In situ simultaneous photovoltaic and structural evolution of perovskite solar cells during film formation

Mejd Almheiri; Oier Bikondoa; James Bishop; Mojtaba Abdi-Jalebi; Lütfiye Y. Ozer; Mark Hampton; Paul Thompson; Maximilian T. Hörantner; Suhas Mahesh; Claire Greenland; J. Emyr Macdonald; Giovanni Palmisano; Henry J. Snaith; David G. Lidzey; Samuel D. Stranks; Richard H. Friend; Samuele Lilliu

doi:10.1039/c7ee03013d

In situ simultaneous photovoltaic and structural evolution of perovskite solar cells during film formation

Mejd Almheiri, Oier Bikondoa, James Bishop, Mojtaba Abdi-Jalebi, Lütfiye Y. Ozer, Mark Hampton, Paul Thompson, Maximilian T. Hörantner, Suhas Mahesh, Claire Greenland, J. Emyr Macdonald, Giovanni Palmisano, Henry J. Snaith, David G. Lidzey, Samuel D. Stranks, Richard H. Friend, Samuele Lilliu

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76 Scopus citations

Abstract

Metal-halide perovskites show remarkably clean semiconductor behaviour, as evidenced by their excellent solar cell performance, in spite of the presence of many structural and chemical defects. Here, we show how this clean semiconductor performance sets in during the earliest phase of conversion from the metal salts and organic-based precursors and solvent, using simultaneous in situ synchrotron X-ray and in operando current-voltage measurements on films prepared on interdigitated back-contact substrates. These structures function as working solar cells as soon as sufficient semiconductor material is present across the electrodes. We find that at the first stages of conversion from the precursor phase, at the percolation threshold for bulk conductance, high photovoltages are observed, even though the bulk of the material is still present as precursors. This indicates that at the earliest stages of perovskite structure formation, the semiconductor gap is already well-defined and free of sub-gap trap states. The short circuit current, in contrast, continues to grow until the perovskite phase is fully formed, when there are bulk pathways for charge diffusion and collection. This work reveals important relationships between the precursors conversion and device performance and highlights the remarkable defect tolerance of perovskite materials.

Original language	British English
Pages (from-to)	383-393
Number of pages	11
Journal	Energy and Environmental Science
Volume	11
Issue number	2
DOIs	https://doi.org/10.1039/c7ee03013d
State	Published - Feb 2018

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Almheiri, M., Bikondoa, O., Bishop, J., Abdi-Jalebi, M., Ozer, L. Y., Hampton, M., Thompson, P., Hörantner, M. T., Mahesh, S., Greenland, C., Macdonald, J. E., Palmisano, G., Snaith, H. J., Lidzey, D. G., Stranks, S. D., Friend, R. H., & Lilliu, S. (2018). In situ simultaneous photovoltaic and structural evolution of perovskite solar cells during film formation. Energy and Environmental Science, 11(2), 383-393. https://doi.org/10.1039/c7ee03013d

@article{8bc5b861341346c8a7f9d45bb90a1126,

title = "In situ simultaneous photovoltaic and structural evolution of perovskite solar cells during film formation",

abstract = "Metal-halide perovskites show remarkably clean semiconductor behaviour, as evidenced by their excellent solar cell performance, in spite of the presence of many structural and chemical defects. Here, we show how this clean semiconductor performance sets in during the earliest phase of conversion from the metal salts and organic-based precursors and solvent, using simultaneous in situ synchrotron X-ray and in operando current-voltage measurements on films prepared on interdigitated back-contact substrates. These structures function as working solar cells as soon as sufficient semiconductor material is present across the electrodes. We find that at the first stages of conversion from the precursor phase, at the percolation threshold for bulk conductance, high photovoltages are observed, even though the bulk of the material is still present as precursors. This indicates that at the earliest stages of perovskite structure formation, the semiconductor gap is already well-defined and free of sub-gap trap states. The short circuit current, in contrast, continues to grow until the perovskite phase is fully formed, when there are bulk pathways for charge diffusion and collection. This work reveals important relationships between the precursors conversion and device performance and highlights the remarkable defect tolerance of perovskite materials.",

author = "Mejd Almheiri and Oier Bikondoa and James Bishop and Mojtaba Abdi-Jalebi and Ozer, {L{\"u}tfiye Y.} and Mark Hampton and Paul Thompson and H{\"o}rantner, {Maximilian T.} and Suhas Mahesh and Claire Greenland and Macdonald, {J. Emyr} and Giovanni Palmisano and Snaith, {Henry J.} and Lidzey, {David G.} and Stranks, {Samuel D.} and Friend, {Richard H.} and Samuele Lilliu",

note = "Funding Information: This work was funded by {\textquoteleft}The President of the UAE{\textquoteright}s Distinguished Student Scholarship Program (DSS), granted by the Ministry of Presidential Affairs, UAE{\textquoteright} (M. A. PhD scholarship). S. L. obtained funding for the synchrotron measurements. XMaS is a mid-range facility supported by the Engineering and Physical Sciences Research Council (EPSRC). We are grateful to all the XMaS beamline team staff for their support. D. G. L. obtained the following funding from the EPSRC: J. B. PhD scholarship via the University of Sheffield DTG account and C. G. PhD scholarship from the Centre for Doctoral Training in New and Sustainable PV, EP/L01551X/1. M. A. J. gratefully acknowledges Nava Technology Limited and Nyak Technology Limited for a PhD scholarship. S. D. S. has received funding from the European Union{\textquoteright}s Seventh Framework Programme (Marie Curie Actions) under REA grant number PIOF-GA-2013-622630. Publisher Copyright: {\textcopyright} 2018 The Royal Society of Chemistry.",

year = "2018",

month = feb,

doi = "10.1039/c7ee03013d",

language = "British English",

volume = "11",

pages = "383--393",

journal = "Energy and Environmental Science",

issn = "1754-5692",

publisher = "Royal Society of Chemistry",

number = "2",

}

Almheiri, M, Bikondoa, O, Bishop, J, Abdi-Jalebi, M, Ozer, LY, Hampton, M, Thompson, P, Hörantner, MT, Mahesh, S, Greenland, C, Macdonald, JE, Palmisano, G, Snaith, HJ, Lidzey, DG, Stranks, SD, Friend, RH & Lilliu, S 2018, 'In situ simultaneous photovoltaic and structural evolution of perovskite solar cells during film formation', Energy and Environmental Science, vol. 11, no. 2, pp. 383-393. https://doi.org/10.1039/c7ee03013d

TY - JOUR

T1 - In situ simultaneous photovoltaic and structural evolution of perovskite solar cells during film formation

AU - Almheiri, Mejd

AU - Bikondoa, Oier

AU - Bishop, James

AU - Abdi-Jalebi, Mojtaba

AU - Ozer, Lütfiye Y.

AU - Hampton, Mark

AU - Thompson, Paul

AU - Hörantner, Maximilian T.

AU - Mahesh, Suhas

AU - Greenland, Claire

AU - Macdonald, J. Emyr

AU - Palmisano, Giovanni

AU - Snaith, Henry J.

AU - Lidzey, David G.

AU - Stranks, Samuel D.

AU - Friend, Richard H.

AU - Lilliu, Samuele

N1 - Funding Information: This work was funded by ‘The President of the UAE’s Distinguished Student Scholarship Program (DSS), granted by the Ministry of Presidential Affairs, UAE’ (M. A. PhD scholarship). S. L. obtained funding for the synchrotron measurements. XMaS is a mid-range facility supported by the Engineering and Physical Sciences Research Council (EPSRC). We are grateful to all the XMaS beamline team staff for their support. D. G. L. obtained the following funding from the EPSRC: J. B. PhD scholarship via the University of Sheffield DTG account and C. G. PhD scholarship from the Centre for Doctoral Training in New and Sustainable PV, EP/L01551X/1. M. A. J. gratefully acknowledges Nava Technology Limited and Nyak Technology Limited for a PhD scholarship. S. D. S. has received funding from the European Union’s Seventh Framework Programme (Marie Curie Actions) under REA grant number PIOF-GA-2013-622630. Publisher Copyright: © 2018 The Royal Society of Chemistry.

PY - 2018/2

Y1 - 2018/2

N2 - Metal-halide perovskites show remarkably clean semiconductor behaviour, as evidenced by their excellent solar cell performance, in spite of the presence of many structural and chemical defects. Here, we show how this clean semiconductor performance sets in during the earliest phase of conversion from the metal salts and organic-based precursors and solvent, using simultaneous in situ synchrotron X-ray and in operando current-voltage measurements on films prepared on interdigitated back-contact substrates. These structures function as working solar cells as soon as sufficient semiconductor material is present across the electrodes. We find that at the first stages of conversion from the precursor phase, at the percolation threshold for bulk conductance, high photovoltages are observed, even though the bulk of the material is still present as precursors. This indicates that at the earliest stages of perovskite structure formation, the semiconductor gap is already well-defined and free of sub-gap trap states. The short circuit current, in contrast, continues to grow until the perovskite phase is fully formed, when there are bulk pathways for charge diffusion and collection. This work reveals important relationships between the precursors conversion and device performance and highlights the remarkable defect tolerance of perovskite materials.

AB - Metal-halide perovskites show remarkably clean semiconductor behaviour, as evidenced by their excellent solar cell performance, in spite of the presence of many structural and chemical defects. Here, we show how this clean semiconductor performance sets in during the earliest phase of conversion from the metal salts and organic-based precursors and solvent, using simultaneous in situ synchrotron X-ray and in operando current-voltage measurements on films prepared on interdigitated back-contact substrates. These structures function as working solar cells as soon as sufficient semiconductor material is present across the electrodes. We find that at the first stages of conversion from the precursor phase, at the percolation threshold for bulk conductance, high photovoltages are observed, even though the bulk of the material is still present as precursors. This indicates that at the earliest stages of perovskite structure formation, the semiconductor gap is already well-defined and free of sub-gap trap states. The short circuit current, in contrast, continues to grow until the perovskite phase is fully formed, when there are bulk pathways for charge diffusion and collection. This work reveals important relationships between the precursors conversion and device performance and highlights the remarkable defect tolerance of perovskite materials.

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U2 - 10.1039/c7ee03013d

DO - 10.1039/c7ee03013d

M3 - Article

AN - SCOPUS:85042203028

SN - 1754-5692

VL - 11

SP - 383

EP - 393

JO - Energy and Environmental Science

JF - Energy and Environmental Science

IS - 2

ER -

In situ simultaneous photovoltaic and structural evolution of perovskite solar cells during film formation

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