Search results for "litium"

showing 10 items of 29 documents

Pot-Economy Autooxidative Condensation of 2-Aryl-2-lithio-1,3-dithianes

2018

The autoxidative condensation of 2-aryl-2-lithio-1,3-dithianes is here reported. Treatment of 2-aryl-1,3-dithianes with n-BuLi in the absence of any electrophile leads to condensation of three molecules of 1,3-dithianes and formation of highly functionalized α-thioether ketones orthothioesters in 51-89% yields upon air exposure. The method was further expanded to benzaldehyde dithioacetals, affording corresponding orthothioesters and α-thioether ketones in 48-97% yields. The experimental results combined with density functional theory studies support a mechanism triggered by the autoxidation of 2-aryl-2-lithio-1,3-dithianes to yield a highly reactive thioester that undergoes condensation wi…

116 Chemical sciencesorganometalliyhdisteet010402 general chemistryThioester01 natural sciencesMedicinal chemistryBenzaldehydechemistry.chemical_compoundorganometallic compoundsMoleculeta116chemistry.chemical_classificationAutoxidation010405 organic chemistryoxidation (passive)ArylOrganic ChemistryCondensationhapettuminenautooxidative condensation0104 chemical scienceslitiumchemistrylithiumYield (chemistry)ElectrophileThe Journal of Organic Chemistry

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An over-the-distance wireless battery charger based on RF energy harvesting

2017

An RF powered receiver silicon IC (integrated circuit) for RF energy harvesting is presented as wireless battery charger. This includes an RF-to-DC energy converter specifically designed with a sensitivity of -18.8 dBm and an energy conversion efficiency of â¼45% at 900 MHz with a transmitting power of 0.5 W in free space. Experimental results concerned with remotely battery charging using a complete prototype working in realistic scenarios will be shown.

Battery (electricity)EngineeringInternet of Things02 engineering and technologyIntegrated circuitInternet of Things; Litium Ion Battery; Radio Frequency Harvesting; Wireless Battery Charger; Wireless Sensor Networks; Hardware and Architecture; Electrical and Electronic Engineering; Modeling and SimulationSettore ING-INF/01 - ElettronicaRadio Frequency Harvestinglaw.inventionBattery chargerlawWireless Battery ChargerHardware_INTEGRATEDCIRCUITS0202 electrical engineering electronic engineering information engineeringElectronic engineeringElectrical and Electronic Engineeringbusiness.industry020208 electrical & electronic engineeringEnergy conversion efficiencyElectrical engineering020206 networking & telecommunicationsHardware and ArchitectureModeling and SimulationLitium Ion BatteryRadio frequencyInternet of ThingWireless Sensor NetworksbusinessEnergy harvestingSensitivity (electronics)Wireless sensor networkWireless Sensor Network2017 14th International Conference on Synthesis, Modeling, Analysis and Simulation Methods and Applications to Circuit Design (SMACD)

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In-Operando Lithium-Ion Transport Tracking in an All-Solid-State Battery.

2022

An all-solid-state battery is a secondary battery that is charged and discharged by the transport of lithium ions between positive and negative electrodes. To fully realize the significant benefits of this battery technology, for example, higher energy densities, faster charging times, and safer operation, it is essential to understand how lithium ions are transported and distributed in the battery during operation. However, as the third lightest element, methods for quantitatively analyzing lithium during operation of an all-solid-state device are limited such that real-time tracking of lithium transport has not yet been demonstrated. Here, the authors report that the transport of lithium …

BiomaterialsionitlitiumsäteilyfysiikkatutkimusmenetelmätGeneral Materials ScienceelektrolyytitGeneral ChemistryjäljitysakutBiotechnologySmall (Weinheim an der Bergstrasse, Germany)

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A Battery-Free Smart Sensor Powered with RF Energy

2018

The development of Internet of Things (IoT) infrastructure and applications is stimulating advanced and innovative ideas and solutions, some of which are pushing the limits of state-of-the-art technology. The increasing demand for Wireless Sensor Network (WSN) that must be capable of collecting and sharing data wirelessly while often positioned in places hard to reach and service, motivates engineers to look for innovative energy harvesting and wireless power transfer solutions to implement battery-free sensor nodes. Due to the pervasiveness of RF (Radio Frequency) energy, RF harvesting that can reach out-of-sight places could be a key technology to wirelessly power IoT sensor devices, whic…

Computer Networks and CommunicationsComputer scienceInternet of ThingsEnergy Engineering and Power TechnologyRadio Frequency HarvestingIndustrial and Manufacturing EngineeringArtificial IntelligenceWireless Battery ChargerWirelessRenewable EnergyWireless power transferInstrumentationSustainability and the Environmentbusiness.industryRF power amplifierTransmitterElectrical engineeringComputer Science Applications1707 Computer Vision and Pattern RecognitionInternet of Things; Litium Ion Battery; Radio Frequency Harvesting; Wireless Battery Charger; Wireless Power Transfer; Wireless Sensor Networks; Artificial Intelligence; Computer Networks and Communications; Computer Science Applications1707 Computer Vision and Pattern Recognition; Energy Engineering and Power Technology; Renewable Energy Sustainability and the Environment; Industrial and Manufacturing Engineering; InstrumentationSensor nodeLitium Ion BatteryWireless Power TransferRadio frequencyInternet of ThingWireless Sensor NetworksbusinessEnergy harvestingWireless sensor network2018 IEEE 4th International Forum on Research and Technology for Society and Industry (RTSI)

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Precipitation and Calcination of High-Capacity LiNiO2 Cathode Material for Lithium-Ion Batteries

2020

This article presents the electrochemical results that can be achieved for pure LiNiO2 cathode material prepared with a simple, low-cost, and efficient process. The results clarify the roles of the process parameters, precipitation temperature, and lithiation temperature in the performance of high-quality LiNiO2 cathode material. Ni(OH)2 with a spherical morphology was precipitated at different temperatures and mixed with LiOH to synthesize the LiNiO2 cathode material. The LiNiO2 calcination temperature was optimized to achieve a high initial discharge capacity of 231.7 mAh/g (0.1 C/2.6 V) with a first cycle efficiency of 91.3% and retaining a capacity of 135 mAh/g after 400 cycles. These a…

LNOcathodeMaterials scienceelektroditlitiumioniakutchemistry.chemical_elementlithium-ion battery02 engineering and technology010402 general chemistryElectrochemistrylcsh:Technology01 natural sciencesLithium-ion batteryIonlaw.inventionlcsh:Chemistrylithium nickel oxideCathode materiallawGeneral Materials ScienceCalcinationlcsh:QH301-705.5InstrumentationFluid Flow and Transfer Processeslcsh:TPrecipitation (chemistry)Process Chemistry and TechnologyGeneral Engineeringmateriaalit021001 nanoscience & nanotechnologysähkökemialcsh:QC1-999Cathode0104 chemical sciencesComputer Science Applicationslitiumlcsh:Biology (General)lcsh:QD1-999Chemical engineeringchemistrylcsh:TA1-2040oksiditLithiumnikkelilcsh:Engineering (General). Civil engineering (General)0210 nano-technologylcsh:PhysicsApplied Sciences

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Correlation of aluminum doping and lithiation temperature with electrochemical performance of LiNi1-xAlxO2 cathode material

2022

Abstract This article presents a process for producing LiNi1-xAlxO2 (0 < × < 0.05) cathode material with high capacity and enhanced cycle properties of 145 mAh/g after 600 cycles. The LiNi1-xAlxO2 (0 < × < 0.05) cathode material is prepared by mixing coprecipitated Ni(OH)2 with LiOH and Al(OH)3, followed by lithiation at temperature range of 650–710 °C, after which any residual lithium from lithiation is washed from the particle surfaces. Electrochemical performance was studied within full-cell and half-cell application; in addition, different material characterization methods were carried out to explain structure changes when certain amount of aluminum is introduced in the …

LNOcathodealuminumlitiumioniakutElectrochemistryGeneral Materials Sciencelithium-ion batteryalumiiniElectrical and Electronic EngineeringCondensed Matter Physicslithium-nickel oxideJournal of Solid State Electrochemistry

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Reaction pathways for atomic layer deposition with lithium hexamethyl disilazide, trimethyl phosphate, and oxygen plasma

2020

Atomic layer deposition (ALD) of lithium-containing films is of interest for the development of next-generation energy storage devices. Lithium hexamethyl disilazide (LiHMDS) is an established precursor to grow these types of films. The LiHMDS molecule can either be used as a single-source precursor molecule for lithium or as a dual-source precursor molecule for lithium and silicon. Single-source behavior of LiHMDS is observed in the deposition process with trimethylphosphate (TMP) resulting in the deposition of crystalline lithium phosphate (Li3PO4). In contrast, LiHMDS exhibits dual-source behavior when combined with O2 plasma, resulting in a lithium silicate. Both processes were characte…

Materials scienceInorganic chemistryReaction productschemistry.chemical_elementEnergy storageCoatings and FilmsPlasmaAtomic layer depositionchemistry.chemical_compoundElectronicOptical and Magnetic MaterialsPhysical and Theoretical ChemistryOXIDESPrecursorsALUMINUM PHOSPHATEMoleculesatomikerroskasvatusSurfaces Coatings and FilmsElectronic Optical and Magnetic MaterialsTrimethyl phosphateSurfacesChemistryGeneral EnergylitiumchemistryOxygen plasmaLithiumAdsorptionohutkalvotALUMINUM PHOSPHATE

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Optimization of spodumene identification by statistical approach for laser-induced breakdown spectroscopy data of lithium pegmatite ores

2021

Mapping with laser-induced breakdown spectroscopy (LIBS) can offer more than just the spatial distribution of elements: the rich spectral information also enables mineral recognition. In the present study, statistical approaches were used for the recognition of the spodumene from lithium pegmatite ores. A broad spectral range (280–820 nm) with multiple lines was first used to establish the methods based on vertex component analysis (VCA) and K-means and DBSCAN clusterings. However, with a view to potential on-site applications, the dimensions of the datasets must be reduced in order to accomplish fast analysis. Therefore, the capability of the methods in mineral identification was tested wi…

Materials scienceMineralLIBSspektroskopiatilastomenetelmätpegmatiititAnalytical chemistrychemistry.chemical_elementDBSCANVCASpodumenechemistryoptimointilitiummalmimineraalitalkuaineanalyysimineraalitLithiumLaser-induced breakdown spectroscopySpectroscopyInstrumentationK-meansSpectroscopyPegmatitelithium pegmatite ore

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Novel Functionality of Lithium-Impregnated Titania as Nanocatalyst

2019

The present work incorporates the synthesis of a multifunctional catalyst for the transesterification of waste cooking oil (WCO) to biodiesel and recovery of rare earth elements (REEs). For this purpose, TiO2 nanoparticles and TiO2 doped with lithium ions were prepared. The influence of lithium ions on the catalytic performance of TiO2 was attained by impregnation of the different molar ratios of lithium hydroxide to bare TiO2. Then each catalyst was screened for catalytic conversion of WCO to fatty acid methyl ester (FAME) and also for REEs recovery. All synthesized materials were characterized using scanning electron microscopy (SEM), X-ray diffraction (XRD), Transmission electron microsc…

Materials sciencekasviöljytScanning electron microscope020209 energychemistry.chemical_elementbiodieselrare earth elements02 engineering and technologylcsh:Chemical technologyCatalysisLithium hydroxidewaste cooking oilNanomaterialsCatalysislcsh:Chemistrychemistry.chemical_compoundkatalyytit0202 electrical engineering electronic engineering information engineeringTiO2lcsh:TP1-1185Physical and Theoretical ChemistryFatty acid methyl esternanocatalystBiodieselTransesterificationharvinaiset maametallit021001 nanoscience & nanotechnologylitiumchemistrylcsh:QD1-999nanohiukkasetLithiumtitaanidioksidi0210 nano-technologyTiO<sub>2</sub>Nuclear chemistryCatalysts

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Helicates with Ether-Substituted Catechol Esters as Ligands

2020

European journal of organic chemistry 2020(32), 5161-5172 (2020). doi:10.1002/ejoc.202000843

Molecular switchCatecholesteritOrganic ChemistryEtherkompleksiyhdisteet540Combinatorial chemistrymolecular switchhelicatethermodynamicschemistry.chemical_compoundlitiumchemistrytermodynamiikkatemplatingddc:540supramolekulaarinen kemiacatecholatePhysical and Theoretical Chemistry

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