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Beitrag Nanoimprinting with non conventional molds
Beitrag Kick-off meeting of IAS Focus Group “Nanoimprinting and Nanotransfer”
2009
Nanotransfering multilayered structures and devices
Beitrag Kick-off meeting of IAS Focus Group “Nanoimprinting and Nanotransfer”
2009
Cutting edge technology at attocube systems AG
Beitrag Kick-off meeting of IAS Focus Group “Nanoimprinting and Nanotransfer”
2009
The focus Group "Nanoimprinting and Nanotransfer"
Beitrag Kick-off meeting of IAS Focus Group “Nanoimprinting and Nanotransfer”
2009
Innovative Nanofabrication Methods and Thin-Film Organic Devices
Nanyang Technology University Singapore
Singapore, Nov 2009
2009
Spray-coating deposition for large area organic thin-film devices
Spray -coating deposition for large are a organic thin -film devices Alaa Abdellah, Daniela Baierl, Bernhard Fabel , Paolo Lugli, Giuseppe Scarpa Institute for Nanoelectronics, Technische Universität München, 80333 Munich, Germany ABSTRACT We report the implementation and testing of an airbrush coating system for the fabrication of a variety of organic electronic and optoelectronic devices using a commercially available airbrush unit. Our setup was implemented inside a glove box in or der to allow the entire fabrication process of the test devices to be performed under nitrogen atmosphere. Several devices such as organic photodetectors, organic light -emitting diodes and organic thin -film transistors were fabricated using c ommerciall y available polymers (such as MEH -PPV, P3HT and PCBM). IV -characteristics, as well as film morphology and roughness of spray coated devices were compared to those of spin coated devices with similar architecture. Although films deposited by spray coating showed a considerably higher surface roughness, the corresponding devices are capable of achieving performances comparable to those of spin coated devices. Keywords : spray -coating, organic photovoltaics, organic light emitting dio des, organic photodetectors, organic thin - film transistors. 1 INTRODUCTION Organic electronic devices based on solution - processable polymers are among the most promising applications of organic semiconductors. Low -cost fabrication by means of simple coatin g and printing techniques is surely one of their greatest advantages. Although several possible deposition techniques are mentioned in literature [1, 2] , spin -coating seems to be the me thod of choice in many research activities presented so far. Despite th e simplicity and effectiveness of this technique in producing high quality thin films, it lacks several aspects necessary for large -scale production. One very promising, yet little examined, alternative deposition technique is spray -coating , which would of fer much a higher suitability and flexibility with respect to large -area industrial -scale application processes [3, 4] . Other advantages of sp ray-coating as an alternative deposition technique for organic thin -film devices are an easier thickness control over wider ranges, the capability of deposition on non -flat surfaces and lower material losses during deposition, which are of great value for industrial - scale and lab -scale applications likewise. On the other hand, some of the significant disadvantages of this technique are the lower overall layer homogeneity and the extremely high surface roughness when compared to spin - coated layers. Nevertheless, it can be shown, that these issues do not have a significant effect on device performance . Previously, a special spray deposition method called evaporative spray deposition was specially designed in order to obtain smooth polymer layers [5]. This method however involved a vacuum process, which makes it less practical for the implementation in large area deposition systems. In this ar ticle we demonstrate the suitability of spray -coating for different classes of organic thin -film devices while comparing them with spin -coated devices of similar architecture. 2 EXPERIMENTAL DETAILS For the deposition of the organic layers by spray - coatin g, a commercially available airbrush unit (Gabbert Triplex) was used. All ink -containing parts of the airbrush are resistant to organic solvents, such as toluene, and are therefore suitable for the desired application. Our test setup was implemented insid e a glove box in order to ensure well controlled environmental conditions throughout the entire fabrication process. Figure 1 shows a schematic drawing of the airbrush coating system, indicating the atomizing gas and material inlets as well as the vertical arrangement of airbrush unit and substrate. Figure 1: Illustration of the impl emented airbrush coating system. All experiments were carried out inside a glove box under nitrogen atmosphere. The most important process parameters were found to be atomiz ing gas (N 2 ) pressure, nozzle -to-sample distance and spray time. Atomiz ing gas pressure directly affects the beam profile and the mean drop size . In all our experiments NSTI-Nanotech 2009, www.nsti.org, ISBN 978-1-4398-1783-4 Vol. 2, 2009
Nano Science and Technology Institute NSTI
2009
Analytical Study of Carriers in Silicon Nanowires
MASAUM Journal of Basic and Applied Sciences Vol.1, No. 2
2009
Sep
Analytical study of drift velocity in N-type silicon nanowires
Quality Electronic Design, 2009. ASQED 2009. 1st Asia Symposium on
Kuala Lumpur, Malaysia, 15-16 July 2009
IEEE Xplore Digital Library
2009
Band Structure Effect on Carbon Nanotube Fermi Energy
International Review of PHYSICS, Vol. 3. n. 4, pp. 224
2009