Calculation and optimization of plasma-optic focusing devices

(i) The focusing of an ion beam by a Morozov lens formed by a current ring in a plasma is calculated using an exact expression for the magnetic field and taking into account the nonparaxial character of the focused beam. The possible ways of optimizing such a lens are considered. (ii) Different versions of extended plasmaoptic devices in which spherical aberrations are minimized are analyzed. It is proposed to optimize extended plasma-optic devices by changing the magnetic field from the entrance end to the exit end of the solenoid in such a way that the boundary magnetic surface always coincides with the boundary surface of the focused beam. It is shown that, under the same conditions, the focusing power of the optimized devices is one to two orders of magnitude higher than that of traditional thin plasma lenses. (iii) The problem of creating a magnetic field whose strength is optimized as a function of the longitudinal coordinate is solved by the Tikhonov regularization method. (iv) An extended plasma-optic device with an optimized solenoid for focusing 1-MeV ion beams is calculated, and the ion trajectories in the device are traced. (v) It is proved expedient to develop special-purpose computer codes aimed at modeling and optimizing the existing and planned experimental plasma-optic focusing devices.     

Multifunctional Manganese Ions Trapping and Hydrofluoric Acid Scavenging Separator for Lithium Ion Batteries Based on Poly(ethylene‐alternate‐maleic acid) Dilithium Salt

Manganese dissolution from positive electrodes seriously reduces the life of Li‐ion batteries, due to its detrimental impact on the passivation of negative electrodes. A novel multifunctional separator incorporating inexpensive mass‐produced polymeric materials may dramatically increases the durability of Li‐ion batteries. The separator is made by embedding the poly(ethylene‐alternate‐maleic acid) dilithium salt polymer into a poly(vinylidene fluoride‐hexafluoropropylene) copolymer matrix. LiMn₂O₄‐graphite cells comprising a 1 m LiPF₆ solution in ethylene carbonate plus dimethyl carbonate (1:1 v/v) and the functional separator retain 31% and 100% more capacity than baseline cells with plain commercial separators after 100 cycles at C/5 rate, respectively, at 30 and 55 °C. Analyses of cycled cells indicate greatly reduced Mn contamination of the graphite negative electrodes and almost no irreversible structural change in the LiMn₂O₄ positive electrodes from cells containing the functional separator. The Mn amount in the graphite electrodes from cycled cells with functional separators is ≈80% lower than in the graphite electrodes from cycled baseline cells. Mn ions are found in the functional separators but not in baseline (plain) separators from cycled cells. Finally, it is shown that the reported performance improvements stem from the ability of the novel separator to chelate Mn ions and to scavenge trace HF.     

Polyester Separators for Lithium‐Ion Cells: Improving Thermal Stability and Abuse Tolerance

This report describes the preparation and performance of electro‐spun polyester‐based separators for lithium‐ion batteries. Polyester fibers (200–500 nm) are electro‐spun into nonwoven mats and pressed into separator sheets ～55 μm thick. The resulting polyester separators are 75% porous, highly permeable (Gurley number (s/100 mL) = 6), and have good wettability with conventional carbonate‐based electrolyte. In NMC/graphite lithium‐ion cells, results show comparable performance to commercially available polyolefin separators (rate, capacity fade, and reactivity) but with improved thermal stability to >200 °C. The use of this higher melting temperature polymer separator is one approach to close the gap between potential thermal instabilities (softening, shrinking, melting, etc.) of separators and the onset of thermal runaway reactions of commonly used cathode materials.     

Magnetotactic bacteria: promising biosorbents for heavy metals

Magnetotactic bacteria (MTB), which can orient and migrate along a magnetic line of force due to intracellular nanosized magnetosomes, have been a subject of research in the medical field, in dating environmental changes, and in environmental remediation. This paper reviews the recent development of MTB as biosorbents for heavy metals. Ultrastructures and taxis of MTB are investigated. Adsorptions in systems of unitary and binary ions are highlighted, as well as adsorption conditions (temperature, pH value, biomass concentration, and pretreatments). The separation and desorption of MTB in magnetic separators are also discussed. A green method to produce metal nanoparticles is provided, and an energy-efficient way to recover precious metals is put forward during biosorption.     

Stable Li–Organic Batteries with Nafion‐Based Sandwich‐Type Separators

Similar to Li–S batteries, Li–organic batteries have also been plagued by the dissolution of active materials and the resulting shuttle effect for many years. An effective strategy to eliminate the shuttle effect is adopting solid electrolytes or Li–ion permselective separators to prohibit the dissolved electroactive species from migrating to the Li anode. A polypropylene/Nafion/polypropylene (PNP) sandwich‐type separator is reported with many advantages in comparison with previously reported LISICON, polymer electrolyte, and other Nafion utilization forms. The physical and chemical properties of PNP separators are studied in detail by cross‐section scanning electron microscopy (SEM), infrared spectroscopy (IR), and electrochemical impedance spectroscopy. 1,1′‐Iminodianthraquinone (IDAQ), a novel organic cathode, is taken as an example to quantitatively investigate the function of PNP separators. In the presence of PNP5 with the most appropriate Nafion loading of 0.5 mg cm^–2, IDAQ is able to achieve dramatically improved cycling stability with capacity retention of 76% after 400 cycles and Coulombic efficiency above 99.6%, which reaches the highest level for reported soluble organic electrode materials. Besides Li–organic batteries, such kind of Nafion‐based sandwich‐type separators are also promising for Li–S batteries and other new battery designs involving dissolved electroactive species.     

Interface Engineering of MXene Composite Separator for High‐Performance Li–Se and Na–Se Batteries

Selenium (Se), due to its high electronic conductivity and high energy density, has recently attracted considerable interest as a cathode material for rechargeable Li/Na batteries. However, the poor cycling stability originating from the severe shuttle effect of polyselenides hinders their practical applications. Herein, highly stable Li/Na–Se batteries are developed using ultrathin (≈270 nm, loading of 0.09 mg cm^?2) cetrimonium bromide (CTAB)/carbon nanotube (CNT)/Ti₃C₂T_x MXene hybrid modified polypropylene (PP) (CCNT/MXene/PP) separators. The hybrid separator can immobilize the polyselenides via enhanced Lewis acid–base interactions between CTAB/MXene and polyselenides, which is demonstrated by theoretical calculations and X‐ray photoelectron spectroscopy. The incorporation of CNT helps to improve the electrolyte infiltration and facilitate the ionic transport. In situ permeation experiments are conducted for the first time to visually study the behavior of polyselenides, revealing the prohibited shuttle effect and protected Li anode from corrosion with CCNT/MXene/PP separators. As a result, the Li–Se batteries with CCNT/MXene/PP separators deliver an outstanding cycling performance over 500 cycles at 1C with an extremely low capacity decay of 0.05% per cycle. Moreover, the hybrid separators also perform well in Na–Se batteries. This study develops a preferable separator–electrolyte interface and the concept can be applied in other conversion‐type battery systems.     

Selection of chemical spacers to improve isoelectric focusing resolving power: implications for use in two-dimensional electrophoresis

Presented here is a straightforward and inexpensive method for expanding isoelectric focusing pH gradients relative to the gradients that are formed by commercially available narrow range ampholytes. This method requires no special equipment or techniques and is applicable to isoelectric focusing in acrylamide gels, in Sephadex, and in agarose. The utility of separators in improving the resolving power of two-dimensional polyacrylamide gel electrophoresis is demonstrated using proteins from the exocytotic trichocyst organelle of Paramecium tetraurelia. The mode of action of separators is briefly described.     

Extensions and improvements to the chordal graph approach to the multistate perfect phylogeny problem

The multistate perfect phylogeny problem is a classic problem in computational biology. When no perfect phylogeny exists, it is of interest to find a set of characters to remove in order to obtain a perfect phylogeny in the remaining data. This is known as the character removal problem. We show how to use chordal graphs and triangulations to solve the character removal problem for an arbitrary number of states, which was previously unsolved. We outline a preprocessing technique that speeds up the computation of the minimal separators of a graph. Minimal separators are used in our solution to the missing data character removal problem and to Gusfield's solution of the perfect phylogeny problem with missing data.     

A new computational method to split large biochemical networks into coherent subnets

Background  

Compared to more general networks, biochemical networks have some special features: while generally sparse, there are a small number of highly connected metabolite nodes; and metabolite nodes can also be divided into two classes: internal nodes with associated mass balance constraints and external ones without. Based on these features, reclassifying selected internal nodes (separators) to external ones can be used to divide a large complex metabolic network into simpler subnetworks. Selection of separators based on node connectivity is commonly used but affords little detailed control and tends to produce excessive fragmentation.     

Stretchable Polymerized High Internal Phase Emulsion Separators for High Performance Soft Batteries

Powering soft embodiments of robots, machines and electronics is a key issue that impacts emerging human friendly forms of technologies. Batteries as energy source enable their untethered operation at high power density but must be rendered elastic to fully comply with (soft) robots and human beings. Current intrinsically stretchable batteries typically show decreased performance when deformed due to design limitations, mainly imposed by the separator material. High quality stretchable separators such as gel electrolytes represent a key component of soft batteries that affects power, internal resistance, and capacity independently of battery chemistry. Here, polymerized high internal phase emulsions (polyHIPEs) are introduced as highly ionically conductive separators in stretchable (rechargeable) batteries. Highly porous (>80%) separators result in electrolyte to polyHIPE conductivity ratios of below 2, while maintaining stretchability of ≈50% strain. The high stretchability, tunable porosity, and fast ion transport enable stretchable batteries with internal resistance below 3 Ω and 16.8 mAh cm^?2 capacity that power on‐skin processing and communication electronics. The battery/separator architecture is universally applicable to boost battery performance and represents a step towards autonomous operation of conformable electronic skins for healthcare, robotics, and consumers.     

Recent advances in the separators for microbial fuel cells

Separator plays an important role in microbial fuel cells (MFCs). Despite of the rapid development of separators in recent years, there are remaining barriers such as proton transfer limitation and oxygen leakage, which increase the internal resistance and decrease the MFC performance, and thus limit the practical application of MFCs. In this review, various separator materials, including cation exchange membrane, anion exchange membrane, bipolar membrane, microfiltration membrane, ultrafiltration membranes, porous fabrics, glass fibers, J-Cloth and salt bridge, are systematically compared. In addition, recent progresses in separator configuration, especially the development of separator electrode assemblies, are summarized. The advances in separator materials and configurations have opened up new promises to overcome these limitations, but challenges remain for the practical application. Here, an outlook for future development and scaling-up of MFC separators is presented and some suggestions are highlighted.     

Electrochemically Stable Rechargeable Lithium–Sulfur Batteries with a Microporous Carbon Nanofiber Filter for Polysulfide

As a primary component in lithium–sulfur (Li–S) batteries, the separator may require a custom design in order to facilitate electrochemical stability and reversibility. Here, a custom separator with an activated carbon nanofiber (ACNF)‐filter coated onto a polypropylene membrane is presented. The entire configuration is comprised of the ACNF filter arranged adjacent to the sulfur cathode so that it can filter out the freely migrating polysulfides and suppress the severe polysulfide diffusion. Four differently optimized ACNF‐filter‐coated separators have been developed with tunable micropores as an investigation into the electrochemical and engineering design parameters of functionalized separators. The optimized parameters that are verified by electrochemical and microstructural analyses require the coated ACNF filter to possess the following: (i) a porous architecture with abundant micropores, (ii) small micropore sizes, and (iii) high electrical conductivity and effective electrolyte immersion. It is found that the ACNF20‐filter‐coated separator demonstrates an overall superior boost in the electrochemical utilization (discharge capacity: 1270 mA h g^?1) and polysulfide retention (capacity fade rate: 0.13% cycle^?1 after 200 cycles). These results show that the modified thin‐film‐coating technique is a viable approach to designing ultratough ACNF‐filter‐coated separators with outstanding mechanical strength and flexibility as an advanced component in Li–S cells.     

Some Features of ICR Heating by a Solenoidal Antenna

A study is made of some characteristic features of ion cyclotron resonance (ICR) heating in plasma-based isotope separators. The effects associated with ion drift in the RF field of a solenoidal antenna are considered in the single-particle approximation. Estimates are obtained and numerical calculations are carried out for ICR heating in the case of a “narrow” (ρ/r ～ 1, where ρ is the ion gyroradius) plasma flow.     

Construction of a simple flat magnetic separator

Summary A procedure for the construction of a cheap and simple flat magnetic separator is described. The separator can be used to remove magnetic carriers and sorbents from up to 500 – 1000 ml of suspension. The properties of this model and commercially available separators are similar.     

Engineering properties of separated manure solids

Separated manure solids were collected from three dairy farms with different solid-liquid separators to study the engineering properties of the material. The specific heat, thermal conductivity and mean dry particle density of the solids were determined. Equations to estimate thermal diffusivity and air-filled porosity were also developed.     

Water desorption properties of separated manure solids

Separated manure solids were collected from three dairy farms with different solid-liquid manure separators. Desorption isotherms were obtained for water desorption equilibria at five temperature levels. Three isotherm models were fitted to the data. Equations for estimating the isosteric and integral heats of desorption were also developed.     

The influence of serum separators on biochemical values in experimental animals]

The influence of three serum separators, A, B and C, on biochemical values was examined. With A or B, changes in the values of ChE, LAP, UN, K, P, Cl and Ca in rat serum; ChE, UN, Cl and Ca in dog serum; and K and P in monkey serum took place over a period of 20 min after blood collection. Therefore, the biochemical values of whole blood were considered to be stable after 20 min. Thus, biochemical tests were conducted on serum from the three serum separators after allowing the blood to stand 20 min. The values obtained for each separator were not markedly different from those of the control. These results suggest that a serum separator is useful for separation of serum of experimental animals under the proper conditions.     

High-frequency dielectrical separation of microfossils

Wang Yu-xian 1981 12 15: High-frequency dielectrical separation of microfossils. Lethaia , Vol. 14, pp. 261–268. Oslo. ISSN 0024–1164.
Microfossils can be separated from matrix particles in washed and graded samples by making use of the different dielectric properties of these two components. The separators used represent a development of earlier bi-electrode mineral separators and apply a single-electrode high-frequency electromagnetic radiation field. The sample is immersed in a fluid, generally a mixture of CCl₄ and C₂H₅OH, calibrated to a given dielectric constant. One of the particle components, normally the mudstone matrix with the higher dielectric constant (15–20), is attracted to the loop-like electrode and lifted off into an immersed small vessel, whilst the calcareous microfossils (constant 8–13) are repelled and remain; similarly the fossils may be lifted off from remaining quartz particles (constant < 7). The paper presents the constants and frequencies applied for a range of washed samples (etched samples not yet considered) and some constraints of the method. An intermediate-frequency separator is also taken into use. * Microfossils, separation methods, sample preparation, dielectric separator .     

Performance of a two-stage fermentor with cell recycle for continuous production of lactic acid

The performasnce of a recycle two-stage fermentor with cell separators after each stage is analyzed numerically for continuous production of lactic acid. In this system, the bleed broth withdrawn from the first stage is provided to the second fermentor to reuse viable cells in the bleed. Biological rate expressions and parametric values are taken from the literature. The effects of operating parameters on the concentrations of total and viable cells, substrate and product in each stage, the lactic acid productivity and the substrate conversion are examined and discussed. With respect to overall productivity and conversion, it is found that the present fermentor system is more efficient than a conventional chemostat fermentor with cell recycle.     

Application of aqueous hydrazine solution for beta-elimination of O-glycans from gastric mucin

O-Glycans from pig gastric mucin were released by beta-elimination in 0.2 M triethylamine and 50% aqueous hydrazine solution. The released glycan hydrazides were isolated using Centricon 10 separators, brought to their reducing form and reductive by labelled with p-aminobenzoic acid ethyl ester (ABEE). Labelled products were fractionated into neutral and acid fractions on a Bio-Gel P4 column, calibrated with a mixture of dextran oligosaccharides, labelled according to the same procedure.