Comparison of Computational Modeling of Precision Glass Molding of Infrared Lenses

Moghaddas, Mohamad Amin

09 July 2014

No description available.

Engineering

Optics

Amorphous Semiconductors: From Photocatalyst to Computer Memory

Sundararajan, Mayur

05 July 2017

No description available.

Physics

Materials Science

CBRAM

Non-Volatile Memory

Photocatalysts

Bandgap Engineering

Silica

FSDP

Intermediate Range Order

Irena

SAXS

SEM

Chalcogenide Glasses

Sol-gel synthesis

Fiber Based Mode Locked Fiber Laser Using Kerr Effect

Wang, Long

17 May 2016

No description available.

Optics

Direct Write of Chalcogenide Glass Integrated Optics Using Electron Beams

Hoffman, Galen Brandt

16 December 2011

No description available.

Optics

integrated optics

photonics

waveguide

waveguide fabrication

electron beam lithography

electron beam

chalcogenide glass

photolithography

germanium selenide

Ge0.2Se0.8

Ge20Se80

bragg grating

bragg mirror

waveguide bragg grating

Theories of Charge Transport and Nucleation in Disordered Systems

Nardone, Marco

18 May 2011

No description available.

Physics

photovoltaics

solar cells

phase change memory

threshold switch

chalcogenide

charge transport

thin-film

disorder

field induced nucleation

noise

relaxation oscillations

non-crystalline junctions

<b>Fundamental Inorganic Chemistry for Renewable Energy Resources: Highlights in Tellurium, Zirconium, Hafnium, and Neptunium Coordination Chemistry</b>

Madeleine Claire Uible (19173208)

18 July 2024

<p dir="ltr">The separation of tellurium from cadmium telluride is examined using a unique combination of mild, anhydrous chlorination and complexation of the subsequent tellurium tetrachloride with 3,5-di-<i>tert</i>-butylcatechol. The resulting tellurium complex, Te(dtbc)₂, is isolated in moderate yield and features a 10³ to 10⁴ reduction in cadmium content, as provided by XRF and ICP-MS analysis. Similar results were obtained from zinc telluride. A significant separation between Te, Se, and S was observed after treating a complex mixture of metal chalcogenides with this protocol. These three tunable steps can be applied for future applications of CdTe photovoltaic waste.</p><p dir="ltr">We report the synthesis and characterization of the first series of tellurium and selenium complexes featuring an η⁵-cyclopentadienyl ligand. Reaction of Ph₃TeX (X = Cl, S₂CNEt₂) with MCp^R (M = Li, K; R = H, Me₄, Me₅) results in high yields of [Cp][TePh₃] (<b>1</b>), [Cp^Me4][TePh₃] (<b>2</b>), and [Cp*][TePh₃] (<b>3</b>), respectively. Similarly, reaction of Ph₃SeCl with LiCp and KCp* furnishes [Cp][SePh₃] (<b>4</b>) and [Cp*][SePh₃] (<b>5</b>). Each was characterized by X-ray crystallography, revealing similar η⁵-coordination with little distortion from an idealized half-sandwich geometry, presumably from the remaining lone pair on tellurium and selenium. The Te–centroid distances are relatively long (<b>1</b>: 2.770(3), <b>2</b>: 2.746(1), and <b>3</b>: 2.733(1) Å), suggesting a mostly ionic interaction. Se–centroid distances (<b>4</b>: 2.748(3), <b>5</b>: 2.707(2), 2.730(2) Å) were found to be surprisingly similar despite its smaller atomic radius. Compounds <b>2</b>, <b>3</b>, and <b>5</b> display rapid decomposition at room temperature, extruding a phenylated cyclopentadiene and the and the respective diphenylchalcogenide. The nature of bonding within these complexes was investigated through DFT methods and found to be primarily ionic in nature.</p><p dir="ltr">Synthesis of homoleptic zirconium and hafnium dithiocarbamate via carbon disulfide insertion into zirconium and hafnium amides were investigated for their utility as soluble molecular precursors for chalcogenide perovskites and binary metal sulfides. Treating M(NEtR)₄ (M= Zr, Hf and R= Me, Et) with CS₂ resulted in quantitative yields of homoleptic Group IV dithiocarbamates. Zr(k²-S₂CNMeEt) (<b>1</b>), Zr(k²-S₂CNEt₂)₄ (<b>2</b>), and Hf(k²-S₂CNEt₂)₄(<b>4</b>), a rare example of a crystal of a homoleptic hafnium CS₂ inserted amide species, were characterized. A computational analysis confirmed assignments for IR spectroscopy.<b> </b>To exemplify the utility of the Group IV dithiocarbamates, a solution-phase nanoparticle synthesis was performed to obtain ZrS₃ via the thermal decomposition of Zr(S₂CNMeEt)₄</p><p dir="ltr">Chalcogenide perovskites have garnered interest for applications in semiconductor devices due to their excellent predicted optoelectronic properties and stability. However, high synthesis temperatures have historically made these materials incompatible with the creation of photovoltaic devices. Here, we demonstrate the solution processed synthesis of luminescent BaZrS₃ and BaHfS₃ chalcogenide perovskite films using single-phase molecular precursors at sulfurization temperatures of 575 °C and sulfurization times as short as one hour. These molecular precursor inks were synthesized using known carbon disulfide insertion chemistry to create Group 4 metal dithiocarbamates, and this chemistry was extended to create species, such as barium dithiocarboxylates, that have never been reported before. These findings, with added future research, have the potential to yield fully solution processed thin films of chalcogenide perovskites for various optoelectronic applications.</p><p dir="ltr">Np(IV) Lewis base adducts were prepared by ligand substitution of NpCl₄(DME)₂. Using acetonitrile and pyridine, NpCl₄(MeCN)₄ (<b>1</b>) and NpCl₄(pyr)₄ (<b>2</b>), were isolated, respectively. All species were fully characterized using spectroscopic and structural analyses.</p>

Crystallography

F-block chemistry

Main group metal chemistry

Organometallic chemistry

Transition metal chemistry

tellurium complexes

Zirconium (Zr)

selenium

separation

hafnium

neptunium

chalcogenide perovskites

dithiocarbamates

Electrical Switching And Thermal Studies On Certain Ternary Telluride Glasses With Silicon Additive And Investigations On Their Suitability For Phase Change Memory Applications

Anbarasu, M

10 1900

The Phase Change Memories (PCM) based on chalcogenide glasses are being considered recently as a possible replacement for conventional Non Volatile Random Access Memories (NVRAM). The main advantages of chalcogenide phase change memories are their direct write/overwrite capability, lower voltages of operation, large write/erase cycles, easiness to integrate with logic, etc. The phase change random access memories work on the principle of memory switching exhibited by chalcogenide glasses during which a local structural change (between amorphous and crystalline states) occurs due to an applied electric field. The development of newer phase change materials for NVRAM applications is based on synthesizing newer glass compositions and investigating their electrical switching characteristics by applying current/voltage pulses of different waveforms. The thermal studies on chalcogenide glasses which provide information about thermal stability, glass forming ability, etc., are also important while selecting a chalcogenide glass for PCM applications. The present thesis work deals with electrical switching and thermal studies on certain silicon based ternary telluride glasses (As-Te-Si, Ge-Te-Si and Al-Te-Si). The effect of network topological thresholds on the composition dependence of switching voltages and thermal parameters such as glass transition temperature, specific heat capacity, non-reversing enthalpy, etc., of these glasses has been investigated. The first chapter of the thesis provides an introduction to various properties of chalcogenide glasses, including their applications in phase change memories. The fundamental aspects of amorphous solids such as glass formation, glass transition, etc., are presented. Further, the concepts of rigidity percolation and self organization in glassy networks and the influence of local structural effects on the properties of glassy chalcogenides are discussed. Also, a brief history of evolution of phase change memories is presented. The second chapter deals with the experimental techniques employed in this thesis work; for sample preparation and for electrical switching studies, Alternating Differential Scanning Calorimetry (ADSC), Raman spectroscopy, NMR spectroscopy, etc. The third chapter discusses the electrical switching and thermal studies on As30Te70-xSix (2 ≤ x ≤ 22) and As40Te60-xSix (2 ≤ x ≤ 17) glasses. The composition dependence of electrical switching voltage (VT) and thermal parameters such as glass transition temperature (Tg), crystallization temperature (Tc), thermal stability (Tc-Tg), etc., reveals the occurrence of extended rigidity percolation and chemical thresholds in As30Te70-xSix and As40Te60-xSix glasses. Chapter 4 presents the electrical switching and thermal studies on Ge15Te85-xSix glasses (2 ≤ x ≤ 12). These glasses have been found to exhibit memory type electrical switching. While Ge15Te85-xSix glasses with x ≤ 5 exhibit a normal electrical switching, an unstable behavior is seen in the I-V characteristics of Ge15Te85-xSix glasses with x > 5 during the transition to ON state. Further, the switching voltage (VT) and initial resistance (R) are found to increase with addition of Si, exhibiting a change in slope at the rigidity percolation threshold of the Ge15Te85-xSix system. The ADSC studies on these glasses indicate the presence of an extended stiffness transition and a thermally reversing window in Ge15Te85-xSix in the composition range of 2 ≤ x ≤ 6. The fifth chapter deals with electrical switching investigations, thermal and structural studies on Al15Te85-xSix glasses (2 ≤ x ≤ 12). These glasses have been found to exhibit two crystallization reactions (Tc1 and Tc2) for compositions with x < 8 and a single stage crystallization is seen for compositions above x = 8. Also, a trough is seen in the composition dependence of non-reversing enthalpy (ΔHNR), based on which it is proposed that there is a thermally reversing window in Al15Te85-xSix glasses in the composition range 4 ≤ x ≤ 8. Further, Al15Te85-xSix glasses are found to exhibit a threshold type electrical switching at ON state currents less than 2 mA. The start and the end of the thermally reversing window seen in the thermal studies are exemplified by a kink and saturation in the composition dependence of switching voltages respectively. 27Al Solid State NMR measurements reveal that in Al15Te85-xSix glasses, Al atoms reside in 4-fold as well as 6-fold coordinated environments. Unlike in Al-As-Te glasses, there is no correlation seen between the composition dependence of the fraction of 4-fold and 6-fold coordinated aluminum atoms and the switching behavior of Al-Te-Si samples. Chapter 6 provides a comparison of the properties of the three glassy systems studied (As-Te-Si, Ge-Te-Si and Al-Te-Si), made to identify the system better suited for phase change memory applications. It is found that the Ge-Te-Si glassy system has better electrical/thermal properties for phase change memory applications. The seventh chapter describes easily reversible SET-RESET processes in Ge15Te83Si2 glass which is a promising candidate for phase change memory applications. This sample exhibits memory switching at a comparatively low threshold electric field (Eth) of 7.3 kV/cm. The SET and RESET processes have been achieved with 1 mA triangular current pulse for the SET process and 1 mA rectangle pulse (of 10 msec width) for RESET operation respectively. Further, a self-resetting effect is seen in this material upon excitation with a saw-tooth/square pulse. About 6.5x104 SET-RESET cycles have been achieved without any damage to the device. In chapter 8, results of in-situ Raman scattering studies on the structural changes occurring during the SET and RESET processes in Ge15Te83Si2 sample, are presented. It is found that the degree of disorder in the glass is reduced from OFF to SET state. The local structure of the sample under RESET condition is similar to that in the OFF state. The Raman results are found to be consistent with the switching results which indicate that the Ge15Te83Si2 glass can be SET and RESET easily. Further, Electron Microscopic studies on switched samples indicate the formation of nanometer sized particles of cSiTe2. A summary of the results obtained and the scope for future work are included in the chapter 9 of the thesis.

Chalcogenide Glasses

Telluride Glasses - Thermal Properties

Glassy Chalcogenides

As-Te-Si Glasses

Ge-Te-Si Glasses

Al-Te-Si Glasses

Phase Change Memory

Raman Scattering

Electrical Switching

SET-RESET Processes

Materials Science

UNVEILING THE AMINE-THIOL MOLECULAR PRECURSOR CHEMISTRY FOR FABRICATION OF SEMICONDUCTING MATERIALS

Swapnil Dattatray Deshmukh (11146737)

22 July 2021

<div>Inorganic metal chalcogenide materials are of great importance in the semiconducting field for various electronic applications such as photovoltaics, thermoelectrics, sensors, and many others. Compared to traditional vacuum processing routes, solution processing provides an alternate cost-effective route to synthesize these inorganic materials through its ease of synthesis and device fabrication, higher material utilization, mild processing conditions, and opportunity for roll-to-roll manufacturing. One such versatile solution chemistry involving a mixture of amine and thiol species has evolved in the past few years as a common solvent for various precursor dissolutions including metal salts, metal oxides, elemental metals, and chalcogens.</div><div><br></div><div>The amine-thiol solvent system has been used by various researchers for the fabrication of inorganic materials, but without the complete understanding of the chemistry involved in this system, utilizing its full potential, and overcoming any inherent limitations will be difficult. So, to identify the organometallic complexes and their reaction pathways, the precursor dissolutions in amine-thiol solutions, specifically for elemental metals like Cu, In and chalcogens like Se, Te were studied using X-ray absorption, nuclear magnetic resonance, infrared, and Raman spectroscopy along with electrospray ionization mass spectrometry techniques. These analyses suggested the formation of metal thiolate complexes in the solution with the release of hydrogen gas in the case of metal dissolutions confirming irreversibility of the dissolution. Insights gained for chalcogen dissolutions confirmed the formation of different species like monoatomic or polyatomic clusters when different amine-thiol pair is used for dissolution. Results from these analyses also identified the role of each component in the dissolution which allowed for tuning of the solutions by isolating the complexes to reduce their reactivity and corrosivity for commercial applications.</div><div><br></div><div>After identifying complexes in metal dissolution for Cu and In metals, the decomposition pathway for these complexes was studied using X-ray diffraction and gas chromatography mass spectrometry techniques which confirmed the formation of phase pure metal chalcogenide material with a release of volatile byproducts like hydrogen sulfide and thiirane. This allowed for the fabrication of impurity-free thin-film Cu(In,Ga)S2 material for use in photovoltaic applications. The film fabrication with reduced carbon impurity achieved using this solvent system yielded a preliminary promising efficiency beyond 12% for heavy alkali-free, low bandgap CuInSe2 material. Along with promising devices, by utilizing the understanding of the chalcogen complexation, a new method for CuInSe2 film fabrication was developed with the addition of selenide precursors and elemental selenium which enabled first-ever fabrication of a solution-processed CuInSe2 thin film with thickness above 2 μm and absence of any secondary fine-grain layer.</div><div><br></div><div>Along with thin-film fabrication, a room temperature synthesis route for lead chalcogenide materials (PbS, PbSe, PbTe) with controlled size, shape, crystallinity, and composition of nanoparticle self-assemblies was demonstrated. Micro-assemblies formed via this route, especially the ones with hollow-core morphology were subjected to a solution-based anion and cation exchange to introduced desired foreign elements suitable for improving the thermoelectric properties of the material. Adopting from traditional hot injection and heat up synthesis routes, a versatile synthesis procedure for various binary, ternary, and quaternary metal chalcogenide (sulfide and sulfoselenide) nanoparticles from elemental metals like Cu, Zn, Sn, In, Ga, and Se was developed. This new synthesis avoids the incorporation of impurities like O, Cl, I, Br arising from a traditional metal oxide, halide, acetate, or other similar metal salt precursors giving an opportunity for truly impurity-free colloidal metal chalcogenide nanoparticle synthesis.</div>

Inorganic Chemistry

Compound Semiconductors

Synthesis of Materials

Solution Chemistry

Amine

Thiol

CIGS

CIS

Selenium

Tellurium

PbS

PbSe

PbTe

Lead Chalcogenide

Nanoparticles

Metal Chalcogenide

Solar Cell

Photovoltaic

Solution Processing

Thin Film

Metal Dissolution

Silver and/or mercury doped thioarsenate and thiogermanate glasses : Transport, structure and ionic sensibility / Verres thioarsénate et thiogermanate dopés à l'argent et/ou au mercure : Transport, structure et sensibilité ionique

Zaiter, Rayan

11 December 2018

Le but de ce travail de thèse consiste à étudier les propriétés physico-chimiques des verres chalcogénures afin de pouvoir les utiliser comme membranes de capteurs chimiques destinés pour le dosage des ions Hg²⁺. Dans un premier temps, les propriétés macroscopiques des systèmes vitreux AgY-As₂S₃ (Y = Br, I), HgS-GeS₂, AgI-HgS-As₂S₃ et AgI-HgS-GeS₂, telles que les densités et les températures caractéristiques (Tg et Tc) ont été mesurées et analysées selon les compositions des verres. Puis, dans un second temps, les propriétés de transport ont été étudiés à l'aide de la spectroscopie d'impédance complexe d'une part, ou d'autre part, par des mesures de la résistivité. Ces dernières montrent que les verres de chalcogénures dopés à l'halogénure d'argent présentent deux différents régimes de transports au-dessus du seuil de percolation xc ≈ 30 ppm : (i) domaine de percolation critique, et (ii) domaine contrôlé par modificateur. Vient ensuite la troisième partie, elle consiste à déchiffrer les relations composition/structure/propriété grâce à plusieurs études structurales. Des mesures par spectroscopie Raman, par diffraction de neutrons et de rayons X haute énergie, par diffusion des neutrons sous petits angles (SANS), ainsi que des modélisations RMC/DFT et AMID ont été réalisées. Enfin, la dernière partie de ce travail était une étude préliminaire des caractéristiques des nouveaux capteurs chimiques. Il a été consacré à l'étude des relations entre la composition et la sensibilité des membranes ainsi qu'aux limites de détection qui les définissent. / The aim of the thesis is to study the physicochemical properties of the silver halide doped chalcogenide glasses for the possibility to use them as chemical sensors for quantitative analysis of Hg²⁺ ions. First, the macroscopic properties of AgY-As₂S₃ (Y = Br, I), HgS-GeS₂, AgI-HgS-As₂S₃ and AgI-HgS-GeS₂ glassy systems such as the densities and the characteristic temperatures (Tg and Tc) were measured and analyzed according to the glass compositions. Second, the transport properties were studied using complex impedance and dc conductivity. Measurements show that the silver halide doped chalcogenide glasses exhibit two drastically different ion transport regimes above the percolation threshold at xc ≈ 30 ppm : (i) critical percolation, and (ii) modifier-controlled regimes. Third, to unveil the composition/structure/property relationships, various structural studies were carried out. Raman spectroscopy, high-energy X-ray diffraction, neutron diffraction and small-angle neutron scattering experiments, together with RMC/DFT and AMID modelling were employed. Finally, the last part was a preliminary study of the characteristics of new chemical sensors. It was devoted to study the relationship between the membranes' composition and sensitivity but also detection limits.

Verres chalcogénures

Conductivité

Domaine de percolation critique

Domaine contrôlé par modificateur

Séparation de phases

Dimorphisme HgS

Connectivité réseau

Capteurs chimiques

Chalcogenide glasses

Conductivity

Critical percolation

Phase-separation

HgS dimorphism

Network connectivity

Chemical sensors

Traitement d'eaux usées par adsorption sur des polymères de cyclodextrine et développement de capteurs chimiques à base de membranes de verres de chalcogénures destinées à la détection des ions Hg²⁺ / Wastewater treatment by adsorption on cyclodextrin polymer and development of chemical sensors containing membranes of chalcogenides glasses intended in detection of ions Hg²⁺

Khaoulani, Sohayb

16 December 2015

L'objectif de ce travail a consisté à identifier des polluants émergents dans des eaux usées issues de stations d'épuration ainsi que dans le milieu naturel et à proposer une méthode de remédiation et un suivi de ces polluants. Dans un premier temps, nous avons identifié les polluants organiques contenus dans les échantillons d'eaux usées et issues du milieu naturel par chromatographie en phase liquide ou gazeuse couplée à une spectrométrie de masse, chromatographie en phase gazeuse par espace de tête statique et par spectrométrie par torche à plasma couplée à une spectrométrie de masse. Différents polluants ont été trouvés tels que les phtalates, des substances médicamenteuses, le cholestérol et des éléments de traces métalliques. Dans le but de piéger ces polluants, différents polymères de cyclodextrine (CD) solubles et insolubles dans l'eau ont été synthétisés et leurs capacités d'adsorption ont été évaluées. Après adsorption sur les polymères de CD, nous avons observé une diminution de la teneur en carbone organique total (COT) de l'effluent. Ces polymères se sont révélés être des adsorbants efficaces. Dans un second temps, des verres du système pseudo-ternaire Agl-HgS-As₂S₃ ont été synthétisés en ajoutant le composé le composé Agl dans le système pseudo-binaire HgS-As₂S₃. Ces verres de chalcogénures sont des membranes ionosélectives permettant de détecter les ions Hg²⁺ dans les effluents. Tout d'abord, nous avons défini le domaine vitreux des verres à l'aide de la diffraction des rayons X, ensuite les propriétés macroscopiques des verres ont été déterminées. Ainsi, les propriétés de transport ont été étudiées à l'aide de la spectroscopie d'impédance complexe montrant que l'ajout d'Agl dans le verre pseudo-binaire HgS-As₂S₃ provoque une augmentation de la conductivité ionique. Afin de comprendre ce phénomène, diverses études structurales ont été déployées par spectroscopie Raman, diffraction de neutrons et de rayon X haute énergie. Ces techniques ont montré que l'évolution de la conductivité ionique est dépendante de la structure du verre qui forme des chemins préférentiels de conduction. Enfin, différents capteurs avec différentes compositions sont testés afin de définir la sensibilité, la limite de détection et les coefficients de sélectivité en présence d'ions interférents. / The aim of this work was to identify the emerging pollutants in the effluents of wastewater treatment plants as well as in the natural environment, and to propose a method of remediation and monitoring of these pollutants. In the first part of the thesis, we have identified the organic pollutants contained in the wastewater samples using (i) gas and/or liquid chromatography coupled with a mass spectrometry, (ii) static-headspace gas chromatography, and (iii) inductively coupled plasma atomic emission spectroscopy. Different pollutants were found such as phthalates, drugs, cholesterol, and heavy metal traces. In order to trap these pollutants, various water soluble/insoluble cyclodextrin β-CD polymers have been synthesized and their adsorption capacities were evaluated. After the analysis of the effluent samples, we observed a decrease of the Total Organic Carbon (TOC). This decrease was attributed to the adsorption of pollutant by CD polymers which have proven to be effective adsorbents. The second part of the thesis included two main sub-parts : (i) a synthesis and characterization part and (ii) an application part. In the first sub-part, chalcogenide glasses in the pseudo-ternary Agl-HgS-As₂S₃ system have been synthesized by adding silver iodide "Agl" to the quasi-binary HgS-As₂S₃ system. The vitreous domain and the macroscopic properties of glass samples were determined. Electrical conductivity of glasses was studied using both the complex impedance spectroscopy and resistivity measurements ; it was found that adding Agl to the quasi-binary HgS-As₂S₃ alloy causes an increase in the ionic conductivity. Structural studies, using various techniques as Raman spectroscopy, neutron scattering and high-energy X-ray diffraction, have been performed in order to decipher the relation between both structural and transport properties in these glasses. In the second sub-part, the obtained glasses in the ternary system were used as membranes in chemical sensors dedicated to mercury detection in aqueous solution. As a result, various sensors with different compositions were tested to determine their corresponding sensitivity, detection limit and selectivity coefficients in the presence of interfering ions.

Pollution

Eaux usées

Traitement des eaux usées

Cyclodextrine

Adsorption

Polymères

COT

Verres de chalcogénures

Conductivité ionique

Structure des verres

Capteur sélectif

Pollution

Wastewater

Wastewater treatment

Cyclodextrin

Adsorption

Polymers

TOC

Chalcogenide glasses

Ionic conductivity

Glass structure

Sensors selective