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

1. Alloying and Strain Relaxation in SiGe Islands Grown on Pit-Patterned Si(001) Substrates Probed by Nanotomography

Author

Merdzhanova T, Pezzoli F, Stoffel M, Rastelli A, and Schmidt OG

Subjects

SiGe, Island, Alloying, Wet etching, Tomography, AFM, Lateral ordering, Materials of engineering and construction. Mechanics of materials, TA401-492

Abstract

Abstract The three-dimensional composition profiles of individual SiGe/Si(001) islands grown on planar and pit-patterned substrates are determined by atomic force microscopy (AFM)-based nanotomography. The observed differences in lateral and vertical composition gradients are correlated with the island morphology. This approach allowed us to employ AFM to simultaneously gather information on the composition and strain of SiGe islands. Our quantitative analysis demonstrates that for islands with a fixed aspect ratio, a modified geometry of the substrate provides an enhancement of the relaxation, finally leading to a reduced intermixing.

Published

2009

2. Multi-scale ordering of self-assembled InAs/GaAs(001) quantum dots

Author

Kiravittaya S, Songmuang R, Rastelli A, Heidemeyer H, and Schmidt OG

Subjects

Self-assembly, Semiconductor quantum dots, Photoluminescence, Materials of engineering and construction. Mechanics of materials, TA401-492

Abstract

AbstractOrdering phenomena related to the self-assembly of InAs quantum dots (QD) grown on GaAs(001) substrates are experimentally investigated on different length scales. On the shortest length-scale studied here, we examine the QD morphology and observe two types of QD shapes, i.e., pyramids and domes. Pyramids are elongated along the 12345678910 directions and are bounded by {137} facets, while domes have a multi-facetted shape. By changing the growth rates, we are able to control the size and size homogeneity of freestanding QDs. QDs grown by using low growth rate are characterized by larger sizes and a narrower size distribution. The homogeneity of buried QDs is measured by photoluminescence spectroscopy and can be improved by low temperature overgrowth. The overgrowth induces the formation of nanostructures on the surface. The fabrication of self-assembled nanoholes, which are used as a template to induce short-range positioning of QDs, is also investigated. The growth of closely spaced QDs (QD molecules) containing 2–6 QDs per QD molecule is discussed. Finally, the long-range positioning of self-assembled QDs, which can be achieved by the growth on patterned substrates, is demonstrated. Lateral QD replication observed during growth of three-dimensional QD crystals is reported.

Published

2006

3. Temperature dependent optical properties of single, hierarchically self-assembled GaAs/AlGaAs quantum dots

Author

Ulrich SM, Michler P, Benyoucef M, Rastelli A, and Schmidt OG

Subjects

GaAs quantum dots, Hierarchical selfassembly, Single dot spectroscopy, Room temperature luminescence, Photon correlation, 42.50.Ar, 78.55.Cr, 78.67.Hc, Materials of engineering and construction. Mechanics of materials, TA401-492

Abstract

AbstractWe report on the experimental observation of bright photoluminescence emission at room temperature from single unstrained GaAs quantum dots (QDs). The linewidth of a single-QD ground-state emission (≈ 8.5 meV) is comparable to the ensemble inhomogeneous broadening (≈ 12.4 meV). At low temperature (T ≤ 40 K) photon correlation measurements under continuous wave excitation show nearly perfect single-photon emission from a single GaAs QD and reveal the single photon nature of the emitted light up to 77 K. The QD emission energies, homogeneous linewidths and the thermally activated behavior as a function of temperature are discussed.

Published

2006

4. Guided self-assembly of lateral InAs/GaAs quantum-dot molecules for single molecule spectroscopy

Author

Krause B, Metzger TH, Wang L, Rastelli A, Kiravittaya S, Songmuang R, and Schmidt OG

Subjects

Lateral quantum-dot molecules, Quantum dots, Quantum dot composition, Self-assembled growth, Materials of engineering and construction. Mechanics of materials, TA401-492

Abstract

Abstract We report on the growth and characterization of lateral InAs/GaAs (001) quantum-dot molecules (QDMs) suitable for single QDM optical spectroscopy. The QDMs, forming by depositing InAs on GaAs surfaces with self-assembled nanoholes, are aligned along the [] direction. The relative number of isolated single quantum dots (QDs) is substantially reduced by performing the growth on GaAs surfaces containing stepped mounds. Surface morphology and X-ray measurements suggest that the strain produced by InGaAs-filled nanoholes superimposed to the strain relaxation at the step edges are responsible for the improved QDM properties. QDMs are Ga-richer compared to single QDs, consistent with strain- enhanced intermixing. The high optical quality of single QDMs is probed by micro-photoluminescence spectroscopy in samples with QDM densities lower than 108 cm−2.

Published

2006

5. Magnetization reversal and local switching fields of ferromagnetic Co/Pd microtubes with radial magnetization

Author

Puwenberg, N, Reiche, CF, Streubel, R, Khan, M, Mukherjee, D, Soldatov, IV, Melzer, M, Schmidt, OG, Büchner, B, and Mühl, T

Abstract

Three-dimensional nanomagnetism is a rapidly growing field of research covering both noncollinear spin textures and curved magnetic geometries including microtubular structures. We spatially resolve the field-induced magnetization reversal of free-standing ferromagnetic microtubes utilizing multifrequency magnetic force microscopy (MFM). The microtubes are composed of Co/Pd multilayer films with perpendicular magnetic anisotropy that translates to an anisotropy with radial easy axis upon rolling-up. Simultaneously mapping the topography and the perpendicular magnetostatic force derivative, the relation between surface angle and local magnetization configuration is evaluated for a large number of locations with slopes exceeding 45 degrees. The angle-dependence of the switching field is concurrent with the Kondorsky model, i.e., the rolled-up nanomembrane behaves like a planar magnetic film with perpendicular anisotropy and a pinning dominated magnetization reversal. Additionally, we discuss methodological challenges when detecting magnetostatic force derivatives near steep surfaces.

Published

2019

6. Magnetism in curved geometries

Author

Streubel, R, Fischer, P, Kronast, F, Kravchuk, VP, Sheka, DD, Gaididei, Y, Schmidt, OG, and Makarov, D

Subjects

magnetic helix, magnetic shell, Dzyaloshinskii-Moriya interaction, curvilinear magnetism, shapeable magnetoelectronics, curved magnetic thin films, magnetic tubes, Applied Physics, Physical Sciences, Engineering

Abstract

Extending planar two-dimensional structures into the three-dimensional space has become a general trend in multiple disciplines, including electronics, photonics, plasmonics and magnetics. This approach provides means to modify conventional or to launch novel functionalities by tailoring the geometry of an object, e.g. its local curvature. In a generic electronic system, curvature results in the appearance of scalar and vector geometric potentials inducing anisotropic and chiral effects. In the specific case of magnetism, even in the simplest case of a curved anisotropic Heisenberg magnet, the curvilinear geometry manifests two exchange-driven interactions, namely effective anisotropy and antisymmetric exchange, i.e. Dzyaloshinskii-Moriya-like interaction. As a consequence, a family of novel curvature-driven effects emerges, which includes magnetochiral effects and topologically induced magnetization patterning, resulting in theoretically predicted unlimited domain wall velocities, chirality symmetry breaking and Cherenkov-like effects for magnons. The broad range of altered physical properties makes these curved architectures appealing in view of fundamental research on e.g. skyrmionic systems, magnonic crystals or exotic spin configurations. In addition to these rich physics, the application potential of three-dimensionally shaped objects is currently being explored as magnetic field sensorics for magnetofluidic applications, spin-wave filters, advanced magneto-encephalography devices for diagnosis of epilepsy or for energy-efficient racetrack memory devices. These recent developments ranging from theoretical predictions over fabrication of three-dimensionally curved magnetic thin films, hollow cylinders or wires, to their characterization using integral means as well as the development of advanced tomography approaches are in the focus of this review.

Published

2016

7. Vortex circulation and polarity patterns in closely packed cap arrays

Author

Streubel, R, Kronast, F, Reiche, CF, Mühl, T, Wolter, AUB, Schmidt, OG, and Makarov, D

Subjects

Applied Physics, Engineering, Physical Sciences, Technology

Abstract

We studied curvature-driven modifications to the magnetostatic coupling of vortex circulation and polarity in soft-magnetic closely packed cap arrays. A phase diagram for the magnetic remanent/transition states at room temperature as a function of diameter and thickness was assembled. For specimens with vortex remanent state (40 nm-thick Permalloy on 330 nm spherical nanoparticles), both vortex circulation and polarity were visualized. Intercap coupling upon vortex nucleation leads to the formation of vortex circulation patterns in closely packed arrays. The remanent circulation pattern can be tailored choosing the direction of the applied magnetic field with respect to the symmetry axis of the hexagonal array. An even and random distribution of vortex polarity indicates the absence of any circulation-polarity coupling.

Published

2016

8. Alloying and Strain Relaxation in SiGe Islands Grown on Pit-Patterned Si(001) Substrates Probed by Nanotomography

Author

Pezzoli, F, Stoffel, M, Merdzhanova, T, Rastelli, A, and Schmidt, OG

Published

2009

9. Temperature dependent optical properties of single, hierarchically self-assembled GaAs/AlGaAs quantum dots

Author

Benyoucef, M, Rastelli, A, Schmidt, OG, Ulrich, SM, and Michler, P

Published

2006

10. Magnetic sensing platform technologies for biomedical applications

Author

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

Abstract

© 2017 The Royal Society of Chemistry. Detection and quantification of a variety of micro- and nanoscale entities, e.g. molecules, cells, and particles, are crucial components of modern biomedical research, in which biosensing platform technologies play a vital role. Confronted with the drastic global demographic changes, future biomedical research entails continuous development of new-generation biosensing platforms targeting even lower costs, more compactness, and higher throughput, sensitivity and selectivity. Among a wide choice of fundamental biosensing principles, magnetic sensing technologies enabled by magnetic field sensors and magnetic particles offer attractive advantages. The key features of a magnetic sensing format include the use of commercially available magnetic field sensing elements, e.g. magnetoresistive sensors which bear huge potential for compact integration, a magnetic field sensing mechanism which is free from interference by complex biomedical samples, and an additional degree of freedom for the on-chip handling of biochemical species rendered by magnetic labels. In this review, we highlight the historical basis, routes, recent advances and applications of magnetic biosensing platform technologies based on magnetoresistive sensors.

Published

2017

11. Microtubular Fuel Cell with Ultrahigh Power Output per Footprint

Author

Miao, S, He, S, Liang, M, Lin, G, Cai, B, Schmidt, OG, Miao, S, He, S, Liang, M, Lin, G, Cai, B, and Schmidt, OG

Abstract

© 2017 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim A novel realization of microtubular direct methanol fuel cells (µDMFC) with ultrahigh power output is reported by using “rolled-up” nanotechnology. The microtube (Pt-RuO2-RUMT) is prepared by rolling up Ru2O layers coated with magnetron-sputtered Pt nanoparticles (cat-NPs). The µDMFC is fabricated by embedding the tube in a fluidic cell. The footprint of per tube is as small as 1.5 × 10−4 cm2. A power density of ≈257 mW cm−2 is obtained, which is three orders of magnitude higher than the present microsized DFMCs. Atomic layer deposition technique is applied to alleviate the methanol crossover as well as improve stability of the tube, sustaining electrolyte flow for days. A laminar flow driven mechanism is proposed, and the kinetics of the fuel oxidation depends on a linear-diffusion-controlled process. The electrocatalytic performance on anode and cathode is studied by scanning both sides of the tube wall as an ex situ working electrode, respectively. This prototype µDFMC is extremely interesting for integration with micro- and nanoelectronics systems.

Published

2017

12. Magnetic Suspension Array Technology: Controlled Synthesis and Screening in Microfluidic Networks.

Author

Lin, G, Karnaushenko, DD, Bermúdez, GSC, Schmidt, OG, Makarov, D, Lin, G, Karnaushenko, DD, Bermúdez, GSC, Schmidt, OG, and Makarov, D

Abstract

Information tagging and processing are vital in information-intensive applications, e.g., telecommunication and high-throughput drug screening. Magnetic suspension array technology may offer intrinsic advantages to screening applications by enabling high distinguishability, the ease of code generation, and the feasibility of fast code readout, though the practical applicability of magnetic suspension array technology remains hampered by the lack of quality administration of encoded microcarriers. Here, a logic-controlled microfluidic system enabling controlled synthesis of magnetic suspension arrays in multiphase flow networks is realized. The smart and compact system offers a practical solution for the quality administration and screening of encoded magnetic microcarriers and addresses the universal need of process control for synthesis in microfluidic networks, i.e., on-demand creation of droplet templates for high information capacity. The demonstration of magnetic suspension array technology enabled by magnetic in-flow cytometry opens the avenue toward point-of-care multiplexed bead-based assays, clinical diagnostics, and drug discovery.

Published

2016

13. Droplet Microfluidics: Magnetic Suspension Array Technology: Controlled Synthesis and Screening in Microfluidic Networks (Small 33/2016)

Author

Lin, G, Karnaushenko, DD, Bermúdez, GSC, Schmidt, OG, Makarov, D, Lin, G, Karnaushenko, DD, Bermúdez, GSC, Schmidt, OG, and Makarov, D

Published

2016

14. Monolithic Growth of Ultrathin Ge Nanowires on Si(001)

Author

Zhang, J, Katsaros, G, Montalenti, F, Scopece, D, Rezaev, R, Mickel, C, Rellinghaus, B, Miglio, L, De Franceschi, S, Rastelli, A, Schmidt, O, Zhang, JJ, MONTALENTI, FRANCESCO CIMBRO MATTIA, SCOPECE, DANIELE, Rezaev, RO, MIGLIO, LEONIDA, Schmidt, OG, Zhang, J, Katsaros, G, Montalenti, F, Scopece, D, Rezaev, R, Mickel, C, Rellinghaus, B, Miglio, L, De Franceschi, S, Rastelli, A, Schmidt, O, Zhang, JJ, MONTALENTI, FRANCESCO CIMBRO MATTIA, SCOPECE, DANIELE, Rezaev, RO, MIGLIO, LEONIDA, and Schmidt, OG

Abstract

Self-assembled Ge wires with a height of only 3 unit cells and a length of up to 2 micrometers were grown on Si(001) by means of a catalyst-free method based on molecular beam epitaxy. The wires grow horizontally along either the [100] or the [010] direction. On atomically flat surfaces, they exhibit a highly uniform, triangular cross section. A simple thermodynamic model accounts for the existence of a preferential base width for longitudinal expansion, in quantitative agreement with the experimental findings. Despite the absence of intentional doping, the first transistor-type devices made from single wires show low-resistive electrical contacts and single-hole transport at sub-Kelvin temperatures. In view of their exceptionally small and self-defined cross section, these Ge wires hold promise for the realization of hole systems with exotic properties and provide a new development route for silicon-based nanoelectronics.

Published

2012

15. Stretchable spin valves on elastomer membranes by predetermined periodic fracture and random wrinkling

Author

Melzer, M, Lin, G, Makarov, D, Schmidt, OG, Melzer, M, Lin, G, Makarov, D, and Schmidt, OG

Abstract

The first highly stretchable and sensitive spin valve sensor on elastomeric membranes are demonstrated. The sensor elements exhibit stable GMR behavior up to tensile strains of 29% in in situ stretching experiments and show no fatigue over 500 loading cycles. This remarkable stretchability is achieved by a predetermined periodic fracture mechanism that creates a meander-like pattern upon stretching. © 2012 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.

Published

2012

16. Strain engineering of silicon-germaium (SiGe) micro- and nanostructures

Author

Shiraki, Y, Usami, N, Pezzoli, F, Deneke, C, Schmidt, O, Schmidt, OG, Shiraki, Y, Usami, N, Pezzoli, F, Deneke, C, Schmidt, O, and Schmidt, OG

Abstract

This chapter is intended to provide an overview of strain-engineered heterostructures and quantum devices based on SiGe alloys. The growth of SiGe on Si(00 l) substrates is introduced by focusing on the morphological evolution of SiGe nanostructures and the ways of precisely controlling lateral and vertical ordering. Afterwards, the chapter discusses a revolutionary process technology leading to strain-driven architectures. Finally, a new emerging generation of SiGe-based systems with unique capabilities, ranging from fast field-effect transistors to energy harvesting devices, is reviewed

Published

2011

17. Self-Ordering of Misfit Dislocation Segments in Epitaxial SiGe Islands on Si(001)

Author

Boioli, F, Zinovyev, V, Gatti, R, Marzegalli, A, Montalenti, F, Stoffel, M, Merdzhanova, T, Wang, L, Pezzoli, F, Rastelli, A, Schmidt, O, Miglio, L, BOIOLI, FRANCESCA, MARZEGALLI, ANNA, MONTALENTI, FRANCESCO CIMBRO MATTIA, PEZZOLI, FABIO, MIGLIO, LEONIDA, Zinovyev, VA, Schmidt, OG, Boioli, F, Zinovyev, V, Gatti, R, Marzegalli, A, Montalenti, F, Stoffel, M, Merdzhanova, T, Wang, L, Pezzoli, F, Rastelli, A, Schmidt, O, Miglio, L, BOIOLI, FRANCESCA, MARZEGALLI, ANNA, MONTALENTI, FRANCESCO CIMBRO MATTIA, PEZZOLI, FABIO, MIGLIO, LEONIDA, Zinovyev, VA, and Schmidt, OG

Abstract

Ordering of misfit dislocation segments in concentric polygons at the base of SiGe epitaxial islands on Si(001) has been recently indicated by in situ Transmission Electron Microscope observation. In this paper we confirm the very regular spacing by Atomic Force Microscope and He-ion Microscope measurements of the footprint carved in the Si substrate by the plastic events. We explain the intriguing ordering, as obtained with no gliding rearrangements, by cyclic occurrence of the thermodynamic critical conditions for plastic events. Quantitative predictions by a fully analytical model, which includes the dependence on island shape and composition in the generation of misfit dislocations, matched very well experimental measurements.

Published

2011

18. Collective Shape Oscillations of SiGe Islands on Pit-Patterned Si(001) Substrates: A Coherent-Growth Strategy Enabled by Self-Regulated Intermixing

Author

Zhang, J, Montalenti, F, Rastelli, A, Hrauda, N, Scopece, D, Groiss, H, Stangl, J, Pezzoli, F, Schaffler, F, Schmidt, O, Miglio, L, Bauer, G, Zhang, JJ, Schmidt, OG, Bauer, G., MONTALENTI, FRANCESCO CIMBRO MATTIA, SCOPECE, DANIELE, PEZZOLI, FABIO, MIGLIO, LEONIDA, Zhang, J, Montalenti, F, Rastelli, A, Hrauda, N, Scopece, D, Groiss, H, Stangl, J, Pezzoli, F, Schaffler, F, Schmidt, O, Miglio, L, Bauer, G, Zhang, JJ, Schmidt, OG, Bauer, G., MONTALENTI, FRANCESCO CIMBRO MATTIA, SCOPECE, DANIELE, PEZZOLI, FABIO, and MIGLIO, LEONIDA

Abstract

The shape of coherent SiGe islands epitaxially grown on pit-patterned Si(001) substrates displays very uniform collective oscillations with increasing Ge deposition, transforming cyclically between shallower "dome'' and steeper "barn'' morphologies. Correspondingly, the average Ge content in the alloyed islands also displays an oscillatory behavior, superimposed on a progressive Si enrichment with increasing size. We show that such a growth mode, remarkably different from the flat-substrate case, allows the islands to keep growing in size while avoiding plastic relaxation

Published

2010

19. n-Channel MOSFETs Fabricated on SiGe Dots for Strain-Enhanced Mobility

Author

Jovanovi, V, Biasotto, C, Nanver, L, Moers, J, Grtzmacher, D, Gerharz, J, Mussler, G, van der Cingel, J, Zhang, J, Bauer, G, Schmidt, O, Miglio, L, Nanver, LK, Zhang, JJ, Schmidt, OG, MIGLIO, LEONIDA, Jovanovi, V, Biasotto, C, Nanver, L, Moers, J, Grtzmacher, D, Gerharz, J, Mussler, G, van der Cingel, J, Zhang, J, Bauer, G, Schmidt, O, Miglio, L, Nanver, LK, Zhang, JJ, Schmidt, OG, and MIGLIO, LEONIDA

Abstract

The silicon germanium dots grown in the StranskiKrastanow mode are used to induce biaxial tensile strain in a silicon capping layer. A high Ge content and correspondingly high Si strain levels are reached due to the 3-D growth of the dots. The n-channel MOS devices, referred to in this letter as DotFETs, are processed with the main gate segment above the strained Si layer on a single dot. To prevent the intermixing of the Si/SiGe/Si structure, a novel low-temperature FET structure processed below 400 °C has been implemented: The ultrashallow source/drain junctions formed by excimer-laser annealing in the full-melt mode of ion-implanted dopants are self-aligned to a metal gate. The crystallinity of the structure is preserved throughout the processing, and compared to reference devices, an average increase in the drain current of up to 22.5% is obtained. © 2006 IEEE.

Published

2010

20. Strain in a single ultrathin silicon layer on top of SiGe islands: Raman spectroscopy and simulations

Author

Bonera, E, Pezzoli, F, Picco, A, Vastola, G, Stoffel, M, Grilli, E, Guzzi, M, Rastelli, A, Schmidt, O, Miglio, L, BONERA, EMILIANO, PEZZOLI, FABIO, GRILLI, EMANUELE ENRICO, GUZZI, MARIO, MIGLIO, LEONIDA, Schmidt, OG, Bonera, E, Pezzoli, F, Picco, A, Vastola, G, Stoffel, M, Grilli, E, Guzzi, M, Rastelli, A, Schmidt, O, Miglio, L, BONERA, EMILIANO, PEZZOLI, FABIO, GRILLI, EMANUELE ENRICO, GUZZI, MARIO, MIGLIO, LEONIDA, and Schmidt, OG

Abstract

By means of resonant Raman spectroscopy we investigated the strain on a single ultrathin crystalline silicon layer, locally induced by buried SiGe nanostructures. The spectrum of a 5-nm-thick silicon layer on top of SiGe islands shows a single highly strained feature attributed to the out-of-plane phonon. The direct comparison of the experimental results with finite-element methods through spectral simulation shows excellent agreement that clarifies the physical origin of the spectrum. An increase in the silicon layer thickness up to 40 nm results in a progressive reduction in the strain

Published

2009

21. Critical shape and size for dislocation nucleation in si1-xGex islands on Si(001)

Author

Marzegalli, A, Zinovyev, V, Montalenti, F, Rastelli, A, Stoffel, M, Merdzhanova, T, Schmidt, O, Miglio, L, MARZEGALLI, ANNA, Zinovyev, VA, Schmidt, OG, MONTALENTI, FRANCESCO CIMBRO MATTIA, MIGLIO, LEONIDA, Marzegalli, A, Zinovyev, V, Montalenti, F, Rastelli, A, Stoffel, M, Merdzhanova, T, Schmidt, O, Miglio, L, MARZEGALLI, ANNA, Zinovyev, VA, Schmidt, OG, MONTALENTI, FRANCESCO CIMBRO MATTIA, and MIGLIO, LEONIDA

Abstract

The critical volume for the onset of plastic strain relaxation in SiGe islands on Si(001) is computed for different Ge contents and realistic shapes by using a three-dimensional model, with position-dependent dislocation energy. It turns out that the critical bases for dome- and barnlike islands are different for any composition. By comparison to extensive atomic force microscopy measurements of the footprints left on the Si substrates by islands grown at different temperatures (and compositions), we conclude that, in contrast with planar films, dislocation nucleation in 3D islands is fully thermodynamic. © 2007 The American Physical Society.

Published

2007

22. Atomic-scale pathway of the pyramid-to-dome transition during Ge growth on Si(001)

Author

Montalenti, F, Raiteri, P, Migas, D, von Kanel, H, Rastelli, A, Manzano, C, Costantini, G, Denker, U, Schmidt, O, Kern, K, Miglio, L, MONTALENTI, FRANCESCO CIMBRO MATTIA, Migas, DB, Schmidt, OG, MIGLIO, LEONIDA, Montalenti, F, Raiteri, P, Migas, D, von Kanel, H, Rastelli, A, Manzano, C, Costantini, G, Denker, U, Schmidt, O, Kern, K, Miglio, L, MONTALENTI, FRANCESCO CIMBRO MATTIA, Migas, DB, Schmidt, OG, and MIGLIO, LEONIDA

Abstract

The morphological transition from pyramid to dome islands during the growth of Ge on Si(001)was investigated using high resolution scanning tunneling microscopy (STM). It was observed that the pyramids were grown from top to bottom and that from a critical size on incomplete facets were formed. It was also observed that the bunching of the steps delimiting the facets evolved into the steeper dome facets. It was found that a microscopic model was developed based on first principles and Tersoff-potential calculations for the onset of the morphological transition.

Published

2004

23. Transport of cargo by catalytic Janus micro-motors

Author

Mykola Tasinkevych, Mihail N. Popescu, Siegfried Dietrich, Samuel Sanchez, Oliver G. Schmidt, Larysa Baraban, Baraban, L, Tasinkevych, Mykola, Popescu, Mihail Nicolae, Sanchez, S, Dietrich, S, and Schmidt, OG

Subjects

Complex dynamics, micro-motors, carrier-cargo, Materials science, catalytic Janus, Nanotechnology, General Chemistry, Janus, Condensed Matter Physics, Catalysis

Abstract

Catalytically active Janus micro-spheres are capable of autonomous motion and can potentially act as carriers for transportation of cargo at the micron-scale. Focusing on the cases in which a single or a pair of Janus micro-motors is used as carrier, we investigate the complex dynamics exhibited by various active carrier-cargo composites. Refereed/Peer-reviewed

Published

2012

24. Eksistensens æstetik

Author

Frandsen, Finn and Lars-Henrik Schmidt og Jens Erik Kristensen, null

Subjects

Foucault, Fransk filosofi, HHÅ forskning, Seksualitetens historie

Published

1985

25. Modular Design of Functional Glucose Monomer and Block Co-Polymer toward Stable Zn Anodes.

Author

Yan Y, Mei R, Ma J, Huang Y, Zhu Y, Lang Z, Li C, Tang H, Zhang W, Lu J, Schmidt OG, Zhang K, and Zhu M

Abstract

Aqueous Zn batteries employing mildly acidic electrolytes have emerged as promising contenders for safe and cost-effective energy storage solutions. Nevertheless, the intrinsic reversibility of the Zn anode becomes a focal concern due to the involvement of acidic electrolyte, which triggers Zn corrosion and facilitates the deposition of insulating byproducts. Moreover, the unregulated growth of Zn over cycling amplifies the risk of internal short-circuiting, primarily induced by the formation of Zn dendrites. In this study, a class of glucose-derived monomers and a block copolymer are synthesized through a building-block assembly strategy, ultimately leading to uncover the optimal polymer structure that suppresses the Zn corrosion while allowing efficient ion conduction with a substantial contribution from cation transport. Leveraging these advancements, remarkable enhancements are achieved in the realm of Zn reversibility, exemplified by a spectrum of performance metrics, including robust cycling stability without voltage overshoot and short-circuiting during 3000 h of cycling, stable operation at a high depth of charge/discharge of 75% and a high current density, >95% Coulombic efficiency over 2000 cycles, successful translation of the anode improvement to full cell performance. These polymer designs offer a transformative path based on the modular synthesis of polymeric coatings toward highly reversible Zn anode., (© 2024 The Authors. Small published by Wiley‐VCH GmbH.)

Published

2024

26. Magnetotactic Sperm Cells for Assisted Reproduction.

Author

Striggow F, Ribeiro C, Aziz A, Nauber R, Hebenstreit F, Schmidt OG, and Medina-Sánchez M

Subjects

Male, Reproductive Techniques, Assisted, Humans, Magnetics, Animals, Spermatozoa physiology, Sperm Motility physiology

Abstract

Biohybrid micromotors are active microscopic agents consisting of biological and synthetic components that are being developed as novel tools for biomedical applications. By capturing motile sperm cells within engineered microstructures, they can be controlled remotely while being propelled forward by the flagellar beat. This makes them an interesting tool for reproductive medicine that can enable minimally invasive sperm cell delivery to the oocyte in vivo, as a treatment for infertility. The generation of sperm-based micromotors in sufficiently large numbers, as they are required in biomedical applications has been challenging, either due to the employed fabrication techniques or the stability of the microstructure-sperm coupling. Here, biohybrid micromotors, which can be assembled in a fast and simple process using magnetic microparticles, are presented. These magnetotactic sperm cells show a high motility and swimming speed and can be transferred between different environments without large detrimental effects on sperm motility and membrane integrity. Furthermore, clusters of micromotors are assembled magnetically and visualized using dual ultrasound (US)/photoacoustic (PA) imaging. Finally, a protocol for the scaled-up assembly of micromotors and their purification for use in in vitro fertilization (IVF) is presented, bringing them closer to their biomedical implementation., (© 2023 The Authors. Small published by Wiley‐VCH GmbH.)

Published

2024

27. Bio-Inspired Dynamically Morphing Microelectronics toward High-Density Energy Applications and Intelligent Biomedical Implants.

Author

Merces L, Ferro LMM, Thomas A, Karnaushenko DD, Luo Y, Egunov AI, Zhang W, Bandari VK, Lee Y, McCaskill JS, Zhu M, Schmidt OG, and Karnaushenko D

Abstract

Choreographing the adaptive shapes of patterned surfaces to exhibit designable mechanical interactions with their environment remains an intricate challenge. Here, a novel category of strain-engineered dynamic-shape materials, empowering diverse multi-dimensional shape modulations that are combined to form fine-grained adaptive microarchitectures is introduced. Using micro-origami tessellation technology, heterogeneous materials are provided with strategic creases featuring stimuli-responsive micro-hinges that morph precisely upon chemical and electrical cues. Freestanding multifaceted foldable packages, auxetic mesosurfaces, and morphable cages are three of the forms demonstrated herein of these complex 4-dimensional (4D) metamaterials. These systems are integrated in dual proof-of-concept bioelectronic demonstrations: a soft foldable supercapacitor enhancing its power density (≈108 mW cm -2 ), and a bio-adaptive device with a dynamic shape that may enable novel smart-implant technologies. This work demonstrates that intelligent material systems are now ready to support ultra-flexible 4D microelectronics, which can impart autonomy to devices culminating in the tangible realization of microelectronic morphogenesis., (© 2024 The Authors. Advanced Materials published by Wiley‐VCH GmbH.)

Published

2024

28. Polymer hetero-electrolyte enabled solid-state 2.4-V Zn/Li hybrid batteries.

Author

Chen Z, Wang T, Wu Z, Hou Y, Chen A, Wang Y, Huang Z, Schmidt OG, Zhu M, Fan J, and Zhi C

Abstract

The high redox potential of Zn 0/2+ leads to low voltage of Zn batteries and therefore low energy density, plaguing deployment of Zn batteries in many energy-demanding applications. Though employing high-voltage cathode like spinel LiNi 0.5 Mn 1.5 O 4 can increase the voltages of Zn batteries, Zn 2+ ions will be immobilized in LiNi 0.5 Mn 1.5 O 4 once intercalated, resulting in irreversibility. Here, we design a polymer hetero-electrolyte consisting of an anode layer with Zn 2+ ions as charge carriers and a cathode layer that blocks the Zn 2+ ion shuttle, which allows separated Zn and Li reversibility. As such, the Zn‖LNMO cell exhibits up to 2.4 V discharge voltage and 450 stable cycles with high reversible capacity, which are also attained in a scale-up pouch cell. The pouch cell shows a low self-discharge after resting for 28 days. The designed electrolyte paves the way to develop high-voltage Zn batteries based on reversible lithiated cathodes., (© 2024. The Author(s).)

Published

2024

29. Author Correction: Self-assembly of Co/Pt stripes with current-induced domain wall motion towards 3D racetrack devices.

Author

Fedorov P, Soldatov I, Neu V, Schäfer R, Schmidt OG, and Karnaushenko D

Published

2024

30. A Photolithographable Electrolyte for Deeply Rechargeable Zn Microbatteries in On-Chip Devices.

Author

Qu Z, Ma J, Huang Y, Li T, Tang H, Wang X, Liu S, Zhang K, Lu J, Karnaushenko DD, Karnaushenko D, Zhu M, and Schmidt OG

Abstract

Zn batteries show promise for microscale applications due to their compatibility with air fabrication but face challenges like dendrite growth and chemical corrosion, especially at the microscale. Despite previous attempts in electrolyte engineering, achieving successful patterning of electrolyte microscale devices has remained challenging. Here, successful patterning using photolithography is enabled by incorporating caffeine into a UV-crosslinked polyacrylamide hydrogel electrolyte. Caffeine passivates the Zn anode, preventing chemical corrosion, while its coordination with Zn 2+ ions forms a Zn 2+ -conducting complex that transforms into ZnCO 3 and 2ZnCO 3 ·3Zn(OH) 2 over cycling. The resulting Zn-rich interphase product significantly enhances Zn reversibility. In on-chip microbatteries, the resulting solid-electrolyte interphase allows the Zn||MnO 2 full cell to cycle for over 700 cycles with an 80% depth of discharge. Integrating the photolithographable electrolyte into multilayer microfabrication creates a microbattery with a 3D Swiss-roll structure that occupies a footprint of 0.136 mm 2 . This tiny microbattery retains 75% of its capacity (350 µAh cm -2 ) for 200 cycles at a remarkable 90% depth of discharge. The findings offer a promising solution for enhancing the performance of Zn microbatteries, particularly for on-chip microscale devices, and have significant implications for the advancement of autonomous microscale devices., (© 2024 The Authors. Advanced Materials published by Wiley‐VCH GmbH.)

Published

2024

31. 3D nanofabricated soft microrobots with super-compliant picoforce springs as onboard sensors and actuators.

Author

Xu H, Wu S, Liu Y, Wang X, Efremov AK, Wang L, McCaskill JS, Medina-Sánchez M, and Schmidt OG

Subjects

Locomotion, Research Design

Abstract

Microscale organisms and specialized motile cells use protein-based spring-like responsive structures to sense, grasp and move. Rendering this biomechanical transduction functionality in an artificial micromachine for applications in single-cell manipulations is challenging due to the need for a bio-applicable nanoscale spring system with a large and programmable strain response to piconewton-scale forces. Here we present three-dimensional nanofabrication and monolithic integration, based on an acrylic elastomer photoresist, of a magnetic spring system with quantifiable compliance sensitive to 0.5 pN, constructed with customized elasticity and magnetization distributions at the nanoscale. We demonstrate the effective design programmability of these 'picospring' ensembles as energy transduction mechanisms for the integrated construction of customized soft micromachines, with onboard sensing and actuation functions at the single-cell scale for microrobotic grasping and locomotion. The integration of active soft springs into three-dimensional nanofabrication offers an avenue to create biocompatible soft microrobots for non-disruptive interactions with biological entities., (© 2024. The Author(s).)

Published

2024

32. Author Correction: 3D nanofabricated soft microrobots with super-compliant picoforce springs as onboard sensors and actuators.

Author

Xu H, Wu S, Liu Y, Wang X, Efremov AK, Wang L, McCaskill JS, Medina-Sánchez M, and Schmidt OG

Published

2024

33. Self-assembly of Co/Pt stripes with current-induced domain wall motion towards 3D racetrack devices.

Author

Fedorov P, Soldatov I, Neu V, Schäfer R, Schmidt OG, and Karnaushenko D

Abstract

Modification of the magnetic properties under the induced strain and curvature is a promising avenue to build three-dimensional magnetic devices, based on the domain wall motion. So far, most of the studies with 3D magnetic structures were performed in the helixes and nanowires, mainly with stationary domain walls. In this study, we demonstrate the impact of 3D geometry, strain and curvature on the current-induced domain wall motion and spin-orbital torque efficiency in the heterostructure, realized via a self-assembly rolling technique on a polymeric platform. We introduce a complete 3D memory unit with write, read and store functionality, all based on the field-free domain wall motion. Additionally, we conducted a comparative analysis between 2D and 3D structures, particularly addressing the influence of heat during the electric current pulse sequences. Finally, we demonstrated a remarkable increase of 30% in spin-torque efficiency in 3D configuration., (© 2024. The Author(s).)

Published

2024

34. Microelectronic Morphogenesis: Smart Materials with Electronics Assembling into Artificial Organisms.

Author

McCaskill JS, Karnaushenko D, Zhu M, and Schmidt OG

Abstract

Microelectronic morphogenesis is the creation and maintenance of complex functional structures by microelectronic information within shape-changing materials. Only recently has in-built information technology begun to be used to reshape materials and their functions in three dimensions to form smart microdevices and microrobots. Electronic information that controls morphology is inheritable like its biological counterpart, genetic information, and is set to open new vistas of technology leading to artificial organisms when coupled with modular design and self-assembly that can make reversible microscopic electrical connections. Three core capabilities of cells in organisms, self-maintenance (homeostatic metabolism utilizing free energy), self-containment (distinguishing self from nonself), and self-reproduction (cell division with inherited properties), once well out of reach for technology, are now within the grasp of information-directed materials. Construction-aware electronics can be used to proof-read and initiate game-changing error correction in microelectronic self-assembly. Furthermore, noncontact communication and electronically supported learning enable one to implement guided self-assembly and enhance functionality. Here, the fundamental breakthroughs that have opened the pathway to this prospective path are reviewed, the extent and way in which the core properties of life can be addressed are analyzed, and the potential and indeed necessity of such technology for sustainable high technology in society is discussed., (© 2023 The Authors. Advanced Materials published by Wiley-VCH GmbH.)

Published

2023

35. Molecular Electronics: Creating and Bridging Molecular Junctions and Promoting Its Commercialization.

Author

Li T, Bandari VK, and Schmidt OG

Abstract

Molecular electronics is driven by the dream of expanding Moore's law to the molecular level for next-generation electronics through incorporating individual or ensemble molecules into electronic circuits. For nearly 50 years, numerous efforts have been made to explore the intrinsic properties of molecules and develop diverse fascinating molecular electronic devices with the desired functionalities. The flourishing of molecular electronics is inseparable from the development of various elegant methodologies for creating nanogap electrodes and bridging the nanogap with molecules. This review first focuses on the techniques for making lateral and vertical nanogap electrodes by breaking, narrowing, and fixed modes, and highlights their capabilities, applications, merits, and shortcomings. After summarizing the approaches of growing single molecules or molecular layers on the electrodes, the methods of constructing a complete molecular circuit are comprehensively grouped into three categories: 1) directly bridging one-molecule-electrode component with another electrode, 2) physically bridging two-molecule-electrode components, and 3) chemically bridging two-molecule-electrode components. Finally, the current state of molecular circuit integration and commercialization is discussed and perspectives are provided, hoping to encourage the community to accelerate the realization of fully scalable molecular electronics for a new era of integrated microsystems and applications., (© 2023 The Authors. Advanced Materials published by Wiley-VCH GmbH.)

Published

2023

36. Zn Microbatteries Explore Ways for Integrations in Intelligent Systems.

Author

Ma J, Quhe R, Zhang W, Yan Y, Tang H, Qu Z, Cheng Y, Schmidt OG, and Zhu M

Abstract

As intelligent microsystems develop, many revolutionary applications, such as the swallowing surgeon proposed by Richard Feynman, are about to evolve. Nonetheless, integrable energy storage satisfying the demand for autonomous operations has emerged as a major obstacle to the deployment of intelligent microsystems. A reason for the lagging development of integrable batteries is the challenge of miniaturization through microfabrication procedures. Lithium batteries, generated by the most successful battery chemistry, are not stable in the air, thus creating major manufacturing challenges. Other cations (Na + , Mg 2+ , Al 3+ , K + ) are still in the early stages of development. In contrast, the superior stability of zinc batteries in the air brings high compatibility to microfabrication protocols and has already demonstrated excellent practicability in full-sized devices. To obtain energy-dense and high-power zinc microbatteries within square-millimeter or smaller footprints, sandwich, pillar, and Swiss-roll configurations are developed. Thin interdigital and fiber microbatteries find their applications being integrated into wearable devices and electronic skin. It is foreseeable that zinc microbatteries will find their way into highly integrated microsystems unlocking their full potential for autonomous operation. This review summarizes the material development, configuration innovation, and application-oriented integration of zinc microbatteries., (© 2023 The Authors. Small published by Wiley-VCH GmbH.)

Published

2023

37. Fast-Response Micro-Phototransistor Based on MoS 2 /Organic Molecule Heterojunction.

Author

Andleeb S, Wang X, Dong H, Valligatla S, Saggau CN, Ma L, Schmidt OG, and Zhu F

Abstract

Over the past years, molybdenum disulfide (MoS 2 ) has been the most extensively studied two-dimensional (2D) semiconductormaterial. With unique electrical and optical properties, 2DMoS 2 is considered to be a promising candidate for future nanoscale electronic and optoelectronic devices. However, charge trapping leads to a persistent photoconductance (PPC), hindering its use for optoelectronic applications. To overcome these drawbacks and improve the optoelectronic performance, organic semiconductors (OSCs) are selected to passivate surface defects, tune the optical characteristics, and modify the doping polarity of 2D MoS 2 . Here, we demonstrate a fast photoresponse in multilayer (ML) MoS 2 by addressing a heterojunction interface with vanadylphthalocyanine (VOPc) molecules. The MoS 2 /VOPc van der Waals interaction that has been established encourages the PPC effect in MoS 2 by rapidly segregating photo-generated holes, which move away from the traps of MoS 2 toward the VOPc molecules. The MoS 2 /VOPc phototransistor exhibits a fast photo response of less than 15 ms for decay and rise, which is enhanced by 3ordersof magnitude in comparison to that of a pristine MoS 2 -based phototransistor (seconds to tens of seconds). This work offers a means to realize high-performance transition metal dichalcogenide (TMD)-based photodetection with a fast response speed.

Published

2023

38. Technology Roadmap for Flexible Sensors.

Author

Luo Y, Abidian MR, Ahn JH, Akinwande D, Andrews AM, Antonietti M, Bao Z, Berggren M, Berkey CA, Bettinger CJ, Chen J, Chen P, Cheng W, Cheng X, Choi SJ, Chortos A, Dagdeviren C, Dauskardt RH, Di CA, Dickey MD, Duan X, Facchetti A, Fan Z, Fang Y, Feng J, Feng X, Gao H, Gao W, Gong X, Guo CF, Guo X, Hartel MC, He Z, Ho JS, Hu Y, Huang Q, Huang Y, Huo F, Hussain MM, Javey A, Jeong U, Jiang C, Jiang X, Kang J, Karnaushenko D, Khademhosseini A, Kim DH, Kim ID, Kireev D, Kong L, Lee C, Lee NE, Lee PS, Lee TW, Li F, Li J, Liang C, Lim CT, Lin Y, Lipomi DJ, Liu J, Liu K, Liu N, Liu R, Liu Y, Liu Y, Liu Z, Liu Z, Loh XJ, Lu N, Lv Z, Magdassi S, Malliaras GG, Matsuhisa N, Nathan A, Niu S, Pan J, Pang C, Pei Q, Peng H, Qi D, Ren H, Rogers JA, Rowe A, Schmidt OG, Sekitani T, Seo DG, Shen G, Sheng X, Shi Q, Someya T, Song Y, Stavrinidou E, Su M, Sun X, Takei K, Tao XM, Tee BCK, Thean AV, Trung TQ, Wan C, Wang H, Wang J, Wang M, Wang S, Wang T, Wang ZL, Weiss PS, Wen H, Xu S, Xu T, Yan H, Yan X, Yang H, Yang L, Yang S, Yin L, Yu C, Yu G, Yu J, Yu SH, Yu X, Zamburg E, Zhang H, Zhang X, Zhang X, Zhang X, Zhang Y, Zhang Y, Zhao S, Zhao X, Zheng Y, Zheng YQ, Zheng Z, Zhou T, Zhu B, Zhu M, Zhu R, Zhu Y, Zhu Y, Zou G, and Chen X

Subjects

Humans, Quality of Life, Wearable Electronic Devices

Abstract

Humans rely increasingly on sensors to address grand challenges and to improve quality of life in the era of digitalization and big data. For ubiquitous sensing, flexible sensors are developed to overcome the limitations of conventional rigid counterparts. Despite rapid advancement in bench-side research over the last decade, the market adoption of flexible sensors remains limited. To ease and to expedite their deployment, here, we identify bottlenecks hindering the maturation of flexible sensors and propose promising solutions. We first analyze challenges in achieving satisfactory sensing performance for real-world applications and then summarize issues in compatible sensor-biology interfaces, followed by brief discussions on powering and connecting sensor networks. Issues en route to commercialization and for sustainable growth of the sector are also analyzed, highlighting environmental concerns and emphasizing nontechnical issues such as business, regulatory, and ethical considerations. Additionally, we look at future intelligent flexible sensors. In proposing a comprehensive roadmap, we hope to steer research efforts towards common goals and to guide coordinated development strategies from disparate communities. Through such collaborative efforts, scientific breakthroughs can be made sooner and capitalized for the betterment of humanity.

Published

2023

39. Ultra-dense plasmonic nanogap arrays for reorientable molecular fluorescence enhancement and spectrum reshaping.

Author

Wang J, Hao Q, Dong H, Zhu M, Wu L, Liu L, Wang W, Schmidt OG, and Ma L

Abstract

Understanding interactions between molecular transition and intense electromagnetic fields confined by plasmon nanostructures is of great significance due to their huge potential in fundamental cavity quantum electrodynamics and practical applications. Here, we report reorientable plasmon-enhanced fluorescence leveraging the flexibilities in densely-packed gold nanogap arrays by template-assisted depositions. By finely adjusting the symmetry of the unit structure, arrays of nanogaps along two nearly-orthogonal axes can be tailored collectively with spacing down to sub-10 nm on a single chip, facilitating distinct "inter-cell" and "intra-cell" plasmon couplings. Through engineering two sets of nanogaps, the varying hybridization-induced plasmonic bonding modes lead to adjustable splitting of the fluorescence emission peak with a width up to 81 nm and narrowing of linewidths up to a factor of 3. Besides, polarization anisotropy with a ratio up to 63% is obtained on the basis of spectrally separated local hotspots with discrepant oscillation directions. The developed plasmonic nanogap array is envisaged to provide a promising chip-scale, cost-effective platform for advancing fluorescence-based detection and emission technologies in both classical and quantum regimes.

Published

2023

40. Nanomaterial-decorated micromotors for enhanced photoacoustic imaging.

Author

Aziz A, Nauber R, Iglesias AS, Tang M, Ma L, Liz-Marzán LM, Schmidt OG, and Medina-Sánchez M

Abstract

Micro-and nanorobots have the potential to perform non-invasive drug delivery, sensing, and surgery in living organisms, with the aid of diverse medical imaging techniques. To perform such actions, microrobots require high spatiotemporal resolution tracking with real-time closed-loop feedback. To that end,  photoacoustic imaging has appeared as a promising technique for imaging microrobots in deep tissue with higher molecular specificity and contrast. Here, we present different strategies to track magnetically-driven micromotors with improved contrast and specificity using dedicated contrast agents (Au nanorods and nanostars). Furthermore, we discuss the possibility of improving the light absorption properties of the employed nanomaterials considering possible light scattering and coupling to the underlying metal-oxide layers on the micromotor's surface. For that, 2D COMSOL simulation and experimental results were correlated, confirming that an increased spacing between the Au-nanostructures and the increase of thickness of the underlying oxide layer lead to enhanced light absorption and preservation of the characteristic absorption peak. These characteristics are important when visualizing the micromotors in a complex in vivo environment, to distinguish them from the light absorption properties of the surrounding natural chromophores., Supplementary Information: The online version contains supplementary material available at 10.1007/s12213-023-00156-7., Competing Interests: Competing interestsThe authors declare no competing interests.Conflicts of interestThe authors declare no competing financial interest or conflicts of interest., (© The Author(s) 2023.)

Published

2023

41. Single "Swiss-roll" microelectrode elucidates the critical role of iron substitution in conversion-type oxides.

Author

Liu L, Huang S, Shi W, Sun X, Pang J, Lu Q, Yang Y, Xi L, Deng L, Oswald S, Yin Y, Liu L, Ma L, Schmidt OG, Shi Y, and Zhang L

Abstract

Advancing the lithium-ion battery technology requires the understanding of electrochemical processes in electrode materials with high resolution, accuracy, and sensitivity. However, most techniques today are limited by their inability to separate the complex signals from slurry-coated composite electrodes. Here, we use a three-dimensional "Swiss-roll" microtubular electrode that is incorporated into a micrometer-sized lithium battery. This on-chip platform combines various in situ characterization techniques and precisely probes the intrinsic electrochemical properties of each active material due to the removal of unnecessary binders and additives. As an example, it helps elucidate the critical role of Fe substitution in a conversion-type NiO electrode by monitoring the evolution of Fe 2 O 3 and solid electrolyte interphase layer. The markedly enhanced electrode performances are therefore explained. Our approach exposes a hitherto unexplored route to tracking the phase, morphology, and electrochemical evolution of electrodes in real time, allowing us to reveal information that is not accessible with bulk-level characterization techniques.

Published

2022

42. Microbatteries with twin-Swiss-rolls redefine performance limits in the sub-square millimeter range.

Author

Li Y, Zhu M, Karnaushenko DD, Li F, Qu J, Wang J, Zhang P, Liu L, Ravishankar R, Bandari VK, Tang H, Qu Z, Zhu F, Weng Q, and Schmidt OG

Abstract

To maintain the downscaling of microelectronic devices with footprints less than one square millimeter, next-generation microbatteries should occupy the same area and deliver adequate energy for running a new generation of multi-functional microautonomous systems. However, the current microbattery technology fails in accomplishing this task because the micrometer-sized electrodes are not compatible with on-chip integration protocols and technologies. To tackle this critical challenge, an on-chip Swiss-roll microelectrode architecture is employed that exploits the self-assembly of thin films into ultra-compact device architectures. A twin-Swiss-roll microelectrode on a chip occupies a footprint of 0.045 mm 2 and delivers an energy density up to 458 μW h cm -2 . After packaging, the footprint of a full cell increases to 0.11 mm 2 with a high energy density of 181 μW h cm -2 . The volumetric energy density excluding the chip thickness is 16.3 mW h cm -3 . These results open opportunities for deploying microbatteries as energy and power sources to drive smart dust microelectronics and microautonomous systems.

Published

2022

43. Multifunctional 4D-Printed Sperm-Hybrid Microcarriers for Assisted Reproduction.

Author

Rajabasadi F, Moreno S, Fichna K, Aziz A, Appelhans D, Schmidt OG, and Medina-Sánchez M

Subjects

Male, Animals, Sperm-Ovum Interactions physiology, Sperm Capacitation physiology, Oocytes metabolism, Semen, Spermatozoa metabolism

Abstract

Remotely controllable microrobots are appealing for various biomedical in vivo applications. In particular, in recent years, our group has focused on developing sperm-microcarriers to assist sperm cells with motion deficiencies or low sperm count (two of the most prominent male infertility problems) to reach the oocyte toward in-vivo-assisted fertilization. Different sperm carriers, considering their motion in realistic media and confined environments, have been optimized. However, the already-reported sperm carriers have been mainly designed to transport single sperm cell, with limited functionality. Thus, to take a step forward, here, the development of a 4D-printed multifunctional microcarrier containing soft and smart materials is reported. These microcarriers can not only transport and deliver multiple motile sperm cells, but also release heparin and mediate local enzymatic reactions by hyaluronidase-loaded polymersomes (HYAL-Psomes). These multifunctional facets enable in situ sperm capacitation/hyperactivation, and the local degradation of the cumulus complex that surrounds the oocyte, both to facilitate the sperm-oocyte interaction for the ultimate goal of in vivo assisted fertilization., (© 2022 The Authors. Advanced Materials published by Wiley-VCH GmbH.)

Published

2022

44. Direct imaging of nanoscale field-driven domain wall oscillations in Landau structures.

Author

Singh B, Ravishankar R, Otálora JA, Soldatov I, Schäfer R, Karnaushenko D, Neu V, and Schmidt OG

Abstract

Linear oscillatory motion of domain walls (DWs) in the kHz and MHz regime is crucial when realizing precise magnetic field sensors such as giant magnetoimpedance devices. Numerous magnetically active defects lead to pinning of the DWs during their motion, affecting the overall behavior. Thus, the direct monitoring of the domain wall's oscillatory behavior is an important step to comprehend the underlying micromagnetic processes and to improve the magnetoresistive performance of these devices. Here, we report an imaging approach to investigate such DW dynamics with nanoscale spatial resolution employing conventional table-top microscopy techniques. Time-averaged magnetic force microscopy and Kerr imaging methods are applied to quantify the DW oscillations in Ni 81 Fe 19 rectangular structures with Landau domain configuration and are complemented by numeric micromagnetic simulations. We study the oscillation amplitude as a function of external magnetic field strength, frequency, magnetic structure size, thickness and anisotropy and understand the excited DW behavior as a forced damped harmonic oscillator with restoring force being influenced by the geometry, thickness, and anisotropy of the Ni 81 Fe 19 structure. This approach offers new possibilities for the analysis of DW motion at elevated frequencies and at a spatial resolution of well below 100 nm in various branches of nanomagnetism.

Published

2022

45. Collective Coupling of 3D Confined Optical Modes in Monolithic Twin Microtube Cavities Formed by Nanomembrane Origami.

Author

Wang X, Wang Z, Dong H, Saggau CN, Tang H, Tang M, Liu L, Baunack S, Bai L, Liu J, Yin Y, Ma L, and Schmidt OG

Abstract

We report the monolithic fabrication of twin microtube cavities by a nanomembrane origami method for achieving collective coupling of 3D confined optical modes. Owing to the well-aligned twin geometries, two sets of 3D confined optical modes in twin microtubes are spectrally and spatially matched, by which both the fundamental and higher-order axial modes are respectively coupled with each other. Multiple groups of the coupling modes provide multiple effective channels for energy exchange between coupled microcavities illustrated by the measured spatial optical field distributions. The spectral anticrossing and changing-over features of each group of coupled modes are revealed in experiments and calculations, indicating the occurrence of strong coupling. In addition, the simulated 3D mode profiles of twin microcavities confirm the collective strong coupling behavior, which shows good agreement with experiments. The collective coupling of 3D confined resonant modes promises broad applications in multichannel optical signal processing, nanophotonics, and 3D non-Hermitian systems.

Published

2022

46. An Anode-Free Zn-Graphite Battery.

Author

Wang G, Zhu M, Chen G, Qu Z, Kohn B, Scheler U, Chu X, Fu Y, Schmidt OG, and Feng X

Abstract

The anode-free battery concept is proposed to pursue the aspiration of energy-dense, rechargeable metal batteries, but this has not been achieved with dual-ion batteries. Herein, the first anode-free Zn-graphite battery enabled by efficient Zn plating-stripping onto a silver-coated Cu substrate is demonstrated. The silver coating guides uniform Zn deposition without dendrite formation or side reaction over a wide range of electrolyte concentrations, enabling the construction of anode-free Zn cells. In addition, the graphite cathode operates efficiently under reversible bis(trifluoromethanesulfonyl)imide anion (TFSI - ) intercalation without anodic corrosion. An extra high-potential TFSI - intercalation plateau is recognized at 2.75 V, contributing to the high capacity of graphite cathode. Thanks to efficient Zn plating-stripping and TFSI - intercalation-deintercalation, an anode-free Zn-graphite dual-ion battery that exhibits impressive cycling stability with 82% capacity retention after 1000 cycles is constructed. At the same time, a specific energy of 79 Wh kg -1 based on the mass of cathode and electrolyte is achieved, which is over two times higher than conventional Zn-graphite batteries (<30 Wh kg -1 )., (© 2022 The Authors. Advanced Materials published by Wiley-VCH GmbH.)

Published

2022

47. Tailoring electron beams with high-frequency self-assembled magnetic charged particle micro optics.

Author

Huber R, Kern F, Karnaushenko DD, Eisner E, Lepucki P, Thampi A, Mirhajivarzaneh A, Becker C, Kang T, Baunack S, Büchner B, Karnaushenko D, Schmidt OG, and Lubk A

Abstract

Tunable electromagnets and corresponding devices, such as magnetic lenses or stigmators, are the backbone of high-energy charged particle optical instruments, such as electron microscopes, because they provide higher optical power, stability, and lower aberrations compared to their electric counterparts. However, electromagnets are typically macroscopic (super-)conducting coils, which cannot generate swiftly changing magnetic fields, require active cooling, and are structurally bulky, making them unsuitable for fast beam manipulation, multibeam instruments, and miniaturized applications. Here, we present an on-chip microsized magnetic charged particle optics realized via a self-assembling micro-origami process. These micro-electromagnets can generate alternating magnetic fields of about ±100 mT up to a hundred MHz, supplying sufficiently large optical power for a large number of charged particle optics applications. That particular includes fast spatiotemporal electron beam modulation such as electron beam deflection, focusing, and wave front shaping as required for stroboscopic imaging., (© 2022. The Author(s).)

Published

2022

48. On-chip integrated process-programmable sub-10 nm thick molecular devices switching between photomultiplication and memristive behaviour.

Author

Li T, Hantusch M, Qu J, Bandari VK, Knupfer M, Zhu F, and Schmidt OG

Abstract

Molecular devices constructed by sub-10 nm thick molecular layers are promising candidates for a new generation of integratable nanoelectronic applications. Here, we report integrated molecular devices based on ultrathin copper phthalocyanine/fullerene hybrid layers with microtubular soft-contacts, which exhibit process-programmable functionality switching between photomultiplication and memristive behaviour. The local electric field at the interface between the polymer bottom electrode and the enclosed molecular channels modulates the ionic-electronic charge interaction and hence determines the transition of the device function. When ions are not driven into the molecular channels at a low interface electric field, photogenerated holes are trapped as electronic space charges, resulting in photomultiplication with a high external quantum efficiency. Once mobile ions are polarized and accumulated as ionic space charges in the molecular channels at a high interface electric field, the molecular devices show ferroelectric-like memristive switching with remarkable resistive ON/OFF and rectification ratios., (© 2022. The Author(s).)

Published

2022

49. A new dimension for magnetosensitive e-skins: active matrix integrated micro-origami sensor arrays.

Author

Becker C, Bao B, Karnaushenko DD, Bandari VK, Rivkin B, Li Z, Faghih M, Karnaushenko D, and Schmidt OG

Subjects

Magnetics, Skin, Touch Perception, Wearable Electronic Devices

Abstract

Magnetic sensors are widely used in our daily life for assessing the position and orientation of objects. Recently, the magnetic sensing modality has been introduced to electronic skins (e-skins), enabling remote perception of moving objects. However, the integration density of magnetic sensors is limited and the vector properties of the magnetic field cannot be fully explored since the sensors can only perceive field components in one or two dimensions. Here, we report an approach to fabricate high-density integrated active matrix magnetic sensor with three-dimensional (3D) magnetic vector field sensing capability. The 3D magnetic sensor is composed of an array of self-assembled micro-origami cubic architectures with biased anisotropic magnetoresistance (AMR) sensors manufactured in a wafer-scale process. Integrating the 3D magnetic sensors into an e-skin with embedded magnetic hairs enables real-time multidirectional tactile perception. We demonstrate a versatile approach for the fabrication of active matrix integrated 3D sensor arrays using micro-origami and pave the way for new electronic devices relying on the autonomous rearrangement of functional elements in space., (© 2022. The Author(s).)

Published

2022

50. Interfacial Chemistry Triggers Ultrafast Radiative Recombination in Metal Halide Perovskites.

Author

Dong H, Zhang C, Nie W, Duan S, Saggau CN, Tang M, Zhu M, Zhao YS, Ma L, and Schmidt OG

Abstract

Efficient radiative recombination is essential for perovskite luminescence, but the intrinsic radiative recombination rate as a basic material property is challenging to tailor. Here we report an interfacial chemistry strategy to dramatically increase the radiative recombination rate of perovskites. By coating aluminum oxide on the lead halide perovskite, lead-oxygen bonds are formed at the perovskite-oxide interface, producing the perovskite surface states with a large exciton binding energy and a high localized density of electronic state. The oxide-bonded perovskite exhibits a ≈500 fold enhanced photoluminescence with a ≈10 fold reduced lifetime, indicating an unprecedented ≈5000 fold increase in the radiative recombination rate. The enormously enhanced radiative recombination promises to significantly promote the perovskite optoelectronic performance., (© 2022 The Authors. Angewandte Chemie International Edition published by Wiley-VCH GmbH.)

Published

2022