Laboratory Study on the Physical Properties of Sea Salt Aerosol Particles and Model Systems

Hamza, Mariam Abdou Mahmoud

20 April 2004

Single levitated microdroplets of sodium chloride, potassium chloride, and natural seawater are investigated under conditions similar to that in the troposphere by using the electrodynamic balance technique. The thermodynamics and the kinetics of liquid-to-solid phase transitions have been investigated as a function of temperature and humidity. The temperature dependence of the critical partial pressure of water vapor over aqueous supersaturated aerosol droplets allows us to determine negative values for the integral heat of solution of KCl, NaCl and Mediterranean Sea droplets. In addition, the rates of homogeneous nucleation from supersaturated solution droplets are reported, where the data are fitted with three exponential functions to give three values for the nucleation rates. The phase transition processes which occur on different time scales are identified. The investigation of natural sea salt aerosol droplets collected from the Mediterranean Sea, Atlantic Ocean, Pacific Ocean, North Sea, and Suez Canal show that the phase change (liquid-to-solid) can occur at relative humidities that are greater than 33% RH, where the deliquescence humidity of MgCl2 is known to occur. It is found that there are slight variations (either a decrease or an increase) in water vapor pressure over the supersaturated aerosol droplets due to the change in water salinity, organic components that are present in the water sample, the depth, where the water sample is gathered, and its geographic location. The experimental results show that the presence of the organic substances in the aerosol particles affects the crystallization process depending on the amount and the type of the organic substance. It is observed that adding 1-heptanol to a NaCl droplet increases the crystallization diameter, which is attributed to the formation of a layer of the organic substance on the droplet surface, so that water evaporation cannot efficiently occur.

Sea salt aerosol

Supersaturated droplet

Homogeneous nucleation

Organic surface film

29 - Physik, Astronomie

ddc:550

Experimental and Modeling Studies of Dendrite Initiation during Lithium Electrodeposition

Maraschky, Adam M.

07 September 2020

No description available.

Chemical Engineering

dendritic growth

electroplating

Li dendrites

mass transport

transport limitation

solid electrolyte interphase

surface film

alkali metal

Towards Safer Lithium-Ion Batteries

Herstedt, Marie

January 2003

<p>Surface film formation at the electrode/electrolyte interface in lithium-ion batteries has a crucial impact on battery performance and safety. This thesis describes the characterisation and treatment of electrode interfaces in lithium-ion batteries. The focus is on interface modification to improve battery safety, in particular to enhance the onset temperature for thermally activated reactions, which also can have a negative influence on battery performance. </p><p>Photoelectron Spectroscopy (PES) and Differential Scanning Calorimetry (DSC) are used to investigate the surface chemistry of electrodes in relation to their electrochemical performance. Surface film formation and decomposition reactions are discussed.</p><p>The upper temperature limit for lithium-ion battery operation is restricted by exothermic reactions at the graphite anode; the onset temperature is shown to be governed by the composition of the surface film on the anode. Several electrolyte salts, additives and an anion receptor have been exploited to modify the surface film composition. The most promising thermal behaviour is found for graphite anodes cycled with the anion receptor, tris(pentafluorophenyl)borane, which reduces salt reactions and increases the onset temperature from ~80 °C to ~150 °C.</p><p>The electrochemical performance and surface chemistry of Swedish natural graphite, carbon-treated LiFePO₄ and anodes from high-power lithium-ion batteries are also investigated. Jet-milled Swedish natural graphite exhibits a high capacity and rate capability, together with a decreased susceptibility to solvent co-intercalation. Carbon-treated LiFePO₄ shows promising results: no solvent reaction products are detected. The amount of salt compounds increases, with power fade occurring for anodes from high-power lithium-ion batteries; the solvent reduction products comprise mainly Li-carboxylate type compounds.</p>

Inorganic chemistry

lithium-ion batteries

photoelectron spectroscopy

surface film

thermal stability

electrolyte additive

graphite

lithium iron phosphate

Oorganisk kemi

Inorganic chemistry

Oorganisk kemi

Towards Safer Lithium-Ion Batteries

Herstedt, Marie

January 2003

Surface film formation at the electrode/electrolyte interface in lithium-ion batteries has a crucial impact on battery performance and safety. This thesis describes the characterisation and treatment of electrode interfaces in lithium-ion batteries. The focus is on interface modification to improve battery safety, in particular to enhance the onset temperature for thermally activated reactions, which also can have a negative influence on battery performance. Photoelectron Spectroscopy (PES) and Differential Scanning Calorimetry (DSC) are used to investigate the surface chemistry of electrodes in relation to their electrochemical performance. Surface film formation and decomposition reactions are discussed. The upper temperature limit for lithium-ion battery operation is restricted by exothermic reactions at the graphite anode; the onset temperature is shown to be governed by the composition of the surface film on the anode. Several electrolyte salts, additives and an anion receptor have been exploited to modify the surface film composition. The most promising thermal behaviour is found for graphite anodes cycled with the anion receptor, tris(pentafluorophenyl)borane, which reduces salt reactions and increases the onset temperature from ~80 °C to ~150 °C. The electrochemical performance and surface chemistry of Swedish natural graphite, carbon-treated LiFePO4 and anodes from high-power lithium-ion batteries are also investigated. Jet-milled Swedish natural graphite exhibits a high capacity and rate capability, together with a decreased susceptibility to solvent co-intercalation. Carbon-treated LiFePO4 shows promising results: no solvent reaction products are detected. The amount of salt compounds increases, with power fade occurring for anodes from high-power lithium-ion batteries; the solvent reduction products comprise mainly Li-carboxylate type compounds.

Inorganic chemistry

lithium-ion batteries

photoelectron spectroscopy

surface film

thermal stability

electrolyte additive

graphite

lithium iron phosphate

Oorganisk kemi

Inorganic chemistry

Oorganisk kemi

Galvanic Corrosion of Magnesium Coupled to Steel at High Cathode-to-Anode Area Ratios

Banjade, Dila Ram

01 December 2015

In this study, the impact of galvanic coupling of magnesium to steel on the corrosion rate, surface morphology, and surface film formation was investigated. In particular, the role of self-corrosion was quantified as previous studies showed discrepancies between model predictions and experimental results that were likely due to significant self-corrosion. This experimental study examined the corrosion of Mg coupled to steel in 5 wt% NaCl at cathode-to-anode area ratios that ranged from 5 to 27. Results showed that self-corrosion was significant and accounted for, on average, one-third of total corrosion. Moreover, self-corrosion varied with time and cathode size, and was accelerated by the high dissolution rate. Film formation was observed on the magnesium surface that inhibited the corrosion rates. This film contained approximately 30% of the Mg lost to corrosion. The morphology of the coupled Mg showed the rapid formation of pits with considerable depth, and was quite distinct from previously studied filiform and disk corrosion for uncoupled Mg. This study demonstrates the important role of self-corrosion during galvanic corrosion of Mg and the need to account for such corrosion when predicting corrosion rates. This study also provides important insight into the processes that control Mg corrosion under several conditions.

magnesium corrosion

galvanic corrosion

self-corrosion

surface film

surface morphology

high cathode-to-anode ratio

high anodic dissolution

galvanic couple

magnesium-steel couple

Chemical Engineering

Low Alloy Steel Susceptibility to Stress Corrosion Cracking in Hydraulic Fracturing Environment

Anyanwu, Ezechukwu John

06 June 2014

No description available.

Chemical Engineering

Chemistry

Materials Science

Slow Strain Rate Tests

Low Alloy Steel

AISI 4340

Localized Corrosion

Surface Film Analysis

Diagnosis of the Lifetime Performance Degradation of Lithium-Ion Batteries : Focus on Power-Assist Hybrid Electric Vehicle and Low-Earth-Orbit Satellite Applications

Brown, Shelley

January 2008

Lithium-ion batteries are a possible choice for the energy storage system onboard hybrid electric vehicles and low-earth-orbit satellites, but lifetime performance remains an issue. The challenge is to diagnose the effects of ageing and then investigate the dependence of the magnitude of the deterioration on different accelerating factors (e.g. state-of-charge (SOC), depth-of-discharge (DOD) and temperature). Lifetime studies were undertaken incorporating different accelerating factors for two different applications: (1) coin cells with a LixNi0.8Co0.15Al0.05O2-based positive electrode were studied with a EUCAR power-assist HEV cycle, and (2) laminated commercial cells with a LixMn2O4-based positive electrode were studied with a low-earth-orbit (LEO) satellite cycle. Cells were disassembled and the electrochemical performance of harvested electrodes measured with two- and three-electrode cells. The LixNi0.8Co0.15Al0.05O2-based electrode impedance results were interpreted with a physically-based three-electrode model incorporating justifiable effects of ageing. The performance degradation of the cells with nickelate chemistry was independent of the cycling condition or target SOC, but strongly dependent on the temperature. The positive electrode was identified as the main source of impedance increase, with surface films having a composition that was independent of the target SOC, but with more of the same species present at higher temperatures. Furthermore, impedance results were shown to be highly dependent on both the electrode SOC during the measurement and the pressure applied to the electrode surface. An ageing hypothesis incorporating a resistive layer on the current collector and a local contact resistance (dependent on SOC) between the carbon and active material, both possibly leading to particle isolation, was found to be adequate in fitting the harvested aged electrode impedance data. The performance degradation of the cells with manganese chemistry was accelerated by both higher temperatures and larger DODs. The impedance increase was small, manifested in a SOC-dependent increase of the high-frequency semicircle and a noticeable increase of the high-frequency real axis intercept. The positive electrode had a larger decrease in capacity and increase in the magnitude of the high-frequency semi-circle (particularly at high intercalated lithium-ion concentrations) in comparison with the negative electrode. This SOC-dependent change was associated with cells cycled for either extended periods of time or at higher temperatures with a large DOD. An observed change of the cycling behaviour in the second potential plateau for the LixMn2O4-based electrode provided a possible kinetic-based explanation for the change of the high-frequency semi-circle. / Litiumjonbatteriet är en möjlig kandidat för energilagring i hybridfordon och i satelliter i låg omloppsbana, men än så länge är livslängden på batterierna ett problem. Utmaningen ligger i att kunna förstå hur batteriet åldras genom att utforska hur åldringsprocessen accelereras av faktorer som laddningstillstånd, urladdningsdjup och temperatur. Livslängdsstudier för två olika typer av batterier tänkta för olika applikationer utfördes: (1) knappceller med positiva LixNi0,8Co0,15Al0,05O2-baserade elektroder studerades med en effektstödd (power-assist) hybridcykel från EUCAR, och (2) laminerade kommersiella celler med positiva LixMn2O4-baserade elektroder studerades med en satellitcykel, avsedd för en satellit med låg omloppsbana. Cellerna öppnades och de uttagna elektrodernas elektrokemiska egenskaper utvärderades i två- och tre-elektroduppställningar. Resultaten från elektrokemiska impedansmätningar för den positiva LixNi0,8Co0,15Al0,05O2-baserade elektroden tolkades med hjälp av en fysikalisk tre-elektrod modell som tog hänsyn till de i litteraturen främst föreslagna effekterna av åldring. Prestandadegraderingen av celler med nickelkemi var oberoende av cykel och laddningstillståndet där åldringen skedde, men starkt beroende av temperaturen. Den positiva elektroden visade sig vara den största orsaken till impedansökningen i batteriet. Ytfilmerna på den positiva elektroden hade en sammansättning som var oberoende av laddningstillståndet men beroende av temperaturen. Impedansresultaten från de uttagna elektroderna var starkt beroende av både laddningstillstånd och yttre tryck på elektrodytan. Det visade sig att det var tillräckligt att ta hänsyn till ett resistivt skikt på strömtilledaren och en lokal kontaktresistans mellan kolet och det aktiva materialet (som är beroende av laddningstillståndet) för att anpassa modellen till impedansdata mätt på de uttagna elektroderna. Prestandadegraderingen av celler med mangankemi påskyndades av både högre temperaturer och högre urladdningsdjup. Impedansen ökade något, då både högfrekvenshalvcirkeln och högfrekvensintercepten ändrades. Positiva elektroden hade en större degradering i kapaciteten och en större ökning i magnituden av högfrekvenshalvcirkeln (speciellt vid högre litiumjon koncentrationer i elektroden) jämfört med den negativa elektroden. Denna laddningstillståndsberoende impedans-ökning var kopplad till celler som hade cyklats under en längre tid eller vid en högre temperatur och med ett högt urladdningsdjup. Ökningen i magnituden av högfrekvenshalvcirkeln skulle kunna vara relaterad till kinetiska begränsningar eftersom cyklingsbeteendet vid andra spänningsplatån ändrades samtidigt för de LixMn2O4-baserade elektroderna. / QC 20100621

lithium-ion battery

LixNi0.8Co0.15Al0.05O2

LixMn2O4

LiyC6

ageing

three-electrode measurements

impedance modelling

surface film characterisation

hybrid electric vehicle

low-earth-orbit satellite

litiumjonbatteri

åldring

treelektroduppställning

impedansmodell

ytfilmskarakterisering

hybridfordon

satelliter

Electrochemistry

Elektrokemi