High-efficiency selective boron emitter formed by wet chemical etch-back for <i>n</i>-type screen-printed Si solar cells

Tao, Yuguo; Madani, Keeya; Cho, Eunhwan; Rounsaville, Brian; Upadhyaya, Vijaykumar; Rohatgi, A.

doi:10.1063/1.4973626

Cited by 44 publications

(12 citation statements)

References 18 publications

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“…In this regard, optimization of diffusion technology to form good-quality p-n junctions is the basis for realizing the high-efficiency potential of n-types and must be emphasized in the future. This is because the formation of p + diffused layers using BBr 3 is expected to maintain about 85% of the market share until 2029, as there is no viable alternative available [3, [9][10][11].…”

Section: Introductionmentioning

confidence: 99%

Correlation between Boron–Silicon Bonding Coordination, Oxygen Complexes and Electrical Properties for n-Type c-Si Solar Cell Applications

et al. 2020

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In this paper, the relationship between coordination complexes and electrical properties according to the bonding structure of boron and silicon was analyzed to optimize the p–n junction quality for high-efficiency n-type crystalline solar cells. The p+ emitter layer was formed using boron tribromide (BBr3). The etch-back process was carried out with HF-HNO3-CH3COOH solution to vary the sheet resistance (Rsheet). The correlation between boron–silicon bonding in coordination complexes and electrical properties according to the Rsheet was analyzed. Changes in the boron coordination complex and boron–oxygen (B–O) bonding in the p+ diffused layer were measured through X-ray photoelectron spectroscopy (XPS). The correlation between electrical properties, such as minority carrier lifetime (τeff), implied open-circuit voltage (iVoc) and saturation current density (J0), according to the change in element bonding, was analyzed. For the interstitial defect, the boron ratio was over 1.8 and the iVoc exceeded 660 mV. Additional gains of 670 and 680 mV were obtained for the passivation layer AlOx/SiNx stack and SiO2/SiNx stack, respectively. The blue response of the optimized p+ was analyzed through spectral response measurements. The optimized solar cell parameters were incorporated into the TCAD tool, and the loss analysis was studied by varying the key parameters to improve the conversion efficiency over 23%.

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Section: Introductionmentioning

confidence: 99%

Correlation between Boron–Silicon Bonding Coordination, Oxygen Complexes and Electrical Properties for n-Type c-Si Solar Cell Applications

et al. 2020

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“…E xtracting energetic carriers from light absorption in socalled hot carrier Schottky barrier (SB) junctions has attracted enormous attention, as it allows harvesting low photon energies that have so far been omitted from semiconductor photodetectors. 1−8 Since metals offer zero bandgap energy, their operation can in principle cover visible, mid-infrared, terahertz, and microwave regimes, which holds great promises for gas detection, 9,10 imaging sensors, 11 wavelength determination, 12,13 power monitoring, 14 and sustainable power supplies. 15−17 Taking silicon photodetectors (with a bandgap energy of 1.1 eV) 18 for instance, exploitation of SB devices can result in a highly integrated CMOScompatible and inexpensive alternative to commercially used germanium (Ge) and gallium arsenide (GaAs) photodetectors at telecommunication wavelengths.…”

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confidence: 99%

TiO_2–x-Enhanced IR Hot Carrier Based Photodetection in Metal Thin Film–Si Junctions

Güsken

Lauri

et al. 2019

ACS Photonics

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We investigate titanium nitride (TiN) thin film coatings on silicon for CMOS-compatible sub-bandgap charge separation upon incident illumination, which is a key feature in the vast field of on-chip photodetection and related integrated photonic devices. Titanium nitride of tunable oxidation distributions serves as an adjustable broadband light absorber with high mechanical robustness and strong chemical resistivity. Backside-illuminated TiN on p-type Si (pSi) constitutes a self-powered and refractory alternative for photodetection, providing a photoresponsivity of about ∼1 mA/W at 1250 nm and zero bias while outperforming conventional metal coatings such as gold (Au). Our study discloses that the enhanced photoresponse of TiN/pSi in the near-infrared spectral range is directly linked to trap states in an ultrathin TiO2–x interfacial interlayer that forms between TiN and Si. We show that a pSi substrate in conjunction with a few nanometer thick amorphous TiO2–x film can serve as a platform for photocurrent enhancement of various other metals such as Au and Ti. Moreover, the photoresponse of Au on a TiO2–x /pSi platform can be increased to about 4 mA/W under 0.45 V reverse bias at 1250 nm, allowing for controlled photoswitching. A clear deviation from the typically assumed Fowler-like response is observed, and an alternative mechanism is proposed to account for the metal/semiconductor TiO2–x interlayer, capable of facilitating hole transport.

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“…In recent years, extensive studies on boron emitter passivation with different films and deposition methods have been reported, such as by thermal SiO 2, 22,23 atomic layer deposited (ALD) TiO 2, 24 ALD Al 2 O 3, 25,26 ALD Al 2 O 3 /TiO 2 stacks, 27,28 plasma‐enhanced ALD (PEALD) Al 2 O 3 /plasma‐enhanced chemical vapor deposited (PECVD) SiN x , 29 atmospheric pressure chemical vapor deposition (APCVD) Al 2 O 3 /PECVD SiN x , 29 PECVD AlO x /SiN x , 30–32 PECVD SiO x /SiN x , 33 and PECVD SiON/SiN x . 34 However, there have been very few reports using boronsilicate glass (BSG) as a passivating film, especially on a textured surface with device applications.…”

Section: Introductionmentioning

confidence: 99%

Unlocking the potential of boronsilicate glass passivation for industrial tunnel oxide passivated contact solar cells

Liao

et al. 2021

Progress in Photovoltaics

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In this work, we present a breakthrough in boronsilicate glass (BSG) passivated industrial tunnel oxide passivated contact (i‐TOPCon) solar cells. We find that a high‐temperature firing process significantly improves the front side BSG passivation quality; however, the use of such high‐temperatures is undesirable for metallization as it could lead to more junction damage by the metal paste spikes. In this study, we present a simple and industrially viable method to resolve this dilemma. With a high‐temperature industrial firing activation step to maximize the potential of BSG passivation, a low emitter saturation current (J0e) of 34 fA/cm2 has been achieved, demonstrating excellent boron emitter passivation that is comparable to state‐of‐the‐art SiO2 and Al2O3‐based passivation methods on similar structures and boron emitters. Applying this solution to cell device, the open‐circuit voltage (Voc) is improved by about 6 mV, corresponding to an absolute cell efficiency improvement of about 0.2%. Furthermore, after activating the BSG passivation, a lower temperature paste could be used at the rear side which further improves the Voc by around 3 mV. Combined together, an overall improvement of Voc close to 10 mV is achieved, propelling the cell Voc into the 690‐mV era. The effectiveness of this solution was also verified in a mass production line, with average cell efficiencies of around 23.2% (0.5% more than the baseline) and a maximum cell efficiency and Voc of 23.4% and 693 mV, respectively. This work opens new routes for further improving conventional solar cell efficiencies, in particular for BSG‐passivated TOPCon solar cells.

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High-efficiency selective boron emitter formed by wet chemical etch-back for n-type screen-printed Si solar cells

Cited by 44 publications

References 18 publications

Correlation between Boron–Silicon Bonding Coordination, Oxygen Complexes and Electrical Properties for n-Type c-Si Solar Cell Applications

Correlation between Boron–Silicon Bonding Coordination, Oxygen Complexes and Electrical Properties for n-Type c-Si Solar Cell Applications

TiO_2–x-Enhanced IR Hot Carrier Based Photodetection in Metal Thin Film–Si Junctions

Unlocking the potential of boronsilicate glass passivation for industrial tunnel oxide passivated contact solar cells

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High-efficiency selective boron emitter formed by wet chemical etch-back for n-type screen-printed Si solar cells

Cited by 44 publications

References 18 publications

Correlation between Boron–Silicon Bonding Coordination, Oxygen Complexes and Electrical Properties for n-Type c-Si Solar Cell Applications

Correlation between Boron–Silicon Bonding Coordination, Oxygen Complexes and Electrical Properties for n-Type c-Si Solar Cell Applications

TiO2–x-Enhanced IR Hot Carrier Based Photodetection in Metal Thin Film–Si Junctions

Unlocking the potential of boronsilicate glass passivation for industrial tunnel oxide passivated contact solar cells

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TiO_2–x-Enhanced IR Hot Carrier Based Photodetection in Metal Thin Film–Si Junctions