Rapid Atmospheric Pressure Plasma Jet Processed Reduced Graphene Oxide Counter Electrodes for Dye-Sensitized Solar Cells

Liu, Hsiao-Wei; Liang, Sheng-Ping; Wu, Ting-Jui; Chang, Haoming; Kao, Peng-Kai; Hsu, Cheng–Che; Chen, Jian-Zhang; Chou, Pi‐Tai; Cheng, I-Chun

doi:10.1021/am503217f

Cited by 72 publications

(66 citation statements)

References 64 publications

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“…The sintering time for TiO2 nanoparticles could be as short as 30 s with a substrate temperature of ~300 °C (heated by APPJs, no external heating source was used) [24]. For producing porous rGO nanosheets, the sintering time was merely 11 s [27]. The schematic of APPJ apparatus is shown in Figure 1a.…”

Section: Atmospheric-pressure-plasma-jet Sintering Processesmentioning

confidence: 99%

“…Finally, the mixture is concentrated using a rotary concentrator. Figure 3 shows the representative optical emission spectra (OES) and snapshots of APPJs during the APPJ-sintering processes for rGO pastes [27]. It is noted that the case is simpler when sintering screen-printed pastes containing oxide nanoparticles instead of rGOs because the main reaction occurs between the APPJs and organic binders only.…”

Section: Atmospheric-pressure-plasma-jet Sintering Processesmentioning

confidence: 99%

“…SEM images of rGOs [27], nanoporous SnO2, Y2O3, and TiO2/SnO2 sintered by APPJs for various durations. Figure 4 shows SEM images of the nanoporous oxides and 3D rGO nanosheets prepared using the rapid APPJ sintering technique [27]. The APPJ-sintered 3D rGO nanosheets are porous with some sharp edges revealed.…”

Section: Atmospheric-pressure-plasma-jet Sintering Processesmentioning

confidence: 99%

“…An ultrafast (30 s-1 min) APPJ sintering process on nanoporous TiO2 photoanodes of DSSCs has been promisingly developed; these DSSCs showed efficiency comparable to those fabricated by conventional furnace calcination process (510 °C × 15 min) [24][25][26]. A similar APPJ sintering process was also applied for producing 3D reduced graphene oxide (rGO) nanosheet counter electrodes of DSSCs; the required processing time was only 11 s [27].…”

Section: Introductionmentioning

confidence: 99%

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Rapid Atmospheric-Pressure-Plasma-Jet Processed Porous Materials for Energy Harvesting and Storage Devices

et al. 2015

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Atmospheric pressure plasma jet (APPJ) technology is a versatile technology that has been applied in many energy harvesting and storage devices. This feature article provides an overview of the advances in APPJ technology and its application to solar cells and batteries. The ultrafast APPJ sintering of nanoporous oxides and 3D reduced graphene oxide nanosheets with accompanying optical emission spectroscopy analyses are described in detail. The applications of these nanoporous materials to photoanodes and counter electrodes of dye-sensitized solar cells are described. An ultrashort treatment (1 min) on graphite felt electrodes of flow batteries also significantly improves the energy efficiency. OPEN ACCESSCoatings 2015, 5 27

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Section: Atmospheric-pressure-plasma-jet Sintering Processesmentioning

confidence: 99%

Section: Atmospheric-pressure-plasma-jet Sintering Processesmentioning

confidence: 99%

Section: Atmospheric-pressure-plasma-jet Sintering Processesmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Rapid Atmospheric-Pressure-Plasma-Jet Processed Porous Materials for Energy Harvesting and Storage Devices

et al. 2015

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“…19 In this paper, we describe the sequential screen-printing and APPJsintering processes, as well as the preparation procedure of the oxide nanoparticle pastes in detail. Nanoporous TiO 2 and TiO 2 -SnO 2 composites are sintered by APPJs and characterized.…”

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confidence: 99%

Ultrafast Atmospheric-Pressure-Plasma-Jet Sintering of Nanoporous TiO₂-SnO₂Composites with Features Defined by Screen-Printing

Wang

Cheng

Chen

2015

ECS J. Solid State Sci. Technol.

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We investigated atmospheric-pressure-plasma-jet (APPJ)-sintered nanoporous TiO 2 and TiO 2 -SnO 2 composites with patterns defined by the screen-printing technique. The pastes used for screen-printing were made of oxide nanoparticles and organic binders. After using screen-printing to define the features, APPJ was then used to rapidly sinter the screen-printed pastes. APPJ sintering for 30 s can efficiently remove the organic compounds and sinter the nanoparticles, with transmittance haze values comparable to those of nanoporous oxides prepared by conventional furnace calcination. Screen-printing is a mature scalable low-cost deposition process that has been extensively used for the fabrication of various types of devices. [1][2][3][4][5][6][7][8] In industry, this technique is commonly used in roll-to-roll processes in which printing is performed when the web is stationary. Because alignment can be more easily achieved in this technique, it is customarily used in printing the second and follow-up layers. 9,10Recently, screen-printing has attracted renewed interest owing to the search for low-cost fabrication processes for flexible/stretchable supercapacitors, 3,4 We have applied the screen-printing technique to produce ceramictype metal oxides. Screen-printing administers the pastes containing the desired oxide nanoparticles with organic solvents or binders to maintain the required viscosity. The removal of these organic compounds usually requires calcination or annealing processes that are time-consuming and require a high thermal budget. In our previous study, we have developed a rapid atmospheric-pressure-plasma-jet (APPJ) sintering process for nanoporous TiO 2 with a sintering time as short as 1 min. The sintering time can be further reduced to 30 s by introducing air-quenching to increase the oxidization ability. [21][22][23] In contrast, furnace calcination would require ∼15 min excluding the temperature ramping and cooling times. This ultrafast sintering process was made possible by the synergistic effect of highly reactive/active N 2 plasmas and heat generated in APPJs. 21,22 Most recently, we further used this sequential screen-printing and APPJ-sintering process for the fabrication of reduced graphene oxide (rGO) counter electrodes of DSSCs. The processing time was only 11 s owing to the vigorous reaction between the N 2 APPJ and the carbon-based materials; in comparison, conventional furnace calcination would take 15 min at 400• C. The estimated energy consumption per unit processing area is less than one-third that of the conventional furnace calcination process. 19In this paper, we describe the sequential screen-printing and APPJsintering processes, as well as the preparation procedure of the oxide nanoparticle pastes in detail. Nanoporous TiO 2 and TiO 2 -SnO 2 composites are sintered by APPJs and characterized. The synthesized nanoporous oxides are implemented as the photoanodes of DSSCs for functionality testing.z E-mail: jchen@ntu.edu.tw; iccheng@ntu.edu.tw ExperimentalDetails of APPJ operatio...

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Atmospheric Dry Hydrogen Plasma Reduction of Inkjet‐Printed Flexible Graphene Oxide Electrodes

et al. 2018

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This study concerns a low-temperature method for dry hydrogen plasma reduction of inkjet-printed flexible graphene oxide (GO) electrodes, an approach compatible with processes envisaged for the manufacture of flexible electronics. The processing of GO to reduced graphene oxide (rGO) was performed in 1-64 s, and sp /sp +sp carbon concentration increased from approximately 20 % to 90 %. Since the plasma reduction was associated with an etching effect, the optimal reduction time occurred between 8 and 16 s. The surface showed good mechanical stability when deposited on polyethylene terephthalate flexible foils and significantly lower sheet resistance after plasma reduction. This method for dry plasma reduction could be important for large-area hydrogenation and reduction of GO flexible surfaces, with present and potential applications in a wide variety of emerging technologies.

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Rapid Atmospheric Pressure Plasma Jet Processed Reduced Graphene Oxide Counter Electrodes for Dye-Sensitized Solar Cells

Cited by 72 publications

References 64 publications

Rapid Atmospheric-Pressure-Plasma-Jet Processed Porous Materials for Energy Harvesting and Storage Devices

Rapid Atmospheric-Pressure-Plasma-Jet Processed Porous Materials for Energy Harvesting and Storage Devices

Ultrafast Atmospheric-Pressure-Plasma-Jet Sintering of Nanoporous TiO₂-SnO₂Composites with Features Defined by Screen-Printing

Atmospheric Dry Hydrogen Plasma Reduction of Inkjet‐Printed Flexible Graphene Oxide Electrodes

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Rapid Atmospheric Pressure Plasma Jet Processed Reduced Graphene Oxide Counter Electrodes for Dye-Sensitized Solar Cells

Cited by 72 publications

References 64 publications

Rapid Atmospheric-Pressure-Plasma-Jet Processed Porous Materials for Energy Harvesting and Storage Devices

Rapid Atmospheric-Pressure-Plasma-Jet Processed Porous Materials for Energy Harvesting and Storage Devices

Ultrafast Atmospheric-Pressure-Plasma-Jet Sintering of Nanoporous TiO2-SnO2Composites with Features Defined by Screen-Printing

Atmospheric Dry Hydrogen Plasma Reduction of Inkjet‐Printed Flexible Graphene Oxide Electrodes

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Ultrafast Atmospheric-Pressure-Plasma-Jet Sintering of Nanoporous TiO₂-SnO₂Composites with Features Defined by Screen-Printing