Formation Mechanisms of ZnO Nanowires: The Crucial Role of Crystal Orientation and Polarity

Guillemin, Samuel; Rapenne, Laëtitia; Roussel, Hervé; Sarigiannidou, E.; Brémond, G.; Consonni, Vincent

doi:10.1021/jp407120j

Cited by 61 publications

(75 citation statements)

References 62 publications

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“…The structural properties of ZnO NWs strongly depend on the structural morphology of the ZnO seed layer, such as nanoparticle size, density, orientation, polarity, and porosity. 12,13 The growth conditions in the chemical bath such as the nature of chemical precursors and related concentrations, pH, and additives are also crucial for controlling the structural morphology of ZnO NWs. 7−11 Owing to the expected increase in light harvesting 14 and extraction efficiency, as well as charge carrier management, the integration of ZnO NWs has recently been achieved in optoelectronic and photovoltaic devices such as light emitting diodes 15 and nanostructured solar cells.…”

Section: Introductionmentioning

confidence: 99%

Physical Properties of Annealed ZnO Nanowire/CuSCN Heterojunctions for Self-Powered UV Photodetectors

Garnier

Parize

Appert

et al. 2015

ACS Appl. Mater. Interfaces

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The low-cost fabrication of ZnO nanowire/CuSCN heterojunctions is demonstrated by combining chemical bath deposition with impregnation techniques. The ZnO nanowire arrays are completely filled by the CuSCN layer from their bottoms to their tops. The CuSCN layer is formed of columnar grains that are strongly oriented along the [003] direction owing to the polymeric form of the β-rhombohedral crystalline phase. Importantly, an annealing step is found essential in a fairly narrow range of low temperatures, not only for outgassing the solvent from the CuSCN layer, but also for reducing the density of interfacial defects. The resulting electrical properties of annealed ZnO nanowire/CuSCN heterojunctions are strongly improved: a maximum rectification ratio of 2644 at ±2 V is achieved following annealing at 150 °C under air atmosphere, which is related to a strong decrease in the reverse current density. Interestingly, the corresponding self-powered UV photodetectors exhibit a responsivity of 0.02 A/W at zero bias and at 370 nm with a UV-to-visible (370-500 nm) rejection ratio of 100 under an irradiance of 100 mW/cm(2). The UV selectivity at 370 nm can also be readily modulated by tuning the length of ZnO nanowires. Eventually, a significant photovoltaic effect is revealed for this type of heterojunctions, leading to an open circuit voltage of 37 mV and a short circuit current density of 51 μA/cm(2), which may be useful for the self-powering of the complete device. These findings show the underlying physical mechanisms at work in ZnO nanowire/CuSCN heterojunctions and reveal their high potential as self-powered UV photodetectors.

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Section: Introductionmentioning

confidence: 99%

Physical Properties of Annealed ZnO Nanowire/CuSCN Heterojunctions for Self-Powered UV Photodetectors

Garnier

Parize

Appert

et al. 2015

ACS Appl. Mater. Interfaces

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“…If a rough or seeded substrate is immersed in that solution, well ordered vertically oriented ZnO NRs can be grown on it [22][23][24]. The seed layer, which consists of zinc oxide crystallites preformed or spin-coated on the substrate,[25][26][27] promotes the heterogeneous nucleation on the substrate (while the homogenous one typically occurs in the bulk solution).…”

mentioning

confidence: 99%

Double Role of HMTA in ZnO Nanorods Grown by Chemical Bath Deposition

Strano¹,

Urso²,

Scuderi

et al. 2014

J. Phys. Chem. C

147

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ZnO nanorods (NRs) grown by chemical bath deposition (CBD) are among the most promising semiconducting nanostructures currently investigated for a variety of applications. Still, contrasting experimental results appear in literature on the microscopic mechanisms leading to high aspect-ratio and vertically aligned ZnO NRs. Here, we report on CBD of ZnO NRs by using Zn nitrate salt and hexamethylenetetramine (HMTA), evidencing a double role of HMTA in the NRs growth mechanism. Beyond the well-established pH buffering activity, HMTA is shown to introduce a strong steric hindrance effect biasing the growth along the c-axis and ensuring the vertical arrangement. This twofold function of HMTA should be taken into account for avoiding detrimental phenomena such as merging or suppression of NRs, which occur at low HMTA concentration.

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“…We attribute the decreased nanorod length (270 nm) to an initially reduced [002] crystalline surface area in the seed layers annealed at 150 °C (table ) compared to nanorods grown on seed layers annealed at higher temperatures (310 nm at 250 °C and 410 nm at 350 °C). Nanorod growth along planes other than the [002] plane is unlikely due to lattice mismatch, and studies on the growth of ZnO nanorods on top of ZnO monocrystals as substrates demonstrated that nanorods grow only on surfaces which provide an exposed c‐plane . During nanorod deposition, the ZnO seed layer is exposed to depletion/etching and attachment simultaneously .…”

Section: Resultsmentioning

confidence: 99%

Controlled Morphology of ZnO Nanorods for Electron Transport in Squaraine Bulk‐Hetero Junction Solar Cells With Thick Active Layers

et al. 2017

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The influence of ZnO seed layer thickness in Squaraine (SQ) is investigated: PC71BM bulk heterojunction solar cells that incorporate ZnO nanorods. The thickness of the ZnO seed layer varies between 16–249 nm by changing the concentration of the precursor solution. With atomic force microscopy (AFM), X‐Ray Diffraction (XRD), and Scanning Electron Microscopy (SEM) studies, it is shown that this approach allows to systematically tune the thickness of the ZnO seed layer without influencing seed layer grain size, or the morphology of the ZnO nanorods that are deposited on top of the seed layer. The proof‐of‐concept is demonstrated in SQ:PC71BM solar cells. It is found that seed layers with 55 nm thickness yield the highest short circuit current densities, resulting in power conversion efficiencies of 2.5 ± 0.1%. These results are compared to SQ:PC71BM solar cells prepared in planar architectures, and it is observed that both device architectures yield comparable results. The optimized nanostructured ZnO electrode enables the fabrication of BHJ devices with thick active layers without the loss in solar cell performance.

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Formation Mechanisms of ZnO Nanowires: The Crucial Role of Crystal Orientation and Polarity

Cited by 61 publications

References 62 publications

Physical Properties of Annealed ZnO Nanowire/CuSCN Heterojunctions for Self-Powered UV Photodetectors

Physical Properties of Annealed ZnO Nanowire/CuSCN Heterojunctions for Self-Powered UV Photodetectors

Double Role of HMTA in ZnO Nanorods Grown by Chemical Bath Deposition

Controlled Morphology of ZnO Nanorods for Electron Transport in Squaraine Bulk‐Hetero Junction Solar Cells With Thick Active Layers

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