Synthesis of nanocrystalline Cu deficient CuCrO<sub>2</sub> – a high figure of merit p-type transparent semiconductor

Farrell, L.; Norton, Emma; Smith, Christopher M.; Caffrey, David; Shvets, I. V.; Fleischer, K.

doi:10.1039/c5tc03161c

Cited by 65 publications

(64 citation statements)

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“…It appears that the relative deficiency of copper in the films is mainly counter balanced by an excess of chromium in CuCrO 2 thin-films. The oxygen concentration close to the stoichiometric value of 50% is also a specific feature of our thin-films when compared to the optimized thin-films reported by Farrell et al 53 (Suggesting in their case an excess of oxygen for the optimum stoichiometry of Cu 0.4 CrO 2.5 .) Considering the chemical composition ( Fig.…”

Section: Xps Analysismentioning

confidence: 78%

“…We obtained a FOM of 2300 mS which is far higher than the best FOM recently reported (350 mS). 53 When plotting the average transmittance (in the visible wavelength range), and the conductivity at room temperature that are obtained for thin films of CuCrO 2 grown by various synthesis methods, we compare the transparency/conductivity of our p-type thin films with reported data in the literature (Fig. 9).…”

Section: View Article Onlinementioning

confidence: 99%

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Transparent conductive CuCrO₂thin films deposited by pulsed injection metal organic chemical vapor deposition: up-scalable process technology for an improved transparency/conductivity trade-off

et al. 2016

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aMetal organic chemical vapor deposition is carefully optimized for the growth of pure CuCrO 2 delafossite coatings on glass substrates. The pulsed direct liquid delivery is demonstrated to be an efficient process technology for the controlled supply of the precursor solution in the evaporation chamber, which is shown to be one of the main process parameters to tailor the thin-film properties.We investigated the influence of the precursor concentration ratio Cu(thd) 2 (bis[2,2,6,6-tetramethyl-3,5-heptanedionato]copper(II)) and Cr(thd) 3 (tris[2,2,6,6-tetramethyl-3,5-heptanedionato]chromium(III)) on the crystal structure, morphology and electrical conductivity, at a reduced temperature of 370 1C. We observe for a low ratio, a pure delafossite phase with a constant Cu-poor/Cr-rich chemical composition, while at a high ratio a mixture of copper oxides and CuCrO 2 was found. The as-grown 140 nm-thick pure delafossite films exhibit an exceptional high electrical conductivity for a non-intentionally doped CuCrO 2 , S cm À1, and a near 50% transparency in the visible spectral range.

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Section: Xps Analysismentioning

confidence: 78%

Section: View Article Onlinementioning

confidence: 99%

Transparent conductive CuCrO₂thin films deposited by pulsed injection metal organic chemical vapor deposition: up-scalable process technology for an improved transparency/conductivity trade-off

et al. 2016

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“…In related work cationic and anion substitution and the role of Cr vacancies in this material has been studied. [66,67] High conductivity has also been shown experimentally in non-Cu metal oxides, most notably spinel-structured TCOs, such as NiCo 2 O 4 , [68,69] perovskites-structured TCOs, such as SrIn x Ti 1-x O 3 and Sr x La 1-x CrO 3 , [70,71] and amorphous or composite oxides, such as ZnO·Rh 2 O 3 and In:MoO 3 . [72,73] Other oxides, such as doped Cr 2 O 3 and Ba 2 BiTaO 6 , have promise but remain to be synthesized with high conductivities.…”

Section: P-type Transparent Conductorsmentioning

confidence: 99%

Transparent Electrodes for Efficient Optoelectronics

Morales‐Masis

Wolf

Woods‐Robinson

et al. 2017

Adv Elect Materials

325

280

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With the development of new generations of optoelectronic devices that combine high performance and novel functionalities (e.g., flexibility/bendability, adaptability, semi or full transparency), several classes of transparent electrodes have been developed in recent years. These range from optimized transparent conductive oxides (TCOs), which are historically the most commonly used transparent electrodes, to new electrodes made from nano‐ and 2D materials (e.g., metal nanowire networks and graphene), and to hybrid electrodes that integrate TCOs or dielectrics with nanowires, metal grids, or ultrathin metal films. Here, the most relevant transparent electrodes developed to date are introduced, their fundamental properties are described, and their materials are classified according to specific application requirements in high efficiency solar cells and flexible organic light‐emitting diodes (OLEDs). This information serves as a guideline for selecting and developing appropriate transparent electrodes according to intended application requirements and functionality.

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“…The defective material allows us, by altering the Cu/Cr ratio, to switch between two regions: a highly copper doped amorphous Cr 2 O 3 :Cu structure and a copper deficient CuCrO 2 . While less conductive than the crystalline CuCrO 2 :Mg, it has one of the highest FOMs, 350 μS, of any solution processed p-type TCOs [34].…”

Section: Introductionmentioning

confidence: 99%

“…1 Nanocrystalline, highly conductive, copper-deficient copper chromium oxide was grown by spray pyrolysis using a simple air blast nozzle. Copper(II) acetylacetonate and chromium(III) acetylacetonate precursors in a methanol solution were sprayed at 623 K on glass microscope slides [34]. The incorporated copper content of the Cu x CrO y films was controlled by altering the concentration of copper acetylacetonate in the initial precursor solution.…”

Section: Introductionmentioning

confidence: 99%

X-ray spectroscopic studies of the electronic structure of chromium-basedp-type transparent conducting oxides

et al. 2016

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The valence band structure of p-type transparent oxides-crystalline Mg x Cr 2−x O 3 and nanocrystalline Cu x CrO y -is analyzed as a function of incoming photon energy. The valence band of both p-type transparent conducting oxides shows striking similarities to measurements on crystalline CuCrO 2 :Mg with all films showing that chromium states compose the top of the valence band, suggesting that the valence-band structure is dominated by the presence of the Cr-O 6 octahedra. A comparison of the valence band between the best performing p-type, crystalline CuCrO 2 :Mg, with crystalline Mg x Cr 2−x O 3 and nanocrystalline Cu x CrO y shows that the chromium 3d states are fixed irrespective of changes in long-range crystallographic order. This indicates little spatial overlap between adjacent Cr 3d states. This further confirms the conduction mechanism via hopping for chromium based p-type TCOs as the Cr 3d states are localized within the Cr-O 6 octahedra.

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Synthesis of nanocrystalline Cu deficient CuCrO₂ – a high figure of merit p-type transparent semiconductor

Cited by 65 publications

References 50 publications

Transparent conductive CuCrO₂thin films deposited by pulsed injection metal organic chemical vapor deposition: up-scalable process technology for an improved transparency/conductivity trade-off

Transparent conductive CuCrO₂thin films deposited by pulsed injection metal organic chemical vapor deposition: up-scalable process technology for an improved transparency/conductivity trade-off

Transparent Electrodes for Efficient Optoelectronics

X-ray spectroscopic studies of the electronic structure of chromium-basedp-type transparent conducting oxides

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Synthesis of nanocrystalline Cu deficient CuCrO2 – a high figure of merit p-type transparent semiconductor

Cited by 65 publications

References 50 publications

Transparent conductive CuCrO2thin films deposited by pulsed injection metal organic chemical vapor deposition: up-scalable process technology for an improved transparency/conductivity trade-off

Transparent conductive CuCrO2thin films deposited by pulsed injection metal organic chemical vapor deposition: up-scalable process technology for an improved transparency/conductivity trade-off

Transparent Electrodes for Efficient Optoelectronics

X-ray spectroscopic studies of the electronic structure of chromium-basedp-type transparent conducting oxides

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Synthesis of nanocrystalline Cu deficient CuCrO₂ – a high figure of merit p-type transparent semiconductor

Transparent conductive CuCrO₂thin films deposited by pulsed injection metal organic chemical vapor deposition: up-scalable process technology for an improved transparency/conductivity trade-off

Transparent conductive CuCrO₂thin films deposited by pulsed injection metal organic chemical vapor deposition: up-scalable process technology for an improved transparency/conductivity trade-off