| Literature DB >> 28983108 |
Ming-Hsuan Kao1, Chang-Hong Shen2, Pei-Chen Yu1, Wen-Hsien Huang2, Yu-Lun Chueh3, Jia-Min Shieh4,5.
Abstract
A p-a-SiC:H window layer was used in amorphous Si thin film solar cells to boost the conversion efficiency in an indoor lighting of 500 lx. The p-a-SiC:H window layer/p-a-Si:H buffer layer scheme moderates the abrupt band bending across the p/i interface for the enhancement of VOC, JSC and FF in the solar spectra of short wavelengths. The optimized thickness of i-a-Si:H absorber layer is 400 nm to achieve the conversion efficiency of ~9.58% in an AM1.5 G solar spectrum. However, the optimized thickness of the absorber layer can be changed from 400 to 600 nm in the indoor lighting of 500 lx, exhibiting the maximum output power of 25.56 μW/cm2. Furthermore, various durability tests with excellent performance were investigated, which are significantly beneficial to harvest the indoor lights for applications in the self-powered internet of thing (IoT).Entities:
Year: 2017 PMID: 28983108 PMCID: PMC5629211 DOI: 10.1038/s41598-017-10661-y
Source DB: PubMed Journal: Sci Rep ISSN: 2045-2322 Impact factor: 4.379
Figure 1(a) A schematic of solar cell configuration and TEM image of a-Si:H thin film solar cells with a p-a-SiC:H window layer (abbreviated p-a-SiC:H solar cell). (b) Tauc’s plots and (c) the depth profiles of atomic ratio between C and Si for p-a-SiC:H window layers with various CH4 flow rates. (d) I-V characteristics of p-a-Si:H and p-a-SiC:H solar cells under the AM1.5 G solar spectrum (e) EQE and (f) Normalized EQEloss (QE(−1 V)/QE(0 V)) of p-a-Si:H and p-a-SiC:H solar cells, respectively. (Inset shows the depth profile of bulk-defect densities in the i-a-Si:H layer retrieved from DLCP measurements for p-a-SiCCH4 = 10:H PV).
Performances of p-a-Si:H, p-a-SiCCH4 = 5:H, p-a-SiCCH4 = 10:H, p-a-SiCCH4 = 15:H and p-a-SiCCH4 = 20:H solar cells under the AM1.5 G solar spectrum where the cell area of 0.25 cm2 was used.
| Illumination condition | Cell type | VOC (volt) | JSC (mA/cm2) | FF (%) | Efficiency (%) |
|---|---|---|---|---|---|
| AM1.5 G solar spectrum | P-a-Si:H | 0.82 | 14.21 | 73.0 | 8.51 |
| P-a-SiCCH4 = 5:H | 0.83 | 14.41 | 72.5 | 8.67 | |
| P-a-SiCCH4 = 10:H | 0.86 | 15.45 | 72.1 | 9.58 | |
| P-a-SiCCH4 = 15:H | 0.82 | 13.58 | 66.0 | 7.35 | |
| P-a-SiCCH4 = 20:H | 0.81 | 12.42 | 61.1 | 6.15 |
Figure 2(a) I-V characteristics of p-a-Si:H and p-a-SiC:H solar cells under the indoor lighting of 500 lx (white FCL illumination). (b) EQE of p-a-SiCCH4 = 10:H solar cells as a function of the thickness of absorber intrinsic layers (di). (c) and (d) I-V characteristics of the p-a-SiCCH4 = 10:H solar cell as a function of di under the AM1.5 G solar spectrum and the indoor lighting of 500 lx (white FCL illumination).
Performances of p-a-Si:H, p-a-SiCCH4 = 5:H, p-a-SiCCH4 = 10:H, p-a-SiCCH4 = 15:H and p-a-SiCCH4 = 20:H solar cells under the indoor lighting of 500 lx by white FCL.
| Illumination condition | Cell type | VOC (volt) | JSC (μA/cm2) | FF (%) | Output power (μW/cm2) |
|---|---|---|---|---|---|
| 500 lx white FCL | P-a-Si:H | 0.61 | 44.81 | 75.2 | 20.56 |
| P-a-SiCCH4 = 5 | 0.62 | 45.81 | 75.1 | 21.33 | |
| P-a-SiCCH4 = 10 | 0.64 | 51.90 | 74.9 | 24.88 | |
| P-a-SiCCH4 = 15 | 0.61 | 43.65 | 72.6 | 19.33 | |
| P-a-SiCCH4 = 20 | 0.60 | 39.86 | 70.5 | 16.86 |
Performances of the p-a-SiCCH4 = 10:H solar cell with different di thicknesses of 400, 600, 800 and 1000 nm under the AM1.5 G solar spectrum, respectively.
| Illumination condition | di thickness | VOC (volt) | JSC (μA/cm2) | FF (%) | Output power (μW/cm2) |
|---|---|---|---|---|---|
| AM1.5 G solar spectrum | 400 nm | 0.85 | 15.45 | 72.1 | 9.50 |
| 600 nm | 0.85 | 16.19 | 68.2 | 9.40 | |
| 800 nm | 0.85 | 15.55 | 63.8 | 8.39 | |
| 1000 nm | 0.84 | 15.10 | 63.1 | 7.98 |
Performances of the p-a-SiCCH4 = 10:H solar cells with different di thicknesses of 400, 600, 800 and 1000 nm under the indoor lighting of 500 lx by the white FCL, respectively.
| Illumination condition | di thickness | VOC (volt) | JSC (μA/cm2) | FF (%) | Output power (μW/cm2) |
|---|---|---|---|---|---|
| 500 lx white FCL | 400 nm | 0.64 | 51.9 | 74.9 | 24.88 |
| 600 nm | 0.64 | 54.18 | 73.7 | 25.56 | |
| 800 nm | 0.64 | 50.97 | 71.5 | 23.37 | |
| 1000 nm | 0.64 | 48.6 | 70.1 | 21.84 |
Figure 3(a) Spectra of white/yellow FCL/LED lights with the lighting of 500 lx. (b) I-V characteristics of the p-a-SiCCH4 = 10:H solar cell with the di of 600 nm under white/yellow FCL/LED lights with the lighting of 500 lx.
Performances of the p-a-SiCCH4 = 10:H solar cell with the di thickness of 600 nm under the indoor lighting of 500 lx by white/yellow FCL/LED.
| Illumination condition | di thickness | VOC (volt) | JSC (μA/cm2) | FF (%) | Output power (μW/cm2) |
|---|---|---|---|---|---|
| 500 lx white FCL | 600 nm | 0.64 | 54.18 | 73.7 | 25.56 |
| 500 lx yellow FCL | 600 nm | 0.64 | 51.43 | 73.8 | 24.29 |
| 500 lx white LED | 600 nm | 0.64 | 52.36 | 73.7 | 24.70 |
| 500 lx yellow LED | 600 nm | 0.64 | 48.60 | 73.6 | 22.89 |
Figure 4(a) Water resistant tests, (b) angle-dependent and (c) heating tolerance measurements of the p-a-SiCCH4 = 10:H solar cell with the di of 600 nm. (d) The conversion efficiency degradation of p-a-SiCCH4 = 10:H PV with the di of 600 nm as a function of exposure time under six AM1.5 G solar spectra at 60 °C.