Investigation of electrically active defects in InGaAs quantum wire intermediate-band solar cells using deep-level transient spectroscopy technique

Noor Alhuda Al Saqri; Jorlandio F. Felix; Mohsin Aziz; Vasyl P. Kunets; Dler Jameel; David Taylor; Mohamed Henini; Mahmmoud S. Abd El-Sadek; Colin Furrow; Morgan E. Ware; Mourad Benamara; Mansour Mortazavi; Gregory Salamo

doi:10.1088/1361-6528/28/4/045707

Investigation of electrically active defects in InGaAs quantum wire intermediate-band solar cells using deep-level transient spectroscopy technique

Noor Alhuda Al Saqri, Jorlandio F. Felix, Mohsin Aziz, Vasyl P. Kunets, Dler Jameel, David Taylor, Mohamed Henini, Mahmmoud S. Abd El-Sadek, Colin Furrow, Morgan E. Ware, Mourad Benamara, Mansour Mortazavi, Gregory Salamo

Physics

نتاج البحث: المساهمة في مجلة › Article › مراجعة النظراء

11 اقتباسات (Scopus)

ملخص

InGaAs quantum wire (QWr) intermediate-band solar cell-based nanostructures grown by molecular beam epitaxy are studied. The electrical and interface properties of these solar cell devices, as determined by current-voltage (I-V) and capacitance-voltage (C-V) techniques, were found to change with temperature over a wide range of 20-340 K. The electron and hole traps present in these devices have been investigated using deep-level transient spectroscopy (DLTS). The DLTS results showed that the traps detected in the QWr-doped devices are directly or indirectly related to the insertion of the Si δ-layer used to dope the wires. In addition, in the QWr-doped devices, the decrease of the solar conversion efficiencies at low temperatures and the associated decrease of the integrated external quantum efficiency through InGaAs could be attributed to detected traps E1_QWR-D, E2_QWR-D, and E3_QWR-D with activation energies of 0.0037, 0.0053, and 0.041 eV, respectively.

اللغة الأصلية	English
رقم المقال	045707
دورية	Nanotechnology
مستوى الصوت	28
رقم الإصدار	4
المعرِّفات الرقمية للأشياء	https://doi.org/10.1088/1361-6528/28/4/045707
حالة النشر	Published - يناير 27 2017

ASJC Scopus subject areas

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الوصول إلى المستند

10.1088/1361-6528/28/4/045707

الملفات والروابط الأخرى

قم بذكر هذا

Al Saqri, N. A., Felix, J. F., Aziz, M., Kunets, V. P., Jameel, D., Taylor, D., Henini, M., Abd El-Sadek, M. S., Furrow, C., Ware, M. E., Benamara, M., Mortazavi, M., & Salamo, G. (2017). Investigation of electrically active defects in InGaAs quantum wire intermediate-band solar cells using deep-level transient spectroscopy technique. Nanotechnology, 28(4), Article 045707. https://doi.org/10.1088/1361-6528/28/4/045707

Investigation of electrically active defects in InGaAs quantum wire intermediate-band solar cells using deep-level transient spectroscopy technique. / Al Saqri, Noor Alhuda; Felix, Jorlandio F.; Aziz, Mohsin وآخرون.
في: Nanotechnology, المجلد 28, رقم 4, 045707, ٢٧.٠١.٢٠١٧.

نتاج البحث: المساهمة في مجلة › Article › مراجعة النظراء

Al Saqri, NA, Felix, JF, Aziz, M, Kunets, VP, Jameel, D, Taylor, D, Henini, M, Abd El-Sadek, MS, Furrow, C, Ware, ME, Benamara, M, Mortazavi, M & Salamo, G 2017, 'Investigation of electrically active defects in InGaAs quantum wire intermediate-band solar cells using deep-level transient spectroscopy technique', Nanotechnology, المجلد 28, رقم 4, 045707. https://doi.org/10.1088/1361-6528/28/4/045707

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title = "Investigation of electrically active defects in InGaAs quantum wire intermediate-band solar cells using deep-level transient spectroscopy technique",

abstract = "InGaAs quantum wire (QWr) intermediate-band solar cell-based nanostructures grown by molecular beam epitaxy are studied. The electrical and interface properties of these solar cell devices, as determined by current-voltage (I-V) and capacitance-voltage (C-V) techniques, were found to change with temperature over a wide range of 20-340 K. The electron and hole traps present in these devices have been investigated using deep-level transient spectroscopy (DLTS). The DLTS results showed that the traps detected in the QWr-doped devices are directly or indirectly related to the insertion of the Si δ-layer used to dope the wires. In addition, in the QWr-doped devices, the decrease of the solar conversion efficiencies at low temperatures and the associated decrease of the integrated external quantum efficiency through InGaAs could be attributed to detected traps E1QWR-D, E2QWR-D, and E3QWR-D with activation energies of 0.0037, 0.0053, and 0.041 eV, respectively.",

keywords = "C-V, DLTS, IV, defects, quantum wire intermediate-band solar cells",

author = "{Al Saqri}, {Noor Alhuda} and Felix, {Jorlandio F.} and Mohsin Aziz and Kunets, {Vasyl P.} and Dler Jameel and David Taylor and Mohamed Henini and {Abd El-Sadek}, {Mahmmoud S.} and Colin Furrow and Ware, {Morgan E.} and Mourad Benamara and Mansour Mortazavi and Gregory Salamo",

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doi = "10.1088/1361-6528/28/4/045707",

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T1 - Investigation of electrically active defects in InGaAs quantum wire intermediate-band solar cells using deep-level transient spectroscopy technique

AU - Al Saqri, Noor Alhuda

AU - Felix, Jorlandio F.

AU - Aziz, Mohsin

AU - Kunets, Vasyl P.

AU - Jameel, Dler

AU - Taylor, David

AU - Henini, Mohamed

AU - Abd El-Sadek, Mahmmoud S.

AU - Furrow, Colin

AU - Ware, Morgan E.

AU - Benamara, Mourad

AU - Mortazavi, Mansour

AU - Salamo, Gregory

PY - 2017/1/27

Y1 - 2017/1/27

N2 - InGaAs quantum wire (QWr) intermediate-band solar cell-based nanostructures grown by molecular beam epitaxy are studied. The electrical and interface properties of these solar cell devices, as determined by current-voltage (I-V) and capacitance-voltage (C-V) techniques, were found to change with temperature over a wide range of 20-340 K. The electron and hole traps present in these devices have been investigated using deep-level transient spectroscopy (DLTS). The DLTS results showed that the traps detected in the QWr-doped devices are directly or indirectly related to the insertion of the Si δ-layer used to dope the wires. In addition, in the QWr-doped devices, the decrease of the solar conversion efficiencies at low temperatures and the associated decrease of the integrated external quantum efficiency through InGaAs could be attributed to detected traps E1QWR-D, E2QWR-D, and E3QWR-D with activation energies of 0.0037, 0.0053, and 0.041 eV, respectively.

AB - InGaAs quantum wire (QWr) intermediate-band solar cell-based nanostructures grown by molecular beam epitaxy are studied. The electrical and interface properties of these solar cell devices, as determined by current-voltage (I-V) and capacitance-voltage (C-V) techniques, were found to change with temperature over a wide range of 20-340 K. The electron and hole traps present in these devices have been investigated using deep-level transient spectroscopy (DLTS). The DLTS results showed that the traps detected in the QWr-doped devices are directly or indirectly related to the insertion of the Si δ-layer used to dope the wires. In addition, in the QWr-doped devices, the decrease of the solar conversion efficiencies at low temperatures and the associated decrease of the integrated external quantum efficiency through InGaAs could be attributed to detected traps E1QWR-D, E2QWR-D, and E3QWR-D with activation energies of 0.0037, 0.0053, and 0.041 eV, respectively.

KW - C-V

KW - DLTS

KW - IV

KW - defects

KW - quantum wire intermediate-band solar cells

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Investigation of electrically active defects in InGaAs quantum wire intermediate-band solar cells using deep-level transient spectroscopy technique

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