Harnessing Mesoporous Spheres - transport studies and biotechnological applications

Ng, Jovice Boon Sing

January 2009

Applications in controlled release and delivery calls for a good understanding of molecular transport within the carrier material and the dominating release mechanisms. It is clear that a better understanding of hindered transport and diffusion of guest molecules is important when developing new porous materials, e.g., surfactant templated silica spheres, for biotechnological applications. Confocal laser scanning microscopy was used to quantify the bulk release and intraparticle transport of small charged fluorescent dyes, and fluorescently-tagged neutral dextran, from mesoporous silica spheres. The time dependent release and the concentration profiles within the spheres have been used to analyze the release mechanisms using appropriate models. While the small, non-adsorbing anionic dye is released following a simple diffusion driven process, the concentration of the cationic dye varies radially within the spheres after loading. The release of the cationic dye is controlled by diffusion after an initial period of rapid release, which could be due to a significant fraction of the cationic dye that remains permanently attached to the negatively charged walls of the mesoporous silica spheres. The diffusion of dextran and the resulting flat concentration profiles could be related to the complex structural feature of the cylindrical pores close to the surface, and a possible conformational change of the dextran with the concentration. The stability and leaching of a catalytic enzyme, lipase, immobilized in hydrophobilized mesoporous support has also been quantified. Colloidal monodisperse mesoporous silica spheres were synthesized and transmission electron microscopy showed that the inner pore structure display a radially extending pores. The mesoporous spheres were used as solid supports for a lipid membrane incorporated with a multi-subunit redox-driven proton pump, which was shown to remain functional. / Synthesis, functionalisation and controlled release of mesoporous materials

Mesoporous

spheres

particles

CLSM

TEM

controlled-release

molecular transport

lipid membrane

enzyme

intraparticle

lipase

solid support

Inorganic chemistry

Oorganisk kemi

Light-Metal Hydrides for Hydrogen Storage

Sahlberg, Martin

January 2009

Demands for zero greenhouse-gas emission vehicles have sharpened with today’s increased focus on global warming. Hydrogen storage is a key technology for the implementation of hydrogen powered vehicles. Metal hydrides can claim higher energy densities than alternative hydrogen storage materials, but a remaining challenge is to find a metal hydride which satisfies all current demands on practical usability. Several metals store large amounts of hydrogen by forming a metal hydride, e.g., Mg, Ti and Al. The main problems are the weight of the material and the reaction energy between the metal and hydrogen. Magnesium has a high storage capacity (7.6 wt.% hydrogen) in forming MgH2; this is a slow reaction, but can be accelerated either by minimizing the diffusion length within the hydride or by changing the diffusion properties. Light-metal hydrides have been studied in this thesis with the goal of finding new hydrogen storage compounds and of gaining a better understanding of the parameters which determine their storage properties. Various magnesium-containing compounds have been investigated. These systems represent different ways to address the problems which arise in exploiting magnesium based materials. The compounds were synthesized in sealed tantalum tubes, and investigated by in situ synchrotron radiation X-ray powder diffraction, neutron powder diffraction, isothermal measurements, thermal desorption spectroscopy and electron microscopy. It is demonstrated that hydrogen storage properties can be improved by alloying magnesium with yttrium or scandium. Mg-Y-compounds decompose in hydrogen to form MgH2 nano-structures. Hydrogen desorption kinetics are improved compared to pure MgH2. The influence of adding a third element, gallium or zinc has also been studied; it is shown that gallium improves hydrogen desorption from YH2. ScAl1-xMgx is presented here for the first time as a hydrogen storage material. It absorbs hydrogen by forming ScH2 and Al(Mg) in a fully reversible reaction. It is shown that the hydrogen desorption temperature of ScH2 is reduced by more than 400 °C by alloying with aluminium and magnesium.

Metal-hydrogen compounds

hydrides

hydrogen storage

X-ray diffraction

neutron diffraction

thermal desorption spectroscopy

Chemistry

Kemi

Inorganic chemistry

Oorganisk kemi

Design of carbide-based nanocomposite coatings

Lewin, Erik

January 2009

In this thesis research on synthesis, microstructure and properties of carbide-based coatings is reported. These coatings are electrically conducting, and can be tailored for high hardness, low friction and wear, along with load-adaptive behaviour. Tailoring these properties is achieved by controlling the relative phase content of the material. Coatings have been synthesised by dc magnetron sputtering, and their structures have been characterised, mainly by X-ray photoelectron spectroscopy and X-ray diffraction. It has been shown that nanocomposites comprising of a nanocrystalline transition metal carbide (nc-MeCx, Me = Ti, Nb or V) and an amorphous carbon (a-C) matrix can result in low contact resistance in electrical contacts. Such materials also exhibit low friction and high resistance to wear, making them especially suitable for application in sliding contacts. The lowest contact resistance is attained for small amounts of the amorphous carbon phase. It has been shown that specific bonding structures are present in the interface between nc-TiCx and the a-C phases in the nanocomposite.  It was found in particular that Ti3d and C2p states are involved, and that considerable charge transfer occurs across the interface, thereby influencing the structure of the carbide. Further design possibilities were demonstrated for TiCx-based nanocomposites by alloying them with weakly carbide-forming metals, i.e., Me = Ni, Cu or Pt.  Metastable supersaturated solid solution carbides, (T1-xMex)Cy, were identified to result from this alloying process. The destabilisation of the TiCx-phase leads to changes in the phase distribution in the deposited nanocomposites, thus providing further control over the amount of carbon phase formed. Additional design possibilities became available through the decomposition of the metastable (Ti1-xMex)Cy phase through an appropriate choice of annealing conditions, yielding either more carbon phase or a new metallic phase involving Me. This alloying concept was also studied theoretically for all 3d transition metals using DFT techniques. It has also been demonstrated that Ar-ion etching (commonly used in the analysis of carbide based nanocomposites) can seriously influence the result of the analysis, especially for materials containing metastable phases. This implies that more sophisticated methods, or considerable care are needed in making these analyses, and that many of the earlier published results could well be in error.

chemistry

thin film

dc magnetron sputtering

carbide

nanocomposite

PVD

solid solution

Chemistry

Kemi

Inorganic chemistry

Oorganisk kemi

Stability Phenomena in Novel Electrode Materials for Lithium-ion Batteries

Stjerndahl, Mårten

January 2007

Li-ion batteries are not only a technology for the future, they are indeed already the technology of choice for today’s mobile phones, laptops and cordless power tools. Their ability to provide high energy densities inexpensively and in a way which conforms to modern environmental standards is constantly opening up new markets for these batteries. To be able to maintain this trend, it is imperative that all issues which relate safety to performance be studied in the greatest detail. The surface chemistry of the electrode-electrolyte interfaces is intrinsically crucial to Li-ion battery performance and safety. Unfortunately, the reactions occurring at these interfaces are still poorly understood. The aim of this thesis is therefore to increase our understanding of the surface chemistries and stability phenomena at the electrode-electrolyte interfaces for three novel Li-ion battery electrode materials. Photoelectron spectroscopy has been used to study the surface chemistry of the anode material AlSb and the cathode materials LiFePO4 and Li2FeSiO4. The cathode materials were both carbon-coated to improve inter-particle contact. The surface chemistry of these electrodes has been investigated in relation to their electrochemical performance and X-ray diffraction obtained structural results. Surface film formation and degradation reactions are also discussed. For AlSb, it has been shown that most of the surface layer deposition occurs between 0.50 and 0.01 V vs. Li°/Li+ and that cycling performance improves when the lower cut-off potential of 0.50 V is used instead of 0.01 V. For both LiFePO4 and Li2FeSiO4, the surface layer has been found to be very thin and does not provide complete surface coverage. Li2CO3 was also found on the surface of Li2FeSiO4 on exposure to air; this was found to disappear from the surface in a PC-based electrolyte. These results combine to give the promise of good long-term cycling with increased performance and safety for all three electrode materials studied.

Inorganic chemistry

Li-ion battery

electrode material

intermetallic

AlSb

lithium iron phosphate

lithium iron silicate

photoelectron spectroscopy

Oorganisk kemi

Prussian blue analogue copper hexacyanoferrate : Synthesis, structure characterization and its applications as battery electrode and CO2 adsorbent

Ojwang, Dickson Odhiambo

January 2017

Prussian blue (PB) and Prussian blue analogues (PBAs) are compounds with potential applications in a large variety of fields such as gas storage, poison antidotes, electrochromism, electrochemistry and molecular magnets. The compounds are easy to synthesize, cheap, environmentally friendly and have been pursued for both fundamental research and industrial purposes. Despite the multifunctionality of PB and PBAs, they have complicated compositions, which are largely dependent on the synthesis methods and storage conditions. Thus, performing investigations on such compounds with defined composition, stoichiometry and crystal structure is essential. This thesis has focused on synthesis and detailed structure characterization of copper hexacyanoferrate (CuHCF) via X-ray powder diffraction (XRPD), neutron powder diffraction (NPD), thermogravimetric analysis (TGA), differential scanning calorimetry (DSC), inductively coupled plasma-optical emission spectroscopy (ICP-OES), scanning electron microscopy-energy dispersive spectroscopy (SEM-EDS), Mössbauer spectroscopy, extended X-ray absorption fine structure (EXAFS), infrared (IR) and Raman techniques. In addition, kinetics of thermal dehydration process, CO2 adsorption and CO2 adsorption kinetics were investigated. Moreover, in operando synchrotron X-ray diffraction experiments were performed to gain insight into the structure-electrochemistry relationships in an aqueous CuHCF/Zn battery during operation. / <p>At the time of the doctoral defense, the following papers were unpublished and had a status as follows: Paper 4: Manuscript. Paper 5: Manuscript.</p>

copper hexacyanoferrate

synthesis

structure refinement

thermal dehydration

CO2 adsorption

kinetic analysis

Inorganic Chemistry

Oorganisk kemi

Controlling the growth of nanoparticles produced in a highpower pulsed plasma

Gunnarsson, Rickard

January 2017

Nanotechnology can profoundly benefit our health, environment and everyday life. In order to make this a reality, both technological and theoretical advancements of the nanomaterial synthesis methods are needed. A nanoparticle is one of the fundamental building blocks in nanotechnology and this thesis describes the control of the nucleation, growth and oxidation of titanium particles produced in a pulsed plasma. It will be shown that by controlling the process conditions both the composition (oxidationstate) and size of the particles can be varied. The experimental results are supported by theoretical modeling. If processing conditions are chosen which give a high temperature in the nanoparticle growth environment, oxygen was found to be necessary in order to nucleate the nanoparticles. The two reasons for this are 1: the lower vapor pressure of a titanium oxide cluster compared to a titanium cluster, meaning a lower probability of evaporation, and 2: the ability of a cluster to cool down by ejecting an oxygen atom when an oxygen molecule condenses on its surface. When the oxygen gas flow was slightly increased, the nanoparticle yield and oxidation state increased. A further increase caused a decrease in particle yield which is attributed to a slight oxidation ofthe cathode. By varying the oxygen flow, it was possible to control the oxidation state of the nanoparticles without fully oxidizing the cathode. Pure titanium nanoparticles could not be produced in a high vacuum system because oxygen containing gases such as residual water vapour have a profound influence on nanoparticle yield and composition. In an ultrahigh vacuum system titanium nanoparticles without significantoxygen contamination were produced by reducing the temperature of the growth environment and increasing the pressure of an argon-helium gas mixture within whichthe nanoparticles grew. The dimer formation rate necessary for this is only achievable at higher pressures. After a dimer has formed, it needs to grow by colliding with a titanium atom followed by cooling by collisions with multiple buffer gas atoms. The condensation event heats up the cluster to a temperature much higher than the gas temperature, where it is during a short time susceptible to evaporation. When the clusters’ internal energy has decreased by collisions with the gas to less than the energy required to evaporate a titanium atom, it is temporarily stable until the next condensation event occurs. The temperature difference by which the cluster has to cool down before it is temporarily stable is exactly as many kelvins as the gas temperature.The addition of helium was found to decrease the temperature of the gas, making it possible for nanoparticles of pure titanium to grow. The process window where this is possible was determined and the results presented opens up new possibilities to synthesize particles with a controlled contamination level and deposition rate.The size of the nanoparticles has been controlled by three means. The first is to change the electrical potential around the growth zone, which allows for size (diameter) control in the order of 25 to 75 nm without influencing the oxygen content of the particles. The second means is by increasing the pressure which decreases the ambipolar diffusion rate of the ions resulting in a higher growth material density. By doing this, the particle size can be increased from 50 to 250 nm, however the oxygen content also increases with increasing pressure when this is done in a high vacuum system. The last means of size control was by adding a helium flow to the process where higher flows resulted in smaller nanoparticle sizes. When changing the pressure in high vacuum, the morphology of the nanoparticles could be controlled. At low pressures, highly faceted near spherical particles were produced. Increasing the pressure caused the formation of cubic particles which appear to ‘fracture’ at higher pressures. At the highest pressure investigated, the particles became poly-crystalline with a cauliflower shape and this morphology was attributed to a lowad atom mobility. The ability to control the size, morphology and composition of the nanoparticles determines the success of applying the process to manufacture devices. In related work presented in this thesis it is shown that 150-200 nm molybdenum particles with cauliflower morphology were found to scatter light in which made them useful in photovoltaic applications, and the size of titanium dioxide nanoparticles were found to influence the selectivity of graphene based gas sensors.

Other Chemical Engineering

Annan kemiteknik

Materials Chemistry

Materialkemi

Metallurgy and Metallic Materials

Metallurgi och metalliska material

Inorganic Chemistry

Oorganisk kemi

Structural and Electrochemical Relations in Electrode Materials for Rechargeable Batteries

Renman, Viktor

January 2017

Rechargeable batteries have already conquered the market of portable electronics (i.e., mobile phones and laptops) and are set to further enable the large-scale deployment of electric vehicles and hybrid electric vehicles in a not too distant future. In this context, a deeper understanding of the fundamental processes governing the electrochemical behavior of electrode materials for batteries is required for further development of these applications. The aims of the work described in this thesis have been to investigate how electrochemical properties and structural properties of novel electrode materials relate to each other. In this sense, electrochemical characterization, structural analysis using XRD and their combined simultaneous use via in operando XRD experiments have played a crucial part. The investigations showed that: Two oxohalides, Ni3Sb4O6F6 and Mn2Sb3O6Cl, react with Li-ions in a complex manner involving different types of reaction mechanisms at low voltages in Li half cells. In operando XRD show that both of these materials are reduced in a conversion reaction via an in situ formation of nanocomposites, which proceed to react reversibly with Li-ions in a combination of alloying and conversion reactions. Carbon-coated Na2Mn2Si2O7 was synthesized and characterized as a possible positive electrode material for non-aqueous Na-ion batteries. DFT calculations point to a structural origin of the modest electrochemical behavior of this material. It is suggested that structural rearrangements upon desodiation are associated with large overpotentials. It is demonstrated via an in operando synchrotron XRD study that Fe(CN)6 vacancies in copper hexacyanoferrate (CuHCF) play an important role in the electrochemical behavior toward Zn2+ in an aqueous CuHCF/Zn cell. Furthermore, manganese hexacyanomanganate (MnHCM) is shown to react reversibly with Li+, Na+ and K+ in non-aqueous alkali metal half cells. In contrast to CuHCF, which is a zero-strain material, MnHCM undergoes a series of structural transitions (from monoclinic to cubic) during electrochemical cycling.

batteries

electrochemical energy storage

oxohalides

conversion

alloy

pyrosilicate

CuHCF

MnHCM

XRD

XANES

in operando

Inorganic Chemistry

Oorganisk kemi

Secondary Steel Metallurgy Slag Design and MgO-C Refractory Implications : Theoretical and Practical Considerations

Simon, Hellgren

January 2019

MgO-C based refractory materials, often used in secondary steel making, are exposed to variouswear mechanisms in its application. The wear could be divided into oxidative, chemical andabrasive categories, all behaving differently and all being influenced by different factors. Dueto the importance of minimizing material loss and to the environmental challenges to run asustainable industry, it is of interest to gain more knowledge of the behavior of the refractorymaterial in use. The present thesis work specifically investigated slag designed of the CaOSiO2-Al2O3-MgO (CSAM) system as well as the chemical and oxidative wear mechanisms ofthree different MgO-C based refractory materials from Höganäs AB, Halmstadverken, whichcontained 5, 10 and 12 wt% carbon (labeled T05, T10 and T12). Different CSAM slags weredesigned to meet certain process criteria such as MgO and CaO saturations and wereinvestigated through thermodynamic calculations using the FactSage software and throughlaboratory scaled slag smelting experiments. The oxidation effect on the refractory material wasalso studied through pre-heating simulations in chamber furnaces, similar to the pre-heating ofa re-built ladle furnace.The thermodynamic calculations made in FactSage 7.0, using the FactPS and FToxid databases, resulted in a few different slag designs with different properties. A few different slagsfulfilled the CaO and MgO saturation limits proposed by Höganäs AB and could be consideredto test experimentally for further evaluation. The simulations also showed trends on how theliquid viscosity behaved with different slag compositions and how the solids content changedwith temperature.The oxidation experiments were performed on the different MgO-C refractory types, where thebricks with 10% carbon also contained Al2O3 antioxidants. The experiments showed that themass loss during the pre-heating is greater for refractory with higher carbon content, withexception to T10, where the mass losses were measured to 3.76 – 4.01%, 1.06 – 1.28% and6.28 – 6.33% for T05, T10 and T12 respectively. Further, the oxidation depth of each materialwas measured to 9-10 mm, 2-3 mm and 2-5 mm for the T05, T10 and T12. The experimentsalso showed that T12 refractory in particular was very susceptible to abrasive wear after beingoxidized.The slag smelting experiments were carried out through two different methods, by melting slagin MgO-C crucibles and by melting pressed slag briquettes on top of refractory bricks. Theformer tests mainly showed that the methodology was not suitable for this type of refractorymaterial due to the crucibles cracking during the experiments. The latter experiments showedsome general behaviour of the different components in the slag, where Ca, Al and Fe stayednear the surface, and Si and Mg penetrated deeper. The spinel formation at the refractory surfacewas then concluded to be the reason for Al not penetrating deeper. Further it was concludedthat no significant difference in refractory dissolution was seen between slags with- and withoutMgO, other than possibly a small increase in refractory dissolution for the latter.

MgO-C

CaO-SiO2-Al2O3-MgO

Slag Design

Refractory Wear

Inorganic Chemistry

Oorganisk kemi

Materials Chemistry

Materialkemi

Titanium carbonitride coatings for electrical contact applications : Deposition by reactive and co-reactive DC magnetron sputtering

Kessler, Juliana

January 2023

Fuel cells play a key role in implementing hydrogen as alternative fuel to eliminate CO2-emissions and their performance is largely dependent on the contact resistance of the surface of bipolar plates. For stainless steel bipolar plates titanium carbonitride coatings were suggested for modifying surface properties and thereby reducing contact resistance while maintaining mechanical strength. This study analysed Ti(C,N) coatings with different carbon content in terms of composition, microstructure chemical bonding and contact resistance. The films were deposited either by reactive co-sputtering from a titanium and a graphite target under nitrogen flow or by co-reactive sputtering from a titanium target under flow of nitrogen and methane. It was found that an increase in carbon content results in a nanocomposite of Ti(C,N) and an amorphous carbon (a-C) matrix leading to nanocrystalline films with a smooth surface. Analysing the amount of a-C as a functions of overall carbon content, it is observed that carbon is more effectively incorporated into carbonitride grains when using methane gas as a carbon source. Furthermore, the contact resistance of the titanium carbonitride coatings was found to be lowest (below 10 mΩ) for a small amount of a-C phase and overall lower than that of carbide and nitride reference samples. Therefore, titanium carbonitrides are a promising coating material for electrical contact applications such as fuel cells.

Natural Sciences

Naturvetenskap

Engineering and Technology

Teknik och teknologier

Materials Chemistry

Materialkemi

Inorganic Chemistry

Oorganisk kemi

Chemical Engineering

Kemiteknik

Impact of Peroxide Speciation on the Kinetics of Oxidative Dissolution of UO2 / Effekt av peroxidspeciering på kinetik för oxidativ upplösning av UO2

Aydogan, Hazal

January 2022

Slutförvaring av använt kärnbränsle måste vara säker under 100 000 år eller mer för att förhindra att miljön skadas och att människor påverkas av långlivade radionuklider. Även om anläggningar för geologiskt djupförvar är utformade för att vara hållbara i många år, kan använt kärnbränsle komma i kontakt med grundvattnet i händelse av att flera barriärer brister. Det använda kärnbränslets inneboende radioaktivitet orsakar radiolys av inträngande grundvatten som producerar oxiderande och reducerande ämnen. Bland de radiolysprodukter som bildas rapporteras väteperoxid (H2O2) som en av de främsta orsakerna till oxidativ upplösning av bränslematrisen, UO2. Även om UO2 har låg löslighet i anoxiskt grundvatten, har oxiderad UO2, UO22+, flera storleksordningar högre löslighet. Detta utgör en risk för att radionukliderna släpps ut i miljön. Bikarbonat (HCO3-) är en av de viktigaste komponenterna i grundvatten och är känd för att öka upplösningen av UO22+. I denna studie undersöktes därför effekterna av HCO3- koncentrationen på den oxidativa upplösningen av UO2 genom att hålla den ursprungliga mängden H2O2 konstant på 0,2 mM och ändra HCO3- koncentrationen (1 mM, 2 mM, 5 mM och 10 mM). Dessutom undersöktes effekten av UO22+ på specieringen av H2O2 genom att tillsätta uranylnitrat (UO2(NO3)2 x 6H2O) till systemen innan de exponerades för H2O2. Specieringens inverkan på kinetiken för oxidativ upplösning av UO2 analyserades. Som ett resultat av experimenten har man dragit slutsatsen att mängden upplöst UO22+ är högre vid högre HCO3- koncentration. Dessutom minskar upplösningshastigheten för UO22+ med initial tillsats av UO22+ på grund av de komplex som bildas i systemen. Det observerades att oxidation av UO2 är den hastighetsbegränsande reaktionen i början av exponeringen, och att upplösningen av UO22+ därför fördröjs. Å andra sidan har man sett att bristen på HCO3- begränsar systemens upplösningsförmåga. Fri H2O2 är den dominerande formen av peroxid i systemen utan initialt tillsatt UO22+, medan -6 och -2 laddade komplex är dominerande i systemen med initialt tillsatt UO22+. H2O2-komplexen är mer effektiva på ytmekanismen i de system som har lägre HCO3- koncentration. Det finns ingen observerbar trend i H2O2-förbrukningshastigheten med avseende på HCO3-koncentrationen. Därför drogs slutsatsen att H2O2-förbrukningen är oberoende av upplösningsreaktionen. Slutligen följer upplösningen i systemet utan ursprungligt tillsatt UO22+ första ordningens kinetik med avseende på HCO3- koncentrationen. / Disposal of spent nuclear fuels is of great importance to prevent the environment and humans from being affected by long-lived radionuclides for 100,000 years or more. Even though the deep geological repositories are designed to remain durable for many years, spent nuclear fuel may come in contact with groundwater in case of a multi-barrier failure. The inherent radioactivity of spent nuclear fuel causes water radiolysis producing oxidizing and reducing agents. Among the radiolysis products, hydrogen peroxide (H2O2) is reported as a primary contributor to the oxidative dissolution of the fuel matrix, UO2. Although UO2 has low solubility in water, oxidized UO2, UO22+ , has several orders of magnitude higher solubility. This poses the risk of the radionuclides being released into the environment. Bicarbonate (HCO3–) is one of the main components of groundwater and is known to increase the dissolution of UO22+. Therefore, in this study, the effects of HCO3– concentration on the oxidative dissolution of UO2 were investigated by keeping the initial amount of H2O2 constant at 0.2 mM and changing the HCO3– concentration (1 mM, 2 mM, 5mM, and 10 mM). Besides, the effect of UO22+ on the speciation was investigated by adding uranyl nitrate (UO2(NO3)2 x 6H2O) to the systems before exposure to H2O2. The impact of speciation on the kinetics of oxidative dissolution of UO2 was analyzed. As a result of experiments, it has been concluded that the amount of dissolved UO22+ is higher in higher HCO3– concentration. Also, the rate of the UO22+ dissolution decreases with addition of UO22+ due to the complexes formed in the systems. It was observed that oxidation of UO2 is the rate limiting reaction atthe beginning of the exposure; therefore, there is a delay in the UO22+ dissolution. On the other hand, it has been seen that the HCO3– deficiency limits the dissolution capacity of the systems. Free H2O2 is the dominant peroxide species in the systems without initially added UO22+ , while -6 and -2 charged complexes are dominant in the systems with initially added UO22+. The H2O2 complexes are found more effective on the surface mechanism in the systems having lower HCO3– concentration. There is no observable trend in H2O2 consumption rate with respect to HCO3– concentration. Therefore, it was concluded that the H2O2 consumption rate is independent of dissolution reaction. Finally, the dissolution in the system without initially added UO22+ follows the first-order kinetics with respect to HCO3– concentration.

Spent nuclear fuel

H2O2

HCO3-

Speciation

Kinetics

Använt kärnbränsle

H2O2

HCO3-

Speciering

Kinetik

Inorganic Chemistry

Oorganisk kemi