An equivalent circuit model proposed for the intermediate band nanostructured quantum dot solar cells

Mohammad Houshmand; Mohammad H. Zandi; Somayeh S. Dehkordi; Mauricio D. Perez; Nima E. Gorji

doi:10.1142/S0217984912501333

An equivalent circuit model proposed for the intermediate band nanostructured quantum dot solar cells

Mohammad Houshmand, Mohammad H. Zandi, Somayeh S. Dehkordi, Mauricio D. Perez, Nima E. Gorji

Research output: Contribution to journal › Article › peer-review

Abstract

The equivalent circuit of the p-i-n structure has been considered and developed for the quantum dot intermediate band solar cells where the nanoparticles are inserted in the active region of the diode. The admittance of the circuits are calculated consisting of frequency dependent capacitance and conductance. The presence of quantum dot layers in the active region of the diode increases the capacitance and conductance of the cell in lower frequencies. However, the number of QD cannot be increased and has an optimum.

Original language	English
Article number	1250133
Journal	Modern Physics Letters B
Volume	26
Issue number	21
DOIs	https://doi.org/10.1142/S0217984912501333
Publication status	Published - 20 Aug 2012
Externally published	Yes

Keywords

admittance spectrocopy
equivalent circuit
intermediate band
Quantum dot
solar cell

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10.1142/S0217984912501333

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title = "An equivalent circuit model proposed for the intermediate band nanostructured quantum dot solar cells",

abstract = "The equivalent circuit of the p-i-n structure has been considered and developed for the quantum dot intermediate band solar cells where the nanoparticles are inserted in the active region of the diode. The admittance of the circuits are calculated consisting of frequency dependent capacitance and conductance. The presence of quantum dot layers in the active region of the diode increases the capacitance and conductance of the cell in lower frequencies. However, the number of QD cannot be increased and has an optimum.",

keywords = "admittance spectrocopy, equivalent circuit, intermediate band, Quantum dot, solar cell",

author = "Mohammad Houshmand and Zandi, \{Mohammad H.\} and Dehkordi, \{Somayeh S.\} and Perez, \{Mauricio D.\} and Gorji, \{Nima E.\}",

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AU - Zandi, Mohammad H.

AU - Dehkordi, Somayeh S.

AU - Perez, Mauricio D.

AU - Gorji, Nima E.

PY - 2012/8/20

Y1 - 2012/8/20

N2 - The equivalent circuit of the p-i-n structure has been considered and developed for the quantum dot intermediate band solar cells where the nanoparticles are inserted in the active region of the diode. The admittance of the circuits are calculated consisting of frequency dependent capacitance and conductance. The presence of quantum dot layers in the active region of the diode increases the capacitance and conductance of the cell in lower frequencies. However, the number of QD cannot be increased and has an optimum.

AB - The equivalent circuit of the p-i-n structure has been considered and developed for the quantum dot intermediate band solar cells where the nanoparticles are inserted in the active region of the diode. The admittance of the circuits are calculated consisting of frequency dependent capacitance and conductance. The presence of quantum dot layers in the active region of the diode increases the capacitance and conductance of the cell in lower frequencies. However, the number of QD cannot be increased and has an optimum.

KW - admittance spectrocopy

KW - equivalent circuit

KW - intermediate band

KW - Quantum dot

KW - solar cell

UR - https://www.scopus.com/pages/publications/84863923659

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DO - 10.1142/S0217984912501333

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JO - Modern Physics Letters B

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M1 - 1250133

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An equivalent circuit model proposed for the intermediate band nanostructured quantum dot solar cells

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Keywords

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