MoO
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           surface passivation of the transparent anode in organic solar cells using ultrathin films

Cattin, Linda; Dahou, Fatima Zohra; Lare, Yendoubé; Morsli, M.; Tricot, R; Houari, S.; Mokrani, A.; Jondo, Koffi; Khelil, A.; Napo, Kossi; Bernède, J.C.

doi:10.1063/1.3077160

Cited by 127 publications

(89 citation statements)

References 34 publications

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“…Metal oxides were used as buffer layer under the anodes to increase their work function (WF), and enhance hole transport across the organic/electrode interface. [11][12][13][14][15][16][17] The energy level alignment has been extensively argued in many reports; [18][19][20][21][22] several models have been proposed to understand their interfacial electronic structures. The electrostatic model based on the density of states in the organic semiconductor predicted the band-bending in organic semiconductors for different work functions.…”

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confidence: 99%

Relation between Interfacial Band‐Bending and Electronic Properties in Organic Semiconductor Pentacene

Zhang

Zhao

Wang

et al. 2017

Adv Elect Materials

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carriers transport across the organic/electrode interface, such as charge injection in organic thin-film transistors and organic light-emission diodes, and carrier extraction in organic photovoltaic cells. Metal oxides were used as buffer layer under the anodes to increase their work function (WF), and enhance hole transport across the organic/electrode interface. [11][12][13][14][15][16][17] The energy level alignment has been extensively argued in many reports; [18][19][20][21][22] several models have been proposed to understand their interfacial electronic structures. The electrostatic model based on the density of states in the organic semiconductor predicted the band-bending in organic semiconductors for different work functions. [23,24] So far, most of the organic electronic devices still depend on the intrinsic properties of organic materials, and the interfacial electronic structures have not been vastly employed to realize the function of semiconductor devices. Therefore, it still remains a challenge for the effective tailoring of interfacial electronic structures to achieve the desired electronic properties in real electronic devices. Here, we demonstrated that the band-bending in organic semiconductors can be tuned by using the substrates with different work functions, and different interfacial structures leaded to various electronic transport properties. The works are promising exploration to realize the function of semiconductor devices by tailoring the desired interfacial electronic structures.We selected typical organic semiconductor pentacene to investigate the interfacial band-bending, and substrates were selected from high work function to low work function, i.e., PEDOT:PSS/ITO (poly(3,4-ethylenedioxythiophene) polystyrene sulfonate/indium tin oxide) of 5.4 eV work function, ITO of 4.1 eV, and PbO/ITO of 3.5 eV. The pentacene/ITO interface was first studied by using the in situ ultraviolet photoelectron spectroscopy (UPS), which is very effective and a direct tool to investigate interfacial electronic structures. Figure 1a gives the molecular structures of pentacene, and Figure 1b shows the UPS spectra of different pentacene coverage on ITO substrate, left panel is the secondary electron cut-off, which represents the work function of the film, and right panel is the valenceband photoelectron spectra in which the onset of first peak represents the highest occupied molecular orbital (HOMO). The work function of ITO is determined as 4.1 eV, which is about 0.9 eV above the HOMO of pentacene. From UPS and inverse photoelectron spectroscopy, [25]

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confidence: 99%

Relation between Interfacial Band‐Bending and Electronic Properties in Organic Semiconductor Pentacene

Zhang

Zhao

Wang

et al. 2017

Adv Elect Materials

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“…The has been used as buffer layer between the anode and the organic electron donor since it has been shown that it is very efficient in improving the hole collection and OPV cells performances [15]. It can be seen in Table 1 and Fig.…”

Section: Organic Photovoltaic Cells Using Azo/in 2 O 3 and Fto/in 2 Omentioning

confidence: 91%

Towards anode with low indium content as effective anode in organic solar cells

Touihri

Cattin

Nguyen

et al. 2012

Applied Surface Science

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“…The introduction of a thin anode buffer layer (ABL) between the ITO and the ED induces a significant improvement of the device efficiency [ 8]. For instance, we have shown that Au [ 9] and MoO x [10] allow achieving this goal, by simple vacuum deposition of an ultra -thin gold film or of a thin MoO x film when CuPc is the ED. Here, the effects of a gold or MoO x ABL onto the ITO anode are studied using ED with different HOMO.…”

Section: Introductionmentioning

confidence: 97%

“…The thicknesses were 40 nm, 9 nm and 130 nm for C 60 , BCP and Al respectively. The ABL thicknesses were 0.5 nm [9] and 3.5 nm [10] for Au and MoO 3 respectively. The thickness of the different ED layers have been optimized, they are 35 nm for CuPc, 25 nm for pentacene, 20 nm for DBP and T3PM.…”

Section: Methodsmentioning

confidence: 99%

About the transparent electrode of the organic photovoltaic cells

Bérnède

Nguyen

Cattin

et al. 2011

Eur. Phys. J. Appl. Phys.

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Abstract. Electrodes and the nature of their contact with organic materials play a crucial role in the realization of efficient optoelectronic components. Whether the injection (organic light emittin g diodesOLEDs) or collection (organic photovoltaic cells -OPV cells) of carriers, contacts must be as efficient as possible. To do this, it is customary to refer to electrode surface treatment and / or using a buffer layer all things to optimize the contac t. Efficiency of organic photovoltaic cells based on organic electron donor/organic electron acceptor junctions can be strongly improved when the transparent conductive anode is coated with a buffer layer (ABL). We show that an ultra-thin gold (0.5 nm) or a thin molybdenum oxide (3-5 nm) can be used as efficient ABL. However, the effects of these ABL depend on the highest occupied molecular orbital (HOMO) of different electron donors of the OPV cells. The results indicate that, in the case of metal ABL, a good matching between the work function of the anode and the highest occupied molecular orbital of the donor material is the major factor limiting the hole transfer efficiency. Indeed, gold is efficient as ABL only when the HOMO of the organic donor is clos e to its work function Au . MoO 3 has a wider field of application as ABL than gold , The role of the oxide is not so clearly understand than that of Au , different models proposed to interpret the experimental results are discussed.

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MoO 3 surface passivation of the transparent anode in organic solar cells using ultrathin films

Cited by 127 publications

References 34 publications

Relation between Interfacial Band‐Bending and Electronic Properties in Organic Semiconductor Pentacene

Relation between Interfacial Band‐Bending and Electronic Properties in Organic Semiconductor Pentacene

Towards anode with low indium content as effective anode in organic solar cells

About the transparent electrode of the organic photovoltaic cells

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