Ink Jet Technology for Large Area Organic Light-Emitting Diode and Organic Photovoltaic Applications

Ren, Maosheng; Gorter, Harrie; Michels, Jasper J.; Andriessen, Ronn

doi:10.2352/j.imagingsci.technol.2011.55.4.040301

Cited by 20 publications

(18 citation statements)

References 12 publications

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“…Figures 1b and 2 imply that elastic responses of the PEDOT:PSS solutions can not significantly contribute to the satellite production. As surfactants take time (typically > 10 -2 s for dynamic surface tension lowering [4]) to reach fresh surfaces, ink-jet satellite production should be enhanced for all of the aqueous solutions. However the major difference here between shear thinning ( Figure 1a) and Newtonian fluids in terms of satellite formation could be due to a difference in their viscosity at the low shear rates relevant to fluid motion in the ligament.…”

Section: Resultsmentioning

confidence: 99%

“…Aqueous dispersions of PEDOT:PSS with or without surfactants have been successfully deposited by inkjet printing for some years to form transparent conductors in printed electronics [1][2][3][4][5][6][7][8], but it has only recently become apparent that their main and satellite drop formation across a wide range of speeds is unusual in comparison with most other printable polymeric fluids.…”

Section: Introductionmentioning

confidence: 99%

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How PEDOT:PSS solutions produce satellite-free inkjets

Hoath

Jung

Hsiao

et al. 2012

Organic Electronics

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Satellite droplets are unwanted in inkjet printing and various approaches have been suggested for their reduction. Low jetting speeds limit applications of the process. Added surfactants for wetting and conductivity enhancement may help but dynamic surface tension effects may counteract improvements. A higher fluid viscosity delays ligament break-up, but also leads to slower jets, while viscoelasticity reduces satellite formation only in certain cases. We show here that aqueous solutions of PEDOT:PSS (1:2.5 by weight) are strongly shear-thinning. They exhibit low viscosity within the printing nozzle over a wide range of jet speeds, yet rapidly (< 100 µs) recover a higher viscosity at the low shear rates applicable once the jet has formed, which give the benefit of delayed satellite formation. The delay over a 0.8 mm standoff distance can be sufficient to completely suppress satellites, which is significant for many printing applications.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

How PEDOT:PSS solutions produce satellite-free inkjets

Hoath

Jung

Hsiao

et al. 2012

Organic Electronics

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“…Inks of this polyelectrolyte system have been prepared and processed by using inkjet for the manufacturing of OLEDs [116,126,127,128]. Control of the PEDOT:PSS ratio, the solvents employed or the addition of surfactants to inks, strongly influence the morphology and the electric properties of the final applied materials after solvent evaporation [129].…”

Section: Inkjet Printing Of Light Emitting Devicesmentioning

confidence: 99%

Inkjet Printing of Functional Materials for Optical and Photonic Applications

et al. 2016

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Inkjet printing, traditionally used in graphics, has been widely investigated as a valuable tool in the preparation of functional surfaces and devices. This review focuses on the use of inkjet printing technology for the manufacturing of different optical elements and photonic devices. The presented overview mainly surveys work done in the fabrication of micro-optical components such as microlenses, waveguides and integrated lasers; the manufacturing of large area light emitting diodes displays, liquid crystal displays and solar cells; as well as the preparation of liquid crystal and colloidal crystal based photonic devices working as lasers or optical sensors. Special emphasis is placed on reviewing the materials employed as well as in the relevance of inkjet in the manufacturing of the different devices showing in each of the revised technologies, main achievements, applications and challenges.

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“…If a display is a rigid structure (i.e., the pitch between OLED cells is equal) and the location of the display is known at all times, the printing task could be executed with a constant velocity and a constant drop-on-demand (DOD) print-frequency [17]. Existing research adopting this technique can be found in, e.g., [18] and [19], an overview of inkjet-based micro-manufacturing is given in [20]. However, due to the flexible nature of the display and the absence of a proper fixation system, a designed trajectory is a necessity.…”

Section: B Industrial Inkjet Printingmentioning

confidence: 99%

“…For the printing task, the print-head shoots a polymer droplet, which has a diameter of 50 [ ], at the center of each OLED cell (see Fig. 3 and [19]). In order to execute an accurate printing task, the delay of the printing task itself needs to be taken into account.…”

Section: B Industrial Inkjet Printingmentioning

confidence: 99%

Direct Motion Planning for Vision-Based Control

Pieters

Jonker

et al. 2014

IEEE Trans. Automat. Sci. Eng.

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This paper presents direct methods for vision-based control for the application of industrial inkjet printing. In this, visual control is designed with a direct coupling between camera measurements and joint motion. Traditional visual servoing commonly has a slow visual update rate and needs an additional local joint controller to guarantee stability. By only using the product as reference and sampling with a high update rate, direct visual measurements are sufficient for controlled positioning. The proposed method is simpler and more reliable than standard motor encoders, despite the tight real-time constraints. This direct visual control method is experimentally verified with a 2D planar motion stage for micrometer positioning. To achieve accurate and fast motion, a balance is found between frame rate and image size. With a frame rate of 1600 fps and an image size of 160 100 pixels we show the effectiveness of the approach. Note to Practitioners-This method of visual control is motivated by the current state-of-the-art in display manufacturing. Traditional solutions for the manufacturing of displays assumes that the transformation between production head and control reference (e.g., kinematic or dynamic model) is known with high accuracy and that the display itself is rigid (i.e., fixed pitch between pixel centers). For flexible displays, this latter assumption is not the case. A method is proposed that takes these issues into account. A camera measures directly where the center of each display cell is located and generates online a trajectory for velocity motion control.This velocity reference is based on a smooth profile with a fixed velocity on cell centers and a higher velocity in between cell centers. This enables a higher overall velocity while ensuring a similar quality of printing compared to a constant velocity reference. Visual control and trajectory generation is executed at 1600 [Hz] with an image size of 160 100 pixels. Feedback is obtained only from visual input, the encoders present in the motors are not used.

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Ink Jet Technology for Large Area Organic Light-Emitting Diode and Organic Photovoltaic Applications

Cited by 20 publications

References 12 publications

How PEDOT:PSS solutions produce satellite-free inkjets

How PEDOT:PSS solutions produce satellite-free inkjets

Inkjet Printing of Functional Materials for Optical and Photonic Applications

Direct Motion Planning for Vision-Based Control

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