Global exponential increase in levels of Photovoltaic (PV) module waste is an increasing concern. The purpose of this study is to investigate if there is energy value in the polymers contained within first-generation crystalline silicon (c-Si) PV modules to help contribute positively to recycling rates and the circular economy. One such thermochemical conversion method that appeals to this application is pyrolysis. As c-Si PV modules are made up of glass, metal, semiconductor and polymer layers; pyrolysis has potential not to promote chemical oxidation of any of these layers to help aid delamination and subsequently, recovery. Herein, we analysed both used polymers taken from a deconstructed used PV module and virgin-grade polymers prior to manufacture to determine if any properties or thermal behaviours had changed. The calorific values of the used and virgin-grade Ethylene vinyl acetate (EVA) encapsulant were found to be high, unchanged and comparable to that of biodiesel at 39.51 and 39.87 MJ.Kg −1 , respectively. This result signifies that there is energy value within used modules. As such, this study has assessed the pyrolysis behaviour of PV cells and has indicated the energy recovery potential within the used polymers found in c-Si PV modules.

“…This equation assumes that every absorbed photon generates a couple of charge carriers contributing to the delivered current. The evaluation of this spectral absorption, , is based on the following equation 53 , 54 : where is the imaginary part of the dielectric permittivity of the material, and is the square of the electric field intensity inside each material. As far as is evaluated at each location of the structure, it is possible to obtain the total absorbed power contributing to the short-circuit current just by integrating within the volume of interest, in this case, the active layer.…”

Section: Methodsmentioning

confidence: 99%

Resonant nano-dimer metasurface for ultra-thin a-Si:H solar cells

Elshorbagy

Sánchez

Cuadrado

et al. 2021

Low-cost hydrogenated amorphous silicon solar cells (a-Si:H) can perform better and be more competitive by including nanostructures. An optimized nano-dimer structure embedded in close contact with the back electrode of an aSi:H ultra-thin solar cells can enhance the deliverable short-circuit current up to 27.5 %. This enhancement is the result of an increase in the absorption at the active layer, that is the product of an efficient scattering from the nanostructure. From our calculations, the nano-dimer structure must be made out of a high-index of refraction material, like GaP. The evaluation of the scattering and absorption cross section of the structure supports the calculated enhancement in short-circuit current, that is always accompanied by a decrease in the total reflectance of the cell, which is reduced by about 50 %.