Development and characterization of a low thermal budget process for multi-crystalline silicon solar cells

Higher conversion efficiencies while reducing costs at the same time is the ultimate goal driving the development of solar cells. Multi-crystalline silicon has attracted considerable attention because of its high stability against light soaking. In case of solar grade multi-crystalline silicon the r...

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Bibliographic Details
Main Author: Krockert, Katja
Other Authors: TU Bergakademie Freiberg, Chemie und Physik
Format: Doctoral Thesis
Language:English
Published: Technische Universitaet Bergakademie Freiberg Universitaetsbibliothek "Georgius Agricola" 2016
Subjects:
Online Access:http://nbn-resolving.de/urn:nbn:de:bsz:105-qucosa-192742
http://nbn-resolving.de/urn:nbn:de:bsz:105-qucosa-192742
http://www.qucosa.de/fileadmin/data/qucosa/documents/19274/Krockert_1b.pdf
id ndltd-DRESDEN-oai-qucosa.de-bsz-105-qucosa-192742
record_format oai_dc
collection NDLTD
language English
format Doctoral Thesis
sources NDLTD
topic Solarzelle
Ionenimplantation
Blitzlampenausheilung
solar cell
ion implantation
flash lamp annealing
ddc:530
Solarzelle
Silicium
Polykristall
Ionenimplantation
Blitzlampe
Ausheilung
spellingShingle Solarzelle
Ionenimplantation
Blitzlampenausheilung
solar cell
ion implantation
flash lamp annealing
ddc:530
Solarzelle
Silicium
Polykristall
Ionenimplantation
Blitzlampe
Ausheilung
Krockert, Katja
Development and characterization of a low thermal budget process for multi-crystalline silicon solar cells
description Higher conversion efficiencies while reducing costs at the same time is the ultimate goal driving the development of solar cells. Multi-crystalline silicon has attracted considerable attention because of its high stability against light soaking. In case of solar grade multi-crystalline silicon the rigorous control of metal impurities is desirable for solar cell fabrication. It is the aim of this thesis to develop a new manufacturing process optimized for solar-grade multi-crystalline silicon solar cells. In this work the goal is to form solar cell emitters in silicon substrates by plasma immersion ion implantation of phosphine and posterior millisecond-range flash lamp annealing. These techniques were chosen as a new approach in order to decrease the production cost by reducing the amount of energy needed during fabrication. Therefore, this approach is called “Low Thermal Budget” process. After ion implantation the silicon surface is strongly disordered or amorphous up to the depth of the projected ion range. Therefore, subsequent annealing is required to remove the implantation damage and activate the doping element. Flash lamp annealing in the millisecond-range is demonstrated here as a very promising technique for the emitter formation at an overall low thermal budget. During flash lamp annealing, only the wafer surface is heated homogeneously to high temperatures at a time scales of ms. Thereby, implantation damages are annealed and phosphorous is electrically activated. The variation of pulse time allows to modify the degree of annealing of the bulk region to some extent as well. This can have an influence on the gettering behavior of metallic impurities. Ion implantation doping got in distinct consideration for doping of single-crystalline solar cells very recently. The efficient doping of multi-crystalline silicon remains the main challenge to reduce costs. The influence of different annealing techniques on the optical and electrical properties of multi-crystalline silicon solar cells was investigated. The Raman spectroscopy showed that the silicon surface is amorphous after ion implantation. It could be demonstrated that flash lamp annealing at 1000 °C for 3 ms even without preheating is sufficient to recrystallize implanted silicon. The sheet resistance of flash lamp annealed samples is in the range of about 60 Ω/□. Without surface passivation the minority carrier diffusion length in the flash lamp annealed samples is in the range of 85 µm. This is up to one order of magnitude higher than that observed for rapid thermal or furnace annealed samples. The highest carrier concentration and efficiency as well as the lowest resistivity were obtained after annealing at 1200 °C for 20 ms for both, single- and multi-crystalline silicon wafers. Photoluminescence results point towards phosphorous cluster formation at high annealing temperatures which affects metal impurity gettering within the emitter. Additionally, in silicon based solar cells, hydrogen plays a fundamental role due to its excellent passivation properties. The optical and electrical properties of the fabricated emitters were studied with particular interest in their dependence on the hydrogen content present in the samples. The influence of different flash lamp annealing parameters and a comparison with traditional thermal treatments such as rapid thermal and furnace annealing are presented. The samples treated by flash lamp annealing at 1200 °C for 20 ms in forming gas show sheet resistance values in the order of 60 Ω/□, and minority carrier diffusion lengths in the range of ~200 µm without the use of a capping layer for surface passivation. These results are significantly better than those obtained from rapid thermal or furnace annealed samples. The simultaneous implantation of hydrogen during the doping process, combined with optimal flash lamp annealing parameters, gave promising results for the application of this technology in replacing the conventional phosphoroxychlorid deposition and diffusion.
author2 TU Bergakademie Freiberg, Chemie und Physik
author_facet TU Bergakademie Freiberg, Chemie und Physik
Krockert, Katja
author Krockert, Katja
author_sort Krockert, Katja
title Development and characterization of a low thermal budget process for multi-crystalline silicon solar cells
title_short Development and characterization of a low thermal budget process for multi-crystalline silicon solar cells
title_full Development and characterization of a low thermal budget process for multi-crystalline silicon solar cells
title_fullStr Development and characterization of a low thermal budget process for multi-crystalline silicon solar cells
title_full_unstemmed Development and characterization of a low thermal budget process for multi-crystalline silicon solar cells
title_sort development and characterization of a low thermal budget process for multi-crystalline silicon solar cells
publisher Technische Universitaet Bergakademie Freiberg Universitaetsbibliothek "Georgius Agricola"
publishDate 2016
url http://nbn-resolving.de/urn:nbn:de:bsz:105-qucosa-192742
http://nbn-resolving.de/urn:nbn:de:bsz:105-qucosa-192742
http://www.qucosa.de/fileadmin/data/qucosa/documents/19274/Krockert_1b.pdf
work_keys_str_mv AT krockertkatja developmentandcharacterizationofalowthermalbudgetprocessformulticrystallinesiliconsolarcells
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spelling ndltd-DRESDEN-oai-qucosa.de-bsz-105-qucosa-1927422016-01-13T03:29:25Z Development and characterization of a low thermal budget process for multi-crystalline silicon solar cells Krockert, Katja Solarzelle Ionenimplantation Blitzlampenausheilung solar cell ion implantation flash lamp annealing ddc:530 Solarzelle Silicium Polykristall Ionenimplantation Blitzlampe Ausheilung Higher conversion efficiencies while reducing costs at the same time is the ultimate goal driving the development of solar cells. Multi-crystalline silicon has attracted considerable attention because of its high stability against light soaking. In case of solar grade multi-crystalline silicon the rigorous control of metal impurities is desirable for solar cell fabrication. It is the aim of this thesis to develop a new manufacturing process optimized for solar-grade multi-crystalline silicon solar cells. In this work the goal is to form solar cell emitters in silicon substrates by plasma immersion ion implantation of phosphine and posterior millisecond-range flash lamp annealing. These techniques were chosen as a new approach in order to decrease the production cost by reducing the amount of energy needed during fabrication. Therefore, this approach is called “Low Thermal Budget” process. After ion implantation the silicon surface is strongly disordered or amorphous up to the depth of the projected ion range. Therefore, subsequent annealing is required to remove the implantation damage and activate the doping element. Flash lamp annealing in the millisecond-range is demonstrated here as a very promising technique for the emitter formation at an overall low thermal budget. During flash lamp annealing, only the wafer surface is heated homogeneously to high temperatures at a time scales of ms. Thereby, implantation damages are annealed and phosphorous is electrically activated. The variation of pulse time allows to modify the degree of annealing of the bulk region to some extent as well. This can have an influence on the gettering behavior of metallic impurities. Ion implantation doping got in distinct consideration for doping of single-crystalline solar cells very recently. The efficient doping of multi-crystalline silicon remains the main challenge to reduce costs. The influence of different annealing techniques on the optical and electrical properties of multi-crystalline silicon solar cells was investigated. The Raman spectroscopy showed that the silicon surface is amorphous after ion implantation. It could be demonstrated that flash lamp annealing at 1000 °C for 3 ms even without preheating is sufficient to recrystallize implanted silicon. The sheet resistance of flash lamp annealed samples is in the range of about 60 Ω/□. Without surface passivation the minority carrier diffusion length in the flash lamp annealed samples is in the range of 85 µm. This is up to one order of magnitude higher than that observed for rapid thermal or furnace annealed samples. The highest carrier concentration and efficiency as well as the lowest resistivity were obtained after annealing at 1200 °C for 20 ms for both, single- and multi-crystalline silicon wafers. Photoluminescence results point towards phosphorous cluster formation at high annealing temperatures which affects metal impurity gettering within the emitter. Additionally, in silicon based solar cells, hydrogen plays a fundamental role due to its excellent passivation properties. The optical and electrical properties of the fabricated emitters were studied with particular interest in their dependence on the hydrogen content present in the samples. The influence of different flash lamp annealing parameters and a comparison with traditional thermal treatments such as rapid thermal and furnace annealing are presented. The samples treated by flash lamp annealing at 1200 °C for 20 ms in forming gas show sheet resistance values in the order of 60 Ω/□, and minority carrier diffusion lengths in the range of ~200 µm without the use of a capping layer for surface passivation. These results are significantly better than those obtained from rapid thermal or furnace annealed samples. The simultaneous implantation of hydrogen during the doping process, combined with optimal flash lamp annealing parameters, gave promising results for the application of this technology in replacing the conventional phosphoroxychlorid deposition and diffusion. Technische Universitaet Bergakademie Freiberg Universitaetsbibliothek "Georgius Agricola" TU Bergakademie Freiberg, Chemie und Physik Prof. Dr. Hans-Joachim Möller Prof. Dr. Hans-Joachim Möller Prof. Dr. Gerhard Gobsch 2016-01-12 doc-type:doctoralThesis application/pdf http://nbn-resolving.de/urn:nbn:de:bsz:105-qucosa-192742 urn:nbn:de:bsz:105-qucosa-192742 http://www.qucosa.de/fileadmin/data/qucosa/documents/19274/Krockert_1b.pdf eng