Your search keyword '"Stutzmann, Natalie"' showing total 7 results

1. Efficient, Stable Bulk Charge Transport in Crystalline/Crystalline Semiconductor-Insulator Blends.

Author

Kumar, Avinesh, Baklar, Mohammed A., Scott, Ken, Kreouzis, Theo, and Stingelin-Stutzmann, Natalie

Published

2009

2. Binary Organic Photovoltaic Blends: A Simple Rationale for Optimum Compositions.

Author

Müller, Christian, Ferenczi, Toby A. M., Campoy-Quiles, Mariano, Frost, Jarvist M., Bradley, Donal D. C., Smith, Paul, Stingelin-Stutzmann, Natalie, and Nelson, Jenny

Published

2008

3. Multicomponent semiconducting polymer systems with low crystallization-induced percolation threshold.

Author

Goffri, Shalom, Müller, Christian, Stingelin-Stutzmann, Natalie, Breiby, Dag W., Radano, Christopher P., Andreasen, Jens W., Thompson, Richard, Janssen, René A. J., Nielsen, Martin M., Smith, Paul, and Sirringhaus, Henning

Subjects

POLYMERS, CRYSTALLIZATION, PERCOLATION, THRESHOLD (Perception), SEMICONDUCTORS, FIELD-effect transistors

Abstract

Blends and other multicomponent systems are used in various polymer applications to meet multiple requirements that cannot be fulfilled by a single material. In polymer optoelectronic devices it is often desirable to combine the semiconducting properties of the conjugated species with the excellent mechanical properties of certain commodity polymers. Here we investigate bicomponent blends comprising semicrystalline regioregular poly(3-hexylthiophene) and selected semicrystalline commodity polymers, and show that, owing to a highly favourable, crystallization-induced phase segregation of the two components, during which the semiconductor is predominantly expelled to the surfaces of cast films, we can obtain vertically stratified structures in a one-step process. Incorporating these as active layers in polymer field-effect transistors, we find that the concentration of the semiconductor can be reduced to values as low as 3 wt% without any degradation in device performance. This is in stark contrast to blends containing an amorphous insulating polymer, for which significant reduction in electrical performance was reported. Crystalline–crystalline/semiconducting–insulating multicomponent systems offer expanded flexibility for realizing high-performance semiconducting architectures at drastically reduced materials cost with improved mechanical properties and environmental stability, without the need to design all performance requirements into the active semiconducting polymer itself. [ABSTRACT FROM AUTHOR]

Published

2006

4. Organic thin-film electronics from vitreous solution-processed rubrene hypereutectics.

Author

Stingelin-Stutzmann, Natalie, Smits, Edsger, Wondergem, Harry, Tanase, Cristina, Blom, Paul, Smith, Paul, and de Leeuw, Dago

Subjects

ORGANIC thin films, THIN films, SURFACES (Technology), ELECTRONIC equipment, ORGANIC semiconductors, SEMICONDUCTORS, ELECTRONIC materials

Abstract

Electronic devices based on single crystals of organic semiconductors provide powerful means for studying intrinsic charge-transport phenomena and their fundamental electronic limits. However, for technological exploitation, it is imperative not to be confined to the tedious growth and cumbersome manipulation of molecular crystals—which generally show notoriously poor mechanical properties—but to be able to process such materials into robust architectures by simple and efficient means. Here, we advance a general route for facile fabrication of thin-film devices from solution. The key beneficial feature of our process—and the principal difference from existing vapour deposition and solution-processing schemes—is the incorporation of a glass-inducing diluent that enables controlled crystallization from an initial vitreous state of the organic semiconductor, formed in a selected area of the phase diagram of the two constituents. We find that the vitrifying diluent does not adversely affect device performance. Indeed, our environmentally stable, discrete rubrene-based transistors rival amorphous silicon devices, reaching saturated mobilities of up to 0.7 cm2 V−1 s−1, ON–OFF ratios of ≥106 and subthreshold slopes as steep as 0.5 V per decade. A nearly temperature-independent device mobility, indicative of a high crystalline quality of our solution-processed, rubrene-based films, corroborates these findings. Inverter and ring-oscillator structures are also demonstrated. [ABSTRACT FROM AUTHOR]

Published

2005

5. Patterning of polymer-supported metal films by microcutting.

Author

Stutzmann, Natalie, Tervoort, Theo A., Bastiaansen, Kees, and Smith, Paul

Subjects

POLYMER solutions, METALLIC films, MICROELECTRONICS industry, INDUSTRIAL processing equipment, TECHNOLOGICAL innovations

Abstract

Presents a report on the creation of well resolved metallic structures on polymer substrates, which is based on solid-state embossing of metal-coated polymer films. Why the ability to micropattern materials is of great importance for manufacturing advanced electronic, optical, and mechanical devices; How the techniques are often of restricted applicability; Illustration of the method through the preparation of patterned electrically conducting structures that are highly efficient infared polarizers.

Published

2000

6. Micropatterned Ceramics by Casting into Polymer Molds.

Author

Schonholzer, Urs P., Stutzmann, Natalie, Tervoort, Theo A., Smith, Paul, and Gauckler, Ludwig J.

Subjects

MOLDING materials, OXIDE ceramics, CERAMIC powders

Abstract

Reports on the generation of patterned ceramic surfaces with a feature resolution in the micrometer range by casting aqueous suspensions of high solids loadings onto nonporous polymer molds. Fabrication of high-quality line patterns for alumina, zirconia, cerium gadolinium oxide and tin oxide powders.

Published

2002

7. Organic electronics: Complexity made simple.

Author

Stingelin-Stutzmann, Natalie

Subjects

ORGANIC electronics, FIELD-effect transistors, ELECTRONICS, SEMICONDUCTORS, ORGANIC solid state chemistry, TRANSISTORS

Abstract

The article reports on a simple, rapid film-deposition technique that allows deposited molecules to self-organize into complex architectures with high charge-carrier mobilities where required within a low-charge-carrier-mobility surround that provides electrical insulation for individual devices. It describes the key features and advantages of organic field-effect transistors.

Published

2008