Optical properties of chain inverted pyramids on silicon

Quansheng Chen; Quansheng Chen; Quansheng Chen; Yaoping Liu; Yaoping Liu; Hanbo Tang; Hanbo Tang; Hanbo Tang; Yan Wang; Yan Wang; Wei Chen; Wei Chen; Juntao Wu; Juntao Wu; Yan Zhao; Yan Zhao; Xiaolong Du; Xiaolong Du; Xiaolong Du; Xiaolong Du

doi:10.1364/AO.381932

Applied Optics
Vol. 59,
Issue 7,
pp. 2065-2071
(2020)
•https://doi.org/10.1364/AO.381932

Optical properties of chain inverted pyramids on silicon

Quansheng Chen, Yaoping Liu, Hanbo Tang, Yan Wang, Wei Chen, Juntao Wu, Yan Zhao, and Xiaolong Du

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Quansheng Chen, Yaoping Liu, Hanbo Tang, Yan Wang, Wei Chen, Juntao Wu, Yan Zhao, and Xiaolong Du, "Optical properties of chain inverted pyramids on silicon," Appl. Opt. 59, 2065-2071 (2020)

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Abstract

Pyramidal structures, including upright pyramids and inverted pyramids (IPs), are commonly used as light-trapping structures for silicon solar cells and silicon photodetectors. In this paper, the possible ray propagation paths in a pyramidal structure are analyzed by establishing a mathematical model in which up to seven ray paths may exist either in a regular or random pyramidal structure. To reduce the reflectivity, the proportion of the quadruple bounce should be increased because of its lower reflectivity. Therefore, a chain IP structure with a quadruple bounce proportion of 10.33% is proposed, of which the overlap value $\Delta x/w$ is 0.4. According to theoretical ray-tracing calculations, the weighted average reflectivity is reduced by 0.75% compared to that of a random IP structure. Experimentally, chain IP structures are fabricated from the surface line damage produced by the diamond wire sawing of a silicon wafer as a mask, and the reflectivity of the structures is 0.80% lower than that of a random IP structure. The theoretical analysis and experimental results both show that the chain IP structure has better optical properties than the random IP structure, indicating promising prospects for the abovementioned applications.

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Supplementary Material (1)

Name	Description
Visualization 1	The area of each ray path with different value of the overlap ?x /w

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Path	Reflective Surface	First Reflection		Second Reflection		Third Reflection		Fourth Reflection		Fifth Reflection
A	$S_{1} - S_{3}$	$S_{1}$	54.74	$S_{3}$	15.79
		109.5	42.78	38.94	58.7
B	$S_{1} - S_{3} - S_{1}$	$S_{1}$	54.74	S ₃	15.79	$S_{1}$	86.32
		109.5	42.78	38.94	58.7	31.59	69.41
C	$S_{1} - S_{2} - S_{3}$	$S_{1}$	54.74	$S_{2}$	78.9	$S_{3}$	33.49
		109.5	42.78	96.38	52.01	31.59	61.47
D	$S_{1} - S_{2} - S_{4}$	$S_{1}$	54.74	$S_{2}$	78.9	$S_{4}$	71.29
		109.5	42.78	96.38	52.01	74.97	57.21
E	$S_{1} - S_{2} - S_{4} - S_{2}$	$S_{1}$	54.74	$S_{2}$	78.9	$S_{4}$	71.29	$S_{2}$	88.77
		109.5	42.78	96.38	52.01	74.97	57.21	73.5	60.69
F	$S_{1} - S_{2} - S_{4} - S_{3}$	$S_{1}$	54.74	$S_{2}$	78.9	$S_{4}$	71.29	$S_{3}$	51.68
		109.5	42.78	96.38	52.01	74.97	57.21	12.76	65.85
G	$S_{1} - S_{2} - S_{4} - S_{2} - S_{3}$	$S_{1}$	54.74	$S_{2}$	78.9	$S_{4}$	71.29	$S_{2}$	88.77	$S_{3}$	52.71
		109.5	42.78	96.38	52.01	74.97	57.21	73.5	60.69	10.41	66.13

Abstract

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Applied Optics