Impact of Fast-Firing Conditions on Light- and Elevated-Temperature-Induced Degradation (LeTID) in Ga-Doped Cz–Si

IF 2.5 3区工程技术 Q3 ENERGY & FUELS IEEE Journal of Photovoltaics Pub Date : 2023-11-01 DOI:10.1109/JPHOTOV.2023.3304118

Michael Winter;Dominic C. Walter;Jan Schmidt

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引用次数: 2

Abstract

The fast-firing step commonly applied at the end of solar cell production lines triggers “Light- and elevated-Temperature-Induced Degradation” (LeTID) effects of the carrier lifetime in Ga-doped Cz–Si wafers and solar cells made thereof. As far as the defect formation within the silicon bulk is concerned, the key parameters of the fast-firing step are the peak firing temperature (FT) and the band velocity v_band of the conveyor belt, where the latter mainly defines the cooling ramp after the firing peak. In this contribution, we show that the extent of LeTID and the dependence on the applied temperature during degradation increase strongly with increasing measured FT (from 680 °C to 800 °C), v_band (from 2.8 to 7.2 m/min), and the refractive index n of the hydrogen-rich silicon nitride layer deposited on the wafer surfaces (from 2.07 to 2.37). Through temperature-dependent degradation experiments, we determine an activation energy of E_A = (0.55 ± 0.10) eV of the LeTID mechanism in Ga-doped Cz–Si, which is independent of FT and v_band. From this observation we conclude that a single defect activation mechanism is most likely responsible for the examined LeTID effect, independent of the firing conditions. However, the concentration of recombination-active defect centers after LeTID depends critically on FT, v_band, and n, which we attribute to variations of the in-diffused hydrogen concentrations from the silicon nitride layers during firing. Our experiments hence point towards an involvement of hydrogen in the LeTID mechanism observed in Ga-doped Cz–Si.

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快速点火条件对光的影响- 和Ga掺杂Cz–Si中的高温诱导降解（LeTID）

通常应用于太阳能电池生产线末端的快速烧制步骤触发了Ga掺杂Cz–Si晶片及其制成的太阳能电池中载流子寿命的“光和高温诱导降解”（LeTID）效应。就硅块体内的缺陷形成而言，快速烧制步骤的关键参数是峰值烧制温度（FT）和传送带的带速度vband，其中后者主要定义烧制峰值之后的冷却斜坡。在这一贡献中，我们发现LeTID的程度和降解过程中对施加温度的依赖性随着测量的FT（从680°C到800°C）、vband（从2.8到7.2 m/min）的增加而强烈增加，以及沉积在晶片表面的富氢氮化硅层的折射率n（从2.07到2.37）。通过温度相关的降解实验，我们确定了Ga掺杂Cz–Si中LeTID机制的激活能EA=（0.55±0.10）eV，它与FT和vband无关。根据这一观察结果，我们得出结论，单个缺陷激活机制最有可能是所检查的LeTID效应的原因，与发射条件无关。然而，LeTID之后的复合活性缺陷中心的浓度主要取决于FT、vband和n，我们将其归因于烧制过程中来自氮化硅层的扩散氢浓度的变化。因此，我们的实验表明，在Ga掺杂的Cz–Si中观察到的LeTID机制中涉及氢。

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来源期刊

IEEE Journal of Photovoltaics ENERGY & FUELS-MATERIALS SCIENCE, MULTIDISCIPLINARY

CiteScore

7.00

自引率

10.00%

发文量

206

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