Large-Area, Full-Color Image Sensors Made with Semiconducting Polymers

Yu, Gang; Wang, Jian; McElvain, Jon S.; Heeger, Alan J.

doi:10.1002/(sici)1521-4095(199812)10:17<1431::aid-adma1431>3.3.co;2-w

Cited by 62 publications

(76 citation statements)

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“…Creating a film of polymer from solution using a spinner is a straightforward process that has been used successfully to create films with good uniformity and conductivity 1,2,5,11,12,14,16,17 . Unfortunately, a single spin coated film has a thickness on the order of 100 nm.…”

Section: Deposition Of Conductive Polymermentioning

confidence: 99%

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Remotely Interrogated Passive Polarizing Dosimeter (RIPPeD).

Kemme¹,

Buller²,

Dirk³

et al. 2008

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Conductive polymers have become an extremely useful class of materials for many optical applications. We have developed an electrochemical growth method for depositing highly conductive (~100 S/cm) polypyrrole. Additionally, we have adapted advanced fabrication methods for use with the polypyrrole resulting in gratings with submicron features. This conductive polymer micro-wire grid provides an optical polarizer with unique properties. When the polymer is exposed to ionizing radiation, its conductivity is affected and the polarization properties of the device, specifically the extinction ratio, change in a corresponding manner. This change in polarization properties can be determined by optically interrogating the device, possibly from a remote location. The result is a passive radiation-sensitive sensor with very low optical visibility. The ability to interrogate the device from a safe standoff distance provides a device useful in potentially dangerous environments. Also, the passive nature of the device make it applicable in applications where external power is not available. We will review the polymer deposition, fabrication methods and device design and modeling. The characterization of the polymer's sensitivity to ionizing radiation and optical testing of infrared polarizers before and after irradiation will also be presented. These experimental results will highlight the usefulness of the conductive infrared polarizer to many security and monitoring applications.

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Section: Deposition Of Conductive Polymermentioning

confidence: 99%

“…Electrically conducting polymers are an active area of research with optical applications ranging from photodetectors 1 and photovoltaic cells 2 to light emitting diodes [3][4][5] . Here we report on the development of a subwavelength grating utilizing conductive polymer.…”

Section: Introductionmentioning

confidence: 99%

Remotely Interrogated Passive Polarizing Dosimeter (RIPPeD).

Kemme¹,

Buller²,

Dirk³

et al. 2008

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“…They also offer simultaneous control over mechanical and chemical features. Semiconducting polymer have the potential to deliver the next generation of flat and flexible image sensors, ink-jet printed integrated circuits, inexpensive solar cells, large area lighting and multimedia displays [1][2][3][4][5][6][7][8][9]. Such applications appeal to students and motivate them to pursue research in light-emitting diodes (LEDs), photodiodes, and transistors based on semiconducting polymers.…”

Section: Research Applications That Attract Interestmentioning

confidence: 99%

Cultivating Graduate Students: Techniques to Inspire Effective Research

et al. 2001

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Each year, U.S. institutions grant well over 10,000 bachelor's degrees in science and engineering. However, only a small fraction of those students pursue graduate study. Many who do often experience great difficulty partly due to a lack of preparation for research: the nature of research is inherently foreign to those who are accustomed to studying course material and demonstrating their mastery of it by passing an exam. Carefully involving undergraduates in research can be an effective means for inspiring students to pursue graduate study. We have found that one can create a positive research experience for the student by implementing simple techniques. In this presentation, we present these practical techniques which include: Defining a manageable undergraduate research project; marketing the project to undergraduates; enabling effective record keeping in laboratory notebooks; focussing and directing research through efficient experimental designs. Along with these techniques, we will present examples-taken mainly from our Polymer Electronics Laboratory. We will also present the inherent pitfalls associated with these techniques.

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“…An exciton adjusting layer (EAL) was delicately designed to construct an energy-level-aligned heterojunction with 4CzIPN. As a result, the bi-functional device exhibited a high detectivity of 1.4 Â 10 12 Jones under 350 nm UV light. Moreover, our device exhibited efficient EL emission utilizing the merit of reverse intersystem crossing process from triplet to singlet excitons of 4CzIPN, showing a maximum luminance, current efficiency, and power efficiency of 26370 cd/m 2 , 8.2 cd/A, and 4.9 lm/W, respectively.…”

mentioning

confidence: 97%

“…Nowadays, organic PDs with sensitivity from ultraviolet (UV)-visible to near-infrared wavelengths have been extensively studied due to their merits of large-area detection and flexibility, as well as their potential applications in chemical/biological sensing, environmental sensing, image sensing, communications, and spectroscopic/ medical instruments. [10][11][12][13][14][15] Especially, photodetection in UV region is of great interest in solar astronomy, missile plume detection, environmental monitoring, and so on. 16 Recently, organic integrated devices with UV photodetective and electroluminescent (EL) properties were realized via intramolecular 17 and intermolecular charge transfer architectures.…”

mentioning

confidence: 99%

High performance organic ultraviolet photodetector with efficient electroluminescence realized by a thermally activated delayed fluorescence emitter

Wang

Zhou

Huang

et al. 2015

Applied Physics Letters

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A high performance organic ultraviolet (UV) photodetector with efficient electroluminescence (EL) was obtained by using a thermally activated delayed fluorescence (TADF) emitter of (4s,6s)-2,4,5,6-tetra(9H-carbazol-9-yl)isophthalonitrile (4CzIPN). An exciton adjusting layer (EAL) was delicately designed to construct an energy-level-aligned heterojunction with 4CzIPN. As a result, the bi-functional device exhibited a high detectivity of 1.4 × 1012 Jones under 350 nm UV light. Moreover, our device exhibited efficient EL emission utilizing the merit of reverse intersystem crossing process from triplet to singlet excitons of 4CzIPN, showing a maximum luminance, current efficiency, and power efficiency of 26370 cd/m2, 8.2 cd/A, and 4.9 lm/W, respectively. This work arouses widespread interest in constructing efficient bi-functional device based on TADF emitter and EAL structure.

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Large-Area, Full-Color Image Sensors Made with Semiconducting Polymers

Cited by 62 publications

References 0 publications

Remotely Interrogated Passive Polarizing Dosimeter (RIPPeD).

Remotely Interrogated Passive Polarizing Dosimeter (RIPPeD).

Cultivating Graduate Students: Techniques to Inspire Effective Research

High performance organic ultraviolet photodetector with efficient electroluminescence realized by a thermally activated delayed fluorescence emitter

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