Conferences related to Organic Electronics

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Oceans 2020 MTS/IEEE GULF COAST

To promote awareness, understanding, advancement and application of ocean engineering and marine technology. This includes all aspects of science, engineering, and technology that address research, development, and operations pertaining to all bodies of water. This includes the creation of new capabilities and technologies from concept design through prototypes, testing, and operational systems to sense, explore, understand, develop, use, and responsibly manage natural resources.

  • OCEANS 2018 MTS/IEEE Charleston

    Ocean, coastal, and atmospheric science and technology advances and applications

  • OCEANS 2017 - Anchorage

    Papers on ocean technology, exhibits from ocean equipment and service suppliers, student posters and student poster competition, tutorials on ocean technology, workshops and town meetings on policy and governmental process.

  • OCEANS 2016

    The Marine Technology Scociety and the Oceanic Engineering Society of the IEEE cosponor a joint annual conference and exposition on ocean science, engineering, and policy. The OCEANS conference covers four days. One day for tutorials and three for approx. 500 technical papers and 150 -200 exhibits.

  • OCEANS 2015

    The Marine Technology Scociety and the Oceanic Engineering Society of the IEEE cosponor a joint annual conference and exposition on ocean science, engineering, and policy. The OCEANS conference covers four days. One day for tutorials and three for approx. 450 technical papers and 150-200 exhibits.

  • OCEANS 2014

    The OCEANS conference covers four days. One day for tutorials and three for approx. 450 technical papers and 150-200 exhibits.

  • OCEANS 2013

    Three days of 8-10 tracks of technical sessions (400-450 papers) and concurent exhibition (150-250 exhibitors)

  • OCEANS 2012

    Ocean related technology. Tutorials and three days of technical sessions and exhibits. 8-12 parallel technical tracks.

  • OCEANS 2011

    The Marine Technology Society and the Oceanic Engineering Scociety of the IEEE cosponsor a joint annual conference and exposition on ocean science engineering, and policy.

  • OCEANS 2010

    The Marine Technology Society and the Oceanic Engineering Scociety of the IEEE cosponsor a joint annual conference and exposition on ocean science engineering, and policy.

  • OCEANS 2009

  • OCEANS 2008

    The Marine Technology Society (MTS) and the Oceanic Engineering Society (OES) of the Institute of Electrical and Electronic Engineers (IEEE) cosponsor a joint conference and exposition on ocean science, engineering, education, and policy. Held annually in the fall, it has become a focal point for the ocean and marine community to meet, learn, and exhibit products and services. The conference includes technical sessions, workshops, student poster sessions, job fairs, tutorials and a large exhibit.

  • OCEANS 2007

  • OCEANS 2006

  • OCEANS 2005

  • OCEANS 2004

  • OCEANS 2003

  • OCEANS 2002

  • OCEANS 2001

  • OCEANS 2000

  • OCEANS '99

  • OCEANS '98

  • OCEANS '97

  • OCEANS '96


2019 44th International Conference on Infrared, Millimeter, and Terahertz Waves (IRMMW-THz)

Science, technology and applications spanning the millimeter-waves, terahertz and infrared spectral regions


2019 IEEE 46th Photovoltaic Specialists Conference (PVSC)

Photovoltaic materials, devices, systems and related science and technology


2019 IEEE 69th Electronic Components and Technology Conference (ECTC)

premier components, packaging and technology conference


2019 IEEE Industry Applications Society Annual Meeting

The Annual Meeting is a gathering of experts who work and conduct research in the industrial applications of electrical systems.


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Periodicals related to Organic Electronics

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Advanced Packaging, IEEE Transactions on

The IEEE Transactions on Advanced Packaging has its focus on the modeling, design, and analysis of advanced electronic, photonic, sensors, and MEMS packaging.


Components and Packaging Technologies, IEEE Transactions on

Component parts, hybrid microelectronics, materials, packaging techniques, and manufacturing technology.


Consumer Electronics, IEEE Transactions on

The design and manufacture of consumer electronics products, components, and related activities, particularly those used for entertainment, leisure, and educational purposes


Device and Materials Reliability, IEEE Transactions on

Provides leading edge information that is critical to the creation of reliable electronic devices and materials, and a focus for interdisciplinary communication in the state of the art of reliability of electronic devices, and the materials used in their manufacture. It focuses on the reliability of electronic, optical, and magnetic devices, and microsystems; the materials and processes used in the ...


Display Technology, Journal of

This publication covers the theory, design, fabrication, manufacturing and application of information displays and aspects of display technology that emphasize the progress in device engineering, device design, materials, electronics, physics and reliabilityaspects of displays and the application of displays.


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Most published Xplore authors for Organic Electronics

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Xplore Articles related to Organic Electronics

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An innovative laboratory course of organic electronics

2011 IEEE EUROCON - International Conference on Computer as a Tool, 2011

The course “Organic Electronics” is an experimental course that is part of the Microelectronics curriculum at the Faculty of Technical Sciences, University of Novi Sad, Serbia. This paper presents the main aspects of the laboratory course which features an emerging field of organic electronics with the new materials and applications in its teaching methodology. The course includes four laboratory exercises, ...


Effect of thermal treatment on the performance of organic bulk-hetrojunction photovoltaic devices

2007 International Workshop on Physics of Semiconductor Devices, 2007

Summary form only given. We have studied the performance of bulk hetorojunction solar cell after the thermal treatment of active layer, where donor and acceptor molecules have been poly(3-hexylthiophene) (P3HT) and Buckminster fullerene (PCBM) respectively. The devices under study were fabricated in bulk hetorojunction configuration ITO/PEDOT:PSS/P3HT:PCBM/Al. Devices have been fabricated in different P3HT:PCBM ratio. For this PEDOT:PSS was spin coated ...


Combining Printing, Coating, and Vacuum Deposition on the Roll-to-Roll Scale: A Hybrid Organic Photovoltaics Fabrication

IEEE Journal of Selected Topics in Quantum Electronics, 2016

The potential for organic electronic technologies to produce low-cost energy at large scales is often cited as the most attractive feature of these materials. Such aspirations depend on the ability of materials to be printed from solution at high speeds across large areas using roll-to-roll (R2R) processing. However, progressing the technology from the laboratory environment into the industrial manufacturing arena ...


Improved efficiency of Organic Light Emitting Diodes by doping of hole transport layer

2007 International Workshop on Physics of Semiconductor Devices, 2007

The electrical doping process in OLED has been investigated by doping of 0.4 wt % of 2,3,5,6- tetrafluoro - 7,7',8,8' -tetracyano-quinodimethane( F4-TCNQ) in hole transport layer (alphaplusmn-NPD). The OLED devices with a structure of ITO/pure:doped alpha-PD/Ir(ppy)3:CBP/BCP/Alq<sub>3</sub>/LiF/Al were fabricated using this combination of HTL with green emitting electrophosphorescent material Ir(ppy)<sub>3</sub> doped in CBP. The J-V-L characteristics and device efficiencies with and ...


Flexible substrates and non-ITO transparent electrodes for organic electronics

2015 22nd International Workshop on Active-Matrix Flatpanel Displays and Devices (AM-FPD), 2015

Flexible substrates and non-ITO transparent electrodes are key technologies for next generation organic electronics. In “Yamagata University Organic Thin Film Device Consortium”, in which 21 companies participate, flexible substrates and non-ITO transparent electrodes for organic electronics are being developed. This paper reviews the developed technologies and the prototype OLED devices.


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Educational Resources on Organic Electronics

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IEEE-USA E-Books

  • An innovative laboratory course of organic electronics

    The course “Organic Electronics” is an experimental course that is part of the Microelectronics curriculum at the Faculty of Technical Sciences, University of Novi Sad, Serbia. This paper presents the main aspects of the laboratory course which features an emerging field of organic electronics with the new materials and applications in its teaching methodology. The course includes four laboratory exercises, which present some important organic electronic technologies, such as OLEDs, flexible RFID tag technology, fabrication process of flexible OLEDs, etc. Finally, students' feedback and observation on the laboratory course is discussed.

  • Effect of thermal treatment on the performance of organic bulk-hetrojunction photovoltaic devices

    Summary form only given. We have studied the performance of bulk hetorojunction solar cell after the thermal treatment of active layer, where donor and acceptor molecules have been poly(3-hexylthiophene) (P3HT) and Buckminster fullerene (PCBM) respectively. The devices under study were fabricated in bulk hetorojunction configuration ITO/PEDOT:PSS/P3HT:PCBM/Al. Devices have been fabricated in different P3HT:PCBM ratio. For this PEDOT:PSS was spin coated on cleaned ITO substrates and cured at 100 degC for 30 min. Subsequently P3HT:PCBM was spin coated and thermal treated at different temperatures. Finally Al electrode was thermally evaporated in vacuum through the shadow mask on the substrates. The films were deposited in inert conditions.

  • Combining Printing, Coating, and Vacuum Deposition on the Roll-to-Roll Scale: A Hybrid Organic Photovoltaics Fabrication

    The potential for organic electronic technologies to produce low-cost energy at large scales is often cited as the most attractive feature of these materials. Such aspirations depend on the ability of materials to be printed from solution at high speeds across large areas using roll-to-roll (R2R) processing. However, progressing the technology from the laboratory environment into the industrial manufacturing arena is highly challenging. Closing the gap between exciting laboratory scale insights and the industrial scale potential requires a new focus on upscaling existing technology. Some recent progress in this area is discussed, concentrating on the need to pursue research across several different scales simultaneously in order to most effectively optimize large-scale fabrication efforts. These discussions are placed in the context of a design philosophy that combines printing, coating, and vacuum-based procedures. The challenges associated with selecting, and subsequently synthesizing, the optimal materials for device construction at large scales are considered. Case histories that highlight the unique challenges encountered during printing, coating, and sputtering at the R2R scale are presented. Developing testing and characterization procedures that can interrogate organic photovoltaic device (OPV) structures in real time is also discussed, and the opportunity for new tools to probe device photophysics is highlighted. The collection of innovative approaches to R2R fabrication challenges discussed here highlights the exciting progress toward efficient OPV modules becoming a commercial reality.

  • Improved efficiency of Organic Light Emitting Diodes by doping of hole transport layer

    The electrical doping process in OLED has been investigated by doping of 0.4 wt % of 2,3,5,6- tetrafluoro - 7,7',8,8' -tetracyano-quinodimethane( F4-TCNQ) in hole transport layer (alphaplusmn-NPD). The OLED devices with a structure of ITO/pure:doped alpha-PD/Ir(ppy)3:CBP/BCP/Alq<sub>3</sub>/LiF/Al were fabricated using this combination of HTL with green emitting electrophosphorescent material Ir(ppy)<sub>3</sub> doped in CBP. The J-V-L characteristics and device efficiencies with and without doping of HTL has been measured. It was found that the doping increases the device current and device efficiency at lower applied voltages.

  • Flexible substrates and non-ITO transparent electrodes for organic electronics

    Flexible substrates and non-ITO transparent electrodes are key technologies for next generation organic electronics. In “Yamagata University Organic Thin Film Device Consortium”, in which 21 companies participate, flexible substrates and non-ITO transparent electrodes for organic electronics are being developed. This paper reviews the developed technologies and the prototype OLED devices.

  • A flexible 240/spl times/320-pixel display with integrated row drivers manufactured in organic electronics

    Rollable electrophoretic displays with an active-matrix backplane are an emerging application of organic electronics. Integrating row shift registers on the display backplane reduces the number of interconnects and the footprint. Stand-alone shift registers using organic electronics on a flexible substrate are designed, realized, and characterized. The circuit contains 240 stages and has over 4000 transistors. Furthermore, a 240-stage shift register is integrated with a QVGA active-matrix display.

  • High-k Polymer Nanocomposites as Gate Dielectrics for Organic Electronics Applications

    Motivated by the recent development in organic electronics such as organic field effect transistors (OFETs), printed electronics,.. etc., these emerging technologies have received increasing attention. In addition to the organic semiconductor, gate dielectrics for organic electronics have been the focus of recent R&amp;D attention as well. For this application, the dielectric materials should ideally be compatible with flexible substrate, solution processible, and exhibit larger capacitance to increase the drain current while operating at low biases. Complementary to conventional high dielectric constant (k) inorganic materials and those readily accessible and solution processible polymer materials, polymer/inorganic hybrid films which could be deposited by spin-coating are well suited to provide a better solution. In this study, a solution processible nanocomposite containing benzocyclobutene (BCB) and barium titanate (BT) nanoparticles was developed. Dielectric and electrical properties of the as-prepared BT nanocomposites were investigated, k values of 50 and capacitance density of 19 nF/cm<sup>2</sup> was achieved for a 50 vol.% BT loading. And the dielectric breakdown strength could be maintained 1.65 MV/cm, which is even higher than that of some other polymers themselves. The preliminary result of the electrical output of OFET prototype incorporating high k BT/BCB nanocomposite as gate insulator layer shows that the OFET can be operated at very low voltage. This demonstrates the feasibility of using high k BT/BCB nanocomposite as gate dielectric insulator in the OFET.

  • Operation and modelling of diffusion-driven organic field-effect transistors for high-performance organic electronics

    High-gain organic transistors are the key building blocks for the development of high-performance organic electronics, including high-sensitivity sensors, signal amplification in sensing systems and large-scale circuits. In this work, we analyze organic transistors based on the diffusion-driven charge- accumulation architecture. This class of organic field-effect transistors maximizes at the same the transconductance and the output resistance. The analysis is based on both electrical measurements and theoretical analysis. The transistor performances are critically compared with that of conventional organic field-effect transistors. A simple analytical model that accounts for the effect of the control drain on the saturation current is developed. The model is included in a circuit simulator and an active-load voltage amplifier with electrically-tunable gain is designed. The gain and bandwidth of the voltage amplifier are suitable for signal conditioning and amplification in organic smart sensors.

  • Soft Organic Electronics Based on Graphene Electrodes

    Graphene is considered as an excellent electrode material with a high transparency, good conductivity, and superior mechanical flexibility for use in next-generation flexible electronic devices, and at the same time as an attractive epitaxial template material for highly ordered organic crystal growth. The growth mode, morphology and the crystallographic structure of the organic semiconductors near the graphene-organic interface are strongly affected by various physicochemical characteristics of graphene, and they critically influence the performance of graphene-based organic electronic devices. In this talk I will discuss the challenges, opportunities, and our recent progresses in flexible organic electronics based on graphene electrodes. First, I will describe the growth behaviour of organic semiconductors on graphene electrodes, and their effects on the performances of organic transistors and photovoltaic cells. Then, I will introduce a new concept of using organic nanopatches to modify a CVD-grown graphene, which improved fracture strength without degrading any other supreme characteristics of graphene. With this mechanically strengthened graphene, robust and soft organic electronic devices were demonstrated.

  • The US display consortium program on flexible, printed, and organic electronics

    To accelerate the development of these new applications, the USDC has organized an academic and industry collaboration, known as the Flexible, Printed and Organic Electronics Initiative, which recommends the formation of a public-private partnership to coordinate research and infrastructure development and provide communications and collaboration across the wide range of industries impacted by this new paradigm shift.



Standards related to Organic Electronics

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IEEE Standard for Test Methods for the Characterization of Organic Transistors and Materials

This standard describes a method for characterizing organic electronic devices, including measurement techniques, methods of reporting data, and the testing conditions during characterization.



Jobs related to Organic Electronics

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