Your search keyword '"Schmidt OG"' showing total 394 results

201. Coupling of chiralities in spin and physical spaces: the Möbius ring as a case study.

Author

Pylypovskyi OV, Kravchuk VP, Sheka DD, Makarov D, Schmidt OG, and Gaididei Y

Abstract

We show that the interaction of the magnetic subsystem of a curved magnet with the magnet curvature results in the coupling of a topologically nontrivial magnetization pattern and topology of the object. The mechanism of this coupling is explored and illustrated by an example of a ferromagnetic Möbius ring, where a topologically induced domain wall appears as a ground state in the case of strong easy-normal anisotropy. For the Möbius geometry, the curvilinear form of the exchange interaction produces an additional effective Dzyaloshinskii-like term which leads to the coupling of the magnetochirality of the domain wall and chirality of the Möbius ring. Two types of domain walls are found, transversal and longitudinal, which are oriented across and along the Möbius ring, respectively. In both cases, the effect of magnetochirality symmetry breaking is established. The dependence of the ground state of the Möbius ring on its geometrical parameters and on the value of the easy-normal anisotropy is explored numerically.

Published

2015

202. A size dependent evaluation of the cytotoxicity and uptake of nanographene oxide.

Author

Mendes RG, Koch B, Bachmatiuk A, Ma X, Sanchez S, Damm C, Schmidt OG, Gemming T, Eckert J, and Rümmeli MH

Abstract

Graphene oxide (GO) has attracted great interest due to its extraordinary potential for biomedical application. Although it is clear that the naturally occurring morphology of biological structures is crucial to their precise interactions and correct functioning, the geometrical aspects of nanoparticles are often ignored in the design of nanoparticles for biological applications. A few in vitro and in vivo studies have evaluated the cytotoxicity and biodistribution of GO, however very little is known about the influence of flake size and cytotoxicity. Herein, we aim at presenting an initial cytotoxicity evaluation of different nano-sized GO flakes for two different cell lines (HeLa (Kyoto) and macrophage (J7742)) when they are exposed to samples containing different sized nanographene oxide (NGO) flakes (mean diameter of 89 and 277 nm). The obtained data suggests that the larger NGO flakes reduce cell viability as compared to smaller flakes. In addition, the viability reduction correlates with the time and the concentration of the NGO nanoparticles to which the cells are exposed. Uptake studies were also conducted and the data suggests that both cell lines internalize the GO nanoparticles during the incubation periods studied.

Published

2015

203. Manipulating topological states by imprinting non-collinear spin textures.

Author

Streubel R, Han L, Im MY, Kronast F, Rößler UK, Radu F, Abrudan R, Lin G, Schmidt OG, Fischer P, and Makarov D

Abstract

Topological magnetic states, such as chiral skyrmions, are of great scientific interest and show huge potential for novel spintronics applications, provided their topological charges can be fully controlled. So far skyrmionic textures have been observed in noncentrosymmetric crystalline materials with low symmetry and at low temperatures. We propose theoretically and demonstrate experimentally the design of spin textures with topological charge densities that can be tailored at ambient temperatures. Tuning the interlayer coupling in vertically stacked nanopatterned magnetic heterostructures, such as a model system of a Co/Pd multilayer coupled to Permalloy, the in-plane non-collinear spin texture of one layer can be imprinted into the out-of-plane magnetised material. We observe distinct spin textures, e.g. vortices, magnetic swirls with tunable opening angle, donut states and skyrmion core configurations. We show that applying a small magnetic field, a reliable switching between topologically distinct textures can be achieved at remanence.

Published

2015

204. Direct transfer of magnetic sensor devices to elastomeric supports for stretchable electronics.

Author

Melzer M, Karnaushenko D, Lin G, Baunack S, Makarov D, and Schmidt OG

Abstract

A novel fabrication method for stretchable magnetoresistive sensors is introduced, which allows the transfer of a complex microsensor systems prepared on common rigid donor substrates to prestretched elastomeric membranes in a single step. This direct transfer printing method boosts the fabrication potential of stretchable magnetoelectronics in terms of miniaturization and level of complexity, and provides strain-invariant sensors up to 30% tensile deformation., (© 2015 The Authors. Published by WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2015

205. Sandwich nanoarchitecture of Si/reduced graphene oxide bilayer nanomembranes for Li-ion batteries with long cycle life.

Author

Liu X, Zhang J, Si W, Xi L, Eichler B, Yan C, and Schmidt OG

Abstract

The large capacity loss and huge volume change of silicon anodes severely restricts their practical applications in lithium ion batteries. In this contribution, the sandwich nanoarchitecture of rolled-up Si/reduced graphene oxide bilayer nanomembranes was designed via a strain released strategy. Within this nanoarchitecture, the inner void space and the mechanical feature of nanomembranes can help to buffer the strain during lithiation/delithiation; the alternately stacked conductive rGO layers can protect the Si layers from excessive formation of SEI layers. As anodes for lithium-ion batteries, the sandwiched Si/rGO nanoarchitecture demonstrates long cycling life of 2000 cycles at 3 A g(-1) with a capacity degradation of only 3.3% per 100 cycles.

Published

2015

206. Wearable magnetic field sensors for flexible electronics.

Author

Melzer M, Mönch JI, Makarov D, Zabila Y, Cañón Bermúdez GS, Karnaushenko D, Baunack S, Bahr F, Yan C, Kaltenbrunner M, and Schmidt OG

Abstract

Highly flexible bismuth Hall sensors on polymeric foils are fabricated, and the key optimization steps that are required to boost their sensitivity to the bulk value are identified. The sensor can be bent around the wrist or positioned on the finger to realize an interactive pointing device for wearable electronics. Furthermore, this technology is of great interest for the rapidly developing market of -eMobility, for optimization of eMotors and magnetic bearings., (© 2014 The Authors. Published by WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2015

207. Sperm dynamics in tubular confinement.

Author

Magdanz V, Koch B, Sanchez S, and Schmidt OG

Subjects

Animals, Cattle, Male, Silicon Dioxide pharmacology, Sperm Motility drug effects, Spermatozoa cytology, Spermatozoa drug effects, Cellular Microenvironment, Spermatozoa physiology

Abstract

An on-chip system that mimics tubular microenvironments is presented for the study of spermatozoa motion in confinement. Using rolled up transparent silicon oxide/dioxide microtubes, the influence of tube diameter on the velocity, directionality, and linearity of spermatozoa is investigated. Tubular microenvironments of diameters 20-45 μm facilitate sperm migration through channels., (© 2014 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2015

208. Plasmonic superlensing in doped GaAs.

Author

Fehrenbacher M, Winnerl S, Schneider H, Döring J, Kehr SC, Eng LM, Huo Y, Schmidt OG, Yao K, Liu Y, and Helm M

Abstract

We demonstrate a semiconductor based broadband near-field superlens in the mid-infrared regime. Here, the Drude response of a highly doped n-GaAs layer induces a resonant enhancement of evanescent waves accompanied by a significantly improved spatial resolution at radiation wavelengths around λ = 20 μm, adjustable by changing the doping concentration. In our experiments, gold stripes below the GaAs superlens are imaged with a λ/6 subwavelength resolution by an apertureless near-field optical microscope utilizing infrared radiation from a free-electron laser. The resonant behavior of the observed superlensing effect is in excellent agreement with simulations based on the Drude-Lorentz model. Our results demonstrate a rather simple superlens implementation for infrared nanospectroscopy.

Published

2015

209. High-performance magnetic sensorics for printable and flexible electronics.

Author

Karnaushenko D, Makarov D, Stöber M, Karnaushenko DD, Baunack S, and Schmidt OG

Abstract

High-performance giant magnetoresistive (GMR) sensorics are realized, which are printed at predefined locations on flexible circuitry. Remarkably, the printed magnetosensors remain fully operational over the complete consumer temperature range and reveal a giant magnetoresistance up to 37% and a sensitivity of 0.93 T(-1) at 130 mT. With these specifications, printed magnetoelectronics can be controlled using flexible active electronics for the realization of smart packaging and energy-efficient switches., (© 2014 The Authors. Published by WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2015

210. Imperceptible magnetoelectronics.

Author

Melzer M, Kaltenbrunner M, Makarov D, Karnaushenko D, Karnaushenko D, Sekitani T, Someya T, and Schmidt OG

Subjects

Equipment Design, Humans, Magnetics, Man-Machine Systems, Monitoring, Ambulatory instrumentation, Pliability, Robotics, Biomimetics, Electronics, Skin pathology, Transistors, Electronic

Abstract

Future electronic skin aims to mimic nature's original both in functionality and appearance. Although some of the multifaceted properties of human skin may remain exclusive to the biological system, electronics opens a unique path that leads beyond imitation and could equip us with unfamiliar senses. Here we demonstrate giant magnetoresistive sensor foils with high sensitivity, unmatched flexibility and mechanical endurance. They are <2 μm thick, extremely flexible (bending radii <3 μm), lightweight (≈3 g m(-2)) and wearable as imperceptible magneto-sensitive skin that enables proximity detection, navigation and touchless control. On elastomeric supports, they can be stretched uniaxially or biaxially, reaching strains of >270% and endure over 1,000 cycles without fatigue. These ultrathin magnetic field sensors readily conform to ubiquitous objects including human skin and offer a new sense for soft robotics, safety and healthcare monitoring, consumer electronics and electronic skin devices.

Published

2015

211. Single photons on-demand from light-hole excitons in strain-engineered quantum dots.

Author

Zhang J, Huo Y, Rastelli A, Zopf M, Höfer B, Chen Y, Ding F, and Schmidt OG

Abstract

We demonstrate for the first time on-demand and wavelength-tunable single-photon emission from light-hole (LH) excitons in strain engineered GaAs quantum dots (QDs). The LH photon emission from tensile-strained GaAs QDs is systematically investigated with polarization-resolved, power-dependent photoluminescence spectroscopy, and photon-correlation measurements. By integrating QD-containing nanomembranes onto a piezo-actuator and driving single QDs with picosecond laser pulses, we achieve triggered and wavelength-tunable LH single-photon emission. Fourier transform spectroscopy is also performed, from which the coherence time of the LH single-photon emission is studied. We envision that this new type of LH exciton-based single-photon source (SPS) can be applied to realize an all-semiconductor based quantum interface in distributed quantum networks [Phys. Rev. Lett. 2008, 100, 096602].

Published

2015

212. Evolution of epitaxial semiconductor nanodots and nanowires from supersaturated wetting layers.

Author

Zhang J, Brehm M, Grydlik M, and Schmidt OG

Abstract

In this tutorial we review recent progress in the design and growth of epitaxial semiconductor nanostructures in lattice-mismatched material systems. We focus on the Ge on Si model system after pointing out the similarities to III-V and other growth systems qualitatively as well as quantitatively. During material deposition, the first layers of the epitaxial film wet the surface before the formation of strain-driven three-dimensional nanostructures. In particular, we stress that the supersaturation of the wetting layer (WL), whose relevance is often neglected, plays a key role in determining the nucleation and growth of nanodots (NDs), nanodot-molecules and nanowires (NWs). At elevated growth temperatures the Ge reservoir in the planar, supersaturated WL is abruptly consumed and generates NDs with highly homogeneous sizes - a process mainly driven by elastic energy minimization. Furthermore, the careful control of the supersaturated Ge layer allows us to obtain perfectly site-controlled, ordered NDs or ND-molecules on pit-patterned substrates for a broad range of pit-periods. At low growth temperatures subtle interplays between surface energies of dominant crystal facets in the system drive the material transfer from the supersaturated WL into the elongating NWs growing horizontally, dislocation- and catalyst-free on the substrate surface. Due to the similarities in the formation of nanostructures in different epitaxial semiconductor systems we expect that the observation of the novel growth phenomena described in this Tutorial Review for Ge/Si should be relevant for other lattice-mismatched heterostructure systems, too.

Published

2015

213. High-rate amorphous SnO2 nanomembrane anodes for Li-ion batteries with a long cycling life.

Author

Liu X, Zhang J, Si W, Xi L, Oswald S, Yan C, and Schmidt OG

Abstract

Amorphous SnO2 nanomembranes as anodes for lithium ion batteries demonstrate a long cycling life of 1000 cycles at 1600 mA g(-1) with a high reversible capacity of 854 mA h g(-1) and high rate capability up to 40 A g(-1). The superior performance is because of the structural features of the amorphous SnO2 nanomembranes. The nanoscale thickness provides considerably reduced diffusion paths for Li(+). The amorphous structure can accommodate the strain of lithiation/delithiation, especially during the initial lithiation. More importantly, the mechanical feature of deformation can buffer the strain of repeated lithiation/delithiation, thus putting off pulverization. In addition, the two-dimensional transport pathways in between nanomembranes make the pseudo-capacitance more prominent. The encouraging results demonstrate the significant potential of nanomembranes for high power batteries.

Published

2015

214. Magnetofluidic platform for multidimensional magnetic and optical barcoding of droplets.

Author

Lin G, Makarov D, Medina-Sánchez M, Guix M, Baraban L, Cuniberti G, and Schmidt OG

Subjects

Electronic Data Processing, Equipment Design, Magnetite Nanoparticles chemistry, Magnetic Phenomena, Microfluidic Analytical Techniques instrumentation, Microfluidic Analytical Techniques methods

Abstract

We present a concept of multidimensional magnetic and optical barcoding of droplets based on a magnetofluidic platform. The platform comprises multiple functional areas, such as an encoding area, an encoded droplet pool and a magnetic decoding area with integrated giant magnetoresistive (GMR) sensors. To prove this concept, penicillin functionalized with fluorescent dyes is coencapsulated with magnetic nanoparticles into droplets. While fluorescent dyes are used as conventional optical barcodes which are decoded with an optical decoding setup, an additional dimensionality of barcodes is created by using magnetic nanoparticles as magnetic barcodes for individual droplets and integrated micro-patterned GMR sensors as the corresponding magnetic decoding devices. The strategy of incorporating a magnetic encoding scheme provides a dynamic range of ~40 dB in addition to that of the optical method. When combined with magnetic barcodes, the encoding capacity can be increased by more than 1 order of magnitude compared with using only optical barcodes, that is, the magnetic platform provides more than 10 unique magnetic codes in addition to each optical barcode. Besides being a unique magnetic functional element for droplet microfluidics, the platform is capable of on-demand facile magnetic encoding and real-time decoding of droplets which paves the way for the development of novel non-optical encoding schemes for highly multiplexed droplet-based biological assays.

Published

2015

215. Supervised discriminant analysis for droplet micro-magnetofluidics.

Author

Lin G, Fomin VM, Makarov D, and Schmidt OG

Abstract

We apply the technique of supervised discriminant analysis (SDA) for in-flow detection in droplet-based magnetofluidics. Based on the SDA, we successfully discriminate bivariant droplets of different volumes containing different encapsulated magnetic content produced by a GMR-based lab-on-chip platform. We demonstrate that the accuracy of discrimination is superior when the correlation of variables for data training is included to the case when the spatial distribution of variables is considered. Droplets produced with differences in ferrofluid concentration of 2.5 mg/ml and volume of 200 pl have been identified with high accuracy (98 %), indicating the significance of SDA for e.g. the discrimination in magnetic immuno-agglutination assays. Furthermore, the results open the way for the development of a unique magnetofluidic platform for future applications in multiplexed droplet-based barcoding assays and screening.

Published

2015

216. A single rolled-up Si tube battery for the study of electrochemical kinetics, electrical conductivity, and structural integrity.

Author

Si W, Mönch I, Yan C, Deng J, Li S, Lin G, Han L, Mei Y, and Schmidt OG

Abstract

A lab-on-chip device is demonstrated for probing the electrochemical kinetics, electrical properties, and structure integrity of a single Si rolled-up tube as the anode in lithium-ion batteries. Cyclic voltammetry of the tube exhibits better-resolved peaks than of the planar film due to the enhanced diffusion. The tube is wrinkled after cycling. The tube could be used as a promising ultra-microelectrode for other voltammetry research., (© 2014 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2014

217. Free-standing Fe2O3 nanomembranes enabling ultra-long cycling life and high rate capability for Li-ion batteries.

Author

Liu X, Si W, Zhang J, Sun X, Deng J, Baunack S, Oswald S, Liu L, Yan C, and Schmidt OG

Abstract

With Fe2O3 as a proof-of-concept, free-standing nanomembrane structure is demonstrated to be highly advantageous to improve the performance of Li-ion batteries. The Fe2O3 nanomembrane electrodes exhibit ultra-long cycling life at high current rates with satisfactory capacity (808 mAh g(-1) after 1000 cycles at 2 C and 530 mAh g(-1) after 3000 cycles at 6 C) as well as repeatable high rate capability up to 50 C. The excellent performance benefits particularly from the unique structural advantages of the nanomembranes. The mechanical feature can buffer the strain of lithiation/delithiation to postpone the pulverization. The two-dimensional transport pathways in between the nanomembranes can promote the pseudo-capacitive type storage. The parallel-laid nanomembranes, which are coated by polymeric gel-like film and SEI layer with the electrolyte in between layers, electrochemically behave like numerous "mini-capacitors" to provide the pseudo-capacitance thus maintain the capacity at high rate.

Published

2014

218. Schottky contact on ultra-thin silicon nanomembranes under light illumination.

Author

Song E, Si W, Cao R, Feng P, Mönch I, Huang G, Di Z, Schmidt OG, and Mei Y

Subjects

Electrodes, Light, Lighting methods, Metals chemistry, Surface Properties, Membranes chemistry, Nanostructures chemistry, Silicon chemistry

Abstract

By repeating oxidation and subsequent wet chemical etching, we produced ultra-thin silicon nanomembranes down to 10 nm based on silicon-on-insulator structures in a controllable way. The electrical property of such silicon nanomembranes is highly influenced by their contacts with metal electrodes, in which Schottky barriers (SBs) can be tuned by light illumination due to the surface doping. Thermionic emission theory of carriers is applied to estimate the SB at the interface between metal electrodes and Si nanomembranes. Our work reveals that the Schottky contacts with Si nanomembranes can be influenced by external stimuli (like light luminescence or surface state) more heavily compared to those in the thicker ones, which implies that such ultra-thin-film devices could be of potential use in optical detectors.

Published

2014

219. Bipolar electric-field enhanced trapping and detrapping of mobile donors in BiFeO3 memristors.

Author

You T, Du N, Slesazeck S, Mikolajick T, Li G, Bürger D, Skorupa I, Stöcker H, Abendroth B, Beyer A, Volz K, Schmidt OG, and Schmidt H

Abstract

Pulsed laser deposited Au-BFO-Pt/Ti/Sapphire MIM structures offer excellent bipolar resistive switching performance, including electroforming free, long retention time at 358 K, and highly stable endurance. Here we develop a model on modifiable Schottky barrier heights and elucidate the physical origin underlying resistive switching in BiFeO3 memristors containing mobile oxygen vacancies. Increased switching speed is possible by applying a large amplitude writing pulse as the resistive switching is tunable by both the amplitude and length of the writing pulse. The local resistive switching has been investigated by conductive atomic force microscopy and exhibits the capability of down-scaling the resistive switching cell to the grain size.

Published

2014

220. Optical properties and electrical transport of thin films of terbium(III) bis(phthalocyanine) on cobalt.

Author

Robaschik P, Siles PF, Bülz D, Richter P, Monecke M, Fronk M, Klyatskaya S, Grimm D, Schmidt OG, Ruben M, Zahn DR, and Salvan G

Abstract

The optical and electrical properties of terbium(III) bis(phthalocyanine) (TbPc2) films on cobalt substrates were studied using variable angle spectroscopic ellipsometry (VASE) and current sensing atomic force microscopy (cs-AFM). Thin films of TbPc2 with a thickness between 18 nm and 87 nm were prepared by organic molecular beam deposition onto a cobalt layer grown by electron beam evaporation. The molecular orientation of the molecules on the metallic film was estimated from the analysis of the spectroscopic ellipsometry data. A detailed analysis of the AFM topography shows that the TbPc2 films consist of islands which increase in size with the thickness of the organic film. Furthermore, the cs-AFM technique allows local variations of the organic film topography to be correlated with electrical transport properties. Local current mapping as well as local I-V spectroscopy shows that despite the granular structure of the films, the electrical transport is uniform through the organic films on the microscale. The AFM-based electrical measurements allow the local charge carrier mobility of the TbPc2 thin films to be quantified with nanoscale resolution.

Published

2014

221. Experimental realization of coexisting states of rolled-up and wrinkled nanomembranes by strain and etching control.

Author

Cendula P, Malachias A, Deneke Ch, Kiravittaya S, and Schmidt OG

Abstract

Self-positioned nanomembranes, such as rolled-up tubes and wrinkled thin films, have been potential systems for a variety of applications and basic studies on elastic properties of nanometer-thick systems. Although there is a clear driving force towards elastic energy minimization in each system, the exploration of intermediate states, in which specific characteristics could be chosen by a slight modification of a processing parameter, have not been experimentally realized. In this work, arrays of freestanding III-V nanomembranes (NM) supported on one edge and presenting a coexistence of these two main behaviors were obtained by design of strain conditions in the NMs and controlled selective etching of patterned substrates. As the etching process continues, a mixture of wrinkled and rolled-up states is achieved. For very long etching times an onset of plastic cracks was observed in the points with localized stress. The well-defined morphological periodicity of the relaxed NMs was compared with finite element simulations of their elastic relaxation. The evolution of strain in the NMs with etching time was directly evaluated by X-ray diffraction, providing a comprehensive scenario of transitions among competing and coexisting strain states.

Published

2014

222. Observation of higher order radial modes in atomic layer deposition reinforced rolled-up microtube ring resonators.

Author

Trommer J, Böttner S, Li S, Kiravittaya S, Jorgensen MR, and Schmidt OG

Abstract

We present a detailed investigation of the resonator properties of high-quality rolled-up SiO2 optical microtubes reinforced by atomic layer deposition. The evolution of the resonant modes with increasing film thickness and the transition to a multimode regime, including higher order radial modes, is discussed. Measurements and simulations show that the higher order modes exhibit high optical quality and an increased extension of the evanescent field from the resonator into the surrounding matrix, making them a promising solution for future on-chip sensor applications with increased sensitivity.

Published

2014

223. Confinement and deformation of single cells and their nuclei inside size-adapted microtubes.

Author

Koch B, Sanchez S, Schmidt CK, Swiersy A, Jackson SP, and Schmidt OG

Subjects

Cell Line, Tumor, Cell Proliferation physiology, Cell Survival, DNA metabolism, Humans, Osteosarcoma pathology, Oxides chemistry, Silicon Compounds chemistry, Silicon Dioxide chemistry, Single-Cell Analysis methods, Cell Culture Techniques methods, Cell Nucleus pathology

Published

2014

224. A highly flexible and compact magnetoresistive analytic device.

Author

Lin G, Makarov D, Melzer M, Si W, Yan C, and Schmidt OG

Abstract

A grand vision of realization of smart and compact multifunctional microfluidic devices for wearable health monitoring, environment sensing and point-of-care tests emerged with the fast development of flexible electronics. As a vital component towards this vision, magnetic functionality in flexible fluidics is still missing although demanded by the broad utility of magnetic nanoparticles in medicine and biology. Here, we demonstrate the first flexible microfluidic analytic device with integrated high-performance giant magnetoresistive (GMR) sensors. This device can be bent to a radius of 2 mm while still retaining its full performance. Various dimensions of magnetic emulsion droplets can be probed with high precision using a limit of detection of 0.5 pl, providing broad applicability in high-throughput droplet screening, flow cytometry and drug development. The flexible feature of this analytic device holds great promise in the realization of wearable, implantable multifunctional platforms for biomedical, pharmaceutical and chemical applications.

Published

2014

225. Biofunctionalized self-propelled micromotors as an alternative on-chip concentrating system.

Author

Restrepo-Pérez L, Soler L, Martínez-Cisneros C, Sánchez S, and Schmidt OG

Subjects

Models, Molecular, Streptavidin, Microfluidic Analytical Techniques instrumentation, Miniaturization instrumentation

Abstract

Sample pre-concentration is crucial to achieve high sensitivity and low detection limits in lab-on-a-chip devices. Here, we present a system in which self-propelled catalytic micromotors are biofunctionalized and trapped acting as an alternative concentrating mechanism. This system requires no external energy source, which facilitates integration and miniaturization.

Published

2014

226. Rolled-up functionalized nanomembranes as three-dimensional cavities for single cell studies.

Author

Xi W, Schmidt CK, Sanchez S, Gracias DH, Carazo-Salas RE, Jackson SP, and Schmidt OG

Subjects

HeLa Cells, Humans, Membranes, Artificial, Metaphase, Nanostructures chemistry

Abstract

We use micropatterning and strain engineering to encapsulate single living mammalian cells into transparent tubular architectures consisting of three-dimensional (3D) rolled-up nanomembranes. By using optical microscopy, we demonstrate that these structures are suitable for the scrutiny of cellular dynamics within confined 3D-microenvironments. We show that spatial confinement of mitotic mammalian cells inside tubular architectures can perturb metaphase plate formation, delay mitotic progression, and cause chromosomal instability in both a transformed and nontransformed human cell line. These findings could provide important clues into how spatial constraints dictate cellular behavior and function.

Published

2014

227. Photoactive rolled-up TiO 2 microtubes: fabrication, characterization and applications†Electronic supplementary information (ESI) available. See DOI: 10.1039/c4tc00796dClick here for additional data file.

Author

Giudicatti S, Marz SM, Soler L, Madani A, Jorgensen MR, Sanchez S, and Schmidt OG

Abstract

Because of its unique properties, titania (TiO 2 ) represents a promising candidate in a wide variety of research fields. In this paper, some of the properties and potential applications of titania within rolled-up nanotechnology are explored. It is shown how the structural and optical properties of rolled titania microtubes can be controlled by properly tuning the microfabrication parameters. The rolling up of titania films on different sacrificial layers and containing different shapes, achieving a control on the diameter of the fabricated titania microtubes, is presented. In order to obtain the more photoactive crystalline form of titania, one during-fabrication and two post-fabrication methods are demonstrated. Interesting applications in the fields of photocatalysis and photonics are suggested: the use of titania rolled-up microtubes as micromotors and optical microresonators is presented.

Published

2014

228. Spermbots: potential impact for drug delivery and assisted reproductive technologies.

Author

Magdanz V and Schmidt OG

Subjects

Humans, Male, Nanotechnology, Drug Delivery Systems, Reproductive Techniques, Assisted, Robotics, Spermatozoa

Abstract

Micromotors and nanomotors are an emerging research field that aims at achieving locomotion on the microscale for a variety of applications such as drug delivery, single cell manipulation, microsensors and lab-on-a-chip devices, just to point out a few. The enthusiastic development of hybrid micromotors harnessing biological power sources for physiologically compatible nano/microdevices has recently brought a lot of attention to the international research community that is looking for a solution for the actuation and locomotion on the microscale. This article describes the potential of sperm-driven micro-bio-robots in the biomedical field such as drug delivery or single cell manipulation. Herein, a specific potential of the sperm-driven micro-bio-robot is described that might have impact on the development of assisted reproductive technologies.

Published

2014

229. Hierarchically designed SiOx/SiOy bilayer nanomembranes as stable anodes for lithium ion batteries.

Author

Zhang L, Deng J, Liu L, Si W, Oswald S, Xi L, Kundu M, Ma G, Gemming T, Baunack S, Ding F, Yan C, and Schmidt OG

Abstract

Hierarchically designed SiOx /SiOy rolled-up bilayer nanomembranes are used as anodes for lithium-ion batteries. The functionalities of the SiO(x,y) layers can be engineered by simply controlling the oxygen content, resulting in anodes that exhibit a reversible capacity of about 1300 mA h g(-1) with an excellent stability of over 100 cycles, as well as a good rate capability., (© 2014 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2014

230. Imaging of buried 3D magnetic rolled-up nanomembranes.

Author

Streubel R, Han L, Kronast F, Unal AA, Schmidt OG, and Makarov D

Abstract

Increasing performance and enabling novel functionalities of microelectronic devices, such as three-dimensional (3D) on-chip architectures in optics, electronics, and magnetics, calls for new approaches in both fabrication and characterization. Up to now, 3D magnetic architectures had mainly been studied by integral means without providing insight into local magnetic microstructures that determine the device performance. We prove a concept that allows for imaging magnetic domain patterns in buried 3D objects, for example, magnetic tubular architectures with multiple windings. The approach is based on utilizing the shadow contrast in transmission X-ray magnetic circular dichroism (XMCD) photoemission electron microscopy and correlating the observed 2D projection of the 3D magnetic domains with simulated XMCD patterns. That way, we are not only able to assess magnetic states but also monitor the field-driven evolution of the magnetic domain patterns in individual windings of buried magnetic rolled-up nanomembranes.

Published

2014

231. Pure thiophene-sulfur doped reduced graphene oxide: synthesis, structure, and electrical properties.

Author

Wang Z, Li P, Chen Y, He J, Zhang W, Schmidt OG, and Li Y

Abstract

Here we propose, for the first time, a new and green ethanol-thermal reaction method to synthesize high-quality and pure thiophene-sulfur doped reduced graphene oxide (rGO), which establishes an excellent platform for studying sulfur (S) doping effects on the physical/chemical properties of this material. We have quantitatively demonstrated that the conductivity enhancement of thiophene-S doped rGO is not only caused by the more effective reduction induced by S doping, but also by the doped S atoms, themselves. Furthermore, we demonstrate that the S doping is more effective in enhancing conductivity of rGO than nitrogen (N) doping due to its stronger electron donor ability. Finally, the dye-sensitized solar cell (DSCC) employing the S-doped rGO/TiO2 photoanode exhibits much better performance than undoped rGO/TiO2, N-doped rGO/TiO2 and TiO2 photoanodes. It therefore seems promising for thiophene-S doped rGO to be widely used in electronic and optoelectronic devices.

Published

2014

232. Highly entangled photons from hybrid piezoelectric-semiconductor quantum dot devices.

Author

Trotta R, Wildmann JS, Zallo E, Schmidt OG, and Rastelli A

Abstract

Entanglement resources are key ingredients of future quantum technologies. If they could be efficiently integrated into a semiconductor platform, a new generation of devices could be envisioned, whose quantum-mechanical functionalities are controlled via the mature semiconductor technology. Epitaxial quantum dots (QDs) embedded in diodes would embody such ideal quantum devices, but a fine-structure splitting (FSS) between the bright exciton states lowers dramatically the degree of entanglement of the sources and hampers severely their real exploitation in the foreseen applications. In this work, we overcome this hurdle using strain-tunable optoelectronic devices, where any QD can be tuned for the emission of photon pairs featuring the highest degree of entanglement ever reported for QDs, with concurrence as high as 0.75 ± 0.02. Furthermore, we study the evolution of Bell's parameters as a function of FSS and demonstrate for the first time that filtering-free violation of Bell's inequalities requires the FSS to be smaller than 1 μeV. This upper limit for the FSS also sets the tuning range of exciton energies (∼1 meV) over which our device operates as an energy-tunable source of highly entangled photons. A moderate temporal filtering further increases the concurrence and the tunability of exciton energies up to 0.82 and 2 meV, respectively, though at the expense of 60% reduction of count rate.

Published

2014

233. Colonization of Enterococcus faecalis in a new SiO/SiO(2)-microtube in vitro model system as a function of tubule diameter.

Author

Sigusch BW, Kranz S, Klein S, Völpel A, Harazim S, Sanchez S, Watts DC, Jandt KD, Schmidt OG, and Guellmar A

Subjects

In Vitro Techniques, Enterococcus faecalis growth & development, Models, Biological, Silicon Dioxide chemistry

Abstract

Objectives: Endodontic pathogens can penetrate deep into dentinal tubules and therefore survive the chemo-mechanical disinfection procedures. Bacterial penetration has been mainly studies using sliced infected human teeth which, besides creating artifacts, can hinder the observation of the inner tubules due to the dense and opaque dentin structure. The aim of the present study was to develop a standardized dentin model by using artificial SiO/SiO2-microtubes of different diameters and lengths to test the penetration ability of Enterococcus faecalis., Methods: E. faecalis was grown in Schaedler fluid media for 24h and thereafter cell density was settled to 10(3)cells/ml by addition of fresh media. The bacterial solution was then incubated for 2, 3, 5 and 10 days with the SiO/SiO2-microtubes of different diameters (2-5.5μm) and lengths (100-500μm). The colonization of the tubes was evaluated by phase-contrast microscopy and the amount of colonization was determined by using a colonization index (CI; 0-none, 1-mild, 2-moderate, 3-heavy)., Results: The diameter of the tubes strongly influences the microbial colonization. After 2 days of cultivation the 5.5μm tubes showed a moderate to heavy colonization (CI 2-3). In comparison, the 2 and 3μm tubes were clearly less colonized at the same point in time. In detail: at day 3, only mild to moderate bacteria colonization (CI 1-2) were found in the 3μm tubes and at day 10 penetration of the 2μm tubes just started. The colonization of the 5.5μm tubes was also influenced by their length. In case of the longer microtubes, though, a smaller share of heavily colonized tubes was observed., Significance: Our results show that E. faecalis was able to penetrate and reproduce within the standardized SiO/SiO2-microtubes in a short time. To examine the mechanisms of bacterial adhesion and invasion into tubular structures the 2μm tubes could serve as a model system because the diameters are similar to those of dentinal tubules., (Copyright © 2014 Academy of Dental Materials. Published by Elsevier Ltd. All rights reserved.)

Published

2014

234. Thermal conductivity of mechanically joined semiconducting/metal nanomembrane superlattices.

Author

Grimm D, Wilson RB, Teshome B, Gorantla S, Rümmeli MH, Bublat T, Zallo E, Li G, Cahill DG, and Schmidt OG

Abstract

The decrease of thermal conductivity is crucial for the development of efficient thermal energy converters. Systems composed of a periodic set of very thin layers show among the smallest thermal conductivities reported to-date. Here, we fabricate in an unconventional but straightforward way hybrid superlattices consisting of a large number of nanomembranes mechanically stacked on top of each other. The superlattices can consist of an arbitrary composition of n- or p-type doped single-crystalline semiconductors and a polycrystalline metal layer. These hybrid multilayered systems are fabricated by taking advantage of the self-rolling technique. First, differentially strained nanomembranes are rolled into three-dimensional microtubes with multiple windings. By applying vertical pressure, the tubes are then compressed and converted into a planar hybrid superlattice. The thermal measurements show a substantial reduction of the cross-sectional heat transport through the nanomembrane superlattice compared to a single nanomembrane layer. Time-domain thermoreflectance measurements yield thermal conductivity values below 2 W m(-1) K(-1). Compared to bulk values, this represents a reduction of 2 orders of magnitude by the incorporation of the mechanically joined interfaces. The scanning thermal atomic force microscopy measurements support the observation of reduced thermal transport on top of the superlattices. In addition, small defects with a spatial resolution of ∼100 nm can be resolved in the thermal maps. The low thermal conductivity reveals the potential of this approach to fabricate miniaturized on-chip solutions for energy harvesters in, e.g., microautonomous systems.

Published

2014

235. Trapping self-propelled micromotors with microfabricated chevron and heart-shaped chips.

Author

Restrepo-Pérez L, Soler L, Martínez-Cisneros CS, Sánchez S, and Schmidt OG

Subjects

Equipment Design, Microfluidic Analytical Techniques instrumentation, Microfluidic Analytical Techniques methods, Motion

Abstract

We demonstrate that catalytic micromotors can be trapped in microfluidic chips containing chevron and heart-shaped structures. Despite the challenge presented by the reduced size of the traps, microfluidic chips with different trapping geometries can be fabricated via replica moulding. We prove that these microfluidic chips can capture micromotors without the need for any external mechanism to control their motion.

Published

2014

236. Ultrasmall SnO₂ nanocrystals: hot-bubbling synthesis, encapsulation in carbon layers and applications in high capacity Li-ion storage.

Author

Ding L, He S, Miao S, Jorgensen MR, Leubner S, Yan C, Hickey SG, Eychmüller A, Xu J, and Schmidt OG

Abstract

Ultrasmall SnO2 nanocrystals as anode materials for lithium-ion batteries (LIBs) have been synthesized by bubbling an oxidizing gas into hot surfactant solutions containing Sn-oleate complexes. Annealing of the particles in N2 carbonifies the densely packed surface capping ligands resulting in carbon encapsulated SnO2 nanoparticles (SnO2/C). Carbon encapsulation can effectively buffer the volume changes during the lithiation/delithiation process. The assembled SnO2/C thus deliver extraordinarily high reversible capacity of 908 mA·h·g(-1) at 0.5 C as well as excellent cycling performance in the LIBs. This method demonstrates the great potential of SnO2/C nanoparticles for the design of high power LIBs.

Published

2014

237. Effect of surfactants on the performance of tubular and spherical micromotors - a comparative study.

Author

Simmchen J, Magdanz V, Sanchez S, Chokmaviroj S, Ruiz-Molina D, Baeza A, and Schmidt OG

Abstract

The development of artificial micromotors is one of the greatest challenges of modern nanotechnology. Even though many kinds of motors have been published in recent times, systematic studies on the influence of components of the fuel solution are widely missing. Therefore, the autonomous movement of Pt-microtubes and Pt-covered silica particles is comparatively observed in the presence and absence of surfactants in the medium. One representative of each of the three main surfactant classes - anionic (sodium dodecyl sulfate, SDS), cationic (benzalkonium chloride, BACl) and non-ionic (Triton X) - has been chosen and studied.

Published

2014

238. Stimuli-responsive microjets with reconfigurable shape.

Author

Magdanz V, Stoychev G, Ionov L, Sanchez S, and Schmidt OG

Subjects

Catalysis, Particle Size, Polymers chemical synthesis, Surface Properties, Temperature, Hydrogen Peroxide chemistry, Platinum chemistry, Polymers chemistry

Abstract

Flexible thermoresponsive polymeric microjets are formed by the self-folding of polymeric layers containing a thin Pt film used as catalyst for self-propulsion in solutions containing hydrogen peroxide. The flexible microjets can reversibly fold and unfold in an accurate manner by applying changes in temperature to the solution in which they are immersed. This effect allows microjets to rapidly start and stop multiple times by controlling the radius of curvature of the microjet. This work opens many possibilities in the field of artificial nanodevices, for fundamental studies on self-propulsion at the microscale, and also for biorelated applications., (© 2014 The Authors. Published by Wiley-VCH Verlag GmbH & Co. KGaA. This is an open access article under the terms of the Creative Commons Attribution Non-Commercial NoDerivs License, which permits use and distribution in any medium, provided the original work is properly cited, the use is non-commercial and no modifications or adaptations are made.)

Published

2014

239. Femtosecond imaging of nonlinear acoustics in gold.

Author

Pezeril T, Klieber C, Shalagatskyi V, Vaudel G, Temnov V, Schmidt OG, and Makarov D

Subjects

Time Factors, Gold chemistry, Imaging, Three-Dimensional methods, Nonlinear Dynamics

Abstract

We have developed a high-sensitivity, low-noise femtosecond imaging technique based on pump-probe time-resolved measurements with a standard CCD camera. The approach used in the experiment is based on lock-in acquisitions of images generated by a femtosecond laser probe synchronized to modulation of a femtosecond laser pump at the same rate. This technique allows time-resolved imaging of laser-excited phenomena with femtosecond time resolution. We illustrate the technique by time-resolved imaging of the nonlinear reshaping of a laser-excited picosecond acoustic pulse after propagation through a thin gold layer. Image analysis reveals the direct 2D visualization of the nonlinear acoustic propagation of the picosecond acoustic pulse. Many ultrafast pump-probe investigations can profit from this technique because of the wealth of information it provides over a typical single diode and lock-in amplifier setup, for example it can be used to image ultrasonic echoes in biological samples.

Published

2014

240. Wireless magnetic-based closed-loop control of self-propelled microjets.

Author

Khalil IS, Magdanz V, Sanchez S, Schmidt OG, and Misra S

Subjects

Magnetic Fields, Models, Theoretical, Nanotechnology

Abstract

In this study, we demonstrate closed-loop motion control of self-propelled microjets under the influence of external magnetic fields. We control the orientation of the microjets using external magnetic torque, whereas the linear motion towards a reference position is accomplished by the thrust and pulling magnetic forces generated by the ejecting oxygen bubbles and field gradients, respectively. The magnetic dipole moment of the microjets is characterized using the U-turn technique, and its average is calculated to be 1.3x10⁻¹⁰ A.m² at magnetic field and linear velocity of 2 mT and 100 µm/s, respectively. The characterized magnetic dipole moment is used in the realization of the magnetic force-current map of the microjets. This map in turn is used for the design of a closed-loop control system that does not depend on the exact dynamical model of the microjets and the accurate knowledge of the parameters of the magnetic system. The motion control characteristics in the transient- and steady-states depend on the concentration of the surrounding fluid (hydrogen peroxide solution) and the strength of the applied magnetic field. Our control system allows us to position microjets at an average velocity of 115 µm/s, and within an average region-of-convergence of 365 µm.

Published

2014

241. Propulsion Mechanism of Catalytic Microjet Engines.

Author

Fomin VM, Hippler M, Magdanz V, Soler L, Sanchez S, and Schmidt OG

Abstract

We describe the propulsion mechanism of the catalytic microjet engines that are fabricated using rolled-up nanotech. Microjets have recently shown numerous potential applications in nanorobotics but currently there is a lack of an accurate theoretical model that describes the origin of the motion as well as the mechanism of self-propulsion. The geometric asymmetry of a tubular microjet leads to the development of a capillary force, which tends to propel a bubble toward the larger opening of the tube. Because of this motion in an asymmetric tube, there emerges a momentum transfer to the fluid. In order to compensate this momentum transfer, a jet force acting on the tube occurs. This force, which is counterbalanced by the linear drag force, enables tube velocities of the order of 100 μ m/s. This mechanism provides a fundamental explanation for the development of driving forces that are acting on bubbles in tubular microjets.

Published

2014

242. Magnetic microstructure of rolled-up single-layer ferromagnetic nanomembranes.

Author

Streubel R, Lee J, Makarov D, Im MY, Karnaushenko D, Han L, Schäfer R, Fischer P, Kim SK, and Schmidt OG

Abstract

The magnetic microstructure of rolled-up magnetic nanomembranes is revealed both theoretically and experimentally. Two types of nanomembranes are considered, one with a non-magnetic spacer layer and the other without. Experimentally, by using different materials and tuning the dimensions of the rolled-up nanomembranes, domain patterns consisting of spiral-like and azimuthally magnetized domains are observed, which are in qualitative agreement with the theoretical predictions., (© 2013 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2014

243. Rolled-up TiO₂ optical microcavities for telecom and visible photonics.

Author

Madani A, Böttner S, Jorgensen MR, and Schmidt OG

Abstract

The fabrication of high-quality-factor polycrystalline TiO₂ vertically rolled-up microcavities (VRUMs) by the controlled release of differentially strained TiO₂ bilayered nanomembranes, operating at both telecom and visible wavelengths, is reported. Optical characterization of these resonators reveals quality factors as high as 3.8×10³ in the telecom wavelength range (1520-1570 nm) by interfacing a TiO₂ VRUMs with a tapered optical fiber. In addition, a splitting in the fundamental modes is experimentally observed due to the broken rotational symmetry in our resonators. This mode splitting indicates coupling between clockwise and counterclockwise traveling whispering gallery modes of the VRUMs. Moreover, we show that our biocompatible rolled-up TiO₂ resonators function at several positions along the tube, making them promising candidates for multiplexing and biosensing applications.

Published

2014

244. Eleven nanometer alignment precision of a plasmonic nanoantenna with a self-assembled GaAs quantum dot.

Author

Pfeiffer M, Lindfors K, Zhang H, Fenk B, Phillipp F, Atkinson P, Rastelli A, Schmidt OG, Giessen H, and Lippitz M

Subjects

Light, Materials Testing, Nanoparticles ultrastructure, Particle Size, Arsenicals chemistry, Arsenicals radiation effects, Gallium chemistry, Gallium radiation effects, Nanoparticles chemistry, Nanoparticles radiation effects, Quantum Dots, Surface Plasmon Resonance instrumentation, Transducers

Abstract

Plasmonics offers the opportunity of tailoring the interaction of light with single quantum emitters. However, the strong field localization of plasmons requires spatial fabrication accuracy far beyond what is required for other nanophotonic technologies. Furthermore, this accuracy has to be achieved across different fabrication processes to combine quantum emitters and plasmonics. We demonstrate a solution to this critical problem by controlled positioning of plasmonic nanoantennas with an accuracy of 11 nm next to single self-assembled GaAs semiconductor quantum dots, whose position can be determined with nanometer precision. These dots do not suffer from blinking or bleaching or from random orientation of the transition dipole moment as colloidal nanocrystals do. Our method introduces flexible fabrication of arbitrary nanostructures coupled to single-photon sources in a controllable and scalable fashion.

Published

2014

245. Ultracompact three-dimensional tubular conductivity microsensors for ionic and biosensing applications.

Author

Martinez-Cisneros CS, Sanchez S, Xi W, and Schmidt OG

Subjects

Electric Impedance, Electrochemical Techniques instrumentation, Electrodes, Equipment Design, HeLa Cells, Humans, Biosensing Techniques instrumentation, Gold chemistry, Ions analysis, Microfluidic Analytical Techniques instrumentation, Single-Cell Analysis instrumentation

Abstract

We present ultracompact three-dimensional tubular structures integrating Au-based electrodes as impedimetric microsensors for the in-flow determination of mono- and divalent ionic species and HeLa cells. The microsensors show an improved performance of 2 orders of magnitude (limit of detection = 0.1 nM for KCl) compared to conventional planar conductivity detection systems integrated in microfluidic platforms and the capability to detect single HeLa cells in flowing phosphate buffered saline. These highly integrated conductivity tubular sensors thus open new possibilities for lab-in-a-tube devices for bioapplications such as biosensing and bioelectronics.

Published

2014

246. Forming-free resistive switching in multiferroic BiFeO3 thin films with enhanced nanoscale shunts.

Author

Ou X, Shuai Y, Luo W, Siles PF, Kögler R, Fiedler J, Reuther H, Zhou S, Hübner R, Facsko S, Helm M, Mikolajick T, Schmidt OG, and Schmidt H

Abstract

A controlled shunting of polycrystalline oxide thin films on the nanometer length scale opens the door to significantly modify their transport properties. In this paper, the low energy Ar(+) irradiation induced shunting effect of forming-free, non-volatile resistive switching in polycrystalline BiFeO3 thin film capacitor-like structures with macroscopic bottom and top contacts was investigated. Oxygen atoms at the BiFeO3 surface are preferentially sputtered by Ar(+) ion irradiation and oxygen vacancies and a metallic Bi phase are formed at the surface of the BiFeO3 thin film before deposition of the top contacts. A phenomenological model is that of nanoscale shunt resistors formed in parallel to the actual BiFeO3 thin film capacitor-like structure. This model fits the noticeable increase of the retention stability and current density after irradiation. The formation of stable and conductive shunts is further evidenced by conductive atomic force microscopy measurements.

Published

2013

247. Development of a sperm-flagella driven micro-bio-robot.

Author

Magdanz V, Sanchez S, and Schmidt OG

Abstract

A new biohybrid micro-robot is developed by capturing bovine sperm cells inside magnetic microtubes that use the motile cells as driving force. These micro-bio-robots can be remotely controlled by an external magnetic field. The performance of micro-robots is described in dependence on tube radius, cell penetration, and temperature. The combination of a biological power source and a microdevice is a compelling approach to the development of new microrobotic devices with fascinating future applications., (© 2013 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2013

248. Self-propelled micromotors for cleaning polluted water.

Author

Soler L, Magdanz V, Fomin VM, Sanchez S, and Schmidt OG

Abstract

We describe the use of catalytically self-propelled microjets (dubbed micromotors) for degrading organic pollutants in water via the Fenton oxidation process. The tubular micromotors are composed of rolled-up functional nanomembranes consisting of Fe/Pt bilayers. The micromotors contain double functionality within their architecture, i.e., the inner Pt for the self-propulsion and the outer Fe for the in situ generation of ferrous ions boosting the remediation of contaminated water.The degradation of organic pollutants takes place in the presence of hydrogen peroxide, which acts as a reagent for the Fenton reaction and as main fuel to propel the micromotors. Factors influencing the efficiency of the Fenton oxidation process, including thickness of the Fe layer, pH, and concentration of hydrogen peroxide, are investigated. The ability of these catalytically self-propelled micromotors to improve intermixing in liquids results in the removal of organic pollutants ca. 12 times faster than when the Fenton oxidation process is carried out without catalytically active micromotors. The enhanced reaction-diffusion provided by micromotors has been theoretically modeled. The synergy between the internal and external functionalities of the micromotors, without the need of further functionalization, results into an enhanced degradation of nonbiodegradable and dangerous organic pollutants at small-scale environments and holds considerable promise for the remediation of contaminated water.

Published

2013

249. Thermal activation of catalytic microjets in blood samples using microfluidic chips.

Author

Soler L, Martínez-Cisneros C, Swiersy A, Sánchez S, and Schmidt OG

Subjects

Catalysis, Erythrocytes physiology, Humans, Microfluidic Analytical Techniques instrumentation, Solutions chemistry, Temperature, Viscosity, Microfluidic Analytical Techniques methods

Abstract

We demonstrate that catalytic microjet engines can out-swim high complex media composed of red blood cells and serum. Despite the challenge presented by the high viscosity of the solution at room temperature, the catalytic microjets can be activated at physiological temperature and, consequently, self-propel in diluted solutions of blood samples. We prove that these microjets self-propel in 10× diluted blood samples using microfluidic chips.

Published

2013

250. Corrosion of self-propelled catalytic microengines.

Author

Zhao G, Khezri B, Sanchez S, Schmidt OG, Webster RD, and Pumera M

Abstract

Here we show that rolled-up and electroplated catalytic microjet engines undergo dramatic corrosion in fuel solution.

Published

2013