Ex-situ doping of polysilicon hole contacts for silicon solar cells via electron-beam boron evaporation

IF 6.3 2区材料科学 Q2 ENERGY & FUELS Solar Energy Materials and Solar Cells Pub Date : 2025-04-01 Epub Date: 2025-01-08 DOI:10.1016/j.solmat.2024.113387

Yida Pan , Di Yan , Zhongshu Yang , Di Kang , Sergey Rubanov , Jiali Wang , Peiting Zheng , Jie Yang , Xinyu Zhang , James Bullock

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Abstract

In this study, a novel method for doping of p⁺ polysilicon (poly-Si)/SiO_x passivated contacts is demonstrated. This is achieved by using a thin (∼3 nm) boron layer, deposited by electron beam evaporation, as a dopant source on top of an intrinsic poly-Si layer, which allows diffusion of boron into the structure at temperatures above 900 °C. Surface passivation, exemplified by the implied open circuit voltage (iV_oc), and contact resistance, represented by the specific contact resistivity (ρ_c), were studied as a function of activation parameters including the drive-in temperature/time. By optimising the activation condition, doping layer thickness, and hydrogenation process, an iV_oc of 709 mV and a ρ_c of 3.2 mΩcm² is achieved for a 180 nm poly-Si film. This technique was also demonstrated to allow simple patterning of p⁺ poly-Si regions via use of a shadow mask during the boron deposition process. These results highlight an alternative way to form patterned region doping for high performance p⁺ poly-Si/SiO_x passivated contacts, allowing advanced silicon solar cell architectures.

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电子束硼蒸发法在硅太阳电池多晶硅空穴触点的非原位掺杂

在这项研究中，展示了一种新的掺杂p+多晶硅(poly-Si)/SiOx钝化触点的方法。这是通过使用电子束蒸发沉积的薄（~ 3nm）硼层作为掺杂源，在本态多晶硅层上实现的，这允许硼在900°C以上的温度下扩散到结构中。表面钝化，以隐含开路电压（iVoc）为例，接触电阻，以比接触电阻率（ρc）为例，研究了活化参数包括驱动温度/时间的函数。通过优化活化条件、掺杂层厚度和加氢工艺，获得了180nm的多晶硅膜的iVoc为709 mV， ρc为3.2 mΩcm2。该技术还被证明可以在硼沉积过程中通过使用阴影掩膜对p+多晶硅区域进行简单的图像化。这些结果强调了形成高性能p+多晶硅/SiOx钝化触点的图案区域掺杂的另一种方法，从而实现了先进的硅太阳能电池结构。

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来源期刊

Solar Energy Materials and Solar Cells 工程技术-材料科学：综合

CiteScore

12.60

自引率

11.60%

发文量

513

审稿时长

47 days

期刊介绍： Solar Energy Materials & Solar Cells is intended as a vehicle for the dissemination of research results on materials science and technology related to photovoltaic, photothermal and photoelectrochemical solar energy conversion. Materials science is taken in the broadest possible sense and encompasses physics, chemistry, optics, materials fabrication and analysis for all types of materials.