Your search keyword '"Sensors and biosensors"' showing total 238 results

1. MIPs-Based Sensors and Biosensors for Environmental Monitoring

Author

Yang, Lanqing, Ge, Kun, Qadir, Muhammad Farhan, Wang, Xiaomin, Gu, Ying, Yang, Yukun, Patra, Santanu, editor, and Sillanpaa, Mika, editor

Published

2024

2. Spinel Sensors and Biosensors

Author

Abou Hammad, Ali B., El Nahrawy, Amany M., Ali, Gomaa A. M., editor, Chong, Kwok Feng, editor, and Makhlouf, Abdel Salam H., editor

Published

2024

3. Probing many-body dynamics in a two-dimensional dipolar spin ensemble

Author

Davis, EJ, Ye, B, Machado, F, Meynell, SA, Wu, W, Mittiga, T, Schenken, W, Joos, M, Kobrin, B, Lyu, Y, Wang, Z, Bluvstein, D, Choi, S, Zu, C, Jayich, AC Bleszynski, and Yao, NY

Subjects

Quantum Physics, Physical Sciences, Magnetic properties and materials, Quantum metrology, Quantum simulation, Sensors and biosensors, Mathematical Sciences, Fluids & Plasmas, Mathematical sciences, Physical sciences

Abstract

The most direct approach for characterizing the quantum dynamics of a strongly interacting system is to measure the time evolution of its full many-body state. Despite the conceptual simplicity of this approach, it quickly becomes intractable as the system size grows. An alternate approach is to think of the many-body dynamics as generating noise, which can be measured by the decoherence of a probe qubit. Here we investigate what the decoherence dynamics of such a probe tells us about the many-body system. In particular, we utilize optically addressable probe spins to experimentally characterize both static and dynamical properties of strongly interacting magnetic dipoles. Our experimental platform consists of two types of spin defects in nitrogen delta-doped diamond: nitrogen-vacancy colour centres, which we use as probe spins, and a many-body ensemble of substitutional nitrogen impurities. We demonstrate that the many-body system's dimensionality, dynamics and disorder are naturally encoded in the probe spins' decoherence profile. Furthermore, we obtain direct control over the spectral properties of the many-body system, with potential applications in quantum sensing and simulation.

Published

2023

4. Recent Advances in Electrochemical Sensor and Biosensors for Environmental Contaminants

Author

Mei, Li-Ping, Song, Pei, Zhu, Yuan-Cheng, Ruan, Yi-Fan, Shi, Xiao-Mei, Zhao, Wei-Wei, Xu, Jing-Juan, Chen, Hong-Yuan, Prasad, Ram, Series Editor, Inamuddin, editor, and Asiri, Abdullah M., editor

Published

2020

5. Green Synthesis of NanoMaterials for BioSensing

Author

García-Guzmán, Juan José, López-Iglesias, David, Bellido-Milla, Dolores, Palacios-Santander, José María, Cubillana-Aguilera, Laura, Prasad, Ram, Series Editor, Inamuddin, editor, and Asiri, Abdullah M., editor

Published

2020

6. UV-activated ZnO films on a flexible substrate for room temperature O2 and H2O sensing

Author

Ivanov, Ilia [Oak Ridge National Lab. (ORNL), Oak Ridge, TN (United States). Center for Nanophase Materials Science and Inst. for Functional Imaging of Materials] (ORCID:0000000267262502)

Published

2017

7. Real-time Crystal Growth Visualization and Quantification by Energy-Resolved Neutron Imaging

Author

Bourret, Edith [Lawrence Berkeley National Lab. (LBNL), Berkeley, CA (United States)]

Published

2017

8. State of the Art in Alcohol Sensing with 2D Materials

Author

Ramin Boroujerdi, Amor Abdelkader, and Richard Paul

Subjects

Sensors and biosensors, Alcohol probes, Electrochemical detectors, Ethanol metabolites, 2D materials, Technology

Abstract

Abstract Since the discovery of graphene, the star among new materials, there has been a surge of attention focused on the monatomic and monomolecular sheets which can be obtained by exfoliation of layered compounds. Such materials are known as two-dimensional (2D) materials and offer enormous versatility and potential. The ultimate single atom, or molecule, thickness of the 2D materials sheets provides the highest surface to weight ratio of all the nanomaterials, which opens the door to the design of more sensitive and reliable chemical sensors. The variety of properties and the possibility of tuning the chemical and surface properties of the 2D materials increase their potential as selective sensors, targeting chemical species that were previously difficult to detect. The planar structure and the mechanical flexibility of the sheets allow new sensor designs and put 2D materials at the forefront of all the candidates for wearable applications. When developing sensors for alcohol, the response time is an essential factor for many industrial and forensic applications, particularly when it comes to hand-held devices. Here, we review recent developments in the applications of 2D materials in sensing alcohols along with a study on parameters that affect the sensing capabilities. The review also discusses the strategies used to develop the sensor along with their mechanisms of sensing and provides a critique of the current limitations of 2D materials-based alcohol sensors and an outlook for the future research required to overcome the challenges.

Published

2020

9. Organ-On-A-Chip Devices: Technology Progress and Challenges.

Author

Obeid PJ, Yammine P, El-Nakat H, Kassab R, Tannous T, Nasr Z, Maarawi T, Dahdah N, El Safadi A, Mansour A, and Chmayssem A

Abstract

Organ-On-a-Chip (OOC) is a multichannel 3D-microfluidic cell-culture system incorporated in a chip that simulates the behavior of an organ. This technology relies on a multidisciplinary science that benefits from and contributes in the progress of many fields including microbiology, microfluidics, biomaterials, and bioengineering. This review article summarizes the progress and achievements of various organ-on-chip technologies. It highlights the significant advantages of this technology in terms of reducing animal testing and providing personalized medical responses. In addition, this paper demonstrates how OOC is becoming a promising and powerful tool in pharmaceutical research to combat diseases. It predicts not only the effects of drugs on the target organs but also, using body-on-a-chip systems, it may provide insights into the side effects of the drug delivery on the other organs. Likewise, the models used for the construction of various organ-on-a-chip devices are investigated along with the design and materials of microfluidic devices. For each OOC, the integrated monitoring devices within the chips (e. g., sensors and biosensors) are discussed. We also discuss the evolution of FDA regulations and the potential in the near future for integrating OOCs into protocols that support and reduce the need for and the failure rates in preclinical and clinical studies., (© 2024 Wiley-VCH GmbH.)

Published

2024

10. Electrochemical Impedance Spectroscopy in the Characterisation and Application of Modified Electrodes for Electrochemical Sensors and Biosensors

Author

Christopher M. A. Brett

Subjects

electrochemical impedance spectroscopy, modified electrodes, constant phase element, charge transfer resistance, Warburg impedance, sensors and biosensors, Organic chemistry, QD241-441

Abstract

Electrochemical impedance spectroscopy is finding increasing use in electrochemical sensors and biosensors, both in their characterisation, including during successive phases of sensor construction, and in application as a quantitative determination technique. Much of the published work continues to make little use of all the information that can be furnished by full physical modelling and analysis of the impedance spectra, and thus does not throw more than a superficial light on the processes occurring. Analysis is often restricted to estimating values of charge transfer resistances without interpretation and ignoring other electrical equivalent circuit components. In this article, the important basics of electrochemical impedance for electrochemical sensors and biosensors are presented, focussing on the necessary electrical circuit elements. This is followed by examples of its use in characterisation and in electroanalytical applications, at the same time demonstrating how fuller use can be made of the information obtained from complete modelling and analysis of the data in the spectra, the values of the circuit components and their physical meaning. The future outlook for electrochemical impedance in the sensing field is discussed.

Published

2022

11. Determination of Drugs in Clinical Trials: Current Status and Outlook

Author

Babak Tavana and Aicheng Chen

Subjects

clinical trials, analytical methods, drugs, sensors and biosensors, MEMS, Chemical technology, TP1-1185

Abstract

All pharmaceutical drugs, vaccines, cosmetic products, and many medical breakthroughs must first be approved through clinical research and trials before advancing to standard practice or entering the marketplace. Clinical trials are sets of tests that are required to determine the safety and efficacy of pharmaceutical compounds, drugs, and treatments. There is one pre-phase and four main clinical phase requirements that every drug must pass to obtain final approval. Analytical techniques play a unique role in clinical trials for measuring the concentrations of pharmaceutical compounds in biological matrices and monitoring the conditions of patients (or volunteers) during various clinical phases. This review focuses on recent analytical methods that are employed to determine the concentrations of drugs and medications in biological matrices, including whole blood, plasma, urine, and breast milk. Four primary analytical techniques (extraction, spectroscopy, chromatography, and electrochemical) are discussed, and their advantages and limitations are assessed. Subsequent to a survey of evidence and results, it is clear that microelectromechanical system (MEMS) based electrochemical sensor and biosensor technologies exhibit several notable advantages over other analytical methods, and their future prospects are discussed.

Published

2022

12. State of the Art in Alcohol Sensing with 2D Materials.

Author

Boroujerdi, Ramin, Abdelkader, Amr, and Paul, Richard

Subjects

*CHEMICAL detectors, *ALCOHOL, *REACTION time, *CHEMICAL species

Abstract

Highlights: A current review on the applications of graphene and other two-dimensional (2D) materials in alcohol detection. A thorough discussion on the fundamental principles and the advantages of using 2D materials in sensing alcohol. Critical discussion of the current limitations of alcohol sensors and the role of 2D materials in addressing the challenges. Since the discovery of graphene, the star among new materials, there has been a surge of attention focused on the monatomic and monomolecular sheets which can be obtained by exfoliation of layered compounds. Such materials are known as two-dimensional (2D) materials and offer enormous versatility and potential. The ultimate single atom, or molecule, thickness of the 2D materials sheets provides the highest surface to weight ratio of all the nanomaterials, which opens the door to the design of more sensitive and reliable chemical sensors. The variety of properties and the possibility of tuning the chemical and surface properties of the 2D materials increase their potential as selective sensors, targeting chemical species that were previously difficult to detect. The planar structure and the mechanical flexibility of the sheets allow new sensor designs and put 2D materials at the forefront of all the candidates for wearable applications. When developing sensors for alcohol, the response time is an essential factor for many industrial and forensic applications, particularly when it comes to hand-held devices. Here, we review recent developments in the applications of 2D materials in sensing alcohols along with a study on parameters that affect the sensing capabilities. The review also discusses the strategies used to develop the sensor along with their mechanisms of sensing and provides a critique of the current limitations of 2D materials-based alcohol sensors and an outlook for the future research required to overcome the challenges. [ABSTRACT FROM AUTHOR]

Published

2020

13. Sol–Gel Method Applied to Crystalline Materials

Author

Alessandro Dell’Era and Michelina Catauro

Subjects

biomaterials, nanoparticles, thin films and coatings, organic–inorganic hybrid materials, catalysts, sensors and biosensors, Crystallography, QD901-999

Abstract

Sol–gel chemistry is a versatile synthesis used to produce modern materials at near-room temperature [...]

Published

2021

14. Strategies to control humidity sensitivity of azobenzene isomerisation kinetics in polymer thin films.

Author

Vesamäki S, Meteling H, Nasare R, Siiskonen A, Patrakka J, Roas-Escalona N, Linder M, Virkki M, and Priimagi A

Abstract

Azobenzenes are versatile photoswitches that garner interest in applications ranging from photobiology to energy storage. Despite their great potential, transforming azobenzene-based discoveries and proof-of-concept demonstrations from the lab to the market is highly challenging. Herein we give an overview of a journey that started from a discovery of hydroxyazobenzene's humidity sensitive isomerisation kinetics, developed into commercialization efforts of azobenzene-containing thin film sensors for optical monitoring of the relative humidity of air, and arrives to the present work aiming for better design of such sensors by understanding the different factors affecting the humidity sensitivity. Our concept is based on thermal isomerisation kinetics of tautomerizable azobenzenes in polymer matrices which, using pre-defined calibration curves, can be converted to relative humidity at known temperature. We present a small library of tautomerizable azobenzenes exhibiting humidity sensitive isomerisation kinetics in hygroscopic polymer films. We also investigate how water absorption properties of the polymer used, and the isomerisation kinetics are linked and how the azobenzene content in the thin film affects both properties. Based on our findings we propose simple strategies for further development of azobenzene-based optical humidity sensors., Competing Interests: Competing interestsThe authors declare no competing interests., (© The Author(s) 2024.)

Published

2024

15. Hybrid nanocomposites modified on sensors and biosensors for the analysis of food functionality and safety.

Author

Lu, Lin, Zhu, Zhiwei, and Hu, Xianqiao

Subjects

*FOOD chemistry, *FOOD safety, *BIOSENSORS, *DETECTORS, *CONVENIENCE foods

Abstract

Sensors and biosensors with the advantages of rapidness and convenience have been developed for food analysis. Nanomaterials have been deeply studied for the modification of sensors. Hybrid nanocomposite which is superior to single nanomaterial has been used as an excellent modification instead of nanomaterial for sensors and biosensors. The classification of hybrid nanocomposites modified on sensors and biosensors is a rare topic for food analysis. Hybrid nanocomposites were divided into three classes namely binary hybrid nanocomposite, ternary hybrid nanocomposite and multiple hybrid nanocomposite. In this review, the synergistic effects, interactions and mechanisms of hybrid nanocomposites for food sensors were elaborated, and the types in each class primely for biointegration were pointed out. Furthermore, the nanocomposites possessing the universal application both for food functionality and safety were highlighted. There are various advantages in hybrid nanocomposites modified on sensors and biosensors for food functionality and safety. Several nanocomposites possessing the universal application both for food functionality and safety can be considered to establish a multipurpose platform for simultaneously ensuring food functionality and monitoring food safety. • Three classes of hybrid nanocomposites on food (bio)sensors were summarized. • The synergistic effect of hybrid nanocomposite originates from each component. • Co-applicable nanocomposites can be co-used for food functionality and safety. [ABSTRACT FROM AUTHOR]

Published

2019

16. Chemically modified optical fibers in advanced technology: An overview.

Author

Shukla, S.K., Kushwaha, Chandra Shekhar, Guner, Tugrul, and Demir, Mustafa M.

Subjects

*OPTICAL fibers, *MAGNETIC resonance imaging, *GREEN technology, *ENVIRONMENTAL monitoring, *OPTICAL properties

Abstract

Graphical abstract Highlights • The significance of chemically modified optical fiber have been presented. • These fiber bears catalytic, adsorption and optical properties. • It advances optical based sensing, biomedical and environmental technology. Abstract In recent years, chemically modified optical fibers have widely used for development of several advanced chemical and biosensors, biomedical technology and environmental monitoring. The chemically modified optical fiber bears several valuable properties like energy loss, catalytic behaviour, refractive index, and mechanical strength to advance the optical fiber technology. In this article, we reviewed the chemically-modified optical fiber and their applications in different optical fiber-based technologies. The basics of optical fiber and their modification are discussed along with the adopted methodologies. The advancements in different optical fiber based technologies viz sensing, imaging, tomography, magnetic resonance imaging, photodynamic therapy, optogenics, surgery and environmental monitoring are discussed in the light of the contribution of chemically modified optical fibers. In conclusion, success and challenges for the use of chemically modified-optical fiber are presented on the basis of existing literature. [ABSTRACT FROM AUTHOR]

Published

2019

17. Research on a high-sensitivity asymmetric metamaterial structure and its application as microwave sensor

Author

Yunhao Cao, Cunjun Ruan, Kanglong Chen, and Xingyun Zhang

Subjects

Multidisciplinary, Science, Medicine, Characterization and analytical techniques, Article, Sensors and biosensors

Abstract

In this paper, an Asymmetric Electric Split-Ring Resonator (AESRR) metamaterial structure is proposed to explore the interaction between metamaterials and electromagnetic waves with the influence of Fano resonance on electromagnetic properties. With the symmetry of basic electric Split-Ring Resonator (eSRR) being broken, a new Fano resonant peak appears at around 11.575 GHz and this peak is very sensitive to the dielectric environment. Based on the proposed high sensitivity of AESRR, a microwave sensor based on a 13 × 13 arrays of AESRR was designed and verified using printed circuit board (PCB) technology. T-shape channel was integrated to the sensor by grooving in the FR-4 substrate which improved the integration and provided the feasibility of liquids detection. Seven organic liquids and four dielectric substrates are measured by this sensor. The measured results show the transmission frequency shifts from 11.575 to 11.150 GHz as the liquid samples permittivity changes from 1 to 7 and the transmission frequency shifts from 11.575 to 8.260 GHz as the solid substrates permittivity changes from 1 to 9. The results have proven the improved sensitivity and the larger frequency shift ∆f on material under test (MUTs) compared with the conventional reported sensor. The relative permittivity of liquid samples and solid samples can be obtained by establishing approximate models in CST, respectively. Two transcendental equations derived from measured results are proposed to predict the relative permittivity of liquid samples and solids samples. The accuracy and reliability of measured results and predicted results are numerically verified by comparing them with literature values. Thus, the proposed sensor has many advantages, such as low-cost, high-sensitivity, high-robustness, and extensive detecting range, which provided a great potential to be implemented in a lab-on-a-chip sensor system in the future.

Published

2022

18. Application of Nanostructured Carbon-Based Electrochemical (Bio)Sensors for Screening of Emerging Pharmaceutical Pollutants in Waters and Aquatic Species: A Review

Author

Álvaro Torrinha, Thiago M. B. F. Oliveira, Francisco W.P. Ribeiro, Adriana N. Correia, Pedro Lima-Neto, and Simone Morais

Subjects

sensors and biosensors, carbon nanomaterials, environment, aquatic fauna, waters, Chemistry, QD1-999

Abstract

Pharmaceuticals, as a contaminant of emergent concern, are being released uncontrollably into the environment potentially causing hazardous effects to aquatic ecosystems and consequently to human health. In the absence of well-established monitoring programs, one can only imagine the full extent of this problem and so there is an urgent need for the development of extremely sensitive, portable, and low-cost devices to perform analysis. Carbon-based nanomaterials are the most used nanostructures in (bio)sensors construction attributed to their facile and well-characterized production methods, commercial availability, reduced cost, high chemical stability, and low toxicity. However, most importantly, their relatively good conductivity enabling appropriate electron transfer rates—as well as their high surface area yielding attachment and extraordinary loading capacity for biomolecules—have been relevant and desirable features, justifying the key role that they have been playing, and will continue to play, in electrochemical (bio)sensor development. The present review outlines the contribution of carbon nanomaterials (carbon nanotubes, graphene, fullerene, carbon nanofibers, carbon black, carbon nanopowder, biochar nanoparticles, and graphite oxide), used alone or combined with other (nano)materials, to the field of environmental (bio)sensing, and more specifically, to pharmaceutical pollutants analysis in waters and aquatic species. The main trends of this field of research are also addressed.

Published

2020

19. Flexible mechanical metamaterials enabling soft tactile sensors with multiple sensitivities at multiple force sensing ranges

Author

Alireza Mohammadi, Ying Tan, Peter Choong, and Denny Oetomo

Subjects

Multidisciplinary, Polymers, Science, Medicine, Article, Mechanical engineering, Sensors and biosensors, Composites

Abstract

The majority of existing tactile sensors are designed to measure a particular range of force with a fixed sensitivity. However, some applications require tactile sensors with multiple task-relevant sensitivities at multiple ranges of force sensing. Inspired by the human tactile sensing capability, this paper proposes a novel soft tactile sensor based on mechanical metamaterials which exhibits multiple sensitivity regimes due to the step-by-step locking behaviour of its heterogenous multi-layered structure. By tuning the geometrical design parameters of the collapsible layers, each layer experiences locking behaviour under different ranges of force which provides different sensitivity of the sensor at different force magnitude. The integration of a magnetic-based transduction method with the proposed structure results in high design degrees of freedom for realising the desired contact force sensitivities and corresponding force sensing ranges. A systematic design procedure is proposed to select appropriate design parameters to produce the desired characteristics. Two example designs of the sensor structure were fabricated using widely available benchtop 3D printers and tested for their performance. The results showed the capability of the sensor in providing the desired characteristics in terms of sensitivity and force range and being realised in different shapes, sizes and number of layers in a single structure. The proposed multi-sensitivity soft tactile sensor has a great potential to be used in a wide variety of applications where different sensitivities of force measurement is required at different ranges of force magnitudes, from robotic manipulation and human–machine interaction to biomedical engineering and health-monitoring.

Published

2021

20. Intrareticular charge transfer regulated electrochemiluminescence of donor–acceptor covalent organic frameworks

Author

Rengan Luo, Ningning Wang, Kai Xi, Huangxian Ju, Jiarui Yang, Haifeng Lv, Qiaobo Liao, Jianping Lei, Yang Li, and Xiaojun Wu

Subjects

endocrine system, Multidisciplinary, Materials science, Polymers, Science, General Physics and Astronomy, General Chemistry, Photochemistry, Triphenylamine, Acceptor, Article, Sensors and biosensors, General Biochemistry, Genetics and Molecular Biology, chemistry.chemical_compound, chemistry, Covalent bond, Electrochemiluminescence, Density functional theory, Benzene, Covalent organic framework, Triazine

Abstract

The control of charge transfer between radical anions and cations is a promising way for decoding the emission mechanism in electrochemiluminescence (ECL) systems. Herein, a type of donor-acceptor (D-A) covalent organic framework (COF) with triphenylamine and triazine units is designed as a highly efficient ECL emitter with tunable intrareticular charge transfer (IRCT). The D-A COF demonstrates 123 folds enhancement in ECL intensity compared with its benzene-based COF with small D-A contrast. Further, the COF’s crystallinity- and protonation-modulated ECL behaviors confirm ECL dependence on intrareticular charge transfer between donor and acceptor units, which is rationalized by density functional theory. Significantly, dual-peaked ECL patterns of COFs are achieved through an IRCT mediated competitive oxidation mechanism: the coreactant-mediated oxidation at lower potential and the direct oxidation at higher potential. This work provides a new fundamental and approach to improve the ECL efficiency for designing next-generation ECL devices., Controlling the charge transfer between radical anions and cations is a promising way to tune the emission mechanism in electrochemiluminescence (ECL) systems. Here, the authors report a donor-acceptor based covalent organic framework, using triphenylamine and triazine building units, and demonstrate efficient ECL based on an adjustable intrareticular charge transfer.

Published

2021

21. Microwave brain imaging system to detect brain tumor using metamaterial loaded stacked antenna array

Author

Amran Hossain, Mohammad Tariqul Islam, Gan Kok Beng, Saad Bin Abul Kashem, Mohamed S. Soliman, Norbahiah Misran, and Muhammad E. H. Chowdhury

Subjects

Multidisciplinary, Brain Neoplasms, Brain, Humans, Brain imaging, Neuroimaging, Head and neck cancer, Microwaves, Biological physics, Head, Sensors and biosensors

Abstract

In this paper, proposes a microwave brain imaging system to detect brain tumors using a metamaterial (MTM) loaded three-dimensional (3D) stacked wideband antenna array. The antenna is comprised of metamaterial-loaded with three substrate layers, including two air gaps. One 1 x 4 MTM array element is used in the top layer and middle layer, and one 3 x 2 MTM array element is used in the bottom layer. The MTM array elements in layers are utilized to enhance the performance concerning antenna's efficiency, bandwidth, realized gain, radiation directionality in free space and near the head model. The antenna is fabricated on cost-effective Rogers RT5880 and RO4350B substrate, and the optimized dimension of the antenna is 50 x 40 x 8.66 mm3. The measured results show that the antenna has a fractional bandwidth of 79.20% (1.37-3.16 GHz), 93% radiation efficiency, 98% high fidelity factor, 6.67 dBi gain, and adequate field penetration in the head tissue with a maximum of 0.0018 W/kg specific absorption rate. In addition, a 3D realistic tissue-mimicking head phantom is fabricated and measured to verify the performance of the antenna. Later, a nine-antenna array-based microwave brain imaging (MBI) system is implemented and investigated by using phantom model. After that, the scattering parameters are collected, analyzed, and then processed by the Iteratively Corrected delay-multiply-and-sum algorithm to detect and reconstruct the brain tumor images. The imaging results demonstrated that the implemented MBI system can successfully detect the target benign and malignant tumors with their locations inside the brain. 2022, The Author(s). This research work is supported by the Universiti Kebangsaan Malaysia (UKM) research Grant DIP-2020-009. Scopus

Published

2022

22. Determination of X-ray detection limit and applications in perovskite X-ray detectors

Author

Wanyi Nie, Neil R. Taylor, L. S. Pan, Lei Cao, and Shreetu Shrestha

Subjects

Physics, Photocurrent, Detection limit, Multidisciplinary, business.industry, Science, Detector, X-ray detector, Imaging and sensing, General Physics and Astronomy, General Chemistry, Article, Sensors and biosensors, General Biochemistry, Genetics and Molecular Biology, Photonic crystals, Optics, Optical sensors, X-rays, Figure of merit, Sensitivity (control systems), Limit (mathematics), business, Dark current

Abstract

X-ray detection limit and sensitivity are important figure of merits for perovskite X-ray detectors, but literatures lack a valid mathematic expression for determining the lower limit of detection for a perovskite X-ray detector. In this work, we present a thorough analysis and new method for X-ray detection limit determination based on a statistical model that correlates the dark current and the X-ray induced photocurrent with the detection limit. The detection limit can be calculated through the measurement of dark current and sensitivity with an easy-to-follow practice. Alternatively, the detection limit may also be obtained by the measurement of dark current and photocurrent when repeatedly lowering the X-ray dose rate. While the material quality is critical, we show that the device architecture and working mode also have a significant influence on the sensitivity and the detection limit. Our work establishes a fair comparison metrics for material and detector development., The limit of X-ray detection is an important figure of merit for X-ray detectors, yet the suitability of method adopted from Currie’s 1968 paper and the following international standard is in doubt. Here, the authors propose a statistical model that correlates dark current and photo-current, show how it can be used to determine detection limit.

Published

2021

23. Nano-biosupercapacitors enable autarkic sensor operation in blood

Author

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

Subjects

Science, Electronic devices, Supercapacitors, Sensors and biosensors

Abstract

Today���s smallest energy storage devices for in-vivo applications are larger than 3 mm3 and lack the ability to continuously drive the complex functions of smart dust electronic and microrobotic systems. Here, we create a tubular biosupercapacitor occupying a mere volume of 1/1000 mm3 (=1 nanoliter), yet delivering up to 1.6 V in blood. The tubular geometry of this nano-biosupercapacitor provides efficient self-protection against external forces from pulsating blood or muscle contraction. Redox enzymes and living cells, naturally present in blood boost the performance of the device by 40% and help to solve the self-discharging problem persistently encountered by miniaturized supercapacitors. At full capacity, the nano-biosupercapacitors drive a complex integrated sensor system to measure the pH-value in blood. This demonstration opens up opportunities for next generation intravascular implants and microrobotic systems operating in hard-to-reach small spaces deep inside the human body.

Published

2021

24. Large-area synthesis of nanoscopic catalyst-decorated conductive MOF film using microfluidic-based solution shearing

Author

Dong Soo Kim, Hanul Kim, Calvin Andreas Hutomo, Siyoung Q. Choi, Tae-Hoon Lee, Jin-Oh Kim, Steve Park, Chungseong Park, Il-Doo Kim, and Won-Tae Koo

Subjects

Materials science, Science, Microfluidics, General Physics and Astronomy, Nanotechnology, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, General Biochemistry, Genetics and Molecular Biology, Article, Organic-inorganic nanostructures, Thin film, Porosity, Nanoscopic scale, Shearing (physics), Multidisciplinary, General Chemistry, 021001 nanoscience & nanotechnology, Sensors and biosensors, 0104 chemical sciences, Design, synthesis and processing, Nanometre, Metal-organic framework, 0210 nano-technology, Porous medium

Abstract

Conductive metal-organic framework (C-MOF) thin-films have a wide variety of potential applications in the field of electronics, sensors, and energy devices. The immobilization of various functional species within the pores of C-MOFs can further improve the performance and extend the potential applications of C-MOFs thin films. However, developing facile and scalable synthesis of high quality ultra-thin C-MOFs while simultaneously immobilizing functional species within the MOF pores remains challenging. Here, we develop microfluidic channel-embedded solution-shearing (MiCS) for ultra-fast (≤5 mm/s) and large-area synthesis of high quality nanocatalyst-embedded C-MOF thin films with thickness controllability down to tens of nanometers. The MiCS method synthesizes nanoscopic catalyst-embedded C-MOF particles within the microfluidic channels, and simultaneously grows catalyst-embedded C-MOF thin-film uniformly over a large area using solution shearing. The thin film displays high nitrogen dioxide (NO2) sensing properties at room temperature in air amongst two-dimensional materials, owing to the high surface area and porosity of the ultra-thin C-MOFs, and the catalytic activity of the nanoscopic catalysts embedded in the C-MOFs. Therefore, our method, i.e. MiCS, can provide an efficient way to fabricate highly active and conductive porous materials for various applications., The immobilization of catalysts within the pores of conductive metal-organic frameworks (C-MOFs) via facile and scalable methodologies remains challenging. Here the authors report a microfluidic channel-embedded solution shearing process that enables the high throughput, large-area, single-step preparation of Pt nanocatalyst-embedded C-MOF thin films.

Published

2021

25. Structural colour enhanced microfluidics

Author

10711658, Qin, Detao, Gibbons, Andrew H., Ito, Masateru M., Parimalam, Sangamithirai Subramanian, Jiang, Handong, Enis Karahan, H., Ghalei, Behnam, Yamaguchi, Daisuke, Pandian, Ganesh N., Sivaniah, Easan, 10711658, Qin, Detao, Gibbons, Andrew H., Ito, Masateru M., Parimalam, Sangamithirai Subramanian, Jiang, Handong, Enis Karahan, H., Ghalei, Behnam, Yamaguchi, Daisuke, Pandian, Ganesh N., and Sivaniah, Easan

Abstract

Advances in microfluidic technology towards flexibility, transparency, functionality, wearability, scale reduction or complexity enhancement are currently limited by choices in materials and assembly methods. Organized microfibrillation is a method for optically printing well-defined porosity into thin polymer films with ultrahigh resolution. Here we demonstrate this method to create self-enclosed microfluidic devices with a few simple steps, in a number of flexible and transparent formats. Structural colour, a property of organized microfibrillation, becomes an intrinsic feature of these microfluidic devices, enabling in-situ sensing capability. Since the system fluid dynamics are dependent on the internal pore size, capillary flow is shown to become characterized by structural colour, while independent of channel dimension, irrespective of whether devices are printed at the centimetre or micrometre scale. Moreover, the capability of generating and combining different internal porosities enables the OM microfluidics to be used for pore-size based applications, as demonstrated by separation of biomolecular mixtures.

Published

2022

26. Poly (N-isopropylacrylamide) Microgel-Based Optical Devices for Sensing and Biosensing

Author

Molla R. Islam, Andrews Ahiabu, Xue Li, and Michael J. Serpe

Subjects

stimuli-responsive polymers, sensors and biosensors, photonic materials, poly (N-isopropylacrylamide)-based microgels, etalons, Chemical technology, TP1-1185

Abstract

Responsive polymer-based materials have found numerous applications due to their ease of synthesis and the variety of stimuli that they can be made responsive to. In this review, we highlight the group’s efforts utilizing thermoresponsive poly (N-isopropylacrylamide) (pNIPAm) microgel-based optical devices for various sensing and biosensing applications.

Published

2014

27. Smart material based on boron crosslinked polymers with potential applications in cancer radiation therapy

Author

Sebastián Triviño, J. Vedelago, María del Mar Montesinos, Facundo Mattea, Walter Keil, Marcelo Ariel Romero, and Mauro Valente

Subjects

Boron Compounds, Materials science, Magnetic Resonance Spectroscopy, Chemical Phenomena, Polymers, Science, Monte Carlo method, Physics::Medical Physics, chemistry.chemical_element, Nanotechnology, 02 engineering and technology, Isotopes of boron, 010402 general chemistry, Smart material, 01 natural sciences, Article, Radiation, Ionizing, Polyamines, Neutron, Boron, Polyhydroxyethyl Methacrylate, Drug Carriers, Multidisciplinary, Molecular Structure, 021001 nanoscience & nanotechnology, Neutron temperature, Sensors and biosensors, 0104 chemical sciences, Neutron capture, Cross-Linking Reagents, chemistry, Medicine, Functional polymers, 0210 nano-technology, Actuators

Abstract

Organoboron compounds have been playing an increasingly important role in analytical chemistry, material science, health applications, and particularly as functional polymers like boron carriers for cancer therapy. There are two main applications of boron isotopes in radiation cancer therapy, Boron Neutron Capture Therapy and Proton Boron Fusion Therapy. In this study, a novel and original material consisting of a three-dimensional polymer network crosslinked with $$^{10}$$ 10 B enriched boric acid molecules is proposed and synthesized. The effects of the exposition to thermal neutrons were studied analyzing changes in the mechanical properties of the proposed material. Dedicated Monte Carlo simulations, based on MCNP and FLUKA main codes, were performed to characterize interactions of the proposed material with neutrons, photons, and charged particles typically present in mixed fields in nuclear reactor irradiations. Experimental results and Monte Carlo simulations were in agreement, thus justifying further studies of this promising material.

Published

2021

28. Ultra-compact dual-band smart NEMS magnetoelectric antennas for simultaneous wireless energy harvesting and magnetic field sensing

Author

Adam Khalifa, Xianfeng Liang, Hwaider Lin, Nikita Mirchandani, Isabel Martos-Repath, Gaurav Jha, Ankit Mittal, Sydney S. Cash, Nian X. Sun, Mehdi Nasrollahpour, Marvin Onabajo, Neville Sun, Aatmesh Shrivastava, Alexei Matyushov, Mohsen Zaeimbashi, Huaihao Chen, Anthony Romano, Cunzheng Dong, Ziyue Xu, and Diptashree Das

Subjects

Computer science, Science, General Physics and Astronomy, General Biochemistry, Genetics and Molecular Biology, Article, Mice, Electronic and spintronic devices, Electronic devices, Wireless, Animals, Nanotechnology, Electronics, Wireless power transfer, Nanoelectromechanical systems, Multidisciplinary, business.industry, Electrical engineering, Specific absorption rate, Sense (electronics), General Chemistry, Equipment Design, Electrical and electronic engineering, Sensors and biosensors, Magnetic field, Electrodes, Implanted, Rats, Magnetic Fields, Smart Materials, Models, Animal, Multi-band device, Antenna (radio), business, Wireless Technology, Voltage

Abstract

Ultra-compact wireless implantable medical devices are in great demand for healthcare applications, in particular for neural recording and stimulation. Current implantable technologies based on miniaturized micro-coils suffer from low wireless power transfer efficiency (PTE) and are not always compliant with the specific absorption rate imposed by the Federal Communications Commission. Moreover, current implantable devices are reliant on differential recording of voltage or current across space and require direct contact between electrode and tissue. Here, we show an ultra-compact dual-band smart nanoelectromechanical systems magnetoelectric (ME) antenna with a size of 250 × 174 µm2 that can efficiently perform wireless energy harvesting and sense ultra-small magnetic fields. The proposed ME antenna has a wireless PTE 1–2 orders of magnitude higher than any other reported miniaturized micro-coil, allowing the wireless IMDs to be compliant with the SAR limit. Furthermore, the antenna’s magnetic field detectivity of 300–500 pT allows the IMDs to record neural magnetic fields., Wireless implantable medical devices (IMDs) are hamstrung by both size and efficiency required for wireless power transfer. Here, Zaeimbashi et al. present a magnetoelectric nano-electromechanical systems that can harvest energy and sense weak magnetic fields like those arising from neural activity.

Published

2021

29. Imperceptible energy harvesting device and biomedical sensor based on ultraflexible ferroelectric transducers and organic diodes

Author

Tsuyoshi Sekitani, Esther Karner-Petritz, Philipp Schäffner, Teppei Araki, Barbara Stadlober, Andreas Petritz, and Takafumi Uemura

Subjects

0301 basic medicine, Materials science, Bioelectric Energy Sources, Science, Transducers, General Physics and Astronomy, Biosensing Techniques, 02 engineering and technology, Article, General Biochemistry, Genetics and Molecular Biology, law.invention, Wearable Electronic Devices, 03 medical and health sciences, law, Humans, Electronics, Monitoring, Physiologic, Diode, Electronic circuit, Multidisciplinary, business.industry, Reproducibility of Results, Robotics, General Chemistry, Micro-Electrical-Mechanical Systems, 021001 nanoscience & nanotechnology, Piezoelectricity, Electrical and electronic engineering, Sensors and biosensors, Flexible electronics, Electronics, Medical, Capacitor, 030104 developmental biology, Transducer, Optoelectronics, 0210 nano-technology, business, Biomedical engineering, Energy harvesting

Abstract

Energy autonomy and conformability are essential elements in the next generation of wearable and flexible electronics for healthcare, robotics and cyber-physical systems. This study presents ferroelectric polymer transducers and organic diodes for imperceptible sensing and energy harvesting systems, which are integrated on ultrathin (1-µm) substrates, thus imparting them with excellent flexibility. Simulations show that the sensitivity of ultraflexible ferroelectric polymer transducers is strongly enhanced by using an ultrathin substrate, which allows the mounting on 3D-shaped objects and the stacking in multiple layers. Indeed, ultraflexible ferroelectric polymer transducers have improved sensitivity to strain and pressure, fast response and excellent mechanical stability, thus forming imperceptible wireless e-health patches for precise pulse and blood pressure monitoring. For harvesting biomechanical energy, the transducers are combined with rectifiers based on ultraflexible organic diodes thus comprising an imperceptible, 2.5-µm thin, energy harvesting device with an excellent peak power density of 3 mW·cm−3., Next-generation energy autonomous biomedical devices must easily conform to human skin, provide accurate health monitoring and allow for scalable manufacturing. Here, the authors report ultraflexible ferroelectric transducers and organic diodes for biomedical sensing and energy harvesting. Ultraflexible ferroelectric transducers based on P(VDF:TrFE) co-polymer with optimised crystalline structure by thermal annealing are utilised as sensors for vital parameters detection and as piezoelectric nanogenerators (PENG). The PENGs were incorporated in an energy harvesting system including OTFT-based rectifying circuits and thin film capacitors on a single ultrathin substrate. Both developments could pave the way towards self-powering, imperceptible e-health systems.

Published

2021

30. A novel art of continuous noninvasive blood pressure measurement

Author

Bernd Saugel, Dorothea E. Rogge, Julian Grond, Christian Fellner, Katja Lerche, Doris Flotzinger, and J. Fortin

Subjects

Adult, Male, Cardiac output, Computer science, Remote patient monitoring, Science, 0206 medical engineering, Pulsatile flow, General Physics and Astronomy, Hemodynamics, Wearable computer, Blood Pressure, 02 engineering and technology, 030204 cardiovascular system & hematology, Signal, Article, General Biochemistry, Genetics and Molecular Biology, Computational biophysics, Young Adult, 03 medical and health sciences, 0302 clinical medicine, Humans, Pulse, Monitoring, Physiologic, Miniaturization, Multidisciplinary, Flow monitoring, Blood Pressure Determination, Signal Processing, Computer-Assisted, General Chemistry, Middle Aged, 020601 biomedical engineering, Sensors and biosensors, Blood pressure, ComputingMethodologies_PATTERNRECOGNITION, Calibration, Female, Algorithms, Software, Biomedical engineering

Abstract

Wearable sensors to continuously measure blood pressure and derived cardiovascular variables have the potential to revolutionize patient monitoring. Current wearable methods analyzing time components (e.g., pulse transit time) still lack clinical accuracy, whereas existing technologies for direct blood pressure measurement are too bulky. Here we present an innovative art of continuous noninvasive hemodynamic monitoring (CNAP2GO). It directly measures blood pressure by using a volume control technique and could be used for small wearable sensors integrated in a finger-ring. As a software prototype, CNAP2GO showed excellent blood pressure measurement performance in comparison with invasive reference measurements in 46 patients having surgery. The resulting pulsatile blood pressure signal carries information to derive cardiac output and other hemodynamic variables. We show that CNAP2GO can self-calibrate and be miniaturized for wearable approaches. CNAP2GO potentially constitutes the breakthrough for wearable sensors for blood pressure and flow monitoring in both ambulatory and in-hospital clinical settings., Realizing wearable sensors for blood pressure (BP) monitoring with clinically-acceptable performance remains a significant challenge. Here, the authors report a continuous noninvasive blood pressure measurement system featuring a volume control technique for small wearable sensors.

Published

2021

31. Ultrahigh sensitive refractive index nanosensors based on nanoshells, nanocages and nanoframes: effects of plasmon hybridization and restoring force

Author

Hamidreza Fallah, Hamidreza Mohammadi, and Mir Kazem Omrani

Subjects

Materials science, Nanostructure, Science, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, Article, Nanocages, Nanosensor, Plasmon, Nanophotonics and plasmonics, Multidisciplinary, business.industry, 021001 nanoscience & nanotechnology, Aspect ratio (image), Sensors and biosensors, Nanoshell, 0104 chemical sciences, Optoelectronics, Medicine, Restoring force, 0210 nano-technology, business, Refractive index

Abstract

In this study, the effect of the plasmon hybridization mechanism on the performance and refractive index (RI) sensitivity of nanoshell, nanocage and nanoframe structures is investigated using the finite-difference time-domain simulation. To create nanocage structure, we textured the cubic nanoshell surfaces and examined the impact of its key parameters (such as array of cavities, size of cavities and wall thickness) on the nanocage's RI-sensitivity. Synthesis of the designed nanocages is a challenging process in practice, but here the goal is to understand the physics lied behind it and try to answer the question “Why nanoframes are more sensitive than nanocages?”. Our obtained results show that the RI-sensitivity of nanocage structures increases continuously by decreasing the array of cavities. Transforming the nanocage to the nanoframe structure by reducing the array of cavities to a single cavity significantly increases the RI-sensitivity of the nanostructure. This phenomenon can be related to the simultaneous presence of symmetric and asymmetric plasmon oscillations in the nanocage structure and low restoring force of nanoframe compared to nanocage. As the optimized case shows, the proposed single nanoframe with aspect ratio (wall length/wall thickness) of 12.5 shows RI-sensitivity of 1460 nm/RIU, the sensitivity of which is ~ 5.5 times more than its solid counterpart.

Published

2021

32. Structural colour enhanced microfluidics

Author

Detao Qin, Andrew H. Gibbons, Masateru M. Ito, Sangamithirai Subramanian Parimalam, Handong Jiang, H. Enis Karahan, Behnam Ghalei, Daisuke Yamaguchi, Ganesh N. Pandian, and Easan Sivaniah

Subjects

Excipients, Multidisciplinary, Polymers, Lab-On-A-Chip Devices, Microfluidics, Printing, Three-Dimensional, Color, General Physics and Astronomy, Fluidics, General Chemistry, Porosity, Sensors and biosensors, General Biochemistry, Genetics and Molecular Biology

Abstract

Advances in microfluidic technology towards flexibility, transparency, functionality, wearability, scale reduction or complexity enhancement are currently limited by choices in materials and assembly methods. Organized microfibrillation is a method for optically printing well-defined porosity into thin polymer films with ultrahigh resolution. Here we demonstrate this method to create self-enclosed microfluidic devices with a few simple steps, in a number of flexible and transparent formats. Structural colour, a property of organized microfibrillation, becomes an intrinsic feature of these microfluidic devices, enabling in-situ sensing capability. Since the system fluid dynamics are dependent on the internal pore size, capillary flow is shown to become characterized by structural colour, while independent of channel dimension, irrespective of whether devices are printed at the centimetre or micrometre scale. Moreover, the capability of generating and combining different internal porosities enables the OM microfluidics to be used for pore-size based applications, as demonstrated by separation of biomolecular mixtures., マイクロ流体デバイスの製造に革新をもたらす新手法. 京都大学プレスリリース. 2022-05-19., New process revolutionizes microfluidic fabrication. 京都大学プレスリリース. 2022-05-19.

Published

2022

33. Different Ways to Apply a Measurement Instrument of E-Nose Type to Evaluate Ambient Air Quality with Respect to Odour Nuisance in a Vicinity of Municipal Processing Plants.

Author

Szulczyński, Bartosz, Wasilewski, Tomasz, Wojnowski, Wojciech, Majchrzak, Tomasz, Dymerski, Tomasz, Namieśnik, Jacek, and Gębicki, Jacek

Subjects

*ELECTRONIC noses, *AIR quality, *NUISANCES, *REMOTE control, *BIOSENSORS

Abstract

This review paper presents different ways to apply a measurement instrument of e-nose type to evaluate ambient air with respect to detection of the odorants characterized by unpleasant odour in a vicinity of municipal processing plants. An emphasis was put on the following applications of the electronic nose instruments: monitoring networks, remote controlled robots and drones as well as portable devices. Moreover, this paper presents commercially available sensors utilized in the electronic noses and characterized by the limit of quantification below 1 ppm v/v, which is close to the odour threshold of some odorants. Additionally, information about bioelectronic noses being a possible alternative to electronic noses and their principle of operation and application potential in the field of air evaluation with respect to detection of the odorants characterized by unpleasant odour was provided. [ABSTRACT FROM AUTHOR]

Published

2017

34. Antigen detection using fluorophore-modified antibodies and magnetic microparticles.

Author

Zhang, Wei and Serpe, Michael J.

Subjects

*ANTIGENS, *FLUOROPHORES, *IMMUNOGLOBULIN G, *MAGNETIC particles, *FLUORESCEIN isothiocyanate

Abstract

In this submission, we detail a new method for detecting mouse Immunoglobulin G (IgG) utilizing fluorophore-modified antibodies and antibody-modified magnetic microparticles. This was accomplished by adding an excess amount of fluorescein isothiocyanate (FITC)-modified goat anti-mouse IgG (F(ab’) 2 fragment specific to mouse IgG), and allowing them to react for some time. After a given reaction time, the bound antibody could be isolated from the unbound, excess antibody via addition of goat anti-mouse IgG (Fc fragment specific)-modified magnetic microparticles. After application of a magnetic field, the free, unbound antibody could be isolated and the fluorescence intensity of the isolated solution detected. We show that the fluorescence intensity decreased linearly as antigen concentration increased, has a detection limit of 0.65 nM, and was species specific. In a subsequent experiment, we demonstrated that simple filtration could also be used to separate the bound from unbound antibodies, which enhances the simplicity and ultimate utility of the assay. We also show that the approach can be used to detect two different analytes in a single solution, which could be easily modified to detect multiple antigens. Finally, we demonstrate that simple observation by the naked eye could be used to detect specific antigens in a sample. This sensing approach could be easily modified to detect many other antigens, even biomarkers for disease. It is this versatility, and simplicity that makes this sensing approach potentially very impactful. [ABSTRACT FROM AUTHOR]

Published

2017

35. High precision epidermal radio frequency antenna via nanofiber network for wireless stretchable multifunction electronics

Author

Junyi Zhai, Xun Han, Zhong Lin Wang, Yufei Zhang, Xiandi Wang, Bensong Wan, Hui Wang, Wenqiang Wu, Zhihao Huo, Caofeng Pan, and Juan Tao

Subjects

Materials science, Silver, Radio Waves, Science, Stretchable electronics, Nanofibers, General Physics and Astronomy, Physics::Optics, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, General Biochemistry, Genetics and Molecular Biology, Article, Hardware_GENERAL, ComputerApplications_MISCELLANEOUS, Computer Science::Networking and Internet Architecture, Wireless, Humans, Wireless power transfer, Electronics, lcsh:Science, Computer Science::Information Theory, Skin, Artificial, Multidisciplinary, business.industry, ComputerSystemsOrganization_COMPUTER-COMMUNICATIONNETWORKS, Electrical engineering, General Chemistry, Equipment Design, 021001 nanoscience & nanotechnology, Sensors and biosensors, 0104 chemical sciences, Biosensors, visual_art, Electronic component, visual_art.visual_art_medium, lcsh:Q, Radio frequency, Antenna (radio), Epidermis, 0210 nano-technology, business, Frequency modulation, Wireless Technology

Abstract

Recently, stretchable electronics combined with wireless technology have been crucial for realizing efficient human-machine interaction. Here, we demonstrate highly stretchable transparent wireless electronics composed of Ag nanofibers coils and functional electronic components for power transfer and information communication. Inspired by natural systems, various patterned Ag nanofibers electrodes with a net structure are fabricated via using lithography and wet etching. The device design is optimized by analyzing the quality factor and radio frequency properties of the coil, considering the effects of strain. Particularly, the wireless transmission efficiency of a five-turn coil drops by approximately only 50% at 10 MHz with the strain of 100%. Moreover, various complex functional wireless electronics are developed using near-field communication and frequency modulation technology for applications in content recognition and long-distance transmission (>1 m), respectively. In summary, the proposed device has considerable potential for applications in artificial electronic skins, human healthcare monitoring and soft robotics., Designing efficient radio frequency antenna for wireless stretchable multifunction electronics remains a challenge. Here, the authors present epidermal radio frequency antenna based on silver nanofibers network for wireless power transfer and information identification.

Published

2020

36. Curved neuromorphic image sensor array using a MoS2-organic heterostructure inspired by the human visual recognition system

Author

Juyoung Leem, SungWoo Nam, Changsoon Choi, Amir Taqieddin, Young Min Song, Chullhee Cho, Min Sung Kim, Hyung Jong Bae, Narayana R. Aluru, Kyoung Won Cho, Taeghwan Hyeon, Gil Ju Lee, Dae-Hyeong Kim, and Hyojin Seung

Subjects

Computer science, Machine vision, Science, ComputingMethodologies_IMAGEPROCESSINGANDCOMPUTERVISION, General Physics and Astronomy, 02 engineering and technology, Two-dimensional materials, 010402 general chemistry, 01 natural sciences, Article, General Biochemistry, Genetics and Molecular Biology, law.invention, Set (abstract data type), law, Electronic devices, Computer vision, Image sensor, Data processing, Multidisciplinary, business.industry, Process (computing), General Chemistry, 021001 nanoscience & nanotechnology, Sensors and biosensors, 0104 chemical sciences, Lens (optics), Neuromorphic engineering, Computer Science::Computer Vision and Pattern Recognition, Computer data storage, Artificial intelligence, 0210 nano-technology, business

Abstract

Conventional imaging and recognition systems require an extensive amount of data storage, pre-processing, and chip-to-chip communications as well as aberration-proof light focusing with multiple lenses for recognizing an object from massive optical inputs. This is because separate chips (i.e., flat image sensor array, memory device, and CPU) in conjunction with complicated optics should capture, store, and process massive image information independently. In contrast, human vision employs a highly efficient imaging and recognition process. Here, inspired by the human visual recognition system, we present a novel imaging device for efficient image acquisition and data pre-processing by conferring the neuromorphic data processing function on a curved image sensor array. The curved neuromorphic image sensor array is based on a heterostructure of MoS2 and poly(1,3,5-trimethyl-1,3,5-trivinyl cyclotrisiloxane). The curved neuromorphic image sensor array features photon-triggered synaptic plasticity owing to its quasi-linear time-dependent photocurrent generation and prolonged photocurrent decay, originated from charge trapping in the MoS2-organic vertical stack. The curved neuromorphic image sensor array integrated with a plano-convex lens derives a pre-processed image from a set of noisy optical inputs without redundant data storage, processing, and communications as well as without complex optics. The proposed imaging device can substantially improve efficiency of the image acquisition and recognition process, a step forward to the next generation machine vision., Designing efficient bio-inspired visual recognition system remains a challenge. Here the authors present a curved neuromorphic image sensor array based on a heterostructure of MoS2 and pV3D3 integrated with a plano-convex lens for efficient image acquisition and data pre-processing.

Published

2020

37. Triboelectric nanogenerator sensors for soft robotics aiming at digital twin applications

Author

Zixuan Zhang, Xuyan Hou, Chengkuo Lee, Tao Chen, Zhongda Sun, Long Li, Jin Tao, Quan Zhang, Minglu Zhu, Guangjie Yuan, and Yingzhong Tian

Subjects

Computer science, Science, Soft robotics, General Physics and Astronomy, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, Article, General Biochemistry, Genetics and Molecular Biology, Support vector machine algorithm, Computer vision, lcsh:Science, Triboelectric effect, Multidisciplinary, business.industry, Nanogenerator, Cognitive neuroscience of visual object recognition, General Chemistry, 021001 nanoscience & nanotechnology, Object (computer science), Electrical and electronic engineering, Mechanical engineering, Sensors and biosensors, 0104 chemical sciences, Contact position, lcsh:Q, Artificial intelligence, 0210 nano-technology, business, Tactile sensor

Abstract

Designing efficient sensors for soft robotics aiming at human machine interaction remains a challenge. Here, we report a smart soft-robotic gripper system based on triboelectric nanogenerator sensors to capture the continuous motion and tactile information for soft gripper. With the special distributed electrodes, the tactile sensor can perceive the contact position and area of external stimuli. The gear-based length sensor with a stretchable strip allows the continuous detection of elongation via the sequential contact of each tooth. The triboelectric sensory information collected during the operation of soft gripper is further trained by support vector machine algorithm to identify diverse objects with an accuracy of 98.1%. Demonstration of digital twin applications, which show the object identification and duplicate robotic manipulation in virtual environment according to the real-time operation of the soft-robotic gripper system, is successfully created for virtual assembly lines and unmanned warehouse applications., Designing efficient sensors for human machine interaction remains a challenge. Here, the authors present a soft robotic fingers system based on a triboelectric nanogenerator (L-TENG) sensor to capture the continuous motion of soft gripper and a soft tactile (T-TENG) sensor for tactile sensing, that can achieve an object recognition accuracy of 98.1%.

Published

2020

38. Characterization of capacitive electromyography biomedical sensor insulated with porous medical bandages

Author

Ng, Charn Loong, Reaz, Mamun Bin Ibne, Crespo, Maria Liz, Cicuttin, res, and Chowdhury, Muhammad Enamul Hoque

Subjects

Materials science, Capacitive sensing, Acoustics, lcsh:Medicine, Insulator (electricity), Biosensing Techniques, 02 engineering and technology, Electric Capacitance, Band-stop filter, 01 natural sciences, Capacitance, Article, 0202 electrical engineering, electronic engineering, information engineering, Humans, Porosity, lcsh:Science, Capacitive coupling, Multidisciplinary, Electromyography, System of measurement, 010401 analytical chemistry, lcsh:R, Electromyography - EMG, Bandages, Noise floor, Sensors and biosensors, 0104 chemical sciences, 020201 artificial intelligence & image processing, lcsh:Q, Biomedical engineering

Abstract

A capacitive electromyography (cEMG) biomedical sensor measures the EMG signal from human body through capacitive coupling methodology. It has the flexibility to be insulated by different types of materials. Each type of insulator will yield a unique skin-electrode capacitance which determine the performance of a cEMG biomedical sensor. Most of the insulator being explored are solid and non-breathable which cause perspiration in a long-term EMG measurement process. This research aims to explore the porous medical bandages such as micropore, gauze, and crepe bandage to be used as an insulator of a cEMG biomedical sensor. These materials are breathable and hypoallergenic. Their unique properties and characteristics have been reviewed respectively. A 50 Hz digital notch filter was developed and implemented in the EMG measurement system design to further enhance the performance of these porous medical bandage insulated cEMG biomedical sensors. A series of experimental verifications such as noise floor characterization, EMG signals measurement, and performance correlation were done on all these sensors. The micropore insulated cEMG biomedical sensor yielded the lowest noise floor amplitude of 2.44 mV and achieved the highest correlation coefficient result in comparison with the EMG signals captured by the conventional wet contact electrode. 2020, The Author(s). This research is funded by UKM Research University Grant (Grant number: DIP-2018-017) and Qatar National Research Foundation, QNRF (Grant number: NPRP12s-0227-190164). Support from the ICTP, STEP programme is gratefully acknowledged. Scopus

Published

2020

39. A fully sustainable, self-poled, bio-waste based piezoelectric nanogenerator: electricity generation from pomelo fruit membrane

Author

S. Wazed Ali, Saikat Ghosh, and Satyaranjan Bairagi

Subjects

Materials science, Science, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, Article, Electronic devices, Power density, Multidisciplinary, business.industry, Nanogenerator, 021001 nanoscience & nanotechnology, Piezoelectricity, Sensors and biosensors, 0104 chemical sciences, Electricity generation, Finger tapping, Optoelectronics, Medicine, 0210 nano-technology, Energy source, business, Energy harvesting, Actuators, Voltage

Abstract

A self-powered system is very much essential aspect in the recent trend to improve the working efficiency of the portable and wearable devices. Here, we have reported a fully sustainable, self-poled, bio-compatible, and bio-waste based piezoelectric energy harvester which has been made of Pomelo Fruit Membrane (PFM). PFM based piezoelectric generator (PFMBPEG) could generate ~ 6.4 V output voltage and ~ 7.44 μA output current directly, only by finger tapping on the device and registers a power density of ~ 12 μW cm−2 whereas, the same piezoelectric generator can generate ~ 15 V output voltage, 130 μA output current, and power density of ~ 487.5 μW cm−2 by using a full wave rectifier. The sensitivity and energy harvesting competence of the generator have also been assessed by attaching this nanogenerator into various parts of human body (as energy sources) such as wrist, elbow, finger, throat, jaws, leg and putting the device into ultrasonic bath and in every case, it could successfully generate voltage. Therefore, this bio-waste based energy harvester can be used as a power source for the different potable and wearable electronic goods where a small amount of energy is required, specifically in the biomedical applications (i.e., health monitoring, power source for the implantable devices and so on). Finally, mechanical stability the developed piezoelectric generator has been evaluated by cyclic bending test and it has been observed that there is no significant deformation of the PFM film even after 100 cycles.

Published

2020

40. Reversible visible/near-infrared light responsive thin films based on indium tin oxide nanocrystals and polymer

Author

Jinglei Yang, Chenzhong Mu, and Jian Wu

Subjects

Materials science, Science, 02 engineering and technology, engineering.material, 010402 general chemistry, 01 natural sciences, Article, Coating, Transmittance, Thermal stability, Thin film, chemistry.chemical_classification, Multidisciplinary, Nanocomposite, Polymer, 021001 nanoscience & nanotechnology, Sensors and biosensors, 0104 chemical sciences, Indium tin oxide, chemistry, Nanocrystal, Chemical engineering, engineering, Medicine, Gels and hydrogels, 0210 nano-technology

Abstract

In this study, we design a novel thermo- and photo-responsive nanocomposite film prepared by depositing indium tin oxide nanocrystals via the coating of amphiphilic copolymer on polycaprolactone substrates (INCP). The INCP film shows reversible surface morphology change properties by changing temperature as well as turning ON/OFF NIR laser. Especially, as the temperature changes from 25 to 75 °C, the film could regulate light transmittance from 75 to 90% across the visible and near-infrared region (500–1,750 nm). In addition, the film also exhibits excellent recycle and thermal stability at different temperature. Our results reveal that reversible surface morphology change properties are caused by curvature adjustment of film, which is owing to the coupling effect between copolymer and PCL with different thermal expansion strains. Our results suggest a possible strategy for the preparation of smart responsive materials in the future, which provides a reference for the development of new energy-saving materials.

Published

2020

41. Conjuncted photo-thermoelectric effect in ZnO–graphene nanocomposite foam for self-powered simultaneous temperature and light sensing

Author

Lu Han, Yogendra Kumar Mishra, Bangsen Ouyang, Huiqi Zhao, Ya Yang, and Zhiqiang Zhang

Subjects

Materials science, Fabrication, lcsh:Medicine, Light sensing, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, Article, law.invention, law, Thermoelectric effect, Porous materials, lcsh:Science, Signal interference, Multidisciplinary, Nanocomposite, Graphene, business.industry, lcsh:R, Photoelectric effect, 021001 nanoscience & nanotechnology, Sensors and biosensors, 0104 chemical sciences, Optoelectronics, lcsh:Q, 0210 nano-technology, business

Abstract

The self-powered sensors are more and more important in current society. However, detecting both light and temperature signals simultaneously without energy waste and signal interference is still a challenge. Here, we report a ZnO/graphene nanocomposite foam-based self-powered sensor, which can realize the simultaneous detection of light and temperature by using the conjuncted photo-thermoelectric effect in ZnO–graphene nanocomposite foam sensor. The output current under light, heating and cooling of the device with the best ZnO/graphene ratio (8:1) for the foam can reach 1.75 µA, 1.02 µA and 0.70 µA, respectively, which are approximately three fold higher than them of devices with other ZnO/graphene ratios. The ZnO–graphene nanocomposite foam device also possesses excellent thermoelectric and photoelectric performances for conjuncted lighting and heating detection without mutual interference. The ZnO–graphene nanocomposite foam device exhibits a new designation on the road towards the fabrication of low cost and one-circuit-based multifunction sensors and systems.

Published

2020

42. All-printed nanomembrane wireless bioelectronics using a biocompatible solderable graphene for multimodal human-machine interfaces

Author

Robert Herbert, Young C. Jang, S.G. Kang, Woon-Hong Yeo, Yong-Ho Choa, Yun-Soung Kim, Young-Tae Kwon, Musa Mahmood, Jeongmoon J. Choi, Shinjae Kwon, Hyo-Ryoung Lim, and Si-Woo Park

Subjects

Computer science, Science, General Physics and Astronomy, Nanotechnology, Biosensing Techniques, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, Article, General Biochemistry, Genetics and Molecular Biology, law.invention, Wearable Electronic Devices, Nanomanufacturing, Cleanroom, law, Humans, Wireless, Electronics, lcsh:Science, Wearable technology, Bioelectronics, Multidisciplinary, business.industry, Graphene, Electric Conductivity, General Chemistry, 021001 nanoscience & nanotechnology, Electrical and electronic engineering, Sensors and biosensors, Nanostructures, 0104 chemical sciences, Printed electronics, Graphite, lcsh:Q, 0210 nano-technology, business, Wireless Technology

Abstract

Recent advances in nanomaterials and nano-microfabrication have enabled the development of flexible wearable electronics. However, existing manufacturing methods still rely on a multi-step, error-prone complex process that requires a costly cleanroom facility. Here, we report a new class of additive nanomanufacturing of functional materials that enables a wireless, multilayered, seamlessly interconnected, and flexible hybrid electronic system. All-printed electronics, incorporating machine learning, offers multi-class and versatile human-machine interfaces. One of the key technological advancements is the use of a functionalized conductive graphene with enhanced biocompatibility, anti-oxidation, and solderability, which allows a wireless flexible circuit. The high-aspect ratio graphene offers gel-free, high-fidelity recording of muscle activities. The performance of the printed electronics is demonstrated by using real-time control of external systems via electromyograms. Anatomical study with deep learning-embedded electrophysiology mapping allows for an optimal selection of three channels to capture all finger motions with an accuracy of about 99% for seven classes., Though wearable electronics remain an attractive technology for bioelectronics, fabrication methods that precisely print biocompatible materials for electronics are needed. Here, the authors report an additive manufacturing process that yields all-printed nanomaterial-based wireless electronics.

Published

2020

43. An AgNP-deposited commercial electrochemistry test strip as a platform for urea detection

Author

Roozbeh Siavash Moakhar, Sebastian Wachsmann-Hogiu, Sara Mahshid, Ayyappasamy Sudalaiyadum Perumal, Juanjuan Liu, and Horia N. Roman

Subjects

Materials for devices, Analyte, Working electrode, Materials science, Science, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, Article, chemistry.chemical_compound, medicine, Glucose test, Detection limit, Multidisciplinary, Chromatography, medicine.diagnostic_test, 021001 nanoscience & nanotechnology, Sensors and biosensors, 0104 chemical sciences, Dielectric spectroscopy, Linear range, chemistry, Urea, Medicine, Cyclic voltammetry, 0210 nano-technology, Biomedical engineering

Abstract

We developed an inexpensive, portable platform for urea detection via electrochemistry by depositing silver nanoparticles (AgNPs) on a commercial glucose test strip. We modified this strip by first removing the enzymes from the surface, followed by electrodeposition of AgNPs on one channel (working electrode). The morphology of the modified test strip was characterized by Scanning Electron Microscopy (SEM), and its electrochemical performance was evaluated via Cyclic Voltammetry (CV) and Electrochemical Impedance Spectroscopy (EIS). We evaluated the performance of the device for urea detection via measurements of the dependency of peak currents vs the analyte concentration and from the relationship between the peak current and the square root of the scan rates. The observed linear range is 1–8 mM (corresponding to the physiological range of urea concentration in human blood), and the limit of detection (LOD) is 0.14 mM. The selectivity, reproducibility, reusability, and storage stability of the modified test strips are also reported. Additional tests were performed to validate the ability to measure urea in the presence of confounding factors such as spiked plasma and milk. The results demonstrate the potential of this simple and portable EC platform to be used in applications such as medical diagnosis and food safety.

Published

2020

44. A flexible artificial intrinsic-synaptic tactile sensory organ

Author

Yu Rim Lee, Nae-Eung Lee, Tran Quang Trung, and Byeong-Ung Hwang

Subjects

Information storage, Sensory Receptor Cells, Transistors, Electronic, Computer science, Science, Gate dielectric, General Physics and Astronomy, Sensory system, 02 engineering and technology, Biosensing Techniques, 010402 general chemistry, 01 natural sciences, General Biochemistry, Genetics and Molecular Biology, Article, Merkel Cells, Synaptic weight, chemistry.chemical_compound, Memory, Electronic devices, Neurites, Humans, Learning, lcsh:Science, Multidisciplinary, Sensory memory, General Chemistry, 021001 nanoscience & nanotechnology, Sensors and biosensors, 0104 chemical sciences, Coupling (electronics), chemistry, Touch Perception, Touch, Barium titanate, Synapses, lcsh:Q, Artificial Organs, 0210 nano-technology, Neuroscience, Tactile sensor

Abstract

Imbuing bio-inspired sensory devices with intelligent functions of human sensory organs has been limited by challenges in emulating the preprocessing abilities of sensory organs such as reception, filtering, adaptation, and sensory memory at the device level itself. Merkel cells, which is a part of tactile sensory organs, form synapse-like connections with afferent neuron terminals referred to as Merkel cell-neurite complexes. Here, inspired by structure and intelligent functions of Merkel cell-neurite complexes, we report a flexible, artificial, intrinsic-synaptic tactile sensory organ that mimics synapse-like connections using an organic synaptic transistor with ferroelectric nanocomposite gate dielectric of barium titanate nanoparticles and poly(vinylidene fluoride-trifluoroethylene). Modulation of the post-synaptic current of the device induced by ferroelectric dipole switching due to triboelectric-capacitive coupling under finger touch allowed reception and slow adaptation. Modulation of synaptic weight by varying the nanocomposite composition of gate dielectric layer enabled tuning of filtering and sensory memory functions., Emulating the preprocessing abilities of sensory organs and sensory memory at the device level remains a challenge. Here, the authors demonstrate a flexible tactile sensor based on barium titanate nanoparticles in ferroelectric nanocomposite capable of emulating filtering and sensory memory functions.

Published

2020

45. Locally coupled electromechanical interfaces based on cytoadhesion-inspired hybrids to identify muscular excitation-contraction signatures

Author

Naoji Matsuhisa, Chengcheng Li, Pingqiang Cai, Wei Zhang, Liang Pan, Geng Chen, Jing Yu, Jianwu Wang, Xiaodong Chen, Ming Wang, Changjin Wan, Zequn Cui, Ke He, Ying Jiang, School of Materials Science and Engineering, and Innovative Centre for Flexible Devices

Subjects

Computer science, Science, Interface (computing), Robotic hand, General Physics and Astronomy, Artificial Limbs, Bioengineering, 02 engineering and technology, Prosthesis Design, 010402 general chemistry, 01 natural sciences, Article, General Biochemistry, Genetics and Molecular Biology, Excitation contraction, Biomechanical Phenomena, Fingers, Robustness (computer science), Electronic devices, Electromechanical coupling, Humans, Range of Motion, Articular, Muscle, Skeletal, lcsh:Science, Bioelectronics, Multidisciplinary, Hand Strength, Materials [Engineering], Electromyography, Process (computing), General Chemistry, Hand, Electronic Devices, 021001 nanoscience & nanotechnology, Sensors and biosensors, Electronics, Medical, 0104 chemical sciences, Forearm, Coupling (physics), lcsh:Q, 0210 nano-technology, Biological system, Biomedical engineering, Muscle Contraction

Abstract

Coupling myoelectric and mechanical signals during voluntary muscle contraction is paramount in human–machine interactions. Spatiotemporal differences in the two signals intrinsically arise from the muscular excitation–contraction process; however, current methods fail to deliver local electromechanical coupling of the process. Here we present the locally coupled electromechanical interface based on a quadra-layered ionotronic hybrid (named as CoupOn) that mimics the transmembrane cytoadhesion architecture. CoupOn simultaneously monitors mechanical strains with a gauge factor of ~34 and surface electromyogram with a signal-to-noise ratio of 32.2 dB. The resolved excitation–contraction signatures of forearm flexor muscles can recognize flexions of different fingers, hand grips of varying strength, and nervous and metabolic muscle fatigue. The orthogonal correlation of hand grip strength with speed is further exploited to manipulate robotic hands for recapitulating corresponding gesture dynamics. It can be envisioned that such locally coupled electromechanical interfaces would endow cyber–human interactions with unprecedented robustness and dexterity., Designing efficient systems capable emulating the muscular excitation-contraction signatures, remains a challenge. Here, the authors propose cytoadhesion-inspired hybrids as locally-coupled electromechanical interfaces capable retrieving the myoelectric and mechanical signals.

Published

2020

46. Randomized resonant metamaterials for single-sensor identification of elastic vibrations

Author

Chong Li, Tianxi Jiang, Qingbo He, and Zhike Peng

Subjects

0301 basic medicine, Computer science, Acoustics, Science, General Physics and Astronomy, Physics::Optics, 02 engineering and technology, General Biochemistry, Genetics and Molecular Biology, Article, 03 medical and health sciences, Resonator, Physical information, Encoding (memory), Physics::Chemical Physics, lcsh:Science, Multidisciplinary, Perspective (graphical), Metamaterial, General Chemistry, 021001 nanoscience & nanotechnology, Electrical and electronic engineering, Sensors and biosensors, Vibration, Applied physics, Identification (information), 030104 developmental biology, Compressed sensing, lcsh:Q, 0210 nano-technology

Abstract

Vibrations carry a wealth of useful physical information in various fields. Identifying the multi-source vibration information generally requires a large number of sensors and complex hardware. Compressive sensing has been shown to be able to bypass the traditional sensing requirements by encoding spatial physical fields, but how to encode vibration information remains unexplored. Here we propose a randomized resonant metamaterial with randomly coupled local resonators for single-sensor compressed identification of elastic vibrations. The disordered effective masses of local resonators lead to highly uncorrelated vibration transmissions, and the spatial vibration information can thus be physically encoded. We demonstrate that the spatial vibration information can be reconstructed via a compressive sensing framework, and this metamaterial can be reconfigured while maintaining desirable performance. This randomized resonant metamaterial presents a new perspective for single-sensor vibration sensing via vibration transmission encoding, and potentially offers an approach to simpler sensing devices for many other physical information., Designing efficient and flexible metamaterial with uncorrelated transmissions for spatial vibration encoding and identification remains a challenge. Here, the authors propose a randomized resonant metamaterial with randomly coupled local resonators for single-sensor identification of elastic vibrations.

Published

2020

47. Adhesive Biocomposite Electrodes on Sweaty Skin for Long-Term Continuous Electrophysiological Monitoring

Author

Xiaodong Chen, Shaobo Ji, Hui Yang, Liang Pan, Huarong Xia, Geng Chen, Yew-Soon Ong, Ting Wang, Iti Chaturvedi, Changjin Wan, Dianpeng Qi, and School of Materials Science and Engineering

Subjects

Materials [Engineering], integumentary system, business.industry, General Chemical Engineering, Biomedical Engineering, Stretchable Electronics, Human skin, Electrophysiology, Medicine, General Materials Science, sense organs, Adhesive, Biocomposite, Sensors and Biosensors, business, Body condition, Biomedical engineering

Abstract

Non-invasive on-skin electrodes record the electrical potential changes from human skin, which reflect body condition and are applied for healthcare, sports management, and modern lifestyle. However, current on-skin electrodes have poor conformal properties under sweaty condition in real-life due to decreased electrode-skin adhesion with sweat film at the interface. Here, we fabricated bio-composite electrodes based on silk fibroin (SF) through interfacial polymerization which is applicable on sweaty skin. Interfacial polymerized conductive polypyrrole (PPy) and SF are structurally interlocked and endow the whole electrode with uniform stretchability. Existence of water results in similar Young’s modulus of SF to the skin and enhanced interfacial adhesion. It keeps the electrodes conformal to skin under sweaty condition and allows reliable collection of ambulatory electrophysiological signals during sports and sweating. Wearable devices with these electrodes were used to acquire continuous and stable real-time electrocardiography (ECG) signals during running for 2 hours. The collected signals can provide information for sports management and are also analyzed by artificial intelligence to show their potential for intelligent human emotion monitoring. Our strategy provides opportunities to record long-term continuous electrophysiological signals in real-life conditions for various smart monitoring systems. NRF (Natl Research Foundation, S’pore) ASTAR (Agency for Sci., Tech. and Research, S’pore) Accepted version

Published

2020

48. A magnetic sensor using a 2D van der Waals ferromagnetic material

Author

Sadhu Kolekar, Vijaysankar Kalappattil, Manuel Bonilla, Valery Ortiz Jimenez, Matthias Batzill, Manh-Huong Phan, Tatiana Eggers, and Pham Thanh Huy

Subjects

Materials science, lcsh:Medicine, 02 engineering and technology, 01 natural sciences, Article, symbols.namesake, Condensed Matter::Materials Science, Magnetic properties and materials, Nanosensor, 0103 physical sciences, lcsh:Science, 010302 applied physics, Multidisciplinary, Spintronics, business.industry, lcsh:R, 021001 nanoscience & nanotechnology, Sensors and biosensors, Magnetic field, Ferromagnetism, Magnetic core, Electromagnetic coil, Magnet, symbols, Optoelectronics, lcsh:Q, van der Waals force, 0210 nano-technology, business

Abstract

Two-dimensional (2D) van der Waals ferromagnetic materials are emerging as promising candidates for applications in ultra-compact spintronic nanodevices, nanosensors, and information storage. Our recent discovery of the strong room temperature ferromagnetism in single layers of VSe2 grown on graphite or MoS2 substrate has opened new opportunities to explore these ultrathin magnets for such applications. In this paper, we present a new type of magnetic sensor that utilizes the single layer VSe2 film as a highly sensitive magnetic core. The sensor relies in changes in resonance frequency of the LC circuit composed of a soft ferromagnetic microwire coil that contains the ferromagnetic VSe2 film subject to applied DC magnetic fields. We define sensitivity as the slope of the characteristic curve of our sensor, df0/dH, where f0 is the resonance frequency and H is the external magnetic field. The sensitivity of the sensor reaches a large value of 16 × 106 Hz/Oe, making it a potential candidate for a wide range of magnetic sensing applications.

Published

2020

49. A flexible topo-optical sensing technology with ultra-high contrast

Author

Ding Wang, Cong Wang, Graeme Turnbull, Jie Kong, Yifan Li, Ben Zhong Tang, Ben Bin Xu, Xingyi Dai, Valery N. Kozhevnikov, and Xue Chen

Subjects

Surface (mathematics), F300, Polymers, Science, F100, F200, General Physics and Astronomy, Mechanical properties, H800, 02 engineering and technology, 010402 general chemistry, Curvature, 01 natural sciences, Signal, Article, General Biochemistry, Genetics and Molecular Biology, Electronic engineering, Optical techniques, Layer (object-oriented design), lcsh:Science, Wearable technology, Multidisciplinary, business.industry, Physical science, General Chemistry, Folding (DSP implementation), 021001 nanoscience & nanotechnology, Mechanical engineering, Sensors and biosensors, 0104 chemical sciences, Visualization, lcsh:Q, 0210 nano-technology, business

Abstract

Elastic folding, a phenomenon widely existing in nature, has attracted great interests to understand the math and physical science behind the topological transition on surface, thus can be used to create frontier engineering solutions. Here, we propose a topo-optical sensing strategy with ultra-high contrast by programming surface folds on targeted area with a thin optical indicator layer. A robust and precise signal generation can be achieved under mechanical compressive strains (>0.4). This approach bridges the gap in current mechano-responsive luminescence mechanism, by utilizing the unwanted oxygen quenching effect of Iridium-III (Ir-III) fluorophores to enable an ultra-high contrast signal. Moreover, this technology hosts a rich set of attractive features such as high strain sensing, encoded logic function, direct visualisation and good adaptivity to the local curvature, from which we hope it will enable new opportunities for designing next generation flexible/wearable devices., Flexible materials with mechano-responsive luminescence has gained interest for their potential in sensing devices. Here, the authors demonstrate targeted folding under high compressive strains, which, together with the oxygen quenching of fluorophores, forms the basis for topo-optical sensing.

Published

2020

50. Fully Untethered Battery-free Biomonitoring Electronic Tattoo with Wireless Energy Harvesting

Author

Mahmoud Tavakoli, Anibal T. de Almeida, Cristina Leal, Jose Alberto, Hugo Paisana, Pedro Lopes, and Cláudio Fernandes

Subjects

Computer science, Interface (computing), lcsh:Medicine, 02 engineering and technology, Article, law.invention, Bluetooth, Data acquisition, law, 0202 electrical engineering, electronic engineering, information engineering, Wireless power transfer, Electronics, lcsh:Science, Bioelectronics, Multidisciplinary, business.industry, lcsh:R, Electrical engineering, Battery (vacuum tube), 020206 networking & telecommunications, 021001 nanoscience & nanotechnology, Electrical and electronic engineering, Sensors and biosensors, Transmission (telecommunications), lcsh:Q, 0210 nano-technology, business, Biomedical engineering

Abstract

Bioelectronics stickers that interface the human epidermis and collect electrophysiological data will constitute important tools in the future of healthcare. Rapid progress is enabled by novel fabrication methods for adhesive electronics patches that are soft, stretchable and conform to the human skin. Yet, the ultimate functionality of such systems still depends on rigid components such as silicon chips and the largest rigid component on these systems is usually the battery. In this work, we demonstrate a quickly deployable, untethered, battery-free, ultrathin (~5 μm) passive “electronic tattoo” that interfaces with the human skin for acquisition and transmission of physiological data. We show that the ultrathin film adapts well with the human skin, and allows an excellent signal to noise ratio, better than the gold-standard Ag/AgCl electrodes. To supply the required energy, we rely on a wireless power transfer (WPT) system, using a printed stretchable Ag-In-Ga coil, as well as printed biopotential acquisition electrodes. The tag is interfaced with data acquisition and communication electronics. This constitutes a “data-by-request” system. By approaching the scanning device to the applied tattoo, the patient’s electrophysiological data is read and stored to the caregiver device. The WPT device can provide more than 300 mW of measured power if it is transferred over the skin or 100 mW if it is implanted under the skin. As a case study, we transferred this temporary tattoo to the human skin and interfaced it with an electrocardiogram (ECG) device, which could send the volunteer’s heartbeat rate in real-time via Bluetooth.

Published

2020