Title :
Macroporous Silicon Solar Cells With an Epitaxial Emitter
Author :
Ernst, Michael ; Brendel, Rolf
Author_Institution :
Inst. for Solar Energy Res. Hamelin, Emmerthal, Germany
Abstract :
In this paper, we separate a macroporous silicon absorber from a monocrystalline n-type silicon wafer by means of electrochemical etching. The porosity is (31 ± 3)%. The epitaxial growth of a p +-type Si layer onto one side of the macroporous silicon substrate forms a pn-junction that covers the full outer and inner surface of the macroporous layer. Epitaxy reduces the porosity to (19 ± 2)%. The thickness of the epitaxial layer is (3.0 ± 0.2) μm on the rear side and (0.4 ± 0.1) μm on the pore walls. We process (35 ± 2)-μm-thick macroporous silicon solar cells with an aperture area of 2.25 cm2. The short-circuit current density is 37.1 mA cm-2, and the open-circuit voltage is 544 mV. A fill factor of 65.1% limits the energy-conversion efficiency to 13.1%.
Keywords :
current density; elemental semiconductors; epitaxial growth; etching; p-n heterojunctions; porosity; semiconductor epitaxial layers; semiconductor growth; silicon; solar absorber-convertors; solar cells; Si; aperture area; electrochemical etching; energy-conversion efficiency; epitaxial emitter; epitaxial growth; epitaxial layer thickness; macroporous layer; macroporous silicon solar cells; macroporous silicon substrate; monocrystalline n-type silicon wafer; open-circuit voltage; p +-type Si layer; pn-junction; pore walls; porosity; rear side; short-circuit current density; silicon absorber; size 0.3 mum to 0.5 mum; size 2.8 mum to 3.2 mum; voltage 544 mV; Epitaxial growth; Epitaxial layers; Etching; Photovoltaic cells; Resistance; Silicon; Epitaxy; kerf-free; layer transfer; macroporous silicon; thin films;
Journal_Title :
Photovoltaics, IEEE Journal of
DOI :
10.1109/JPHOTOV.2013.2247094
