Dilute nitrides for boosting the efficiency of III-V multijunction solar cells

Ville Valtteri Polojärvi; Arto Johannes Aho; Antti Tukiainen; Marianna Jenni Sofia Raappana; Timo Antero Aho; Riku Matti Petteri Isoaho; Mircea Guina

Abstrakti

Multijunction III-V solar cells have the highest conversion efficiencies among all photovoltaic devices with current world record of 46 %, measured under concentrated light [1]. Furthermore, III-V semiconductor solar cells are found to be the best choice for generating electricity for satellites, because of high power-to-mass ratio and good radiation hardness. Although so far, the record conversion efficiency has increased almost one percentage point per year, new materials and concepts are needed to overcome the 50 % conversion efficiency barrier.

To this end, one of the most promising III-V photovoltaic material families is dilute nitrides. Introducing nitrogen to GaInAs shrinks the band gap by influencing the conduction band, and forming a localized band inside the material [2]. Nitrogen also compensates the compressive strain caused by In, when material is grown on GaAs or Ge substrates, preventing the formation of harmful dislocations. Capability to achieve a band gap between 1.4-0.8 eV and still maintain lattice matching [3], makes GaInNAs a good candidate as a part of multijunction solar cell with conversion efficiency exceeding 50 %.

In this presentation we discuss the use of optimized [4] bulk GaInNAs hetero-structures in multijunction solar cell (Figure 1.). Moreover, we have used GaInNAs and GaNAs for strain compensation and mediation, to absorb photons, and to boost the thermal escape of charge carriers in InAs quantum dot solar cell [5]. The properties of the dilute nitride based solar cells developed will be discussed.

Figure 1: A photograph of multijunction solar cell for concentrator applications, designed, fabricated and processed by the authors at Optoelectronics Research Centre, Tampere University of Technology.

References
[1] M. A. Green, K. Emery, Y. Hishikawa, W. Warta and E. D. Dunlop, Prog. Photovoltaics Res. Appl. 23, 805 (2015).
[2] M. Henini (Ed.), Dilute Nitride Semiconductors (Elsevier, Amsterdam, 2005).
[3] J. S. Harris, R. Kudrawiec, H. Yuen, S. Bank, H. Bae, M. Wistey, D. Jackrel, E. Pickett, T. Sarmiento and L. Goddard, Phys. Status Solidi B 244, 2707 (2007).
[4] A. Aho, V. Polojärvi, V.-M. Korpijärvi, J. Salmi, A. Tukiainen, P. Laukkanen and M. Guina, Solar Energy Mater. Solar Cells 124, 150 (2014).
[5] V. Polojärvi, E.-M. Pavelescu, A. Schramm, A. Tukiainen, A. Aho, J. Puustinen and M. Guina, Scr. Mater. 108, 122 (2015).

Alkuperäiskieli	Englanti
Tila	Julkaistu - 22 lokak. 2015
Tapahtuma	Nanoscience Days - Agora, Jyväskylä, Suomi Kesto: 22 lokak. 2015 → 23 lokak. 2015

Conference

Conference	Nanoscience Days
Maa/Alue	Suomi
Kaupunki	Jyväskylä
Ajanjakso	22/10/15 → 23/10/15

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@conference{7787d17d813647428297d0309be9e0ac,

title = "Dilute nitrides for boosting the efficiency of III-V multijunction solar cells",

abstract = "Multijunction III-V solar cells have the highest conversion efficiencies among all photovoltaic devices with current world record of 46 %, measured under concentrated light [1]. Furthermore, III-V semiconductor solar cells are found to be the best choice for generating electricity for satellites, because of high power-to-mass ratio and good radiation hardness. Although so far, the record conversion efficiency has increased almost one percentage point per year, new materials and concepts are needed to overcome the 50 % conversion efficiency barrier. To this end, one of the most promising III-V photovoltaic material families is dilute nitrides. Introducing nitrogen to GaInAs shrinks the band gap by influencing the conduction band, and forming a localized band inside the material [2]. Nitrogen also compensates the compressive strain caused by In, when material is grown on GaAs or Ge substrates, preventing the formation of harmful dislocations. Capability to achieve a band gap between 1.4-0.8 eV and still maintain lattice matching [3], makes GaInNAs a good candidate as a part of multijunction solar cell with conversion efficiency exceeding 50 %.In this presentation we discuss the use of optimized [4] bulk GaInNAs hetero-structures in multijunction solar cell (Figure 1.). Moreover, we have used GaInNAs and GaNAs for strain compensation and mediation, to absorb photons, and to boost the thermal escape of charge carriers in InAs quantum dot solar cell [5]. The properties of the dilute nitride based solar cells developed will be discussed. Figure 1: A photograph of multijunction solar cell for concentrator applications, designed, fabricated and processed by the authors at Optoelectronics Research Centre, Tampere University of Technology.References[1] M. A. Green, K. Emery, Y. Hishikawa, W. Warta and E. D. Dunlop, Prog. Photovoltaics Res. Appl. 23, 805 (2015).[2] M. Henini (Ed.), Dilute Nitride Semiconductors (Elsevier, Amsterdam, 2005).[3] J. S. Harris, R. Kudrawiec, H. Yuen, S. Bank, H. Bae, M. Wistey, D. Jackrel, E. Pickett, T. Sarmiento and L. Goddard, Phys. Status Solidi B 244, 2707 (2007).[4] A. Aho, V. Poloj{\"a}rvi, V.-M. Korpij{\"a}rvi, J. Salmi, A. Tukiainen, P. Laukkanen and M. Guina, Solar Energy Mater. Solar Cells 124, 150 (2014).[5] V. Poloj{\"a}rvi, E.-M. Pavelescu, A. Schramm, A. Tukiainen, A. Aho, J. Puustinen and M. Guina, Scr. Mater. 108, 122 (2015).",

author = "Poloj{\"a}rvi, {Ville Valtteri} and Aho, {Arto Johannes} and Antti Tukiainen and Raappana, {Marianna Jenni Sofia} and Aho, {Timo Antero} and Isoaho, {Riku Matti Petteri} and Mircea Guina",

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language = "English",

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T1 - Dilute nitrides for boosting the efficiency of III-V multijunction solar cells

AU - Polojärvi, Ville Valtteri

AU - Aho, Arto Johannes

AU - Tukiainen, Antti

AU - Raappana, Marianna Jenni Sofia

AU - Aho, Timo Antero

AU - Isoaho, Riku Matti Petteri

AU - Guina, Mircea

PY - 2015/10/22

Y1 - 2015/10/22

N2 - Multijunction III-V solar cells have the highest conversion efficiencies among all photovoltaic devices with current world record of 46 %, measured under concentrated light [1]. Furthermore, III-V semiconductor solar cells are found to be the best choice for generating electricity for satellites, because of high power-to-mass ratio and good radiation hardness. Although so far, the record conversion efficiency has increased almost one percentage point per year, new materials and concepts are needed to overcome the 50 % conversion efficiency barrier. To this end, one of the most promising III-V photovoltaic material families is dilute nitrides. Introducing nitrogen to GaInAs shrinks the band gap by influencing the conduction band, and forming a localized band inside the material [2]. Nitrogen also compensates the compressive strain caused by In, when material is grown on GaAs or Ge substrates, preventing the formation of harmful dislocations. Capability to achieve a band gap between 1.4-0.8 eV and still maintain lattice matching [3], makes GaInNAs a good candidate as a part of multijunction solar cell with conversion efficiency exceeding 50 %.In this presentation we discuss the use of optimized [4] bulk GaInNAs hetero-structures in multijunction solar cell (Figure 1.). Moreover, we have used GaInNAs and GaNAs for strain compensation and mediation, to absorb photons, and to boost the thermal escape of charge carriers in InAs quantum dot solar cell [5]. The properties of the dilute nitride based solar cells developed will be discussed. Figure 1: A photograph of multijunction solar cell for concentrator applications, designed, fabricated and processed by the authors at Optoelectronics Research Centre, Tampere University of Technology.References[1] M. A. Green, K. Emery, Y. Hishikawa, W. Warta and E. D. Dunlop, Prog. Photovoltaics Res. Appl. 23, 805 (2015).[2] M. Henini (Ed.), Dilute Nitride Semiconductors (Elsevier, Amsterdam, 2005).[3] J. S. Harris, R. Kudrawiec, H. Yuen, S. Bank, H. Bae, M. Wistey, D. Jackrel, E. Pickett, T. Sarmiento and L. Goddard, Phys. Status Solidi B 244, 2707 (2007).[4] A. Aho, V. Polojärvi, V.-M. Korpijärvi, J. Salmi, A. Tukiainen, P. Laukkanen and M. Guina, Solar Energy Mater. Solar Cells 124, 150 (2014).[5] V. Polojärvi, E.-M. Pavelescu, A. Schramm, A. Tukiainen, A. Aho, J. Puustinen and M. Guina, Scr. Mater. 108, 122 (2015).

AB - Multijunction III-V solar cells have the highest conversion efficiencies among all photovoltaic devices with current world record of 46 %, measured under concentrated light [1]. Furthermore, III-V semiconductor solar cells are found to be the best choice for generating electricity for satellites, because of high power-to-mass ratio and good radiation hardness. Although so far, the record conversion efficiency has increased almost one percentage point per year, new materials and concepts are needed to overcome the 50 % conversion efficiency barrier. To this end, one of the most promising III-V photovoltaic material families is dilute nitrides. Introducing nitrogen to GaInAs shrinks the band gap by influencing the conduction band, and forming a localized band inside the material [2]. Nitrogen also compensates the compressive strain caused by In, when material is grown on GaAs or Ge substrates, preventing the formation of harmful dislocations. Capability to achieve a band gap between 1.4-0.8 eV and still maintain lattice matching [3], makes GaInNAs a good candidate as a part of multijunction solar cell with conversion efficiency exceeding 50 %.In this presentation we discuss the use of optimized [4] bulk GaInNAs hetero-structures in multijunction solar cell (Figure 1.). Moreover, we have used GaInNAs and GaNAs for strain compensation and mediation, to absorb photons, and to boost the thermal escape of charge carriers in InAs quantum dot solar cell [5]. The properties of the dilute nitride based solar cells developed will be discussed. Figure 1: A photograph of multijunction solar cell for concentrator applications, designed, fabricated and processed by the authors at Optoelectronics Research Centre, Tampere University of Technology.References[1] M. A. Green, K. Emery, Y. Hishikawa, W. Warta and E. D. Dunlop, Prog. Photovoltaics Res. Appl. 23, 805 (2015).[2] M. Henini (Ed.), Dilute Nitride Semiconductors (Elsevier, Amsterdam, 2005).[3] J. S. Harris, R. Kudrawiec, H. Yuen, S. Bank, H. Bae, M. Wistey, D. Jackrel, E. Pickett, T. Sarmiento and L. Goddard, Phys. Status Solidi B 244, 2707 (2007).[4] A. Aho, V. Polojärvi, V.-M. Korpijärvi, J. Salmi, A. Tukiainen, P. Laukkanen and M. Guina, Solar Energy Mater. Solar Cells 124, 150 (2014).[5] V. Polojärvi, E.-M. Pavelescu, A. Schramm, A. Tukiainen, A. Aho, J. Puustinen and M. Guina, Scr. Mater. 108, 122 (2015).

M3 - Abstract

T2 - Nanoscience Days

Y2 - 22 October 2015 through 23 October 2015

ER -

Dilute nitrides for boosting the efficiency of III-V multijunction solar cells

Abstrakti

Conference

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