Global ETD Search

11	Light induced charge transfer processes and pyroelectric luminescence in Sn2P2S6 Rüdiger, Andreas 28 August 2006 (has links) Sn2P2S6 is ferroelectric at room temperature. It is of technological interest in a variety of applications such as pyroelectric motion detectors and the photorefractive effect. Until now the defect structure and the light-induced charge transfer processes in this material have not been subject of a detailed investigation. The main part of this thesis describes and interprets data of electron paramagnetic resonance (EPR), optical absorption spectroscopy and their combination at 10 K to unravel the light-induced sensitization and charge transfer paths. In the photosensitized crystal at excitation with 1.5 eV a hole is transferred from a previously generated Sn3(plus) site to another inequivalent site of the ferroelectric phase. For higher excitation energies another hole present as Fe3(plus) is transferred to S2- creating S-. Optical absorption spectroscopy at room temperature indicates the validity of this model for evelated temperature below the Curie-temperature as well. It is consistent with both our interpretation of EPR spectra and the observation of photoinduced persistent conductivity that electronic bipolarons are the negative charge carriers. An additional chapter interprets a manifestation of pyroelectric luminescence already reported in other pyroelectric materials in terms of an internal Poole-Frenkel-effect induced by the pyroelectric field under changing temperature. The numerical simulation based on published material parameters is in good agreement with the experimental data for both heating and cooling. electron paramagnetic resonance (EPR) optical absorption spectroscopy Sn2P2S6 pyroelectrical luminescence light induced charge transfer 29 - Physik, Astronomie ddc:530
12	Substratbindung und -freigabe während des Katalysezyklus eines biotinspezifischen ECF-Transporters Finkenwirth, Friedrich 10 April 2017 (has links) ECF (Energy-Coupling Factor)-Transporter sind prokaryotische Aufnahmesysteme für Mikronährstoffe, die eine spezielle Gruppe von Transportern mit ATP-Bindekassette (ABC) darstellen. Sie beinhalten zwei asymmetrische Membranproteine, von denen eins (S) für die spezifische Bindung und Translokation des Substrates und das andere (T) für die Kopplung mit den ATPasen (A1,A2) zuständig ist. Bei ECF-Transportern der Subklasse I bilden diese Komponenten eine Einheit, während bei Vertretern der Subklasse II ein AAT-Modul mit wechselnden S-Einheiten interagiert. In der vorliegenden Arbeit wurde der Transportmechanismus, der eine Drehung der kompletten S-Einheit in der Membran beinhaltet, anhand des Biotintransporters BioMNY erstmals experimentell validiert. Durch Rekonstitution in Lipid-Nanodiscs, chemische Quervernetzung, fluoreszenz- und ESR-spektroskopische Techniken sowie einen Bindungstest mit radioaktivem Biotin wurde gezeigt, dass (i) die ATP-Bindung an die ATPasen zu einer Aufrichtung der S-Einheit (BioY) führt, (ii) diese Bewegung die Substratbeladung ermöglicht und (iii) BioY dabei ununterbrochen mit der T-Einheit (BioN) interagiert. Dies stellt einen Gegensatz zu Systemen der Subklasse II dar, für die ein ATP-abhängiger Austausch von S-Einheiten im Transportzyklus gezeigt worden war. Darüber hinaus wurde ein Escherichia coli-Stamm konstruiert, der durch Blockierung seines hochaffinen Biotintransporters und des -synthesewegs auf Spuren von Biotin nicht wachsen kann. Dieser Stamm ermöglichte einen eindeutigen Nachweis der Transportaktivität einiger solitärer BioY-Proteine. Aufgrund der einheitlichen Topologie von S-Einheiten ist ein Kippen auch für solitäre BioY-Varianten wahrscheinlich. Auch die metallspezifischen S-Einheiten CbiM und NikM besitzen ohne AAT-Modul eine basale Co2+- bzw. Ni2+-Transportaktivität. Ein ESR-spektroskopischer Kobaltnachweises zeigte, dass die aus nur zwei Membranhelices bestehende CbiN-Einheit für die Metallbeladung von CbiM essentiell ist. / ECF (Energy-Coupling Factor) transporters are a subgroup of ABC transporters that mediate uptake of micronutrients into prokaryotic cells. In contrast to canonical ABC importers, ECF transporters comprise two unrelated membrane proteins, one of which is responsible for specific and high affinity substrate binding (S) and the other one constitutes the coupling component (T) between S and the cytosolic ABC-ATPases (A1,A2). Subclass I transporters consist of four dedicated components whereas in subclass II transporters, a central AAT-module may interact with various S units. The biotin specific subclass I ECF transporter BioMNY was used to experimentally verify the hitherto hypothetic transport mechanism, which involves a rotation of the S unit within the membrane. With a series of experiments including reconstitution of BioMNY into lipid nanodiscs, site-specific cross-linking, a substrate binding assay with radioactive biotin and both fluorescence and EPR spectroscopic techniques, the ATP-dependent rotation of BioY (S) as a prerequisite for substrate binding and release was shown for the first time for an ECF transporter. Unlike subclass II transporters, for which an ATP-dependent release of the S unit was proposed, BioY interacts continuously with BioN (T) during the transport cycle. In a second focus of the work, an Escherichia coli reporter strain for biotin transporters was constructed. Due to inactivation of both biotin synthesis and the intrinsic high affinity biotin transporter, this strain was not capable of growing on trace amounts of biotin. With the use of this strain, transport activity of recombinantly produced solitary BioY proteins that naturally lack other ECF components was evidenced. Transport activity in the absence of AAT modules is also a feature of the Co2+ and Ni2+ specific S components CbiM and NikM. An EPR spectroscopic Co2+ detection assay helped underscoring the essential role of the small membrane protein CbiN for Co2+ loading of CbiM. ABC-Transporter Fluoreszenz ECF-Transporter ATP Nanodiscs Vitaminaufnahme Elektronenspinresonanz (ESR) ABC transporter fluorescence ECF transporter ATP nanodiscs vitamin uptake electron paramagnetic resonance (EPR) 570 Biowissenschaften, Biologie 32 Biologie WX 1101 WE 5440 ddc:570
13	Atividade antioxidante de extratos vegetais da flora brasileira: estudo com ressonância paramagnética eletrônica (RPE) e teoria do funcional da densidade (TFD) / Antioxidant Activity of Plant Extracts from Brazilian Flora: Study of Electron Paramagnetic Resonance (EPR) and Density Functional Theory (DFT). Santos, Adevailton Bernardo dos 03 July 2006 (has links) Há, no Brasil, uma enorme diversidade de espécies vegetais, e um conhecimento popular de várias propriedades medicinais das mesmas. Dentre os estudos realizados com extratos de plantas, há um interesse especial na atividade antioxidante. Este trabalho, focado em atividade antioxidante, é dividido em duas partes: a primeira, utiliza a técnica de RPE para estudar a ação dos antioxidantes neutralizando os radicais livres, enquanto que a segunda utiliza a TFD para, em simulação computacional, ajudar a entender os resultados obtidos na primeira parte. Foram analisados 10 extratos vegetais: Swartzia langsdorffii, Machaerium villosum, Pterogyne nitens, Maytenus ilicifolia (casca de raiz), Pera glabrata, Aegiphyla sellowiana, Copaifera langsdorffii, Chrysophyllum inornatum, Iryanthera juruensis (folhas e sementes), Didymopanax vinosum. O estudo da atividade antioxidante com RPE utiliza dois métodos diferentes: o primeiro método mede a atividade antioxidante por meio do controle da quantidade de radicais livres, TEMPOL e DPPH, em contato com o extrato vegetal, enquanto que o segundo método utiliza o spin trap DMPO em conjunto com a reação de Fenton (Fe2+ + H2O2 => Fe3+ + HO- + HO) para analisar a ação dos extratos vegetais contra o radical hidroxila (OH?). A simulação computacional dos compostos TEMPOL, DPPH e DMPO é realizada em um método de primeiros princípios na Teoria do Funcional da Densidade, com uso de pseudopotenciais. O código utilizado é o SIESTA. As conclusões indicam que o extrato de Iryanthera juruensis, tanto de folhas quanto de sementes, exibe atividades antioxidantes bastante acentuadas, em todos os métodos utilizados. A simulação computacional aponta o TEMPOL menos reativo que o DPPH, devido a menor energia liberada em sua reação de redução. Sabendo que algumas destas espécies já são usadas popularmente por propriedades medicinais, estudos futuros para a correta identificação do agente antioxidante e seu possível uso, tanto na indústria alimentícia quanto na farmacêutica, deverão ser realizados. / There is, in Brazil, a great diversity of vegetable species, and a popular knowledge of several medicinal properties of the some of them. In studies carried out with plants? extracts, there is special interest in antioxidant activities. This work, focused in antioxidant activity, is divided in two parts: the first uses EPR technique to study the antioxidant activities neutralizing free radicals, while the second one uses DFT, in computational simulation, to understand the results obtained from the first part. Ten vegetable extracts were analyzed: Swartzia langsdorffii, Machaerium villosum, Pterogyne nitens, Maytenus ilicifolia (bark root extracts), Pera glabrata, Aegiphyla sellowiana, Copaifera langsdorffii, Chrysophyllum inornatum, Iryanthera juruensis (leaves and seeds), Didymopanax vinosum. The study with EPR uses two different methods: the first method measures the antioxidant activity by monitoring the amount of free radicals, DPPH and TEMPOL, that are in contact with the plant extract, the second method uses spin trap DMPO with Fenton reaction (Fe2+ + H2O2 => Fe3+ + HO- + HO) for the study of the plant extract antioxidant activity against the hydroxyl radical (OH?). The computational simulation of TEMPOL, DPPH and DMPO is carried out using a method of first principles within the Density Functional Theory and pseudopotentials. The code is SIESTA. The conclusions indicate that the Iryanthera juruensis extract, as of leaves as of seeds, exhibits accentuated antioxidants activities, in all of the used methods. The computational simulation indicated that the TEMPOL is less reactive than the DPPH, because the lower energy in its reduction reaction. As some of these species are already used popularly by medicinal properties, future studies for correct identification of the antioxidant compounds and its possible use, as in the food industry as in the pharmaceutical industry, should be realized. antioxidant antioxidante Density Functional Theory (DFT). DMPO DMPO DPPH DPPH Electron Paramagnetic Resonance (EPR) extrato vegetal Fenton reaction free-radicals radicais livres reação de Fenton TEMPOL TEMPOL Teoria do Funcional da Densidade (TFD). vegetal extract
14	Phase Transitions And Relaxation Processes In Water And Glycerol-Water Binary Liquid Mixtures : Spin Probe ESR Sudies Banerjee, Debamalya 08 1900 (has links) A liquid Cooled below its normal freezing temperature is known as a supercooled liquid. On further cooling, supercooled liquids crystallize to thermodynamically stable, ordered structures. Alternatively, if the cooling rate is fast enough, the crystallization may be avoided altogether. Below a particular temperature during rapid cooling the liquid will solidify into a disordered, amorphous phase -also known as the glassy phase of matter. This particular temperature is termed the ”glass transition temperature” (Tg). Unlike a crystalline solid, a glass is neither a thermodynamically stable phase nor does it possess long range molecular ordering. Very slow structural relaxation (in the time scale of ∼ 100 s) is always present in the glassy phase. Thus, this phase is often referred to as a metastable phase of matter. Experimental and theoretical studies related to the behavior of supercooled liquids are the subject matter of many investigations for the last few decades [1]. These studies find their applications in diverse fields such as geology, cryopreservation, glaciology and atmospheric science. However, properties of supercooled liquids and the corresponding amorphous phase are not completely understood at present, particularly for hydrogen bonded (H-bonded) systems. This thesis concerns both the crystallization and the glass formation process of H-bonded systems. The systems of interest are water, the commonly accepted universal solvent, and the aqueous binary mixture of glycerol and water. The technique of molecular probing is often used to study the cooperativety and rotational diffusion of supercooled liquids and for determination of the glass transition temperature. For the present set of work, a molecular probe technique called spin probe ESR is extensively used. Electron paramagnetic resonance or electron spin resonance (EPR/ESR) measures the electronic energy level separation and is well known for the high sensitivity. All of the systems studied in the present set of work are diamagnetic. This issue is circumvented by dissolving paramagnetic spin probe molecules, which are usually organic free radicals with one N-O group, into the systems. Spin probes are added in very low concentrations (~10-3M) to minimize the effect on the host system and also to avoid mutual interactions between them. The unpaired electron delocalized in the direction of the N-O bond serves as the paramagnetic center required for an ESR experiment. The splitting of electron energy level due to the external magnetic field (Zeeman splitting) can give rise to resonance absorption of energy if exposed to a microwave of appropriate frequency. There is also a magnetic coupling (hyperfine) between the spin of the unpaired electron and nuclear spin of the nearby nitrogen atom. The hyperfine coupling splits each electron energy levels, to the first order, symmetrically into three levels. The transitions between these levels -subject to appropriate selection rules -give rise to the ESR spectrum [2]. The spectral shape in a magnetic field sweep ESR experiment appears complex if randomly oriented spin probes are dispersed in an amorphous or polycrystalline solid matrix. The high degree of mobility in probe molecules, present in a liquid solution, can average out the individual anisotropy of magnetic tensors to get a spectrum of three equally spaced liens. Experiments can be performed spanning a spin probe reorientation timescale of 10-7-10-12 s typically in the temperature range of 4.2 -300K. In chapter one we have given a brief overview of the supercooled liquids and the phase transitions related to the present work. Particular emphasis has been given to the dynamical features of the supercooled liquid close to its glass transition temperature and their classification based on the degree of ’fragility’ [3]. Brief general introductions of the systems studied in each of the following chapters are also provided. Then, the details of ESR spectroscopy and a quantum mechanical picture of the method of spin probe ESR have been discussed [4]. A separate section has been devoted to the numerical and analytical methods used to analyze the spectrum to extract information related to the spin probe dynamics [5]. The chapter concludes with a description of the ESR spectrometer. In chapter two we have studied the glass transition and dynamics of the supercooled water by the method of spin probe ESR. The vitrification has been done by direct exposure of the bulk water sample, doped with the spin probe TEMPOL, to the liquid helium flow. The vitrified matrix turns into the ultraviscous liquid above the putative glass transition temperature of ~136 K which further transforms to cubic ice (Ic) above TX ~150 K. The supercooled fraction of water, along with the spin probes which are treated as impurities by the crystallized surroundings, remain trapped inside the veins or triple junctions of the ice grains which serve as the interfacial reservoir of impurities in a polycrystalline ice matrix. The spectra for the entire temperature range have been analyzed with the help of in-depth computation by modelling the reorientation of TEMPOL in terms of the jump angle θs and the rotational correlation time τ [5]. This model, based on a homogeneous mobility scenario of the spin probe, works nicely except in the temperature range of 140-180 K. Dynamical heterogeneity (DH) is apparent in this temperature range and a more mobile (fast) component, as compared to the one corresponding to the very slow dynamics of TEMPOL at lower temperatures (slow), is observed. The relative weight of the fast and the slow component changes with temperature and above ~180 K the entire spectrum changes into the motionally narrowed triplet. The temperature dependence of the slow component of τ shows a change in slope at a temperature close to the putative glass transition temperature of water. The fast component of τ exhibits a fragile, i.e. non-Arrhenius character at high temperature with a crossover to a strong, i.e. Arrhenius behavior below ~225 K, close to the hypothesized fragile-to-strong crossover (FSC) for water at TFSC ~228 K. The breakdown of the Debye-Stokes-Einstein (DSE) law is observed when the τ values are combined with the available viscosity data of water to evaluate the DSE ratio, paralleling the SE breakdown which has recently been observed in nanoconﬁned water [6]. The dynamical heterogeneity is thought to be closely associated with the static structural heterogeneities of supercooled water. The existence of large scale structural fluctuations spanning a range of low-and high-density phases of liquid water have been associated with the heterogeneous dynamics sensed by TEMPOL. Motivated by the Arrhenius like behavior of the slow component, it has been identified with the low density liquid (LDL). The fragile nature of the fast component at high temperature may be identified with that of the high density liquid (HDL) which is the predominant fraction in liquid or weakly supercooled water [6]. Chapter three reports the studies on freezing and dynamics of the supercooled water trapped inside the veins of a polycrystalline ice matrix by dissolving spin probes TEMPO and TEMPOL into it. When a millimolar spin probe aqueous solution is cooled below the freezing point of water, the spin probes -driven by the mechanism described above migrate to the liquid environment inside the ice veins. Local concentration of the probe molecules inside the veins can go up to 1-10 M [7]. Bulk crystallization is evident in differential scanning calorimetry (DSC) studies whereas the liquid environment of the spin probe below the bulk freezing is confirmed by its narrow triplet ESR spectrum. A sudden collapse of this narrow triplet into a single broad line indicates the freezing of the trapped water fraction which usually happens well below the DSC freezing point for both the probes. The spin probe detected freezing point of this interstitial water is found to be largely dependent on the properties and the amount of the dissolved probe molecules. An explanation is sought in terms of the ’destructuring effect’ on the tetrahedral ordering of the water H-bond network by both the high local concentration of the spin probes and the hydrogen bond strength, formed between the water and the spin probe molecules through the polar groups of the latter [8, 9]. These two factors are thought to play important roles in determining the reorientational dynamics of the spin probe molecules, as well. The rotational correlation times of the two probes exhibit a crossover owing to the different mobility of their salvation shells in the more ordered supercooled water. The observed relaxation behavior of this confined water using the probe TEMPO, which has little effect on water H-bond network, is found in agreement with the previous experimental investigations on water confined in a nanochannel [10]. In chapter four, the glass transition, relaxation and the free volume of the glycerol-water (G-W) system are studied over the glycerol concentration range of 5 -85 mol% with TEMPO as the spin probe. G-W mixture is intrinsically inhomogeneous due to the well established phase segregation below a critical glycerol concentration of 40 mol%. In the inhomogeneous regime the water molecules tend to form cooperative domains besides the mesoscopic G-W mixture [11]. Samples are quenched by rapid cooling down to 4.2 K inside the spectrometer cryostat. Spectra were recorded on slow heating of the sample in the temperature range of 130 -305 K. The glass transition temperature is correlated to the sharp transition of the extrema separation of the ESR spectrum. The glass transition temperatures are found to follow a concentration dependence which is closely associated to the mesoscopic inhomogeneities of the G-W system. The steady enhancement in fragility of the G-W system with the addition of water is evident from the temperature dependence of the spin probe correlation time τ for the entire concentration range. In the temperature range of 283 -303 K, the DSE law is followed i.e. the spin probe reorientation process is found to be strongly coupled to the system viscosity. In this regime, the τ values have been used along with the available viscosity data to calculate the effective volume V of the spin probe for the entire concentration range. The spin probe effective volume is a measure of the available free volume of the host matrix. A drastic change in the quantity is seen in the vicinity of the 40 mol% glycerol concentration owing to a similar structural change of the matrix due to the formation of mesoscopic scale inhomogeneities below the critical concentration [12]. The thesis concludes with a discussion about the possible future directions of research. Glycerol-Water Binary Liquid Mixture ESR Studies Electrostatic Resonance Water - Phase Transition Relaxation Glass Transition Electron Spin Resonance (ESR) Supercooled Liquids Electron Paramagnetic Resonance (EPR) Supercooled Bulk Water Chemical Physics
15	Kinetics and Mechanism of Cu-Catalyzed Atom Transfer Radical Polymerization Sörensen, Nicolai 26 May 2015 (has links) No description available. 540 copper deactivation termination chain-length dependence electron paramagnetic resonance (EPR) kinetics spectroscopy pulsed-laser polymerization (PLP) Chemie (PPN62138352X)
16	Atividade antioxidante de extratos vegetais da flora brasileira: estudo com ressonância paramagnética eletrônica (RPE) e teoria do funcional da densidade (TFD) / Antioxidant Activity of Plant Extracts from Brazilian Flora: Study of Electron Paramagnetic Resonance (EPR) and Density Functional Theory (DFT). Adevailton Bernardo dos Santos 03 July 2006 (has links) Há, no Brasil, uma enorme diversidade de espécies vegetais, e um conhecimento popular de várias propriedades medicinais das mesmas. Dentre os estudos realizados com extratos de plantas, há um interesse especial na atividade antioxidante. Este trabalho, focado em atividade antioxidante, é dividido em duas partes: a primeira, utiliza a técnica de RPE para estudar a ação dos antioxidantes neutralizando os radicais livres, enquanto que a segunda utiliza a TFD para, em simulação computacional, ajudar a entender os resultados obtidos na primeira parte. Foram analisados 10 extratos vegetais: Swartzia langsdorffii, Machaerium villosum, Pterogyne nitens, Maytenus ilicifolia (casca de raiz), Pera glabrata, Aegiphyla sellowiana, Copaifera langsdorffii, Chrysophyllum inornatum, Iryanthera juruensis (folhas e sementes), Didymopanax vinosum. O estudo da atividade antioxidante com RPE utiliza dois métodos diferentes: o primeiro método mede a atividade antioxidante por meio do controle da quantidade de radicais livres, TEMPOL e DPPH, em contato com o extrato vegetal, enquanto que o segundo método utiliza o spin trap DMPO em conjunto com a reação de Fenton (Fe2+ + H2O2 => Fe3+ + HO- + HO) para analisar a ação dos extratos vegetais contra o radical hidroxila (OH?). A simulação computacional dos compostos TEMPOL, DPPH e DMPO é realizada em um método de primeiros princípios na Teoria do Funcional da Densidade, com uso de pseudopotenciais. O código utilizado é o SIESTA. As conclusões indicam que o extrato de Iryanthera juruensis, tanto de folhas quanto de sementes, exibe atividades antioxidantes bastante acentuadas, em todos os métodos utilizados. A simulação computacional aponta o TEMPOL menos reativo que o DPPH, devido a menor energia liberada em sua reação de redução. Sabendo que algumas destas espécies já são usadas popularmente por propriedades medicinais, estudos futuros para a correta identificação do agente antioxidante e seu possível uso, tanto na indústria alimentícia quanto na farmacêutica, deverão ser realizados. / There is, in Brazil, a great diversity of vegetable species, and a popular knowledge of several medicinal properties of the some of them. In studies carried out with plants? extracts, there is special interest in antioxidant activities. This work, focused in antioxidant activity, is divided in two parts: the first uses EPR technique to study the antioxidant activities neutralizing free radicals, while the second one uses DFT, in computational simulation, to understand the results obtained from the first part. Ten vegetable extracts were analyzed: Swartzia langsdorffii, Machaerium villosum, Pterogyne nitens, Maytenus ilicifolia (bark root extracts), Pera glabrata, Aegiphyla sellowiana, Copaifera langsdorffii, Chrysophyllum inornatum, Iryanthera juruensis (leaves and seeds), Didymopanax vinosum. The study with EPR uses two different methods: the first method measures the antioxidant activity by monitoring the amount of free radicals, DPPH and TEMPOL, that are in contact with the plant extract, the second method uses spin trap DMPO with Fenton reaction (Fe2+ + H2O2 => Fe3+ + HO- + HO) for the study of the plant extract antioxidant activity against the hydroxyl radical (OH?). The computational simulation of TEMPOL, DPPH and DMPO is carried out using a method of first principles within the Density Functional Theory and pseudopotentials. The code is SIESTA. The conclusions indicate that the Iryanthera juruensis extract, as of leaves as of seeds, exhibits accentuated antioxidants activities, in all of the used methods. The computational simulation indicated that the TEMPOL is less reactive than the DPPH, because the lower energy in its reduction reaction. As some of these species are already used popularly by medicinal properties, future studies for correct identification of the antioxidant compounds and its possible use, as in the food industry as in the pharmaceutical industry, should be realized. antioxidante DMPO DPPH extrato vegetal radicais livres reação de Fenton TEMPOL Teoria do Funcional da Densidade (TFD). antioxidant Density Functional Theory (DFT). DMPO DPPH Electron Paramagnetic Resonance (EPR) Fenton reaction free-radicals TEMPOL vegetal extract
17	Etude de l'effet de l'anisotropie magnétique sur la phase dynamique et sur la phase géométrique des bits quantiques de spins électroniques d'ions de métaux de transition Mn2+, Co2+, Fe3+ isolés et des complexes d'ions Fe3+ dans l'oxyde de zinc monocristallin / Study of the effect of the magnetic anisotropy on the dynamic phase and on the geometric phase qubits of electron spins of transition metals isolated ions Mn2+, Co2+, Fe3+, and Iron Complexes (Fe3+/Cs+ and Fe3+/Na+) in the zinc oxide single crystal Benzid, Khalif 24 February 2016 (has links) Nous avons étudié, par RPE impulsionnelle, la cohérence quantique et des spins électroniques des ions de transition Mn2+, Co2+, Fe3+, et des complexes Fe3+/Cs+ et Fe3+/Na+, tous présents dans le ZnO monocristallin. Nous avons trouvé que l’anisotropie magnétique peut altérer la cohérence de la phase dynamique des qubits des spins électroniques. Nous avons mesuré une faible décohérence pour les spins d’ions Mn2+et Fe3+ dans ZnO, qui ont tous deux une faible anisotropie magnétique uniaxiale, tandis que les ions Co2+ isolés avec une très forte anisotropie magnétique uniaxiale, une décohérence rapide a été mis en évidence. Nous avons trouvé que les spins électroniques des complexes de type Fe3+/Cs+, ayant un tenseur d’anisotropie magnétique plus complexe que la simple anisotropie uniaxiale des ions Fe3+ isolés, possèdent presque le même temps de décohérence. Par la méthode des perturbations, nous avons mis en évidence théoriquement un terme supplémentaire à la phase habituelle de Berry, dû à l’anisotropie magnétique et qui existe dans tout système ayant un spin S>1/2. / We studied by pulsed EPR (p-EPR), the quantum coherence of electronic spins qubits of isolated transition metal ions of Mn2+, Co2+, Fe3+ and Fe3+/Cs+ as well as Fe3+/Na+ complexes, all found as traces in mono-crystalline ZnO. Indeed, we experimentally demonstrated that the magnetic anisotropy can alter the coherence of the dynamic phase of electronic spins qubits. We found a small decoherence for Mn2+ and Fe3+, spins having a small uniaxial magnetic anisotropy, and on the contrary, we found a very strong decoherence for Co2+ spins having a very strong uniaxial magnetic anisotropy. We found that the electronic spins of the Fe3+/Cs+ complex, having a more complex tensor magnetic anisotropy compared to the simplest uniaxial one of isolated Fe3+ spins in ZnO, have almost the same coherence time. By the perturbation method, we have found theoretically an additional term to the usual geometric Berry phase, due to the magnetic anisotropy which exists in any system having a spin S>1/2. Bits quantiques (qubits) Anisotropie magnétique (couplage ZFS) Phase dynamique Phase géométrique Spins électroniques Métaux de transition Resonance paramagnetique électronique Quantum bits (qubits) Dynamical phase Geometrical phase Electron spin Transition metals Electron paramagnetic resonance (EPR) 539 541.3
18	Development of Overhauser-enhanced magnetic resonance imaging in vivo : application to molecular imaging of proteolysis. / Développement de l'imagerie par résonance magnétique rehaussée par l'effet Overhauser in vivo : application à l'imagerie moléculaire de la protéolyse. Koonjoo, Neha 08 October 2015 (has links) Ce travail fait l’objet d’une avancée scientifique dans le développement de la technique d’IRM rehaussée par l’effet Overhauser dans la souris à 0,2 T. Cette dernière repose sur le transfert de polarisation des spins électroniques saturés d’un radical libre vers les spins des protons (généralement de l’eau) voisins pour rehausser le signal RMN du proton. Notre équipe a développé cette technique pour détecter une activité protéolytique au travers de deux stratégies. La première partie de la thèse a été de détecter pour la première fois une activité protéolytique in situ dans des souris saines et in vitro sur cellules vivantes. L’efficacité du rehaussement par effet Overhauser repose sur le temps de corrélation des spins des électrons non-appariés. Un radical nitroxyde greffé à l’élastine a été utilisé comme substrat. La protéolyse de ce dernier par des élastases pancréatiques a conduit l’observation en 3D d’un rehaussement du signal RMN de plus de 10 fois dans le tube digestif de souris vivantes. De plus, des développements méthodologiques, tels que l’implémentation de la séquence TrueFISP, le sous-échantillonnage par la méthode “Keyhole”, et la reconstruction des données en 3D ont été faits. La deuxième stratégie repose sur des molécules de nitroxyde ayant l’unique propriété de pouvoir décaler leurs pics de résonance après hydrolyse. Un nitroxyde phosphorylé en position Béta pouvant être détecté à deux fréquences spécifiques différentes avant et après hydrolyse d’un groupement chimique a été synthétisé par des chimistes à Marseille. L’hydrolyse de cette macromolécule a été observée in vivo dans l’estomac de souris saines avec des rehaussements de plus de 400% et imagée en 3D avec une bonne résolution spatio-temporelle. Ainsi, une prochaine étape serait de poursuivre ce travail sur un modèle pathologique et développer cette technique à un champ magnétique plus bas. / This work relates the continuity and advances in the implementation of the Overhauser-enhanced Magnetic Resonance Imaging technique on a 0.2 T scanner. Briefly, OMRI technique is based on polarization transfer of saturated electronic spins from free nitroxide radicals to proton spins of surrounding water molecules in the aim to drastically enhance proton NMR signal. To this technique, our research team has merged specific strategies for proteolytic activity detection. The first strategy relies on a 3D visualization of proteolytic activity happening in intact living cells or in vivo in healthy mice. With an Overhauser switch based upon changes in molecular tumbling time, high Overhauser enhancements of 10-fold were observed in the intestinal tract of mice after that elastolytic activity of our probe: the nitroxide-labeled elastin macromolecule took place. In addition, MRI developments - TrueFISP sequence implementation, undersampling Keyhole method and data reconstruction were carried out for imaging these rapid biological processes. A second exquisite strategy is also described using nitroxides with shifting resonant peaks. Here, a Beta-phosphorylated nitroxide molecule was specifically detected at two distinct frequencies: one for its substrate and the other for its product once hydrolysis took place. This hydrolysis was imaged in 3D in the stomach of living mice with Overhauser enhancements of more than 400% and with a good spatiotemporal resolution. The perspectives of this work lie on a future detection of a pathological proteolytic activity in vivo and eventually and development of very low magnetic field OMRI. Effet Overhauser Imagerie moléculaire Résonance paramagnétique électronique Protéolyse Activité enzymatique Nitroxydes phosphorylés Sous-échantillonnage “Keyhole" Molecular imaging Electron paramagnetic resonance (EPR) Proteolysis Enzymatic activity Phosphorylated nitroxide radicals Keyhole method
19	Ingénierie des centres colorés dans SiC pour la photonique et la solotronique / Engineering of color centers in SiC for photonics and solotronics Al Atem, Abdul Salam 29 November 2018 (has links) Les défauts ponctuels dans les semi-conducteurs sont étudiés pour la réalisation de bits quantiques d’information (Qubit). A ce jour, le système le plus développé est le centre NV dans le diamant. Récemment, les défauts ponctuels du carbure de silicium (SiC) ont été identifiés comme prometteurs pour la réalisation de Qubit en raison de leur long temps de cohérence de spin et du fonctionnement à température ambiante. Dans ce contexte, nous étudions la formation, la caractérisation optique et magnétique des défauts ponctuels dans SiC, ainsi que l’amélioration de la collection de leur luminescence. Nous commençons par une description des différents critères qui font du SiC un matériau clé pour les applications Qubit. Ensuite, nous présentons une étude bibliographique sur les principaux défauts ponctuels dans SiC en nous focalisant sur les centres : VSi, VSiVC, NV. Nous portons par la suite notre étude sur les conditions optimales d’irradiation ioniques/électroniques et de recuit post-irradiation pour la formation de défauts ponctuels luminescents dans le polytype cubique de SiC. Nous avons identifié les différents types de défauts dans le visible. Dans l’infra-rouge, nous n’avons détecté que le centre VSiVC en trouvant les conditions optimales de sa luminescence dans le cas d’implantation par les protons (dose 1016 cm-2 et le recuit à 750 °C). Puis, nous avons comparé les résultats obtenus par des irradiations aux électrons à ceux obtenus avec les protons en précisant les différents types de défauts ponctuels détectés par deux méthodes: la photoluminescence et la résonance paramagnétique électronique. Enfin, nous avons développé un processus technologique qui consiste en la fabrication de nano-piliers en SiC-4H. Nous avons montré les avantages de leur réalisation sur l’efficacité de la collection de PL des défauts ponctuels comme VSi et VSiVC. Une amélioration d’un facteur 25 pour le centre VSi et d’un facteur 50 pour le centre VSiVC a été obtenue. / Point defects in semiconductor materials are studied for the realization of quantum information bits (Qubit). Nowadays, the most developed system is based on the NV center in diamond. Recently, point defects in silicon carbide (SiC) have been identified as promising for the realization of Qubit due to the combination of their long spin coherence time and room temperature operation. In this context, this thesis studies the formation, optical and magnetic characterization of point defects in SiC, as well as the improvement of their luminescence collection. We begin with a general introduction to SiC in which we describe the different criteria that make SiC a key material for Qubit applications. Next, we present a bibliographical study on the main point defects in SiC, focusing on the centers: VSi, VSiVC, NV. We have studied the optimal conditions of ionic/electronic irradiation and post-irradiation annealing for the formation of luminescent point defects in the cubic polytype of SiC. We have identified the different types of visible range defects. In the infra-red range, we detected only the Ky5 center (VSiVC) by finding the optimal luminescence conditions of this center in the case of implantation by protons (dose 1016 cm-2 and annealing at 750 °C). Then, we compared the results obtained by electron irradiations with those obtained with protons specifying the different types of point defects detected by two methods: photoluminescence and electronic paramagnetic resonance. Finally, we have developed a technological process that consists of nano-pillars fabrication in SiC-4H. We have shown the advantages of realizing these pillars on the efficiency of the PL collection of point defects like VSi and VSiVC : an improvement of a factor of 25 for the VSi center and a factor of 50 for the VSiVC center was obtained. Electronique Semiconducteur Bits quantiques d'information - Qubits Carbure de Silisium - SiC Photoluminescence Défauts ponctuels Dafauts paramagnétiques Implantation ionique Irradiation Gravue plasma Nano-Piliers Electronics Semicondutor Quantum Information Bits - Qubits Siicon carbide - SiC Photoluminescence Electron paramagnetic resonance (EPR) Point defects Paramagnetiocs defects Implant Irradiation Nano-Pillars 537.560 72
20	Návrh nerezonančního držáku vzorku pro obecné použití v terahertzové elektronové spinové resonanční spektroskopii / Design of a Non-Resonant General Purpose Sample Holder for Terahertz Electron Paramagnetic Resonance Spectroscopy Martínek, Tomáš January 2018 (has links) Cílem diplomové práce je navrhnout konstrukční řešení držáků vzorků pro vysokofrekvenční elektron paramagnetickou resonanci. Předmětem návrhu je vytvořit jednoduchý zamykací systém pro spojování mikrovlnného vlnovodu a držáku vzorku. Dále navrhnout systém s řešením držáku pro více vzorků. Toto unikátní provedení držáku povede k několikanásobné úspoře celkového času měření vzorků. Poslední návrh spočívá v optimalizaci držáku vzorku s možností naklápění osy, kterou lze díky přímému napojení na piezoelektrický rotátor pootáčet s přesností na miliradiány. Oba typy držáku vzorku jsou navrženy s ohledem na automatizaci měření.

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