Title :
An Efficient Finite-Difference Time-Domain Algorithm to Simulate the Absorbed Energy of Nonflat Layers or Particles of Thin-Film Solar Cells
Author :
Seok Yong Byun ; Seok-Joo Byun ; Dongwoo Sheen ; Taek-Sung Lee
Author_Institution :
Insideoptics, Inc., Seoul, South Korea
Abstract :
We propose an efficient and accurate finite-difference time-domain (FDTD) algorithm to simulate the absorbance of a thin-film solar cell containing nanometer particles or nonflat layers. This algorithm can extract a closed boundary for an arbitrarily shaped object, with the solar cell model being discretized into a set of Yee´s cells to construct the FDTD system. Using this information, we can distinguish the closed boundaries of the components (e.g., particles or layers) of the solar cell and accurately calculate the absorbance of each particle or layer. Moreover, using the closed line (in 3-D, surface) integration instead of the area (in 3-D, volume) integration enables faster calculation and requires less memory.
Keywords :
finite difference time-domain analysis; integration; semiconductor device models; semiconductor thin films; solar cells; thin film devices; FDTD algorithm; Yee cells; closed line integration; finite-difference time-domain algorithm; nanometer particles; nonflat layer absorbed energy; particle absorbed energy; thin-film solar cell; Absorption; Finite difference methods; Gold; Photovoltaic cells; Plasmons; Ray tracing; Time-domain analysis; Absorbance; finite-difference time domain (FDTD); nanometer particles; nonflat layer; thin-film solar cell;
Journal_Title :
Photovoltaics, IEEE Journal of
DOI :
10.1109/JPHOTOV.2015.2427574
