Karl Amundson scite author profile

Electronic systems that use rugged lightweight plastics potentially offer attractive characteristics (low-cost processing, mechanical flexibility, large area coverage, etc.) that are not easily achieved with established silicon technologies. This paper summarizes work that demonstrates many of these characteristics in a realistic system: organic active matrix backplane circuits (256 transistors) for large (Ϸ5 ؋ 5-inch) mechanically flexible sheets of electronic paper, an emerging type of display. The success of this effort relies on new or improved processing techniques and materials for plastic electronics, including methods for (i) rubber stamping (microcontact printing) high-resolution (Ϸ1 m) circuits with low levels of defects and good registration over large areas, (ii) achieving low leakage with thin dielectrics deposited onto surfaces with relief, (iii) constructing highperformance organic transistors with bottom contact geometries, (iv) encapsulating these transistors, (v) depositing, in a repeatable way, organic semiconductors with uniform electrical characteristics over large areas, and (vi) low-temperature (Ϸ100°C) annealing to increase the on͞off ratios of the transistors and to improve the uniformity of their characteristics. The sophistication and flexibility of the patterning procedures, high level of integration on plastic substrates, large area coverage, and good performance of the transistors are all important features of this work. We successfully integrate these circuits with microencapsulated electrophoretic ''inks'' to form sheets of electronic paper.T he backplane circuit consists of a square array of 256 suitably interconnected p-channel transistors. Fig. 1 shows the circuit layout. Fig. 2 presents a cross-sectional illustration of a transistor and a top view of a unit cell. The completed display (total thickness Ϸ1 mm) comprises a transparent frontplane electrode of indium tin oxide (ITO) and a thin unpatterned layer of flexible electronic ''ink'' mounted against a sheet that supports square pixel electrode pads and pinouts; these pixel pads attach, via a conductive adhesive, to the back planes. Each transistor functions as a switch that locally controls the color of the ink, which consists of a layer of polymeric microcapsules filled with a suspension of charged pigments in a colored fluid (1, 2). In each of the four quadrants of the display, transistors in a given column have connected gates, and those in a given row have connected source electrodes. Applying a voltage to a column (gate) and a row (source) electrode turns on the transistor located at the cell where these electrodes intersect. Activating the transistor generates an electric field between the frontplane ITO and the corresponding pixel electrode. This field causes movement of a pigment within the microcapsules, which changes the color of the pixel, as observed through the ITO: when the pigments flow to the ITO side of the capsules, the color of the pigment (white in this case) determines the color of the pixel; when they ...

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Alignment of Lamellar Block Copolymer Microstructure in an Electric Field. 2. Mechanisms of Alignment

Amundson¹,

Helfand²,

Quan³

et al. 1994

Macromolecules

251

316

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Alignment of lamellar block copolymer microstructure in an electric field was studied. Two mechanisms of alignment are considered: selective electric-field-induced disordering and alignment through movement of defects. The latter mechanism is supported by the findings that, in an aligned sample, defect structures exhibited a highly anisotropic arrangement and were spatially clumped. An analysis of fieldinduced forces on disclination lines and defect walls is presented. Also, defect interactions are considered. Through the interplay between these forces, the alignment process, the kinetics of alignment, and clumping of defects can be rationalized.

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Effect of an electric field on block copolymer microstructure

Amundson¹,

Helfand²,

Davis³

et al. 1991

Macromolecules

214

228

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Alignment of lamellar block copolymer microstructure in an electric field. 1. Alignment kinetics

Amundson¹,

Helfand²,

Quan³

et al. 1993

Macromolecules

221

209

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Poly(phenylenevinylene)s with Dendritic Side Chains: Synthesis, Self-Ordering, and Liquid Crystalline Properties

Bao¹,

Amundson²,

Lovinger³

1998

Macromolecules

136

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Karl Amundson

Paper-like electronic displays: Large-area rubber-stamped plastic sheets of electronics and microencapsulated electrophoretic inks

Alignment of Lamellar Block Copolymer Microstructure in an Electric Field. 2. Mechanisms of Alignment

Effect of an electric field on block copolymer microstructure

Alignment of lamellar block copolymer microstructure in an electric field. 1. Alignment kinetics

Poly(phenylenevinylene)s with Dendritic Side Chains: Synthesis, Self-Ordering, and Liquid Crystalline Properties

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