Abstract
AbstractIn this work, we develop SiOx/poly‐Si carrier‐selective contacts grown by low‐pressure chemical vapor deposition and boron or phosphorus doped by ion implantation. We investigate their passivation properties on symmetric structures while varying the thickness of poly‐Si in a wide range (20‐250 nm). Dose and energy of implantation as well as temperature and time of annealing were optimized, achieving implied open‐circuit voltage well above 700 mV for electron‐selective contacts regardless the poly‐Si layer thickness. In case of hole‐selective contacts, the passivation quality decreases by thinning the poly‐Si layer. For both poly‐Si doping types, forming gas annealing helps to augment the passivation quality. The optimized doped poly‐Si layers are then implemented in c‐Si solar cells featuring SiO2/poly‐Si contacts with different polarities on both front and rear sides in a lean manufacturing process free from transparent conductive oxide (TCO). At cell level, open‐circuit voltage degrades when thinner p‐type poly‐Si layer is employed, while a consistent gain in short circuit current is measured when front poly‐Si thickness is thinned down from 250 to 35 nm (up to +4 mA/cm2). We circumvent this limitation by decoupling front and rear layer thickness obtaining, on one hand, reasonably high current (JSC‐EQE = 38.2 mA/cm2) and, on the other hand, relatively high VOC of approximately 690 mV. The best TCO‐free device using Ti‐seeded Cu‐plated front contact exhibits a fill factor of 75.2% and conversion efficiency of 19.6%.
Highlights
Supported by TCAD simulations, we evaluate the effects of doping profile in polycrystalline silicon (poly-Si)/SiO2/c-Si stack on passivation quality and band alignment for carrier collection
Reduced layer thickness in both electron and hole-selective contact requires a careful tuning of implantation dose, annealing temperature and time to confine the dopants atoms into poly-Si layer, leaving a sufficiently high doping tail that results in better passivation quality
We optimize poly-Si layers as carrier-selective passivating contacts prepared by LPCVD and boron- or phosphorousdoped via ion implantation
Summary
The better passivation properties observed for increased implantation dose can be explained by the higher doping concentration into poly-Si layer that enhances carrier selectivity inducing a stronger electrical field across the junction.[53] A similar trend has been observed in literature by other researchers.[14,54,55] we test the effect of FGA on the investigated stack (sample n3), measuring a significant improvement in the passivation properties.
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