Your search keyword '"Özyilmaz, B."' showing total 4 results

1. Scrolling graphene into nanofluidic channels.

Author

Mirsaidov U, Mokkapati VR, Bhattacharya D, Andersen H, Bosman M, Özyilmaz B, and Matsudaira P

Subjects

Equipment Design, Nanostructures ultrastructure, Nanotechnology, Graphite chemistry, Microfluidic Analytical Techniques instrumentation, Nanostructures chemistry, Water chemistry

Abstract

Here we report on the "scrolling" of planar graphene induced by water as a result of the interplay between water capillarity and graphene elasticity. This scrolling leads to the formation of stable nanochannels that encapsulate water and nanoscale objects. We demonstrate that these graphene nanochannels can be used as nanofluidic platforms for dynamic imaging of nanoscale processes in liquids with Transmission Electron Microscopes (TEMs). These water-impermeable graphene nanochannels have practical application in the design of nanofluidic devices used in biosensors and many analytical separation devices.

Published

2013

2. Graphene-P(VDF-TrFE) multilayer film for flexible applications.

Author

Bae SH, Kahya O, Sharma BK, Kwon J, Cho HJ, Özyilmaz B, and Ahn JH

Subjects

Elastic Modulus, Equipment Design, Equipment Failure Analysis, Materials Testing, Nanostructures ultrastructure, Particle Size, Stress, Mechanical, Acoustics instrumentation, Graphite chemistry, Membranes, Artificial, Micro-Electrical-Mechanical Systems instrumentation, Nanostructures chemistry, Polyvinyls chemistry

Abstract

A flexible, transparent acoustic actuator and nanogenerator based on graphene/P(VDF-TrFE)/graphene multilayer film is demonstrated. P(VDF-TrFE) is used as an effective doping layer for graphene and contributes significantly to decreasing the sheet resistance of graphene to 188 ohm/sq. The potentiality of graphene/P(VDF-TrFE)/graphene multilayer film is realized in fabricating transparent, flexible acoustic devices and nanogenerators to represent its functionality. The acoustic actuator shows good performance and sensitivity over a broad range of frequency. The output voltage and the current density of the nanogenerator are estimated to be ∼3 V and ∼0.37 μAcm(-2), respectively, upon the application of pressure. These values are comparable to those reported earlier for ZnO- and PZT-based nanogenerators. Finally, the possibility of rollable devices based on graphene/P(VDF-TrFE)/graphene structure is also demonstrated under a dynamic mechanical loading condition.

Published

2013

3. Focused-ion-beam milling based nanostencil mask fabrication for spin transfer torque studies.

Author

Özyilmaz, B., Richter, G., Müsgens, N., Fraune, M., Hawraneck, M., Beschoten, B., Güntherodt, G., Bückins, M., and Mayer, J.

Subjects

*ION bombardment, *MAGNETICS, *NANOSTRUCTURES, *PHYSICS, *THIN films, *ELECTRODES, *ETCHING

Abstract

Focused-ion-beam milling is used to fabricate nanostencil masks suitable for the fabrication of magnetic nanostructures relevant for spin transfer torque studies. Nanostencil masks are used to define the device dimensions prior to the growth of the thin film stack. They consist of a wet etch resistant top layer and an insulator on top of a prepatterned bottom electrode. The insulator supports a hard mask and gives rise to an undercut by its selective etching. The approach is demonstrated by fabricating current perpendicular to the plane Co/Cu/Co nanopillar junctions, which exhibit current induced magnetization dynamics. [ABSTRACT FROM AUTHOR]

Published

2007

4. Spin-transfer-induced precessional magnetization reversal.

Author

Kent, A.D., Özyilmaz, B., and del Barco, E.

Subjects

*SPINTRONICS, *MAGNETIZATION, *THIN films, *NANOSTRUCTURES, *MAGNETIC devices, *MAGNETIC fields

Abstract

A magnetoelectronic device is proposed in which a spin-current pulse produces a rapid reversal of the magnetization of a thin film nanomagnet. A spin-transfer torque induces the reversal and the switching speed is determined by the precession frequency of the magnetization in a thin film element's demagnetization field. Micromagnetic simulations show that this switching occurs above a threshold pulse current and can be faster than 50 ps. In contrast to present spin-transfer devices, the switching does not require an initial fluctuation or deviation of magnetic layers from collinear alignment and is far more energy efficient. This device operates at room temperature and can be realized with present-day magnetic nanostructure technology. [ABSTRACT FROM AUTHOR]

Published

2004