Organic-silicon heterojunction solar cells on n-type silicon wafers: The BackPEDOT concept

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Autoren

  • Dimitri Zielke
  • Alexandra Pazidis
  • Florian Werner
  • Jan Schmidt

Organisationseinheiten

Externe Organisationen

  • Institut für Solarenergieforschung GmbH (ISFH)
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Details

OriginalspracheEnglisch
Seiten (von - bis)110-116
Seitenumfang7
FachzeitschriftSolar Energy Materials and Solar Cells
Jahrgang131
PublikationsstatusVeröffentlicht - Dez. 2014

Abstract

We measure saturation current densities down to J0=80 fA/cm2 for organic-silicon heterojunctions with poly(3,4-ethylenedioxythiophene):poly(styrenesulfonate) (PEDOT:PSS) as an organic layer. This remarkably low J0 value corresponds to implied open-circuit voltages around 690 mV, demonstrating the high-efficiency potential of this novel junction type. However, experimentally realized organic-silicon heterojunction solar cells showed relatively moderate efficiencies so far, typically below 12%. We demonstrate in this study that these solar cells were limited by the fact that the organic-silicon junction was localized on the cell front, resulting in a significant parasitic light absorption within the PEDOT:PSS layer. In addition, the rear surface of these front-junction solar cells was either poorly passivated or not passivated at all. In this paper, we overcome these limitations by proposing a back-junction organic-silicon solar cell, the so-called "BackPEDOT" cell. We show that placing PEDOT:PSS on the rear side instead of the front surface avoids parasitic light absorption within the PEDOT:PSS and allows for an improved surface passivation. We fabricate and characterize BackPEDOT solar cells and achieve very high open-circuit voltages of up to 663 mV and short-circuit current densities of up to 39.7 mA/cm2. Despite the relatively high series resistances of our first BackPEDOT cells, we achieve an energy conversion efficiency of 17.4%. The measured pseudo efficiency of the best cell of 21.2% suggests that our novel BackPEDOT cell concept is indeed suitable for easy-to-fabricate high-efficiency solar cells after some further optimization to reduce the contact resistance between the PEDOT and the n-type silicon wafer. Based on realistic assumptions we conclude that Back PEDOT cells have an efficiency potential exceeding 22%.

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Organic-silicon heterojunction solar cells on n-type silicon wafers: The BackPEDOT concept. / Zielke, Dimitri; Pazidis, Alexandra; Werner, Florian et al.
in: Solar Energy Materials and Solar Cells, Jahrgang 131, 12.2014, S. 110-116.

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Zielke, Dimitri ; Pazidis, Alexandra ; Werner, Florian et al. / Organic-silicon heterojunction solar cells on n-type silicon wafers : The BackPEDOT concept. in: Solar Energy Materials and Solar Cells. 2014 ; Jahrgang 131. S. 110-116.
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title = "Organic-silicon heterojunction solar cells on n-type silicon wafers: The BackPEDOT concept",
abstract = "We measure saturation current densities down to J0=80 fA/cm2 for organic-silicon heterojunctions with poly(3,4-ethylenedioxythiophene):poly(styrenesulfonate) (PEDOT:PSS) as an organic layer. This remarkably low J0 value corresponds to implied open-circuit voltages around 690 mV, demonstrating the high-efficiency potential of this novel junction type. However, experimentally realized organic-silicon heterojunction solar cells showed relatively moderate efficiencies so far, typically below 12%. We demonstrate in this study that these solar cells were limited by the fact that the organic-silicon junction was localized on the cell front, resulting in a significant parasitic light absorption within the PEDOT:PSS layer. In addition, the rear surface of these front-junction solar cells was either poorly passivated or not passivated at all. In this paper, we overcome these limitations by proposing a back-junction organic-silicon solar cell, the so-called {"}BackPEDOT{"} cell. We show that placing PEDOT:PSS on the rear side instead of the front surface avoids parasitic light absorption within the PEDOT:PSS and allows for an improved surface passivation. We fabricate and characterize BackPEDOT solar cells and achieve very high open-circuit voltages of up to 663 mV and short-circuit current densities of up to 39.7 mA/cm2. Despite the relatively high series resistances of our first BackPEDOT cells, we achieve an energy conversion efficiency of 17.4%. The measured pseudo efficiency of the best cell of 21.2% suggests that our novel BackPEDOT cell concept is indeed suitable for easy-to-fabricate high-efficiency solar cells after some further optimization to reduce the contact resistance between the PEDOT and the n-type silicon wafer. Based on realistic assumptions we conclude that Back PEDOT cells have an efficiency potential exceeding 22%.",
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TY - JOUR

T1 - Organic-silicon heterojunction solar cells on n-type silicon wafers

T2 - The BackPEDOT concept

AU - Zielke, Dimitri

AU - Pazidis, Alexandra

AU - Werner, Florian

AU - Schmidt, Jan

N1 - Publisher Copyright: © 2014 Elsevier B.V.

PY - 2014/12

Y1 - 2014/12

N2 - We measure saturation current densities down to J0=80 fA/cm2 for organic-silicon heterojunctions with poly(3,4-ethylenedioxythiophene):poly(styrenesulfonate) (PEDOT:PSS) as an organic layer. This remarkably low J0 value corresponds to implied open-circuit voltages around 690 mV, demonstrating the high-efficiency potential of this novel junction type. However, experimentally realized organic-silicon heterojunction solar cells showed relatively moderate efficiencies so far, typically below 12%. We demonstrate in this study that these solar cells were limited by the fact that the organic-silicon junction was localized on the cell front, resulting in a significant parasitic light absorption within the PEDOT:PSS layer. In addition, the rear surface of these front-junction solar cells was either poorly passivated or not passivated at all. In this paper, we overcome these limitations by proposing a back-junction organic-silicon solar cell, the so-called "BackPEDOT" cell. We show that placing PEDOT:PSS on the rear side instead of the front surface avoids parasitic light absorption within the PEDOT:PSS and allows for an improved surface passivation. We fabricate and characterize BackPEDOT solar cells and achieve very high open-circuit voltages of up to 663 mV and short-circuit current densities of up to 39.7 mA/cm2. Despite the relatively high series resistances of our first BackPEDOT cells, we achieve an energy conversion efficiency of 17.4%. The measured pseudo efficiency of the best cell of 21.2% suggests that our novel BackPEDOT cell concept is indeed suitable for easy-to-fabricate high-efficiency solar cells after some further optimization to reduce the contact resistance between the PEDOT and the n-type silicon wafer. Based on realistic assumptions we conclude that Back PEDOT cells have an efficiency potential exceeding 22%.

AB - We measure saturation current densities down to J0=80 fA/cm2 for organic-silicon heterojunctions with poly(3,4-ethylenedioxythiophene):poly(styrenesulfonate) (PEDOT:PSS) as an organic layer. This remarkably low J0 value corresponds to implied open-circuit voltages around 690 mV, demonstrating the high-efficiency potential of this novel junction type. However, experimentally realized organic-silicon heterojunction solar cells showed relatively moderate efficiencies so far, typically below 12%. We demonstrate in this study that these solar cells were limited by the fact that the organic-silicon junction was localized on the cell front, resulting in a significant parasitic light absorption within the PEDOT:PSS layer. In addition, the rear surface of these front-junction solar cells was either poorly passivated or not passivated at all. In this paper, we overcome these limitations by proposing a back-junction organic-silicon solar cell, the so-called "BackPEDOT" cell. We show that placing PEDOT:PSS on the rear side instead of the front surface avoids parasitic light absorption within the PEDOT:PSS and allows for an improved surface passivation. We fabricate and characterize BackPEDOT solar cells and achieve very high open-circuit voltages of up to 663 mV and short-circuit current densities of up to 39.7 mA/cm2. Despite the relatively high series resistances of our first BackPEDOT cells, we achieve an energy conversion efficiency of 17.4%. The measured pseudo efficiency of the best cell of 21.2% suggests that our novel BackPEDOT cell concept is indeed suitable for easy-to-fabricate high-efficiency solar cells after some further optimization to reduce the contact resistance between the PEDOT and the n-type silicon wafer. Based on realistic assumptions we conclude that Back PEDOT cells have an efficiency potential exceeding 22%.

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KW - PEDOT:PSS

KW - Saturation current density

KW - Solar cell

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DO - 10.1016/j.solmat.2014.05.022

M3 - Article

AN - SCOPUS:84908412381

VL - 131

SP - 110

EP - 116

JO - Solar Energy Materials and Solar Cells

JF - Solar Energy Materials and Solar Cells

SN - 0927-0248

ER -

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