Coil Electrode Research Articles

High-Coupled Magnetic-Levitation Hybrid Nanogenerator with Frequency Multiplication Effect for Wireless Water Level Alarm.

Hybrid nanogenerators (HNGs) represent a promising avenue for water energy harvesting, yet their commercial viability faces hurdles such as limited power output, poor coupling, and constrained operational lifespans. Here, a highly coupled triboelectric-electromagnetic magnetic-levitation hybrid nanogenerator (ML-HNG) is introduced that shows great potential for water energy harvesting. The ML-HNG fulfills the challenges of high power output, strong coupling, and long operational lifespans. During the contact-separation process of the triboelectric nanogenerator (TENG), the changing magnetic flux in the electromagnetic generator's coils generates a potential difference between the coils and Cu electrodes. The unique design of the ML-HNG employs a shared coil electrode configuration, which enhances the coupling without adding extra volume. This integration allows the ML-HNG to achieve multi-frequency vibrations and multiple output cycles per external longitudinal movement, a phenomenon known as the frequency multiplication effect. With an average power density of 1.69W m-3 in water, the ML-HNG provides continuous power for a thermo-hygrometer and can quickly drive a wireless water level alarm system within a minute. This groundbreaking hybrid nanogenerator design holds significant promise for the efficient and consistent harvesting of low-frequency ocean wave energy, marking a substantial advancement in blue energy technology.

5‐2: Integrated Design of Capacitive Touch and Electromagnetic Sensor for Flexible OLED Display

This work presents a novel structure for integrating capacitive touch and electromagnetic resonance (EMR) sensors on thin film encapsulation (TFE) of OLED display. Through co‐layer design of touch bridge electrode and EMR coil, the number of mask can be reduced, and the module thickness can also be decreased. In addition, the Cs loading of touch and the resistance of EMR coils are both reduced by the unique pattern design. Finally, an 8‐inch prototype sample was developed, and the hybrid sensor achieved sensitive touch and EMR stylus scribing functions after debugging.

The role of the cardiac vagus in maintaining cardiac function during exercise

There is a strong association between parasympathetic nervous system activity (vagal tone) and physical fitness. High vagal tone is associated with increased capacity to exercise and overall cardiovascular health. Evidence for vagal withdrawal during exercise comes from historic studies examining heart rate control and the use of cholinergic blockers. However, more recent studies have challenged this assumption. We hypothesized that cardiac vagal activity increases during exercise and maintains cardiac function via neurotransmitters other than acetylcholine. The left cardiac vagal branch was identified in anesthetized open-chested sheep. Cardiac innervation of the left cardiac vagal branch was confirmed with lipophilic tracer dyes (DiO). Custom-built coil electrodes were placed around the left cardiac vagal branch. 3-10 days after surgery, conscious, direct recordings of cardiac vagal nerve activity (CVNA), cardiac output, coronary artery blood flow and heart rate were recorded in adult female sheep during whole-body treadmill exercise. Sheep were exercised with pharmacological blockers of acetylcholine (atropine, 250 mg), vasoactive intestinal peptide (VIP) ([4Cl−D-Phe6,Leu17]-VIP 25 μg), or saline control, randomized on different days. In a subset of sheep, the left cardiac vagal branch was denervated. Neural innervation from the cardiac vagal branch is seen at major cardiac ganglionic plexi, and within the fat pads associated with the coronary arteries. Directly recorded CVNA increased during exercise. CVNA increases during the lowest exercise intensity and plateaus as exercise intensity increases. Left cardiac vagal branch, denervation attenuated the maximum changes in coronary artery blood flow (maximum exercise, control: 63.5 ± 5.9 ml/min, n = 8, cardiac vagal denervated: 32.7 ± 5.6 ml/min, n = 6, mean ± SEM. P = 2.5x10−7. Two-way ANOVA-interaction), cardiac output and heart rate during exercise. Atropine did not affect any cardiac parameters during exercise, but VIP antagonism significantly reduced coronary artery blood flow during exercise to a similar level to vagal denervation (maximum exercise, paired: control: 68.2 ± 6.0 ml/min, VIP antagonism: 44.9 ± 3.9 ml/min, n = 6, mean ± SEM. P = 4.8x10−3. Two-way ANOVA-interaction). Our study challenges the conventional view and demonstrates that cardiac vagal nerve activity increases and is crucial for maintaining cardiac function during exercise. Furthermore, our findings show that the dynamic modulation of coronary artery blood flow during exercise is mediated by VIP and that acetylcholine has no role in modulating cardiac function during exercise. This work is supported by the Health Research Council of New Zealand 23/119 (Fellowship. JS) and the New Zealand Heart Foundation (JS, RR). This is the full abstract presented at the American Physiology Summit 2024 meeting and is only available in HTML format. There are no additional versions or additional content available for this abstract. Physiology was not involved in the peer review process.

Effect of Pore Size on the Oxygen Evolution Reaction Activity of Hydrogel Electrodes Composed of Hybrid Cobalt Hydroxide Nanosheets

Introduction Alkaline water electrolysis (AWE) is a promising technology for large-scale production of hydrogen from renewable energy; however, the sluggish oxygen evolution reaction leads to a large overvoltage. Porous electrodes with a large specific surface area are useful to achieve high current densities in AWE, whereas mass transport in small pores often reduces the overall current density. We have reported that hydrogel electrodes, possessing a flexible framework composed of interconnected hybrid cobalt hydroxide nanosheets (Co-ns), exhibit enhanced mass transport at high current density.1 Hydrogel electrodes can be regarded as porous electrodes swollen by electrolytes. They are expected to repair cracked surfaces by recombination of microparticles and to optimize the framework structure suitable for mass transport. In this study, we demonstrate the relationship between the pore size of the hydrogel electrodes and the OER activity at high current density. Experiment Co-ns was synthesized by mixing aqueous solutions of 1.0 M tris(hydroxymethyl)aminomethane and 0.1 M CoCl2·6H2O, followed by heating at 90 °C.2 The heating time was varied as 1, 5 and 10 days in order to control the particle size.Electrochemical measurements were performed in a 1.0 M KOH, using a PFA three-electrode cell. Co-ns was dispersed in the electrolyte (200 ppm). Nickel plate, nickel coil, and reversible hydrogen electrode (RHE) were used as working, counter, and reference electrodes, respectively. Co-ns was deposited on the electrode by constant current electrolysis at 800 mA cm–2 for varied time (10 min–100 h). The OER activity was evaluated by cyclic voltammetry (CV) and electrochemical impedance spectroscopy for iR correction. Result and Discussion TEM images of the synthesized Co-ns exhibited that the diameter (long axis) of Co-ns increased along with the heating time. Therefore, the samples were named as 1d_21, 5d_34 and 10d_42, based on the heating time (days) and average diameter (nm). The FESEM images of the hydrogels after drying showed that nanosheets were assembled into house-of-cards structures (Figure 1). The assembled structures of Co-ns with different diameters were analogous to each other.The charges of the cathodic peaks (Q c) at 0.8–1.5 V vs. RHE due to Co2+/3+ and Co3+/4+ in cyclic voltammograms were used as a measure of the amount of deposited Co-ns. The linear relationship between Q c and the thickness of catalyst layers exhibited that deposited Co-ns presented uniformly along the thickness of catalyst layers (Figure 2). The slope of this line corresponds to the porosity of the hydrogels. The porosity increased along with the diameter of Co-ns; therefore, the pore size is expected to depend on the diameter of Co-ns because of the analogy of the assembled structure.Polarization curves of representative hydrogels are shifted from the Tafel equation at high current densities, indicating the influence of mass transport (Figure 3). The OER current densities at 1.6 V vs. RHE (i geo-1.6 V) of relatively thin hydrogels were linearly correlated with their thicknesses (Figure 4), though they were saturated for hydrogels with larger thicknesses. In the thicker hydrogels, OER is limited by mass transport of generated O2 and OH– in pores. The order of the limiting current densities were 1d_21 < 5d_34 < 10d_42; thus, the influence of mass transport is lowered for hydrogels with larger pores.In conclusion, the size of Co-ns was used to control the porosity and pore size of hydrogel electrodes. Hydrogel electrodes with larger pore size exhibited better mass transport to achieve higher OER activity at high current density. These insights will contribute to designing an optimal hydrogel as an oxygen evolving electrode. Acknowledgement This work was supported partially by the JSPS KAKENHI from MEXT, Japan. References R. Nakajima, T. Taniguchi, Y. Sasaki, Y. Nishiki, A. Zaenal, T. Nakai, A. Kato, S. Mitsushima, and Y. Kuroda, Autumn Meeting of the Electrochemical Society of Japan, 1P15 (2022).Y. Kuroda, T. Koichi, K. Muramatsu, K. Yamaguchi, N. Mizuno, A. Shimojima, H. Wada, and K. Kuroda, Chem. Eur. J., 23 (2017) 5023. Figure 1

Data-driven plasma modelling: surrogate collisional radiative models of fluorocarbon plasmas from deep generative autoencoders

We have developed a deep generative model that can produce accurate optical emission spectra and colour images of an ICP plasma using only the applied coil power, electrode power, pressure and gas flows as inputs—essentially an empirical surrogate collisional radiative model. An autoencoder was trained on a dataset of 812 500 image/spectra pairs in argon, oxygen, Ar/O2, CF4/O2 and SF6/O2 plasmas in an industrial plasma etch tool, taken across the entire operating space of the tool. The autoencoder learns to encode the input data into a compressed latent representation and then decode it back to a reconstruction of the data. We learn to map the plasma tool’s inputs to the latent space and use the decoder to create a generative model. The model is very fast, taking just over 10 s to generate 10 000 measurements on a single GPU. This type of model can become a building block for a wide range of experiments and simulations. To aid this, we have released the underlying dataset of 812 500 image/spectra pairs used to train the model, the trained models and the model code for the community to accelerate the development and use of this exciting area of deep learning. Anyone can try the model, for free, on Google Colab.

Dry Extrusion Process for Manufacturing of High-Energy Cathodes for Lithium-Ion Batteries

For a sustainable production of lithium ion batteries, more environmentally friendly, energy saving and faster strategies are required. For cathode production NCM/NCA layered oxides are commonly used as active materials. Nevertheless, application of the very toxic and teratogenic solvent N-methylpyrrolidone (NMP) is still common for the industrial production of these cathodes. Besides the high toxicity, the NMP recovery after coating is very energy-, time- and cost-intensive.As an alternative, to conventional NMP-based cathode production, we developed a dry extrusion process coupled with slot-die coating, to manufacture high-energy cathodes. The extrusion process offers continuous production, alongside a very good scalability to industrial demands and a significant reduction of mixing time. Since the process is NMP-free and the drying step is saved, it overcomes typical shortcomings of the wet coating as crack formation or binder migration occurring during solvent evaporation. In addition, producing high-energy electrodes leads to lower material costs and space savings, since less layers of Al/Cu foil and separator are required on cell level, compared to a battery of the same capacity and lower electrode mass loading.Herein, we present the development of a dry cathode manufacturing process, a suitable recipe for dry processing, consisting of NCM622, PVdF, carbon black and a superplasticizer, as well as the optimization of the formulation in terms of processability and active material content. We also discuss the influence of process parameters such as temperature or rotation speed on the viscosity of the cathode paste. As a proof of concept, we processed powder mixtures, corresponding to our optimized formulation with about 90 % of NCM, in a pilot scale twin-screw extruder. By melt extrusion through a slot die, we create a thin film from the cathode composite that we directly apply on an Al current collector. We show a schematic representation of the process in the attracted graphic. By repositioning of the electrode coil, we also produce double-sided coatings. After calendaring, we characterize the dry processed electrodes electrochemically in half-cells. The electrochemical performance data is comparable to state of the art cathodes and results are promising that even higher active material contents can be reached. Therefore, the solvent free extrusion of cathodes is highly relevant for industrial applications.AcknowledgementThe presented work was financially supported by BMBF within the project Tropex under the reference number 03XP0235C. Figure 1

Acute human defibrillation performance of a subcutaneous implantable cardioverter-defibrillator with an additional coil electrode

The subcutaneous implantable cardioverter-defibrillator (S-ICD) delivers 80 J shocks from an 8 cm left-parasternal coil to a 59 cm3 left lateral pulse generator (PG). A system that defibrillates with lower energy could significantly reduce PG size. Computer modeling and animal studies suggested that a second shock coil either parallel to the left-parasternal coil or transverse from the xiphoid to the PG pocket would significantly reduce the defibrillation threshold. The purpose of this study was to acutely assess the defibrillation efficacy of parallel and transverse configurations in patients receiving an S-ICD. Testing was performed in patients receiving a conventional S-ICD system. Success at 65 J was required before investigational testing. A second electrode was temporarily inserted from the xiphoid incision connected to the PG with an investigational Y-adapter. Phase 1 (n = 11) tested the parallel configuration. Phase 2 (n = 21) tested both parallel and transverse configurations in random order. This study enrolled 35 patients (28 males (80%); mean age 51 ± 17 years; left ventricular ejection fraction 40% ± 15%; body mass index 26 ± 4 kg/m2; prior myocardial infarction 46%; congestive heart failure 49%; cardiomyopathy 63%). Compared to the conventional S-ICD system, mean shock impedance decreased for both parallel (69 ± 15 Ω vs 86 ± 20 Ω; n = 33; P < .001) and transverse (56 ± 14 Ω vs 81 ± 21 Ω; n = 20; P < .001) configurations. Shock success rates at 20, 30, and 40 J were 55%, 79%, 97%, and 25%, 70%, 90% for parallel and transverse configurations, respectively. Defibrillation threshold testing was well tolerated with no serious adverse events. Adding a second shock coil, particularly in the parallel configuration, significantly reduced the impedance and had a high likelihood of defibrillation success at energies ≤40 J. This may enable the development of a smaller S-ICD.

Utility of a multipurpose catheter for transvenous extraction of old broken leads: A novel technique for fragile leads

Transvenous lead extraction has been possible since the 1980s. However, complications during lead extraction, such as the distal end fragment of the lead remaining in the myocardium or venous system and injury to the veins or heart, have been reported. The purpose of this study was to examine our method for complete removal of a separated lead, as extraction of long-term implanted devices is difficult using standard methods and may require additional procedures. The removal of leads with inner conductor coil and lead tip separated from outer insulation, conductor coil, and proximal ring electrode using a multipurpose catheter is reported. In total, 345 consecutive patients who underwent transvenous lead extraction (TLE) from April 2014 to March 2021 were retrospectively analyzed. Lead characteristics, device type, and indications for extraction were further analyzed in 20 patients who developed separation of the proximal ring electrode and outer conductor coil from the inner conductor and distal tip at the time of extraction. Extractions were performed using an excimer laser sheath laser and a Byrd polypropylene telescoping sheath (n = 15); laser, Byrd polypropylene telescoping sheath, and Evolution RL (n = 2); laser and Evolution RL (n = 3); Byrd polypropylene telescoping sheath and Evolution RL (n = 1); Byrd polypropylene telescoping sheath only (n = 4); and Evolution RL only (n = 2). Twenty-seven leads implanted for more than 10 years had lead separation. A multipurpose catheter was used to protect the fragile leads from further damage. All leads were completely extracted. All distal tip-to-proximal ring electrode separated leads were successfully removed using laser and other sheaths with the assistance of a multipurpose catheter, without any part of the leads remaining in the heart.

Measurement of current distribution using infrared thermography.

Current distribution measurement methods are widely used in medical examinations, predicting faults in semiconductor devices and assessing structural integrity. Several methods for measuring current distribution are available, such as electrode arrays, coils, and magnetic sensors. However, these measurement methods are unable to obtain images of current distribution with high spatial resolution. Therefore, there is a need to develop a non-contact method to measure current distribution that is capable of capturing images with high spatial resolution. In this study, a non-contact current distribution measurement method based on infrared thermography is proposed. The method uses thermal variations to quantify the current amplitude and reconstructs the current direction based on the passivity of the electric field. For quantification of low frequency current amplitude, the experimental results show that the method can provide accurate current measurement results, for example, at the power frequency (50Hz), in the range of 1.05-3.45A, its relative error can be improved to ±3.66% when the calibration fitting method is used. For the high-frequency current, an effective estimate of the current amplitude is obtained using the first-order derivative of temperature variation. When applied to the eddy current detection (256 KHz), it achieves a high-resolution image of the current distribution, and the effectiveness of the method is verified through simulation experiments. The experimental results show that the proposed method not only measures the current amplitude accurately but also improves the spatial resolution in acquiring two-dimensional current distribution images.

Development and implementation of in-line segmentation for continuous electrode production in lithium-ion battery cell manufacturing for traceability applications

One of the biggest challenges in battery cell production is reducing manufacturing costs. Production errors and manufacturing inaccuracies due to a complex process chain and cost-intensive material flows lead to high scrap rates and costs. In order to detect and eliminate production errors early in the manufacturing process, traceability approaches have been increasingly referred to in the literature. Here, process and product parameters are already assigned to the individual intermediate products and used to evaluate whether further processing is possible. When transferring traceability concepts to battery cell production, the challenge is to identify individual sections in the continuous processes of electrode production. These process steps have a decisive influence on the later electrochemical performance of the battery cells and have so far only been performed in batches to reduce possible defects. This paper presents two approaches to segmenting the produced electrodes in-line in the coating process to provide discrete sections for tracking and tracing applications. Production data are allocated to single electrodes instead of the entire electrode coil. Laser and ink marking systems are used to apply unique markings that are subsequently read out for product and process data assignment. Appropriate integration requirements must be met for both marking systems to apply readable markings. The requirements are derived for both marking systems from the respective mode of operation and compared with each other. It is shown that laser systems are more technically challenging and cost-intensive to integrate than ink systems but offer greater geometrical flexibility. Furthermore, it is shown how both marking technologies are integrated into the respective coating lines for lithium-ion battery electrodes within the pilot production lines at two research facilities. The traceability of product data to individual electrode sections is demonstrated using in-line and hand-measured electrode areal mass loading data.

Lowering of Electrostatic Actuator Driving Voltage and Increasing Generated Force Using Spontaneous Polarization of Ferroelectric Nematic Liquid Crystals

AbstractAlthough electrostatic actuators have a simple structure and are lightweight, their range of application is limited because a high applied voltage of more than several kilovolts is required for practical use. Since the force acting between the electrodes of an electrostatic actuator is determined by the electric charge accumulated at the electrode/dielectric interface, the focus is on spontaneous polarization of ferroelectrics to increase the charge. As the ferroelectric material, a nematic liquid crystal material with a spontaneous polarization of 5 µC cm−2 is used. It is demonstrated that a force of 1.3 N is generated at an applied electric field of 0.5 MV m−1. This force is 1200 times higher than that for standard paraelectric materials with a dielectric constant of ten. Further, the generated force responds linearly to the applied voltage, whereas it is proportional to the square of the applied voltage for paraelectric materials. The actuator function of this ferroelectric is examined using a double‐helical coil electrode fabricated using a 3D printer. It can be successfully operated at a voltage of several tens of volts. Under an electric field of 0.25 MV m−1, a remarkable contraction of 6.3 mm occurs, corresponding to 19% of the original length.

Failed shocks in hypertrophic cardiomyopathy patients: prevalence, predictors and outcome

Abstract Funding Acknowledgements Type of funding sources: None. Introduction An implantable cardioverter-defibrillator (ICD) is used in selected high-risk hypertrophic cardiomyopathy (HCM) patients in order to prevent sudden arrhythmic death. The unique features of this population raise concerns regarding the reliability of successful defibrillation. Purpose To describe the rate and discover potential predictors of failed shocks in HCM patients. Methods We retrospectively evaluated all HCM patients with an ICD from a single tertiary medical center. Clinical, electrocardiographic and echocardiographic data were collected and compared among patients with and without failed shocks. Results A total of 99 patients (77% male, 45±17 years old) were analyzed. Over a median follow up of 6.3 years (IQR 2.6-10.7), 20 patients developed sustained ventricular arrhythmia (VTA). Of those, 18 patients received appropriate shocks from their ICD. VTA was associated with younger age at diagnosis, history of syncope and thicker maximal LV width. Six patients experienced at least one failed shock. The likelihood of failed shocks was similar when single or dual coil electrodes were used (dual coils in 67% of patients with failed shocks and 50% in those without), and the only predictor was increased wall thickness [OR 1.2 (1.07-1.38) per 1 mm]. All-cause mortality was low and similar in patients with an without failed shocks (0% vs 8%, P=0.5) Conclusions Failed shocks are a rare entity in HCM patients. Increased maximal LV width was the only predictor of those events. Our findings support avoiding defibrillation threshold testing routinely, but may indicate its need in patients with extreme LV wall thickening (≥23 mm).

Degradation Characteristics of Wastewater Containing 2-Chlorophenol and 4-Chlorophenol Compounds, Using a Dielectric Barrier Discharge (DBD) Cold Plasma Reactor

Wastes containing phenolic compounds, including 2-chlorophenol and 4-chlorophenol at a threshold exceeding 50 mg / L, are very harmful to the environment. The processing of waste containing phenolic compounds using ozone and plasma technology is therefore an environmentally friendly and relatively inexpensive solution. The processing carried out in this study uses ozone plasma technology. Plasma is generated by high voltage transformator which is fed into electrodes wound on a reactor made of quartz glass. The reactor type is dielectric barrier discharge (DBD) have the ability to degrade these waste, by producing reactive oxygen species, including •OH, •O 2 - and molecular species of O 3 , H 2 O 2 . Subsequently, active species with high energy are transferred to the liquid phase, to react with chlorophenol compounds. According to the results, the dielectric barrier discharge plasma reactor using electrode coils was able to degrade waste containing 2-chlorophenol compounds by 70.96% and 79.41%, in acidic and alkaline conditions, respectively, while, 4-chlorophenol was degraded by 23.42% and 53.54%, in acidic and alkaline conditions, respectively.

External Dynamic InTerference Estimation and Removal (EDITER) for low field MRI.

Point-of-care MRI requires operation outside of Faraday shielded rooms normally used to block image-degrading electromagnetic interference (EMI). To address this, we introduce the EDITER method (External Dynamic InTerference Estimation and Removal), an external sensor-based method to retrospectively remove image artifacts from time-varying external interference sources. The method acquires data from multiple EMI detectors (tuned receive coils as well as untuned electrodes placed on the body) simultaneously with the primary MR coil during and between image data acquisition. We calculate impulse response functions dynamically that map the data from the detectors to the time varying artifacts then remove the transformed detected EMI from the MR data. Performance of the EDITER algorithm was assessed in phantom and in vivo imaging experiments in an 80mT portable brain MRI in a controlled EMI environment and with an open 47.5mT MRI scanner in an uncontrolled EMI setting. In the controlled setting, the effectiveness of the EDITER technique was demonstrated for specific types of introduced EMI sources with up to a 97% reduction of structured EMI and up to 76% reduction of broadband EMI in phantom experiments. In the uncontrolled EMI experiments, we demonstrate EMI reductions of up to 99% using an electrode and pick-up coil in vivo. We demonstrate up to a nine-fold improvement in image SNR with the method. The EDITER technique is a flexible and robust method to improve image quality in portable MRI systems with minimal passive shielding and could reduce the reliance of MRI on shielded rooms and allow for truly portable MRI.

Design of Vacuum Post‐Drying Procedures for Electrodes of Lithium‐Ion Batteries

AbstractIn order to reduce the residual moisture in lithium‐ion batteries, electrodes and separators need to be post‐dried prior to cell assembly. On an industrial scale, this is often conducted batch‐wise in vacuum ovens for larger electrode and separator coils. Especially for electrodes, the corresponding post‐drying parameters have to be carefully chosen to sufficiently reduce the moisture without damaging the sensitive microstructure. This requires a fundamental understanding of structural limitations as well as heat transfer and water mass transport in coils. The aim of this study is to establish a general understanding of the vacuum post‐drying process of coils. Moreover, the targeted design of efficient, well‐adjusted and application‐oriented vacuum post‐drying procedures for electrode coils on the basis of modelling is employed, while keeping the post‐drying intensity as low as possible, in order to maintain the sensitive microstructure and to save time and costs. In this way, a comparatively short and moderate 2‐phase vacuum post‐drying procedure is successfully designed and practically applied. The results show that the designed procedure is able to significantly reduce the residual moisture of anode and cathode coils, even with greater electrode lengths and coating widths, without deteriorating the sensitive microstructure of the electrodes.

Comparing the electric fields of transcranial electric and magnetic perturbation

Significance. Noninvasive brain stimulation (NIBS) by quasistatic electromagnetic means is presently comprised of two methods: magnetic induction methods (transcranial magnetic perturbation or TMP) and electrical contact methods (transcranial electric perturbation or TEP). Both methods couple to neuronal systems by means of the electric fields they produce. Both methods are necessarily accompanied by a scalp electric field which is of greater magnitude than anywhere within the brain. A scalp electric field of sufficient magnitude may produce deleterious effects including peripheral nerve stimulation and heating which consequently limit the spatial and temporal characteristics of the brain electric field. Presently the electromagnetic NIBS literature has produced an accurate but non-generalized understanding of the differences between the TEP and TMP methods. Objective. The aim of this work is to contribute a generalized understanding of the differences between the two methods which may open doors to novel TEP or TMP methods and translating advances, when possible, between the two methods. Approach. This article employs a three shell spherical conductor head model to calculate general analytical results showing the relationship between the spatial scale of the brain electric fields and: (1) the scalp-to-brain mean-squared electric field ratio for the two methods and (2) TEP-to-TMP scalp mean-squared electric field ratio for similar electric fields at depth. Main results. The most general result given is an asymptotic limit to the TEP-to-TMP ratio of scalp mean-squared electric fields for similar electric fields at depth. Specific example calculations for these ratios are also given for typical TEP electrode and TMP coil configurations. While TMP has favorable mean-squared electric field ratios compared to TEP this advantage comes at an energetic cost which is briefly elucidated in this work.

Improvement of GaN plasma etching uniformity by optimizing the coil electrode with plasma simulation and experimental validation

GaN-based semiconductor devices such as LEDs and power electronic devices are widely used but device fabrication can be further optimized by improving the uniformity and throughput. In inductively-coupled plasma (ICP) etching, the coil can be optimized to produce a tunable plasma distribution to improve the etching uniformity. Different from planar coils, the dual spiral decreases the electric field and magnetic field coupling between the inner and outer coils by enlarging the space without changing the equipment. The vertically arranged coils in each group can independently control plasma generation in the separate zone and tunable etching uniformity can be achieved by varying the power supplied to the inner and outer coils. The etching uniformity is improved from 5.83% to 2.95% based on maximum-minus-minimum (M-N) calculation and from 3.93% to 1.42% with the average value calculated by using the optimized coil structure. Plasma simulation and experiments confirm the source of etching non-uniformity and the knowledge is important to the fabrication of GaN-based and other devices, especially large-scale industrial production requiring low cost and 450 mm wafer capability.

High shocking and pacing impedances due to defibrillation lead calcification

PurposeWe have reported the calcification of Endotak defibrillation leads that required replacement. The aim of this study was to assess calcified Endotak Reliance leads in the Food and Drug Administration Manufacturer and User Facility Device Experience (MAUDE) database and compare them to calcified Sprint Fidelis, Sprint Quattro Secure, Riata, and Durata leads in MAUDE.MethodsWe searched the MAUDE database from 2008 to 2019 for defibrillation lead calcification using the terms “calcium,” “calcification,” and “calcified”. Included were explanted leads whose manufacturers found calcium on the shocking and/or pacing electrode.ResultsThe MAUDE search identified 113 calcified defibrillation leads that qualified for the study, including 109 Endotak Reliance leads, 1 Sprint Quattro Secure lead, 2 Durata leads, 1 Riata ST lead, and no Sprint Fidelis lead. The sign of calcification was a gradual increase in shocking or pacing impedance. Average implant time was 7.4 ± 3.1 (range: 1.3–16.5) years. Only Endotak Reliance leads had shocking coil calcification (n = 72; 66.0%) and five (6.9%) of these failed defibrillation threshold (DFT) testing. Distal pacing electrode calcification affected 55 (50.4%) Endotak Reliance leads. The four other leads had pacing ring electrode calcification only.ConclusionEndotak Reliance defibrillation leads appear prone to shocking coil and/or distal pacing electrode calcification. High impedances may compromise defibrillation and pacing therapy. Patients who have these leads should be monitored; those exhibiting high shocking impedances should be considered for DFT testing. Lead replacement should be considered for pacemaker-dependent patients whose leads exhibit progressively high impedances.

Effect of Electrode Geometry on Selectivity and Activity in CO2 Electroreduction

We investigated the effect of the electrode geometry on the product selectivity and catalytic activity in CO2 electroreduction (CO2ELR) for equal surface area Cu and Ag electrodes. Three different geometries (wire coil, foil coil, and flag) with relatively smooth surfaces were chosen for this study. The electrode geometry impacts the current density distribution on the electrode and the different current densities create an electric field distribution on the electrode surface. The geometry that causes the higher current density distribution (coil wire) showed higher total current density and lower charge transfer resistance in comparison with the flag-shaped electrodes for both Cu and Ag. The results showed that the current density distribution changes due to the geometry influences the product selectivity as well. Cu coil electrodes showed higher faradaic efficiency (FE) for C2 products in comparison to the Cu flag. Ag coil showed higher FE% for CO compared to the Ag flag.

Vagal Nerve Stimulator Lead Revision Using Needle-Tip Cautery: Case Series, Literature Review, and Technical Note

Abstract INTRODUCTION Vagal nerve stimulators (VNs) have been in use in the United States since the 1990s as a palliative treatment option for drug-resistant epilepsy. Over time, the electrode coils wrapped around the vagus nerve become encapsulated by extensive scar tissue, making complete electrode removal challenging. We present a case series of lead revision surgeries with a unique way to remove the scar tissue around the vagus nerve, demonstrating a technique for complete electrode removal. METHODS This was a case series of 9 consecutive patients who underwent complete removal of an existing VNs electrode using needle tip monopolar electrocautery. RESULTS Complete removal of the entire VNs electrode array was achieved in all patients with no permanent complications seen at postoperative follow-up at 3 mo. CONCLUSION Complete VNs electrode array removal can be safely achieved by using needle tip monopolar electrocautery.