Your search keyword '"Oliver G. Schmidt"' showing total 1,089 results

1. Flexible IGZO TFT Technology for Shift Register Drivers

Author

Bin Bao, Dmitriy D. Karnaushenko, Jiawang Xu, Shouguo Wang, Vineeth Kumar Bandari, Oliver G. Schmidt, and Daniil Karnaushenko

Subjects

atomic layer deposition, flexible electronics, high k dielectrics, IGZO TFTs, integrated circuits, shift registers, Electric apparatus and materials. Electric circuits. Electric networks, TK452-454.4, Physics, QC1-999

Abstract

Abstract Active sensing matrices play a pivotal role in various electronic devices, including optical and X‐ray imaging arrays, electronic skins, and artificial tactile arrays, among others. These matrices function through a thin‐film active switching mechanism, allowing for the scanning of rows and columns by external circuitry to read the sensory signals of individual pixels. Recently, indium–gallium‐zinc oxide thin‐film transistors (IGZO TFTs) have emerged as highly promising technology in the realm of flexible electronics. They enable the large‐scale integration of functional circuits on flexible substrates. Shift registers are commonly employed as peripheral scanning circuits to sequentially address active‐matrix arrays. To enhance system compactness and minimize external electrical connections, it is imperative to seamlessly integrate shift registers within the active matrices. However, contemporary flexible IGZO‐based shift registers suffer from high operating voltages and low frequencies, which constrain their applicability in high‐performance flexible sensors and displays. In response to this challenge, a breakthrough is presented in the form of low‐voltage, high‐frequency bootstrap shift registers implemented with flexible IGZO technology. The approach involves utilizing SU‐8 buffered polyimide (PI) polymer foils as substrates. These foils boast an exceptional level of surface smoothness, significantly increasing the yield and performance of electronic components, including vias, IGZO TFTs, and capacitors used in the shift register circuitry. Additionally, HfO2/Al2O3/HfO2 sandwich structures are employed as high‐k dielectric layers to reduce the operational voltage. Thanks to the innovative circuit design and optimized fabrication methods, the 16‐stage shift register can operate at just 1.8 V with a frequency of 15 kHz. This breakthrough promises to have a profound impact on a wide range of applications for driving flexible active‐matrix electronic systems.

Published

2024

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

Author

Ze Chen, Tairan Wang, Zhuoxi Wu, Yue Hou, Ao Chen, Yanbo Wang, Zhaodong Huang, Oliver G. Schmidt, Minshen Zhu, Jun Fan, and Chunyi Zhi

Subjects

Science

Abstract

Abstract The high redox potential of Zn0/2+ 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 LiNi0.5Mn1.5O4 can increase the voltages of Zn batteries, Zn2+ ions will be immobilized in LiNi0.5Mn1.5O4 once intercalated, resulting in irreversibility. Here, we design a polymer hetero-electrolyte consisting of an anode layer with Zn2+ ions as charge carriers and a cathode layer that blocks the Zn2+ 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.

Published

2024

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

Author

Pavel Fedorov, Ivan Soldatov, Volker Neu, Rudolf Schäfer, Oliver G. Schmidt, and Daniil Karnaushenko

Subjects

Science

Abstract

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.

Published

2024

4. Electrolyte design for reversible metal electrodeposition-based electrochromic energy-saving devices

Author

Jinhui Wang, Ying Lv, Yiping Zhou, Sensen Jia, Feng Zhu, Oliver G. Schmidt, and Guofa Cai

Subjects

Energy conservation, TJ163.26-163.5, Renewable energy sources, TJ807-830

Abstract

Reversible metal electrodeposition (RME)-based electrochromic devices have been attracting significant research interest due to their merits of low cost, simple configuration, and high extinction coefficients. As the key component in the electrochromic system, RME electrolytes with various metal ions and additives have endowed the RME device with flexible functionalities in energy-saving applications such as energy-efficient displays, smart windows, and camouflages. However, it is still challenging to research a widespread commercial application before some critical issues can be solved such as poor reversibility, low optical memory of the mirror state, and slow switching speed. Here, we offer a critical review of the recent progress of RME electrochromic devices based on aqueous, organic, ionic liquid, and eutectic electrolytes. Furthermore, the main challenges and perspectives for RME electrolytes are highlighted and discussed.

Published

2024

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

Author

Pavel Fedorov, Ivan Soldatov, Volker Neu, Rudolf Schäfer, Oliver G. Schmidt, and Daniil Karnaushenko

Subjects

Science

Published

2024

6. Symmetry‐Induced Selective Excitation of Topological States in Su–Schrieffer–Heeger Waveguide Arrays

Author

Min Tang, Jiawei Wang, Sreeramulu Valligatla, Christian N. Saggau, Haiyun Dong, Ehsan Saei Ghareh Naz, Sebastian Klembt, Ching Hua Lee, Ronny Thomale, Jeroen van den Brink, Ion Cosma Fulga, Oliver G. Schmidt, and Libo Ma

Subjects

optical waveguides, phase transition, topological photonics, Applied optics. Photonics, TA1501-1820, Optics. Light, QC350-467

Abstract

The investigation of topological state transition in carefully designed photonic lattices is of high interest for fundamental research, as well as for applied studies such as manipulating light flow in on‐chip photonic systems. Herein, the topological phase transition between symmetric topological zero modes (TZM) and antisymmetric TZMs in Su–Schrieffer–Heeger mirror symmetric waveguides is reported. The transition of TZMs is realized by adjusting the coupling ratio between neighboring waveguide pairs, which is enabled by selective modulation of the refractive index in the waveguide gaps. Bidirectional topological transitions between symmetric and antisymmetric TZMs can be achieved with proposed switching strategy. Selective excitation of topological edge mode is demonstrated owing to the symmetry characteristics of the TZMs. The flexible manipulation of topological states is promising for on‐chip light flow control and may spark further investigations on symmetric/antisymmetric TZM transitions in other photonic topological frameworks.

Published

2023

7. Self-assembly as a tool to study microscale curvature and strain-dependent magnetic properties

Author

Balram Singh, Jorge. A. Otálora, Tong H. Kang, Ivan Soldatov, Dmitriy D. Karnaushenko, Christian Becker, Rudolf Schäfer, Daniil Karnaushenko, Volker Neu, and Oliver G. Schmidt

Subjects

Electronics, TK7800-8360, Materials of engineering and construction. Mechanics of materials, TA401-492

Abstract

Abstract The extension of 2D ferromagnetic structures into 3D curved geometry enables to tune its magnetic properties such as uniaxial magnetic anisotropy. Tuning the anisotropy with strain and curvature has become a promising ingredient in modern electronics, such as flexible and stretchable magnetoelectronic devices, impedance-based field sensors, and strain gauges, however, has been limited to extended thin films and to only moderate bending. By applying a self-assembly rolling technique using a polymeric platform, we provide a template that allows homogeneous and controlled bending of a functional layer adhered to it, irrespective of its shape and size. This is an intriguing possibility to tailor the sign and magnitude of the surface strain of integrated, micron-sized devices. In this article, the impact of strain and curvature on the magnetic ground state and anisotropy is quantified for thin-film Permalloy micro-scale structures, fabricated on the surface of the tubular architectures, using solely electrical measurements.

Published

2022

8. Flexible MXene films for batteries and beyond

Author

Yang Huang, Qiongqiong Lu, Dianlun Wu, Yue Jiang, Zhenjie Liu, Bin Chen, Minshen Zhu, and Oliver G. Schmidt

Subjects

2D materials, flexible batteries, flexible electronics, intelligent system, MXene, Production of electric energy or power. Powerplants. Central stations, TK1001-1841

Abstract

Abstract MXenes add dozens of metallic conductors to the family of two‐dimensional (2D) materials. A top‐down synthesis approach removing A‐layer atoms (e.g., Al, Si, and Ga) in MAX phases to produce 2D flakes attaches various surface terminations to MXenes. With these terminations, MXenes show tunable properties, promising a range of applications from energy storage devices to electronics, including sensors, transistors, and antennas. MXenes are also excellent building blocks to create flexible films used for flexible and wearable devices. This article summarizes the synthesis of MXene flakes and highlights aspects that need attention for flexible devices. Rather than listing the development of energy storage devices in detail, we focus on the main challenges of and solutions for constructing high‐performance devices. Moreover, we show the applications of MXene films in electronics to call on designs to construct a complete system based on MXene with good flexibility, which consists of a power source, sensors, transistors, and wireless communications.

Published

2022

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

Author

Tianming Li, Martin Hantusch, Jiang Qu, Vineeth Kumar Bandari, Martin Knupfer, Feng Zhu, and Oliver G. Schmidt

Subjects

Science

Abstract

Developing molecular electronics is challenged by integrating fragile organic molecules into modern micro/nanoelectronics based on inorganic semiconductors. Li et al. apply rolled-up nanotechnology to assemble on-chip molecular devices, which can be switched between photodiodes and volatile memristors.

Published

2022

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

Author

Christian Becker, Bin Bao, Dmitriy D. Karnaushenko, Vineeth Kumar Bandari, Boris Rivkin, Zhe Li, Maryam Faghih, Daniil Karnaushenko, and Oliver G. Schmidt

Subjects

Science

Abstract

State-of-the-art magnetic skins can only sense in one or two-dimensions, at small spatial resolutions. By combining the ancient art of paper folding, origami, with advanced semiconductor technology, here, authors present cutting edge three-dimensional magnetic sensors.

Published

2022

11. Active Matrix Flexible Sensory Systems: Materials, Design, Fabrication, and Integration

Author

Bin Bao, Dmitriy D. Karnaushenko, Oliver G. Schmidt, Yanlin Song, and Daniil Karnaushenko

Subjects

active matrices, electronic skins (e-skins), flexible electronics, flexible sensors, heterogeneous integration, inkjet printing, Computer engineering. Computer hardware, TK7885-7895, Control engineering systems. Automatic machinery (General), TJ212-225

Abstract

A variety of modern applications including soft robotics, prosthetics, and health monitoring devices that cover electronic skins (e‐skins), wearables as well as implants have been developed within the last two decades to bridge the gap between artificial and biological systems. During this development, high‐density integration of various sensing modalities into flexible electronic devices becomes vitally important to improve the perception and interaction of the human bodies and robotic appliances with external environment. As a key component in flexible electronics, the flexible thin‐film transistors (TFTs) have seen significant advances, allowing for building flexible active matrices. The flexible active matrices have been integrated with distributed arrays of sensing elements, enabling the detection of signals over a large area. The integration of sensors within pixels of flexible active matrices has brought the application scenarios to a higher level of sophistication with many advanced functionalities. Herein, recent progress in the active matrix flexible sensory systems is reviewed. The materials used to construct the semiconductor channels, the dielectric layers, and the flexible substrates for the active matrices are summarized. The pixel designs and fabrication strategies for the active matrix flexible sensory systems are briefly discussed. The applications of the flexible sensory systems are exemplified by reviewing pressure sensors, temperature sensors, photodetectors, magnetic sensors, and biosignal sensors. At the end, the recent development is summarized and the vision on the further advances of flexible active matrix sensory systems is provided.

Published

2022

12. Nano-biosupercapacitors enable autarkic sensor operation in blood

Author

Yeji Lee, Vineeth Kumar Bandari, Zhe Li, Mariana Medina-Sánchez, Manfred F. Maitz, Daniil Karnaushenko, Mikhail V. Tsurkan, Dmitriy D. Karnaushenko, and Oliver G. Schmidt

Subjects

Science

Abstract

The miniaturization of biocompatible microsystems that enable self-sufficiency and autarkic operations is ever increasing. Here, the authors demonstrate a robust integratable nano-biosupercapacitor with enhanced performance in complex biological fluids, thus enabling autarkic sensor operation in blood.

Published

2021

13. Recent developments of stamped planar micro-supercapacitors: Materials, fabrication and perspectives

Author

Fei Li, Yang Li, Jiang Qu, Jinhui Wang, Vineeth Kumar Bandari, Feng Zhu, and Oliver G. Schmidt

Subjects

Microsupercapacitors, Stamping, Microfabrication, Miniaturized electronics, Energy storage devices, Technology, Engineering (General). Civil engineering (General), TA1-2040

Abstract

The rapid development of wearable and portable electronics has dramatically increased the application for miniaturized energy storage components. Stamping micro-supercapacitors (MSCs) with planar interdigital configurations are considered as a promising candidate to meet the requirements. In this review, recent progress of the different stamping materials and various stamping technologies are first discussed. The merits of each material, manufacturing process of each stamping method and the properties of stamping MSCs are scrutinized, respectively. Further insights on technical difficulties and scientific challenges are finally demonstrated, including the limited thickness of printed electrodes, poor overlay accuracy and printing resolution.

Published

2021

14. Nano energy for miniaturized systems

Author

Minshen Zhu, Feng Zhu, and Oliver G. Schmidt

Subjects

Micro-energy-storage devices, Wearability, Flexibility, Electronics, Technology, Engineering (General). Civil engineering (General), TA1-2040

Abstract

Skin mountable electronic devices are in a high-speed development at the crossroads of materials science, electronics, and computer science. Sophisticated functions, such as sensing, actuating, and computing, are integrated into a soft electronic device that can be firmly mounted to any place of human body. These advanced electronic devices are capable of yielding abilities for us whenever they are needed and even expanding our abilities beyond their natural limitations. Despite the great promise of skin mounted electronic devices, they still lack satisfactory power supplies that are safe and continuous. This Perspective discusses the prospects of the development of energy storage devices for the next generation skin mountable electronic devices based on their unique requirements on flexibility and miniaturized size.

Published

2021

15. Advanced architecture designs towards high-performance 3D microbatteries

Author

Yang Li, Jiang Qu, Fei Li, Zhe Qu, Hongmei Tang, Lixiang Liu, Minshen Zhu, and Oliver G. Schmidt

Subjects

Microbatteries, Origami technologies, Rolled-up nanotechnology, 3D devices, Energy storage performance, Technology, Engineering (General). Civil engineering (General), TA1-2040

Abstract

Rechargeable microbatteries are important power supplies for microelectronic devices. Two essential targets for rechargeable microbatteries are high output energy and minimal footprint areas. In addition to the development of new high-performance electrode materials, the device configurations of microbatteries also play an important role in enhancing the output energy and miniaturizing the footprint area. To make a clear vision on the design principle of rechargeable microbatteries, we firstly summarize the typical configurations of microbatteries. The advantages of different configurations are thoroughly discussed from the aspects of fabrication technologies and material engineering. Towards the high energy output at a minimal footprint area, a revolutionary design for microbatteries is of great importance. In this perspective, we review the progress of fabricating microbatteries based on the rolled-up nanotechnology, a derivative origami technology. Finally, we discussed the challenges and perspectives in the device design and materials optimization.

Published

2021

16. Targeted Sub-Attomole Cancer Biomarker Detection Based on Phase Singularity 2D Nanomaterial-Enhanced Plasmonic Biosensor

Author

Yuye Wang, Shuwen Zeng, Aurelian Crunteanu, Zhenming Xie, Georges Humbert, Libo Ma, Yuanyuan Wei, Aude Brunel, Barbara Bessette, Jean-Christophe Orlianges, Fabrice Lalloué, Oliver G. Schmidt, Nanfang Yu, and Ho-Pui Ho

Subjects

2D nanomaterials, Cancer marker detection, Phase singularity, Surface plasmon, Technology

Abstract

Highlights A zero-reflection-induced phase singularity is achieved through precisely controlling the resonance characteristics using two-dimensional nanomaterials. An atomically thin nano-layer having a high absorption coefficient is exploited to enhance the zero-reflection dip, which has led to the subsequent phase singularity and thus a giant lateral position shift. We have improved the detection limit of low molecular weight molecules by more than three orders of magnitude compared to current state-of-art nanomaterial-enhanced plasmonic sensors. Abstract Detection of small cancer biomarkers with low molecular weight and a low concentration range has always been challenging yet urgent in many clinical applications such as diagnosing early-stage cancer, monitoring treatment and detecting relapse. Here, a highly enhanced plasmonic biosensor that can overcome this challenge is developed using atomically thin two-dimensional phase change nanomaterial. By precisely engineering the configuration with atomically thin materials, the phase singularity has been successfully achieved with a significantly enhanced lateral position shift effect. Based on our knowledge, it is the first experimental demonstration of a lateral position signal change > 340 μm at a sensing interface from all optical techniques. With this enhanced plasmonic effect, the detection limit has been experimentally demonstrated to be 10–15 mol L−1 for TNF-α cancer marker, which has been found in various human diseases including inflammatory diseases and different kinds of cancer. The as-reported novel integration of atomically thin Ge2Sb2Te5 with plasmonic substrate, which results in a phase singularity and thus a giant lateral position shift, enables the detection of cancer markers with low molecular weight at femtomolar level. These results will definitely hold promising potential in biomedical application and clinical diagnostics.

Published

2021

17. Fast-Response Micro-Phototransistor Based on MoS2/Organic Molecule Heterojunction

Author

Shaista Andleeb, Xiaoyu Wang, Haiyun Dong, Sreeramulu Valligatla, Christian Niclaas Saggau, Libo Ma, Oliver G. Schmidt, and Feng Zhu

Subjects

transition metal dichalcogenides, MoS2, organic molecule, VOPc, phototransistor, heterostructure, Chemistry, QD1-999

Abstract

Over the past years, molybdenum disulfide (MoS2) has been the most extensively studied two-dimensional (2D) semiconductormaterial. With unique electrical and optical properties, 2DMoS2 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 MoS2. Here, we demonstrate a fast photoresponse in multilayer (ML) MoS2 by addressing a heterojunction interface with vanadylphthalocyanine (VOPc) molecules. The MoS2/VOPc van der Waals interaction that has been established encourages the PPC effect in MoS2 by rapidly segregating photo-generated holes, which move away from the traps of MoS2 toward the VOPc molecules. The MoS2/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 MoS2-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

18. Engineering microrobots for targeted cancer therapies from a medical perspective

Author

Christine K. Schmidt, Mariana Medina-Sánchez, Richard J. Edmondson, and Oliver G. Schmidt

Subjects

Science

Abstract

Microbot delivery devices are the latest development in attempts to overcome the systemic toxicity associated with classical chemotherapy. Here, the authors review the recent progress in the field with a focus on the clinical translation and potential of the research and give a future perspective on this topic.

Published

2020

19. Integrated molecular diode as 10 MHz half-wave rectifier based on an organic nanostructure heterojunction

Author

Tianming Li, Vineeth Kumar Bandari, Martin Hantusch, Jianhui Xin, Robert Kuhrt, Rachappa Ravishankar, Longqian Xu, Jidong Zhang, Martin Knupfer, Feng Zhu, Donghang Yan, and Oliver G. Schmidt

Subjects

Science

Abstract

The demand for miniaturization of electronics has been motivating a growing interest in high-performance molecular electronics. Li, Bandari et al. report a fully integrated molecular rectifier based on a molecular heterojunction and microtubular electrode enabling high frequency operation at more than 10 MHz.

Published

2020

20. System‐Engineered Miniaturized Robots: From Structure to Intelligence

Author

Vineeth Kumar Bandari and Oliver G. Schmidt

Subjects

autonomous systems, flexible micro-electronics, motile miniaturized-machines, soft shareable materials, system-engineered miniaturized robotics, Computer engineering. Computer hardware, TK7885-7895, Control engineering systems. Automatic machinery (General), TJ212-225

Abstract

The development of small machines, once envisioned by Feynman decades ago, has stimulated significant research in materials science, robotics, and computer science. Over the past years, the field of miniaturized robotics has rapidly expanded with many research groups contributing to the numerous challenges inherent to this field. Smart materials have played a particularly important role as they have imparted miniaturized robots with new functionalities and distinct capabilities. However, despite all efforts and many available soft materials and innovative technologies, a fully autonomous system‐engineered miniaturized robot (SEMR) of any practical relevance has not been developed yet. In this review, the foundation of SEMRs is discussed and six main areas (structure, motion, sensing, actuation, energy, and intelligence) which require particular efforts to push the frontiers of SEMRs further are identified. During the past decade, miniaturized robotic research has mainly relied on simplicity in design, and fabrication. A careful examination of current SEMRs that are physically, mechanically, and electrically engineered shows that they fall short in many ways concerning miniaturization, full‐scale integration, and self‐sufficiency. Some of these issues have been identified in this review. Some are inevitably yet to be explored, thus, allowing to set the stage for the next generation of intelligent, and autonomously operating SEMRs.

Published

2021

21. Self‐Assembled Flexible and Integratable 3D Microtubular Asymmetric Supercapacitors

Author

Fei Li, Jinhui Wang, Lixiang Liu, Jiang Qu, Yang Li, Vineeth Kumar Bandari, Daniil Karnaushenko, Christian Becker, Maryam Faghih, Tong Kang, Stefan Baunack, Minshen Zhu, Feng Zhu, and Oliver G. Schmidt

Subjects

Science

Published

2021

22. Shape‐Controlled Flexible Microelectronics Facilitated by Integrated Sensors and Conductive Polymer Actuators

Author

Boris Rivkin, Christian Becker, Farzin Akbar, Rachappa Ravishankar, Dmitriy D. Karnaushenko, Ronald Naumann, Alaleh Mirhajivarzaneh, Mariana Medina-Sánchez, Daniil Karnaushenko, and Oliver G. Schmidt

Subjects

feedback control, magnetic sensors, microactuators, shapeable electroactive polymers, soft microrobots, Computer engineering. Computer hardware, TK7885-7895, Control engineering systems. Automatic machinery (General), TJ212-225

Abstract

The next generation of biomedical tools requires reshapeable electronics to closely interface with biological tissues. This will offer unique mechanical properties and the ability to conform to irregular geometries while being robust and lightweight. Such devices can be achieved with soft materials and thin‐film structures that are able to reshape on demand. However, reshaping at the submillimeter scale remains a challenging task. Herein, shape‐controlled microscale devices are demonstrated that integrate electronic sensors and electroactive polymer actuators. The fast and biocompatible actuators are capable of actively reshaping the device into flat or curved geometries. The curvature and position of the devices are monitored with strain or magnetic sensors. The sensor signals are used in a closed feedback loop to control the actuators. The devices are wafer‐scale microfabricated resulting in multiple functional units capable of grasping, holding, and releasing biological tissues, as demonstrated with a neuronal bundle.

Published

2021

23. Magnetic origami creates high performance micro devices

Author

Felix Gabler, Dmitriy D. Karnaushenko, Daniil Karnaushenko, and Oliver G. Schmidt

Subjects

Science

Abstract

Despite the potential of self-assembly strategies for fabricating 3D micro-electronic devices, technological limitations prohibit widespread industrial adoption. Here, the authors report the magnetic field-assisted Origami-based assembly of high-performance devices with high yield.

Published

2019

24. Covalent Organic Frameworks for Efficient Energy Electrocatalysis: Rational Design and Progress

Author

Hua Zhang, Minshen Zhu, Oliver G. Schmidt, Shuiliang Chen, and Kai Zhang

Subjects

air batteries, catalytic kinetics, clean and sustainable energy conversions, clean fuels, covalent organic frameworks, electrocatalysts, Environmental technology. Sanitary engineering, TD1-1066, Renewable energy sources, TJ807-830

Abstract

An efficient catalyst with a precisely designed and predictable structure is highly desired to optimize its performance and understand the mechanism beyond the catalytic activity. Covalent organic frameworks (COFs), as an emerging class of framework materials linked by strong covalent bonds, simultaneously allow precise structure design with predictable synthesis and show advantages of large surface areas, tunable pore sizes, and unique molecular architectures. Although the research on COF‐based electrocatalysts is at an early age, significant progress has been made. Herein, the recent significant progress in the design and synthesis of COFs as highly efficient electrocatalysts for the oxygen reduction reaction (ORR), oxygen evolution reaction (OER), and hydrogen evolution reaction (HER) is summarized. Design principles for COFs as efficient electrocatalysts are discussed by considering essential factors for catalyzing the OER, ORR, and HER processes at the molecular level. Herein, a summary on the in‐depth understanding of the catalytic mechanism and kinetics limitations of COFs provides a general instruction for further exploring their vast potential for designing highly efficient electrocatalysts.

Published

2021

25. Editorial for a special issue 'Nano energy materials and devices for miniaturized electronics and smart systems'

Author

Feng Zhu and Oliver G. Schmidt

Subjects

Technology, Engineering (General). Civil engineering (General), TA1-2040

Published

2021

26. Stamping Fabrication of Flexible Planar Micro‐Supercapacitors Using Porous Graphene Inks

Author

Fei Li, Jiang Qu, Yang Li, Jinhui Wang, Minshen Zhu, Lixiang Liu, Jin Ge, Shengkai Duan, Tianming Li, Vineeth Kumar Bandari, Ming Huang, Feng Zhu, and Oliver G. Schmidt

Subjects

areal energy density, graphene inks, micro‐supercapacitors, stamping, Science

Abstract

Abstract High performance, flexibility, safety, and robust integration for micro‐supercapacitors (MSCs) are of immense interest for the urgent demand for miniaturized, smart energy‐storage devices. However, repetitive photolithography processes in the fabrication of on‐chip electronic components including various photoresists, masks, and toxic etchants are often not well‐suited for industrial production. Here, a cost‐effective stamping strategy is developed for scalable and rapid preparation of graphene‐based planar MSCs. Combining stamps with desired shapes and highly conductive graphene inks, flexible MSCs with controlled structures are prepared on arbitrary substrates without any metal current collectors, additives, and polymer binders. The interdigitated MSC exhibits high areal capacitance up to 21.7 mF cm−2 at a current of 0.5 mA and a high power density of 6 mW cm−2 at an energy density of 5 µWh cm−2. Moreover, the MSCs show outstanding cycling performance and remarkable flexibility over 10 000 charge–discharge cycles and 300 bending cycles. In addition, the capacitance and output voltage of the MSCs are easily adjustable through interconnection with well‐defined arrangements. The efficient, rapid manufacturing of the graphene‐based interdigital MSCs with outstanding flexibility, shape diversity, and high areal capacitance shows great potential in wearable and portable electronics.

Published

2020

27. A Rotating Spiral Micromotor for Noninvasive Zygote Transfer

Author

Lukas Schwarz, Dmitriy D. Karnaushenko, Franziska Hebenstreit, Ronald Naumann, Oliver G. Schmidt, and Mariana Medina‐Sánchez

Subjects

assisted reproduction, micromotors, micropropellers, rotating magnetic fields, spirals, zygote intrafallopian transfer, Science

Abstract

Abstract Embryo transfer (ET) is a decisive step in the in vitro fertilization process. In most cases, the embryo is transferred to the uterus after several days of in vitro culture. Although studies have identified the beneficial effects of ET on proper embryo development in the earlier stages, this strategy is compromised by the necessity to transfer early embryos (zygotes) back to the fallopian tube instead of the uterus, which requires a more invasive, laparoscopic procedure, termed zygote intrafallopian transfer (ZIFT). Magnetic micromotors offer the possibility to mitigate such surgical interventions, as they have the potential to transport and deliver cellular cargo such as zygotes through the uterus and fallopian tube noninvasively, actuated by an externally applied rotating magnetic field. This study presents the capture, transport, and release of bovine and murine zygotes using two types of magnetic micropropellers, helix and spiral. Although helices represent an established micromotor architecture, spirals surpass them in terms of motion performance and with their ability to reliably capture and secure the cargo during both motion and transfer between different environments. Herein, this is demonstrated with murine oocytes/zygotes as the cargo; this is the first step toward the application of noninvasive, magnetic micromotor‐assisted ZIFT.

Published

2020

28. Uniaxial stress flips the natural quantization axis of a quantum dot for integrated quantum photonics

Author

Xueyong Yuan, Fritz Weyhausen-Brinkmann, Javier Martín-Sánchez, Giovanni Piredda, Vlastimil Křápek, Yongheng Huo, Huiying Huang, Christian Schimpf, Oliver G. Schmidt, Johannes Edlinger, Gabriel Bester, Rinaldo Trotta, and Armando Rastelli

Subjects

Science

Abstract

The natural quantization axis in quantum dots, which is usually parallel to the growth direction, is not ideal for planar photonic circuits. Here Yuan et al. show that for gallium arsenide dots, the quantization axis can be flipped to lie in the growth plane via moderate in-plane uniaxial stress.

Published

2018

29. Highly-efficient extraction of entangled photons from quantum dots using a broadband optical antenna

Author

Yan Chen, Michael Zopf, Robert Keil, Fei Ding, and Oliver G. Schmidt

Subjects

Science

Abstract

Cascade radiative decay in quantum dots is a promising way of generating entangled photon pairs, but the extraction efficiency is a strongly limiting factor. Here, the authors demonstrate high extraction efficiency through a broadband dielectric photonic antenna.

Published

2018

30. (Metallo)porphyrins for potential materials science applications

Author

Lars Smykalla, Carola Mende, Michael Fronk, Pablo F. Siles, Michael Hietschold, Georgeta Salvan, Dietrich R. T. Zahn, Oliver G. Schmidt, Tobias Rüffer, and Heinrich Lang

Subjects

atomic force microscopy, magneto-optical Kerr effect spectroscopy, scanning tunnelling microscopy and spectroscopy, self-assembly, surface-confined 2D polymerization, transport properties, Technology, Chemical technology, TP1-1185, Science, Physics, QC1-999

Abstract

The bottom-up approach to replace existing devices by molecular-based systems is a subject that attracts permanently increasing interest. Molecular-based devices offer not only to miniaturize the device further, but also to benefit from advanced functionalities of deposited molecules. Furthermore, the molecules itself can be tailored to allow via their self-assembly the potential fabrication of devices with an application potential, which is still unforeseeable at this time. Herein, we review efforts to use discrete (metallo)porphyrins for the formation of (sub)monolayers by surface-confined polymerization, of monolayers formed by supramolecular recognition and of thin films formed by sublimation techniques. Selected physical properties of these systems are reported as well. The application potential of those ensembles of (metallo)porphyrins in materials science is discussed.

Published

2017

31. Deposition of exchange-coupled dinickel complexes on gold substrates utilizing ambidentate mercapto-carboxylato ligands

Author

Martin Börner, Laura Blömer, Marcus Kischel, Peter Richter, Georgeta Salvan, Dietrich R. T. Zahn, Pablo F. Siles, Maria E. N. Fuentes, Carlos C. B. Bufon, Daniel Grimm, Oliver G. Schmidt, Daniel Breite, Bernd Abel, and Berthold Kersting

Subjects

ambidentate ligands, chemisorption, gold surfaces, macrocyclic complexes, mercapto-alkanecarboxylic acid, Technology, Chemical technology, TP1-1185, Science, Physics, QC1-999

Abstract

The chemisorption of magnetically bistable transition metal complexes on planar surfaces has recently attracted increased scientific interest due to its potential application in various fields, including molecular spintronics. In this work, the synthesis of mixed-ligand complexes of the type [NiII2L(L’)](ClO4), where L represents a 24-membered macrocyclic hexaazadithiophenolate ligand and L’ is a ω-mercapto-carboxylato ligand (L’ = HS(CH2)5CO2− (6), HS(CH2)10CO2− (7), or HS(C6H4)2CO2− (8)), and their ability to adsorb on gold surfaces is reported. Besides elemental analysis, IR spectroscopy, electrospray ionization mass spectrometry (ESIMS), UV–vis spectroscopy, and X-ray crystallography (for 6 and 7), the compounds were also studied by temperature-dependent magnetic susceptibility measurements (for 7 and 8) and (broken symmetry) density functional theory (DFT) calculations. An S = 2 ground state is demonstrated by temperature-dependent susceptibility and magnetization measurements, achieved by ferromagnetic coupling between the spins of the Ni(II) ions in 7 (J = +22.3 cm−1) and 8 (J = +20.8 cm−1; H = −2JS1S2). The reactivity of complexes 6–8 is reminiscent of that of pure thiolato ligands, which readily chemisorb on Au surfaces as verified by contact angle, atomic force microscopy (AFM) and spectroscopic ellipsometry measurements. The large [Ni2L] tail groups, however, prevent the packing and self-assembly of the hydrocarbon chains. The smaller film thickness of 7 is attributed to the specific coordination mode of the coligand. Results of preliminary transport measurements utilizing rolled-up devices are also reported.

Published

2017

32. Charge transport in organic nanocrystal diodes based on rolled-up robust nanomembrane contacts

Author

Vineeth Kumar Bandari, Lakshmi Varadharajan, Longqian Xu, Abdur Rehman Jalil, Mirunalini Devarajulu, Pablo F. Siles, Feng Zhu, and Oliver G. Schmidt

Subjects

charge transport, nanomembrane, organic diode, organic nanocrystal, rolled-up nanotechnology, Technology, Chemical technology, TP1-1185, Science, Physics, QC1-999

Abstract

The investigation of charge transport in organic nanocrystals is essential to understand nanoscale physical properties of organic systems and the development of novel organic nanodevices. In this work, we fabricate organic nanocrystal diodes contacted by rolled-up robust nanomembranes. The organic nanocrystals consist of vanadyl phthalocyanine and copper hexadecafluorophthalocyanine heterojunctions. The temperature dependent charge transport through organic nanocrystals was investigated to reveal the transport properties of ohmic and space-charge-limited current under different conditions, for instance, temperature and bias.

Published

2017

33. Synthesis, spectroscopic characterization and thermogravimetric analysis of two series of substituted (metallo)tetraphenylporphyrins

Author

Rasha K. Al-Shewiki, Carola Mende, Roy Buschbeck, Pablo F. Siles, Oliver G. Schmidt, Tobias Rüffer, and Heinrich Lang

Subjects

electrospray ionization mass spectrometry, IR spectroscopy, metalloporphyrin, porphyrin, thermogravimetry, UV–vis spectroscopy, Technology, Chemical technology, TP1-1185, Science, Physics, QC1-999

Abstract

Subsequent treatment of H2TPP(CO2H)4 (tetra(p-carboxylic acid phenyl)porphyrin, 1) with an excess of oxalyl chloride and HNR2 afforded H2TPP(C(O)NR2)4 (R = Me, 2; iPr, 3) with yields exceeding 80%. The porphyrins 2 and 3 could be converted to the corresponding metalloporphyrins MTPP(C(O)NR2)4 (R = Me/iPr for M = Zn (2a, 3a); Cu (2b, 3b); Ni (2c, 3c); Co (2d, 3d)) by the addition of 3 equiv of anhydrous MCl2 (M = Zn, Cu, Ni, Co) to dimethylformamide solutions of 2 and 3 at elevated temperatures. Metalloporphyrins 2a–d and 3a–d were obtained in yields exceeding 60% and have been, as well as 2 and 3, characterized by elemental analysis, electrospray ionization mass spectrometry (ESIMS) and IR and UV–vis spectroscopy. Porphyrins 2, 2a–d and 3, 3a–d are not suitable for organic molecular beam deposition (OMBD), which is attributed to their comparatively low thermal stability as determined by thermogravimetric analysis (TG) of selected representatives.

Published

2017

34. Solid-state ensemble of highly entangled photon sources at rubidium atomic transitions

Author

Robert Keil, Michael Zopf, Yan Chen, Bianca Höfer, Jiaxiang Zhang, Fei Ding, and Oliver G. Schmidt

Subjects

Science

Abstract

Scalable and integratable sources of entangled-photon pairs are an important building block for quantum photonic applications. Here, Keilet al. demonstrate that an ensemble of droplet-etched gallium arsenide quantum dots can emit polarization-entangled photons with almost 100% yield.

Published

2017

35. Highly indistinguishable and strongly entangled photons from symmetric GaAs quantum dots

Author

Daniel Huber, Marcus Reindl, Yongheng Huo, Huiying Huang, Johannes S. Wildmann, Oliver G. Schmidt, Armando Rastelli, and Rinaldo Trotta

Subjects

Science

Abstract

Scalable and integratable sources of entangled-photon pairs are an important building block for quantum photonic applications. Here, Huberet al. demonstrate that droplet-etched gallium arsenide quantum dots can emit highly indistinguishable photon pairs with a high degree of entanglement.

Published

2017

36. Purely antiferromagnetic magnetoelectric random access memory

Author

Tobias Kosub, Martin Kopte, Ruben Hühne, Patrick Appel, Brendan Shields, Patrick Maletinsky, René Hübner, Maciej Oskar Liedke, Jürgen Fassbender, Oliver G. Schmidt, and Denys Makarov

Subjects

Science

Abstract

Magnetoelectric coupling allows switching of magnetic states via gate voltage pulses. Here the authors propose and demonstrate a purely antiferromagnetic magnetoelectric random access memory based on Cr2O3, reporting 50-fold reduction of writing threshold compared to ferromagnetic counterparts.

Published

2017

37. Self‐Assembled Flexible and Integratable 3D Microtubular Asymmetric Supercapacitors

Author

Fei Li, Jinhui Wang, Lixiang Liu, Jiang Qu, Yang Li, Vineeth Kumar Bandari, Daniil Karnaushenko, Christian Becker, Maryam Faghih, Tong Kang, Stefan Baunack, Minshen Zhu, Feng Zhu, and Oliver G. Schmidt

Subjects

3D microtubular architecture, footprints, integrated devices, microsupercapacitors, rolled‐up nanotechnology, Science

Abstract

Abstract The rapid development of microelectronics has equally rapidly increased the demand for miniaturized energy storage devices. On‐chip microsupercapacitors (MSCs), as promising power candidates, possess great potential to complement or replace electrolytic capacitors and microbatteries in various applications. However, the areal capacities and energy densities of the planar MSCs are commonly limited by the low voltage window, the thin layer of the electrode materials and complex fabrication processes. Here, a new‐type three‐dimensional (3D) tubular asymmetric MSC with small footprint area, high potential window, ultrahigh areal energy density, and long‐term cycling stability is fabricated with shapeable materials and photolithographic technologies, which are compatible with modern microelectronic fabrication procedures widely used in industry. Benefiting from the novel architecture, the 3D asymmetric MSC displays an ultrahigh areal capacitance of 88.6 mF cm−2 and areal energy density of 28.69 mW h cm−2, superior to most reported interdigitated MSCs. Furthermore, the 3D tubular MSCs demonstrate remarkable cycling stability and the capacitance retention is up to 91.8% over 12 000 cycles. It is believed that the efficient fabrication methodology can be used to construct various integratable microscale tubular energy storage devices with small footprint area and high performance for miniaturized electronics.

Published

2019

38. Wavelength-tunable entangled photons from silicon-integrated III–V quantum dots

Author

Yan Chen, Jiaxiang Zhang, Michael Zopf, Kyubong Jung, Yang Zhang, Robert Keil, Fei Ding, and Oliver G. Schmidt

Subjects

Science

Abstract

Deterministic sources of entangled photons are important for photonic quantum networks, but many applications are only possible when their wavelengths are tunable. Here, the authors use on-chip strain engineering to demonstrate such a source with silicon-integrated InAs/GaAs quantum dots.

Published

2016

39. Towards Bacteria Counting in DI Water of Several Microliters or Growing Suspension Using Impedance Biochips

Author

Mahdi Kiani, Astrid Tannert, Nan Du, Uwe Hübner, Ilona Skorupa, Danilo Bürger, Xianyue Zhao, Daniel Blaschke, Lars Rebohle, Charaf Cherkouk, Ute Neugebauer, Oliver G. Schmidt, and Heidemarie Schmidt

Subjects

bacterial cell counting, biochips, impedance spectroscopy, Escherichia coli, electrical equivalent circuit model, Biotechnology, TP248.13-248.65

Abstract

We counted bacterial cells of E. coli strain K12 in several-microliter DI water or in several-microliter PBS in the low optical density (OD) range (OD = 0.05–1.08) in contact with the surface of Si-based impedance biochips with ring electrodes by impedance measurements. The multiparameter fit of the impedance data allowed calibration of the impedance data with the concentration cb of the E. coli cells in the range of cb = 0.06 to 1.26 × 109 cells/mL. The results showed that for E. coli in DI water and in PBS, the modelled impedance parameters depend linearly on the concentration of cells in the range of cb = 0.06 to 1.26 × 109 cells/mL, whereas the OD, which was independently measured with a spectrophotometer, was only linearly dependent on the concentration of the E. coli cells in the range of cb = 0.06 to 0.50 × 109 cells/mL.

Published

2020

40. Disturbing-Free Determination of Yeast Concentration in DI Water and in Glucose Using Impedance Biochips

Author

Mahdi Kiani, Nan Du, Manja Vogel, Johannes Raff, Uwe Hübner, Ilona Skorupa, Danilo Bürger, Stefan E. Schulz, Oliver G. Schmidt, Daniel Blaschke, and Heidemarie Schmidt

Subjects

biochips, impedance spectroscopy, yeast saccharomyces cerevisiae, electrical equivalent circuit, biomaterial, biosensing, Biotechnology, TP248.13-248.65

Abstract

Deionized water and glucose without yeast and with yeast (Saccharomyces cerevisiae) of optical density OD600 that ranges from 4 to 16 has been put in the ring electrode region of six different types of impedance biochips and impedance has been measured in dependence on the added volume (20, 21, 22, 23, 24, 25 µL). The measured impedance of two out of the six types of biochips is strongly sensitive to the addition of both liquid without yeast and liquid with yeast and modelled impedance reveals a linear relationship between the impedance model parameters and yeast concentration. The presented biochips allow for continuous impedance measurements without interrupting the cultivation of the yeast. A multiparameter fit of the impedance model parameters allows for determining the concentration of yeast (cy) in the range from cy = 3.3 × 107 to cy = 17 × 107 cells/mL. This work shows that independent on the liquid, i.e., DI water or glucose, the impedance model parameters of the two most sensitive types of biochips with liquid without yeast and with liquid with yeast are clearly distinguishable for the two most sensitive types of biochips.

Published

2020

41. Strong Ferromagnetically-Coupled Spin Valve Sensor Devices for Droplet Magnetofluidics

Author

Gungun Lin, Denys Makarov, and Oliver G. Schmidt

Subjects

droplet microfluidics, spin valve, ferromagnetic coupling, high field sensing, ferrofluid, Chemical technology, TP1-1185

Abstract

We report a magnetofluidic device with integrated strong ferromagnetically-coupled and hysteresis-free spin valve sensors for dynamic monitoring of ferrofluid droplets in microfluidics. The strong ferromagnetic coupling between the free layer and the pinned layer of spin valve sensors is achieved by reducing the spacer thickness, while the hysteresis of the free layer is eliminated by the interplay between shape anisotropy and the strength of coupling. The increased ferromagnetic coupling field up to the remarkable 70 Oe, which is five-times larger than conventional solutions, brings key advantages for dynamic sensing, e.g., a larger biasing field giving rise to larger detection signals, facilitating the operation of devices without saturation of the sensors. Studies on the fundamental effects of an external magnetic field on the evolution of the shape of droplets, as enabled by the non-visual monitoring capability of the device, provides crucial information for future development of a magnetofluidic device for multiplexed assays.

Published

2015

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

Author

Peter Robaschik, Pablo F. Siles, Daniel Bülz, Peter Richter, Manuel Monecke, Michael Fronk, Svetlana Klyatskaya, Daniel Grimm, Oliver G. Schmidt, Mario Ruben, Dietrich R. T. Zahn, and Georgeta Salvan

Subjects

current sensing AFM, ellipsometry, spintronics, TbPc2, transport properties, Technology, Chemical technology, TP1-1185, Science, Physics, QC1-999

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

43. P-N Junction-Based Si Biochips with Ring Electrodes for Novel Biosensing Applications

Author

Mahdi Kiani, Nan Du, Manja Vogel, Johannes Raff, Uwe Hübner, Ilona Skorupa, Danilo Bürger, Stefan E. Schulz, Oliver G. Schmidt, and Heidemarie Schmidt

Subjects

biochips, impedance spectroscopy, electrical equivalent circuit, biomaterial, lysinibacillus sphaericus jg-a12, Biotechnology, TP248.13-248.65

Abstract

In this work, we report on the impedance of p-n junction-based Si biochips with gold ring top electrodes and unstructured platinum bottom electrodes which allows for counting target biomaterial in a liquid-filled ring top electrode region. The systematic experiments on p-n junction-based Si biochips fabricated by two different sets of implantation parameters (i.e. biochips PS5 and BS5) are studied, and the comparable significant change of impedance characteristics in the biochips in dependence on the number of bacteria suspension, i.e., Lysinibacillus sphaericus JG-A12, in Deionized water with an optical density at 600 nm from OD600 = 4–16 in the electrode ring region is demonstrated. Furthermore, with the help of the newly developed two-phase electrode structure, the modeled capacitance and resistance parameters of the electrical equivalent circuit describing the p-n junction-based biochips depend linearly on the number of bacteria in the ring top electrode region, which successfully proves the potential performance of p-n junction-based Si biochips in observing the bacterial suspension. The proposed p-n junction-based biochips reveal perspective applications in medicine and biology for diagnosis, monitoring, management, and treatment of diseases.

Published

2019

44. Single pairing spike-timing dependent plasticity in BiFeO3 memristors with a time window of 25ms to 125µs

Author

Nan eDu, Mahdi eKiani, Christian G Mayr, Tiangui eYou, Danilo eBürger, Ilona eSkorupa, Oliver G. Schmidt, and Heidemarie eSchmidt

Subjects

memory consolidation, artificial synapse, low-power device, Learning window, BiFeO3 memristor, single pairing STDP, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Memristive devices are popular among neuromorphic engineers for their ability to emulate forms of spike-driven synaptic plasticity by applying specific voltage and current waveforms at their two terminals. In this paper, we investigate spike-timing dependent plasticity (STDP) with a single pairing of one presynaptic voltage spike and one postsynaptic voltage spike in a BiFeO3 memristive device. In most memristive materials the learning window is primarily a function of the material characteristics and not of the applied waveform. In contrast, we show that the analog resistive switching of the developed artificial synapses allows to adjust the learning time constant of the STDP function from 25ms to 125μs via the duration of applied voltage spikes. Also, as the induced weight change may degrade, we investigate the remanence of the resistance change for several hours after analog resistive switching, thus emulating the processes expected in biological synapses. As the power consumption is a major constraint in neuromorphic circuits, we show methods to reduce the consumed energy per setting pulse to only 4.5 pJ in the developed artificial synapses.

Published

2015

45. Precise Localization and Control of Catalytic Janus Micromotors Using Weak Magnetic Fields

Author

Islam S. M. Khalil, Veronika Magdanz, Samuel Sanchez, Oliver G. Schmidt, and Sarthak Misra

Subjects

Electronics, TK7800-8360, Electronic computers. Computer science, QA75.5-76.95

Abstract

We experimentally demonstrate the precise localization of spherical Pt-Silica Janus micromotors (diameter 5 μm) under the influence of controlled magnetic fields. First, we control the motion of the Janus micromotors in two-dimensional (2D) space. The control system achieves precise localization within an average region-of-convergence of 7 μm. Second, we show that these micromotors provide sufficient propulsion force, allowing them to overcome drag and gravitational forces and move both downwards and upwards. This propulsion is studied by moving the micromotors in three-dimensional (3D) space. The micromotors move downwards and upwards at average speeds of 19.1 μm/s and 9.8 μm/s, respectively. Moreover, our closed-loop control system achieves localization in 3D space within an average region-of-convergence of 6.3 μm in diameter. The precise motion control and localization of the Janus micromotors in 2D and 3D spaces provides broad possibilities for nanotechnology applications.

Published

2015

46. Lab-In-A-Tube: From Molecule to Cell Detection

Author

Mariana Medina-Sánchez, Sonja M. Weiz, Aleksandr Egunov, Bergoi Ibarlucea, Larysa Baraban, Gianaurelio Cuniberti, and Oliver G. Schmidt

Subjects

n/a, General Works

Abstract

The intriguing properties of self-assembled microtubular architectures open new possibilities to develop three-dimensional functional devices for molecule and cell analysis. [...]

Published

2017

47. Transport in ZnCoO thin films with stable bound magnetic polarons

Author

Tim Kaspar, Jan Fiedler, Ilona Skorupa, Danilo Bürger, Oliver G. Schmidt, and Heidemarie Schmidt

Subjects

Biotechnology, TP248.13-248.65, Physics, QC1-999

Abstract

Diluted magnetic ZnCoO films with 5 at.% Co have been fabricated by pulsed laser deposition on c-plane sapphire substrates and Schottky and Ohmic contacts have been prepared in top-top configuration. The diode current is significantly reduced after the diode has been subjected to an external magnetic field. In the reverse bias range the corresponding positive magnetoresistance is persistent and amounts to more than 1800% (50 K), 240% (30 K), and 50% (5 K). This huge magnetoresistance can be attributed to the large internal magnetic field in depleted ZnCoO with ferromagnetic exchange between stable bound magnetic polarons.

Published

2014

48. Correction: Corrigendum: High yield and ultrafast sources of electrically triggered entangled-photon pairs based on strain-tunable quantum dots

Author

Jiaxiang Zhang, Johannes S. Wildmann, Fei Ding, Rinaldo Trotta, Yongheng Huo, Eugenio Zallo, Daniel Huber, Armando Rastelli, and Oliver G. Schmidt

Subjects

Science

Abstract

Nature Communications 6: Article number: 10067 (2015); Published: 1 December 2015; Updated: 11 May 2016 This Article contains errors in the labelling of the ticks of the x axis in Fig. 5. In panel a, the x axis values should have been labelled ‘−10 ns’ and ‘10 ns’ rather than ‘−5 ns’ and ‘5 ns’. In panels b and c, the x axis values should have been labelled ‘−25 ns’ and ‘25 ns’ rather than ‘−10 ns’ and ‘10 ns’.

Published

2016

49. Electroforming-free Memristors for Hardware Security Primitives.

Author

Nan Du, Mahdi Kiani, Xianyue Zhao, Danilo Bürger, Oliver G. Schmidt, Ramona Ecke, Stefan E. Schulz, Heidemarie Schmidt, and Ilia Polian

Published

2019

50. Spermbots: Concept and Applications.

Author

Mariana Medina-Sánchez, Veronika Magdanz, Lukas Schwarz, Haifeng Xu, and Oliver G. Schmidt

Published

2017