MoSe2 formation during fabrication of Cu(In, Ga)Se2 solar cell absorbers by using stacked elemental layer precursor and selenization at high temperatures

S. Schmidt, C. Wolf, N. Papathanasiou, R. Schlatmann, C. Klimm, M. Klaus, C. Genzel, M. Billing, H. Schock
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引用次数: 3

Abstract

Cu(In, Ga)Se2 solar cell absorbers are prepared on a Mo-coated glass substrate by using a sequential process consisting of a sputter deposition of an In/CuGa/In metal precursor, subsequent PVD deposition of a Se layer and annealing in N2 atmosphere. The Se concentration in the final layer stack was found to be relatively up to 20 % higher than expected. The excess Se is bound in a MoSe2 layer with laterally varying thickness, between the absorber and the Mo back contact. Such a layer can lead to an increase in the series resistance of the completed solar cells. By pumping at a specific time, we were able to reduce the Se partial pressure selectively during the selenization. For a constant annealing time, we find that the MoSe2 thickness increases with the time in which a high Se partial pressure is maintained, i.e., the time before the selective pumping. A significant reduction of the Se partial pressure after half the annealing time led to solar cells with the smallest series resistance and overall best conversion efficiency. We further found that the addition of NaF before the annealing led to comparatively thin MoSe2 layers. This suggests that the Na incorporation from the glass substrate in our process is too small to hinder the MoSe2 growth. A more specific control of the Na supply is required in our process to manipulate the MoSe2 growth and the doping density in the absorber.
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利用叠置元素层前驱体和高温硒化法制备Cu(In, Ga)Se2太阳能电池吸收体过程中MoSe2的形成
采用溅射沉积In/CuGa/In金属前驱体、PVD沉积Se层和N2气氛退火的顺序工艺,在mo涂层玻璃衬底上制备了Cu(In, Ga)Se2太阳能电池吸收体。最后一层堆积中的硒浓度比预期高出20%。多余的Se被束缚在吸收剂和Mo背接触之间具有横向变化厚度的MoSe2层中。这样一层可以导致完成的太阳能电池串联电阻的增加。通过在特定时间泵送,我们能够在硒化过程中选择性地降低硒分压。在一定的退火时间下,我们发现MoSe2的厚度随着高Se分压(即选择性泵送前的时间)保持的时间的增加而增加。经过一半的退火时间后,Se分压显著降低,使得太阳能电池具有最小的串联电阻和最佳的转换效率。我们进一步发现,在退火前加入NaF可以得到相对较薄的MoSe2层。这表明在我们的工艺中,来自玻璃衬底的Na掺入量太小,不会阻碍MoSe2的生长。在我们的工艺中,需要对Na供应进行更具体的控制,以操纵吸收剂中MoSe2的生长和掺杂密度。
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