Preparation of p-type Na-doped Cu<sub>2</sub>O by electrodeposition for a p-n homojunction thin film solar cell

Elfadill, Nezar G.; Hashim, M.R.; Chahrour, Khaled M.; Mohammed, S.

doi:10.1088/0268-1242/31/6/065001

Cited by 49 publications

(19 citation statements)

References 24 publications

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“…The doping of Cu 2 O by Na does not change the nature of his conductivity; the calculated energy of the gap is 0.35 eV. Elfadill et al [47] showed that Na doping Cu 2 O is a p-type characteristic, which shows that our calculations are in good agreement with experimental data. In addition, Minami et al used Cu 2 O doped Na as p-type in p-n heterojunction and/or homojunction solar cells [48,49].…”

Section: Na and H Doped Cu 2 Osupporting

confidence: 81%

First principle investigation of hydrogen behavior in M doped Cu2O (M = Na, Li and Ti)

Larabi¹,

Mahmoudi²,

Mebarki³

et al. 2019

Condens. Matter Phys.

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We study the hydrogen effect on the electronic, magnetic and optical properties of Cu 2 O in presence of different dopants (Na, Li and Ti). The electronic properties calculations show that hydrogen changes the conductivity of Cu 2 O from p to n-type. The results show that interstitial hydrogen atom prefers to locate in the tetrahedral site in Cu 2 O system and it decreases the band gap value of the later. The Na or Li doping Cu 2 O preserves the p-type conductivity of Cu 2 O, while hydrogen is the source of n-type conductivity in Na or Li doped Cu 2 O systems. Ti doping increases the band gap value of Cu 2 O and makes it an n-type semiconductor. Hydrogen increases the optical transmittance of M doped Cu 2 O.

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Section: Na and H Doped Cu 2 Osupporting

confidence: 81%

First principle investigation of hydrogen behavior in M doped Cu2O (M = Na, Li and Ti)

Larabi¹,

Mahmoudi²,

Mebarki³

et al. 2019

Condens. Matter Phys.

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Section: Introductionmentioning

confidence: 99%

“…[28] Rather, instability issues and challenges of fabricating doped Cu 2 O absorber layers are considered as some major drawbacks of employing this material as prospect layer in all-oxide heterojunction PVs. [29] Unlike commonly investigated p-on-n architectures (ntype being the front illuminated contact) of MOx PVs, the inverted structures (n-on-p) of these systems remained unattainable due to technical obstacles for synthesizing a MOx p-type layer, which can enable efficient light absorption in a relatively thin thickness, and at the same time delivers enhanced photocurrent. However, a quintessential inverted structure of MOx heterojunction, with p-type illumination window can enable generation of more acceptors and consequently result in higher carrier separation at the p-n junction interface (Figure 1B).…”

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confidence: 99%

Vertically aligned Co₃O₄ nanorods as a platform for inverted all‐oxide heterojunctions

et al. 2021

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Direct stacking of n‐type and p‐type metal oxide (MOx) semiconductors is one of the appealing directions toward low cost and environmentally friendly photovoltaics (PVs). However, the main shortcoming, hindering the PV performance of MOx heterojunction devices is attributed to the tradeoff between light absorption and maximized carrier extraction in p‐type MOx. In this work, we demonstrate that the nanorod (NR) geometry of Co3O4 light absorber with a nearly ideal bandgap of ∼1.48 eV, can remove this hurdle through strong internal light trapping of adjacent one‐dimensional (1D) structure and enhanced carrier mobility. The inverted n‐on‐p configuration of the core‐shell 1D heterojunction, obtained by depositing a thin TiO2 n‐type layer, resulted in enlarged charge generation compared to the typical p‐on‐n counterpart device. Fine‐tuning of Co3O4 NRs length, permits PV investigation of the heterojunctions with respect to absorber layers thickness. The optimized Co3O4 NRs/TiO2 heterojunction (30 nm Co3O4 NR length) presented a record high open circuit photovoltage (Voc) of (0.52 ± 0.03) V under 1 sun irradiation. Impedance analysis of the heterojunctions, indicates formation of the p+‐p depletion. The presented work can highlight some vital venues to enhance photoconversion efficiency of the all‐oxide heterojunctions while introducing a pioneer contender as inverted (n‐on‐p) MOx heterojunction.

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“…1,2 The resistivity of this semiconductor, when prepared by electrodeposition, can vary in the range of 10 1 to 10 11 X cm depending on the deposition parameters and incorporation of dopants. [3][4][5][6][7][8] Cu 2 O is a relevant material for several applications such as photocatalysis 9 and solar cells (see Refs. 10 and 11, and therein), and it is very important to develop doping processes to reduce the resistivity and control the n and p character of the material.…”

Section: Introductionmentioning

confidence: 99%

Electrodeposited Cu2O doped with Cl: Electrical and optical properties

Pelegrini

Tumelero

Brandt

et al. 2018

Journal of Applied Physics

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For understanding the electrical and optical properties of electrodeposited Cl-doped Cu 2 O thin films, we have studied layers with increasing thickness and Cl concentrations of 0.8 and 1.2 at. %. The deposits were characterized by measuring the charge transport, the optical reflectance, and the photoluminescence. No significant decrease of electrical resistivity was observed in doped samples compared to undoped ones. A decrease of about five orders of magnitude was measured and ascribed to the presence of pinholes, as confirmed by scanning electron microscopy analyses. From optical measurements, we concluded that the Cl atoms are incorporated into substitutional sites of Cu 2 O lattices in agreement with photoluminescence results showing a strong reduction in the peak intensity of V O þ2 defects in comparison to undoped layers. Computational calculation using density functional theory has pointed out high formation energy for single Cl related defects, but low formation energy for Cl-defect complexes, such as Cl O þ V Cu , that strongly compensate the carriers generated by the Cl doping.

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Preparation of p-type Na-doped Cu₂O by electrodeposition for a p-n homojunction thin film solar cell

Cited by 49 publications

References 24 publications

First principle investigation of hydrogen behavior in M doped Cu2O (M = Na, Li and Ti)

First principle investigation of hydrogen behavior in M doped Cu2O (M = Na, Li and Ti)

Vertically aligned Co₃O₄ nanorods as a platform for inverted all‐oxide heterojunctions

Electrodeposited Cu2O doped with Cl: Electrical and optical properties

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Preparation of p-type Na-doped Cu2O by electrodeposition for a p-n homojunction thin film solar cell

Cited by 49 publications

References 24 publications

First principle investigation of hydrogen behavior in M doped Cu2O (M = Na, Li and Ti)

First principle investigation of hydrogen behavior in M doped Cu2O (M = Na, Li and Ti)

Vertically aligned Co3O4 nanorods as a platform for inverted all‐oxide heterojunctions

Electrodeposited Cu2O doped with Cl: Electrical and optical properties

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Preparation of p-type Na-doped Cu₂O by electrodeposition for a p-n homojunction thin film solar cell

Vertically aligned Co₃O₄ nanorods as a platform for inverted all‐oxide heterojunctions