氮掺杂氧化亚铜薄膜的低电阻富土金属触点

S. Siah, Y. Lee, R. Brandt, T. Buonassisi
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引用次数: 2

摘要

在光伏器件中,为了最大限度地减少电阻性功率损耗,需要在新型接地吸收材料上形成低电阻欧姆触点。我们首先表明,通过掺杂Cu2O功能层的应用,可以显著降低3种惰性金属(Au, Ag和Pd)对铜(I)氧化物(Cu2O)薄膜的比接触电阻率(ρc)。Pd与氮掺杂(n掺杂)Cu2O薄膜的比接触电阻率低至1.1×10-4 Ω·cm2。这是迄今为止报道的Cu2O薄膜的最低ρc。温度相关的电流电压(IVT)测量表明,名义上未掺杂的薄膜以热离子发射为主,而n掺杂的薄膜则以场发射为主。此外,IVT表明,由于隧道结的形成,氮掺杂薄膜的ρc不依赖于金属类型。最后,我们证明了利用地球上丰富的金属,如Cu和Ni,可以在n掺杂的Cu2O薄膜上实现低接触电阻率。
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Low-resistance earth-abundant metal contacts to nitrogen-doped cuprous oxide thin films
Formation of low-resistance ohmic contacts to novel earth abundant absorber materials is required to minimize resistive power losses in photovoltaic devices. We first show that the specific contact resistivity (ρc) of 3 inert metals (Au, Ag and Pd) to copper (I) oxide (Cu2O) thin films can be reduced significantly through the application of a doped Cu2O functional layer. Specific contact resistivity as low as 1.1×10-4 Ω·cm2 is observed for Pd to nitrogen-doped (N-doped) Cu2O films. This is the lowest-ever reported ρc to date for Cu2O films. Temperature-dependent current-voltage (IVT) measurements indicate that thermionic emission dominates for nominally undoped films whilst field emission dominates for N-doped films. Additionally, IVT suggests that ρc does not depend on metal type for N-doped films due to the formation of a tunneling junction. Lastly, we demonstrate that low contact resistivity can be achieved on N-doped Cu2O films using Earth-abundant metals such as Cu and Ni.
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