Title :
20% Efficient Screen-Printed Cells With Spin-On-Dielectric-Passivated Boron Back-Surface Field
Author :
Das, Arnab ; Meemongkolkiat, Vichai ; Kim, Dong Seop ; Ramanathan, Saptharishi ; Rohatgi, Ajeet
Author_Institution :
Sch. of Electr. & Comput. Eng., Georgia Inst. of Technol. (GIT), Atlanta, GA, USA
Abstract :
This paper reports on the characteristics of a spin-on dielectric which has been used as the rear-surface passivation layer to achieve 20% efficient screen-printed (SP) boron back-surface field (B-BSF) solar cells. The dielectric provides, in a single thermal step, both stable passivation of a heavily doped p+ surface and strong gettering of iron which is a common contaminant in high-temperature boron diffusion processes. It was found that gettering of silicon substrates, contaminated during boron diffusion, is most effective when the dielectric is deposited on top of the boron-doped layer. The effect of dielectric charge density on passivation of p+ surfaces was also studied and a very high charge density of -1013 cm-2 was found to be necessary to significantly improve the passivation on surfaces with a boron concentration.
Keywords :
boron; dielectric thin films; elemental semiconductors; getters; heavily doped semiconductors; iron; passivation; silicon; solar cells; substrates; surface diffusion; Si:B,Fe; boron diffusion process; boron-doped layer; dielectric charge density; rear-surface passivation layer; screen-printed boron back-surface field solar cell; silicon substrates gettering; spin-on dielectric-passivated boron back-surface field; Boron; Costs; Dielectric substrates; Dielectrics; Gettering; Iron; Passivation; Photovoltaic cells; Silicon; Substrates; Surface charging; Surface contamination; Boron; charge carrier lifetime; dielectric films; gettering; passivation; photovoltaic cells; surface charging;
Journal_Title :
Electron Devices, IEEE Transactions on
DOI :
10.1109/TED.2010.2057010
