论文信息 - Laser ablation of SiO2 for locally contacted Si solar cells with ultra‐short pulses

Laser ablation of SiO2 for locally contacted Si solar cells with ultra‐short pulses

We apply ultra-short pulse laser ablation to create local contact openings in thermally grown passivating SiO2 layers. This technique can be used for locally contacting oxide passivated Si solar cells. We use an industrially feasible laser with a pulse duration of τpulse ∼ 10 ps. The specific contact resistance that we reach with evaporated aluminium on a 100 Ω/sq and P-diffused emitter is in the range of 0·3–1 mΩ cm2. Ultra-short pulse laser ablation is sufficiently damage free to abandon wet chemical etching after ablation. We measure an emitter saturation current density of J0e = (6·2 ± 1·6) × 10−13 A/cm2 on the laser-treated areas after a selective emitter diffusion with Rsheet ∼ 20 Ω/sq into the ablated area; a value that is as low as that of reference samples that have the SiO2 layer removed by HF-etching. Thus, laser ablation of dielectrics with pulse durations of about 10 ps is well suited to fabricate high-efficiency Si solar cells. Copyright © 2007 John Wiley & Sons, Ltd.

[1] P. Engelhart,et al. Laser Ablation of Passivating SINx Layers for Locally Contacting Emitters of High-Efficiency Solar Cells , 2006, 2006 IEEE 4th World Conference on Photovoltaic Energy Conference.

[2] M. Green,et al. 24·5% Efficiency silicon PERT cells on MCZ substrates and 24·7% efficiency PERL cells on FZ substrates , 1999 .

[3] Ralf Preu,et al. Laser micromachining for applications in thin film technology , 2000 .

[4] W. Pfleging,et al. New simplified methods for patterning the rear contact of RP-PERC high-efficiency solar cells , 2000, Conference Record of the Twenty-Eighth IEEE Photovoltaic Specialists Conference - 2000 (Cat. No.00CH37036).

[5] D. Schroder,et al. Contact resistance: Its measurement and relative importance to power loss in a solar cell , 1984, IEEE Transactions on Electron Devices.

[6] A. Cuevas,et al. Surface recombination velocity of highly doped n‐type silicon , 1996 .

[7] R. M. Swanson,et al. Approaching the 29% limit efficiency of silicon solar cells , 2005, Conference Record of the Thirty-first IEEE Photovoltaic Specialists Conference, 2005..

[8] R. Sinton,et al. APPLICATIONS OF THE QUASI-STEADY-STATE PHOTOCONDUCTANCE TECHNIQUE , 1998 .