Wook-Jin Choi;Young-Woo Ok;Keeya Madani;Vijaykumar D Upadhyaya;Ajay D Upadhyaya;Brian Rounsaville;Pradeep Padhamnath;Gabby De Luna;John Derek Arcebal;Ajeet Rohatgi
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引用次数: 0
Abstract
This article presents a commercially viable process for fabricating a high-quality double-side tunnel oxide passivating contact (DS-TOPCon) cell precursor using atmospheric pressure chemical vapor deposition deposited boron silicate glass and ex situ POCl
3
diffusion in a single high-temperature step, eliminating the need for additional masking and diffusion processes. A two-tier temperature profile was developed, involving a preannealing at above 900 °C in nitrogen ambient followed by POCl
3
diffusion at 840 °C. We investigated the effect of varying preannealing temperatures, ranging from 875 to 950 °C, on the passivation quality and metal-Si contact properties of both
n
-TOPCon and
p
-TOPCon layers. The resultant DS-TOPCon cell precursor after silicon nitride passivation exhibited an excellent iV
OC
of close to 730 mV. In addition, a rapid asymmetric poly-Si thinning technique, developed in this work, enabled adjustment of the front
n
+
poly-Si thickness while maintaining the rear
p
+
poly-Si thickness. Two types of DS-TOPCon cell architectures can be fabricated: i) full-area thin (≈40 nm)
n
-TOPCon layer on the front and ii) selective-area thick (≈200 nm)
n
-TOPCon fingers underneath the metal grid. Device simulations suggest that full-area DS-TOPCon cell with 40 nm
n+
poly-Si and selective-area DS-TOPCon cell with 200 nm
n+
poly fingers on the front, fabricated from our current DS-TOPCon cell precursor, can achieve cell efficiencies of 22.1% and 23.5%, respectively. Detailed power loss analysis and device simulation reveal that further improvements in material and device parameters have the potential to push the cell efficiencies of DS-TOPCon cell structure beyond 25%, making it a promising alternative to fabricate high-efficiency next-generation solar cells at low cost.
期刊介绍:
The IEEE Journal of Photovoltaics is a peer-reviewed, archival publication reporting original and significant research results that advance the field of photovoltaics (PV). The PV field is diverse in its science base ranging from semiconductor and PV device physics to optics and the materials sciences. The journal publishes articles that connect this science base to PV science and technology. The intent is to publish original research results that are of primary interest to the photovoltaic specialist. The scope of the IEEE J. Photovoltaics incorporates: fundamentals and new concepts of PV conversion, including those based on nanostructured materials, low-dimensional physics, multiple charge generation, up/down converters, thermophotovoltaics, hot-carrier effects, plasmonics, metamorphic materials, luminescent concentrators, and rectennas; Si-based PV, including new cell designs, crystalline and non-crystalline Si, passivation, characterization and Si crystal growth; polycrystalline, amorphous and crystalline thin-film solar cell materials, including PV structures and solar cells based on II-VI, chalcopyrite, Si and other thin film absorbers; III-V PV materials, heterostructures, multijunction devices and concentrator PV; optics for light trapping, reflection control and concentration; organic PV including polymer, hybrid and dye sensitized solar cells; space PV including cell materials and PV devices, defects and reliability, environmental effects and protective materials; PV modeling and characterization methods; and other aspects of PV, including modules, power conditioning, inverters, balance-of-systems components, monitoring, analyses and simulations, and supporting PV module standards and measurements. Tutorial and review papers on these subjects are also published and occasionally special issues are published to treat particular areas in more depth and breadth.