Electrowetting on Paper for Electronic Paper Display

Kim, Duk Young; Steckl, A. J.

doi:10.1021/am100757g

Cited by 132 publications

(87 citation statements)

References 32 publications

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“…[206][207][208][209] However, the high requirements on the drive transistors, the required sealing, and the typically rather expensive fabrication processes of luminescent displays make the use of low-cost paper substrates questionable.…”

Section: Displaysmentioning

confidence: 99%

Paper Electronics

Tobjörk¹,

Österbacka²

2011

Advanced Materials

1,189

1,040

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Paper is ubiquitous in everyday life and a truly low-cost substrate. The use of paper substrates could be extended even further, if electronic applications would be applied next to or below the printed graphics. However, applying electronics on paper is challenging. The paper surface is not only very rough compared to plastics, but is also porous. While this is detrimental for most electronic devices manufactured directly onto paper substrates, there are also approaches that are compatible with the rough and absorptive paper surface. In this review, recent advances and possibilities of these approaches are evaluated and the limitations of paper electronics are discussed.

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Section: Displaysmentioning

confidence: 99%

Paper Electronics

Tobjörk¹,

Österbacka²

2011

Advanced Materials

1,189

1,040

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“…It has already been demonstrated that biodegradable substrates such as cellulose may be used both as substrates for LEDs, displays, and thin-fi lm transistors. [40][41][42] A recent study shows the usage of cellulosebased dielectrics in high-performance organic complementary inverters. [ 43 ] Additionally, FF-MNS, which is almost fully biodegradable, has also been demonstrated as a dielectric layer in top-and bottom-gate organic FETs.…”

Section: Biodegradabilitymentioning

confidence: 99%

Self‐Assembled Peptide–Polyfluorene Nanocomposites for Biodegradable Organic Electronics

Khanra

Cipriano

Lam

et al. 2015

Adv Materials Inter

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Based on self‐assembly and mimicking strategies occurring in nature, peptide nanomaterials play a unique role in a new generation of hybrid materials for the electronics of the 21st century. This report describes the functionalization of diphenylalanine (FF)‐based micro/nanostructures with blue‐emitting conducting polymers of the polyfluorene (PF) family. The FF:PF polymer nanocomposites are synthesized by a liquid‐vapor phase method. Electron microscopy images reveal di‐octyl‐substituted PF (PF8) to bind better to the FF micro/nanotubes in comparison with ethyl‐hexyl PF (PF2/6), which influences its optical properties. Molecular dynamics simulations of FF nanotubes with monomeric units of PFs show that PF8 favors greater proximity to the grooves on the surface of the nanotubes due to a higher van der Waals interaction energy compared to PF2/6. The FF:PF nanocomposites are further utilized in light‐emitting diodes. Biodegradability tests from FF:PF8 nanocomposite films show more than 80% weight loss in 2 h by enzymatic action compared to PF8 pristine films, which do not degrade. Self‐assembly of FF nanostructures with organic semiconductors opens up a new generation of biocompatible and biodegradable materials in organic electronics.

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“…The only existing biodegradable polymer with an all-carbon backbone is polyvinyl alcohol (PVA). The main substrate type that has successfully been integrated in organic electronic technology in recent years is cellulose in its various modifications [10][11][12][13]. Although the initial roughness of these substrate types is initially challenging, the roughness level could be lowered either by adjusted fabrication parameters or by additional (bio)coatings.…”

Section: Substrate Materialsmentioning

confidence: 99%

Bio-Organic Electronics—Overview and Prospects for the Future

Mühl

Beyer

2014

Electronics

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Abstract:In recent years, both biodegradable and bio-based electronics have attracted increasing interest, but are also controversially discussed at the same time. Yet, it is not clear whether they will contribute to science and technology or whether they will disappear without major impact. The present review will address several aspects while showing the potential opportunities of bio-organic electronics. An overview about the complex terminology of this emerging field is given and test methods are presented which are used to evaluate the biodegradable properties. It will be shown that the majority of components of organic electronics can be substituted by biodegradable or bio-based materials. Moreover, application scenarios are presented where bio-organic materials have advantages compared to conventional ones. A variety of publications are highlighted which encompass typical organic devices like organic light emitting diodes, organic solar cells and organic thin film transistors as well as applications in the field of medicine or agriculture.

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Electrowetting on Paper for Electronic Paper Display

Cited by 132 publications

References 32 publications

Paper Electronics

Paper Electronics

Self‐Assembled Peptide–Polyfluorene Nanocomposites for Biodegradable Organic Electronics

Bio-Organic Electronics—Overview and Prospects for the Future

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