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STABILITY AND SPECTROSCOPIC PROPERTIES OF NEGATIVE IONSBehera, Swayamprabha 06 May 2011 (has links)
Negative ions play an important role in chemistry as building blocks of salts and oxidizing agents. Halogen atoms, due to their ability to attract electrons, readily form negative ions. Considerable interest exists in the design and synthesis of new negative ions called superhaogens whose electron affinities are much higher than those of halogen atoms. This thesis deals with the design of such species. Using density functional theory I have studied two classes of superhalogens. First one involves d1 transition metal (Sc, Y, La) atoms surrounded by Cl while the second one involves simple metals (Na, Mg, Al) surrounded by pseudohalogens such as CN. Geometry, electronic structure, and electron affinity of these species containing up to 5 ligands have been calculated. Studies reveal a fundamental difference between the interaction of transition and metal atoms with electronegative ligands. In addition, pseudohalogens can be used to synthesize a new class of superhalogens.
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CLUSTERS BRIDGING DISCIPLINESBehera, Swayamprabha 01 January 2014 (has links)
Clusters constitute an intermediate state of matter between molecules and solids whose properties are size dependent and can be tailored. In recent years, cluster science has become one of the most exciting areas of research since their study can not only bridge our understanding between atoms and their bulk but also between various disciplines. In addition, clusters can serve as a source of new materials with uncommon properties. This dissertation deals with an in-depth study of clusters as a bridge across physics, chemistry, and materials science and provides a fundamental understanding of the structure-property relationships by focusing on three different topics. The first topic deals with superatoms which are clusters that mimic the chemistry of atoms. I show that superhalogens and superalkalis can be designed to mimic the chemistry of halogen and alkali atoms, respectively. An entirely new class of salts can then be synthesized by using these superatoms as the building blocks. I have also explored the possibility of designing highly electronegative species called hyperhalogens by using superhalogens as ligands or superalkalis as core and a combination of both. Another aspect of my work on superatom is to examine if traditional catalysts (namely Pd) can be replaced by clusters composed of earthabundant elements (namely Zr and O). This is accomplished by comparing the electronic structure and reactivity of Pd clusters with isoelectronic ZrO clusters. The second topic deals with a study of the electronic structure of coinage metal (Cu and Ag) clusters and see if they remain unchanged when a metal atom is replaced by an isoelectronic hydrogen atom as is the case with Au-H clusters. The third topic deals with clusters as model of polymeric materials to understand their gas storage and sequestration properties. This is accomplished by studying the trapping of H2, CO2, CH4 and SO2 molecules in borazine-linked polymers (BLPs) and benzimidazole-linked polymers (BILPs). The first two topics provide a bridge between physics and chemistry, while the third topic provides a bridge to materials science.
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Sequence effects on the proton-transfer reaction of the guanine-cytosine base pair radical anion and cationYEH, SHU-WEN 16 July 2012 (has links)
The formation of base pair radical anions and cations is closely related to many fascinating research fields in biology and chemistry such as genetic mutation, radiation-induced DNA damage and dynamics of charge transfer in DNA. However, the relevant knowledge so far mainly comes from studies on isolated base pair radical anions and cations, and their behavior in the DNA environment is less understood. In this study, we focus on how the nucleobase sequence affects the properties of the guanine¡Vcytosine (G:C) base pair radical anion and cation. The energetic barrier and reaction energy for the proton transfer along the N1(G)¡VH¡E¡E¡EN3(C) hydrogen bond and the stability of (G:C)¡E (i.e., electron affinity and ionization potential of G:C) embedded in different sequences of base-pair trimer were evaluated using density functional theory and two-layer ONIOM method. The computational results demonstrated that the presence of neighboring base pairs has an important influence on the behavior of (G:C)¡E in the gas phase. The excess electron and positive hole were found to be localized on the embedded G:C and the charge leakage to neighboring base pairs was very minor in all of the investigated sequences. Accordingly, the sequence behavior of the proton transfer reaction and the stability of (G:C)¡E is chiefly governed by electrostatic interactions with adjacent base pairs. However, the effect of base stacking, due to its electrostatic nature, is severely screened upon hydration, and thus, the sequence dependence of the properties of (G:C)¡E in aqueous environment becomes relatively weak and less than that observed in the gas phase. The effect of geometry relaxation associated with neighboring base pairs as well as the possibility of proton transfer along the N2(G)¡VH¡E¡E¡EO2(C) channel have also been investigated. The implications of the present findings to the electron transport and radiation damage of DNA are discussed.
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Theoretical & Experimental Investigation of Low and Negative Electron Affinity Cold Cathodes Based on Rare-Earth MonosulfidesModukuru, Yamini 02 September 2003 (has links)
No description available.
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Explicitly correlated Green's function methods for calculating electron binding energiesTeke, Nakul Kushabhau 29 July 2019 (has links)
Single-particle Green's function method is a direct way of calculating electron binding energy, which relies on expanding the Fock subspace in a finite single-particle basis. However, these methods suffer from slow asymptotic decay of basis set incompleteness error. An energy-dependent explicitly correlated (F12) formalism for Green's function is presented that achieves faster convergence to the basis set limit. The renormalized second-order Green's function method (NR2-F12) scales as iterative N^5 where N is the system size. These methods are tested on a set of small (O21) and medium-sized (OAM24) organic molecules. The basis set incompleteness error in ionization potential (IP) obtained from the NR2-F12 method and aug-cc-pVDZ basis for OAM24 is 0.033 eV compared to 0.067 eV for NR2 method and aug-cc-pVQZ basis. Hence, accurate electron binding energies can be calculated at a lower cost using NR2-F12 method. For aug-cc-pVDZ basis, the electron binding energies obtained from NR2-F12 are comparable to EOM-IP-CCSD method that uses a CCSD reference and scales as iterative N^6. / Master of Science / Solving the non-relativistic time-independent Schrödinger equation is a central problem in quantum chemistry with the primary goal of finding the exact electronic wave function. Like all many-body problems, the applications of highly accurate electronic structure methods are limited to small molecules since they are computationally expensive. With scalable algorithms and parallel implementation of computer programs, the chemistry of large molecular systems can be investigated. Electron binding energies give an insight into the orbital picture of a molecule, which is manifested in chemical structure and properties of a molecule.
Green’s function provides an alternative to wave function based methods to calculate ionization potential and electron affinity directly rather than solving for the wave function itself. For accurate electron binding energies, the wave function needs to be represented by large number of basis functions, which make these methods computationally expensive.
Explicitly correlated electronic structure methods are designed to produce accurate results at a smaller basis set. This work investigates the use of explicitly correlated Green’s function methods to calculate electron binding energies of small and medium sized organic molecules. These results are compared to coupled cluster methods, which are known to provide accurate benchmarks in quantum chemistry.
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UNCONVENTIONAL SUPERHALOGENS: DESIGN AND APPLICATIONSSamanta, Devleena 11 May 2012 (has links)
Electron affinity is one of the most important parameters that guide chemical reactivity. Halogens have the highest electron affinities among all elements. A class of molecules called superhalogens has electron affinities even greater than that of Cl, the element with the largest electron affinity (3.62 eV). Traditionally, these are metal-halogen complexes which need one electron to close their electronic shell. Superhalogens have been known to chemistry for the past 30 years and all superhalogens investigated in this period are either based on the 8-electron rule or the 18-electron rule. In this work, we have studied two classes of unconventional superhalogens: borane-based superhalogens designed using the Wade-Mingo’s rule that describes the stability of closo-boranes, and pseudohalogen based superhalogens. In addition, we have shown that superhalogens can be utilized to build hyperhalogens, which have electron affinities exceeding that of the constituent superhalogens, and also to stabilize unusually high oxidation states of metals.
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AROMATICITY RULES IN THE DEVELOPMENT OF NEGATIVE IONSChild, Brandon 28 April 2014 (has links)
Organic molecules are known for their stability due to aromaticity. Superhalogens, on the other hand, are highly reactive anions, whose electron affinity is larger than that of chlorine. This thesis, using first principles calculations, explores possible methods for creation of superhalogen aromatic molecules while attempting to also develop a fundamental understanding of the physical properties behind their creation. The first method studied uses anionic cyclopentadienyl and enhances its electron affinity through ligand substitution or ring annulation in combination with core substitutions. The second method studies the possibilities of using benzene, which has a negative electron affinity (EA), as a core to attain similar results. These cases resulted in EAs of 5.59 eV and 5.87 eV respectively, showing that aromaticity rule can be used to create strong anionic organic molecules. These studies will hopefully lead to new advances in the development of organic based technology.
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Amplification de la réaction de photodétachement / Amplification of the photodetachment reactionBresteau, David 30 September 2016 (has links)
Le cœur du travail de notre groupe est l'étude de la réaction de photodétachement, qui consiste en l'expulsion de l'électron excédentaire d'un ion négatif lors de l'absorption d'un photon. Ce travail de thèse s'articule autour de deux projets : la microscopie de photodétachement, technique d'interférométrie électronique permettant de produire des données spectroscopiques sur les ions négatifs ; et le projet SIPHORE qui envisage la neutralisation d'un jet rapide d'ions négatifs à partir de la réaction de photodétachement, dans le but de servir la maîtrise de la fusion thermonucléaire contrôlée. Les évolutions de ces deux projets se recoupent dans la nécessité d'augmenter le nombre d'événements de photodétachement produits en un temps donné. Ce travail a permis d'étudier et de mettre en place différentes techniques expérimentales pour réaliser l'amplification de la réaction de photodétachement. Notre montage nous permet de produire cette réaction dans une zone d'interaction formée par l'intersection d'un jet d'ions et d'un faisceau laser. Nous envisageons d'une part la modification de la section efficace de photodétachement lorsque la réaction est produite en présence d'un champ magnétique, d'autre part l'amplification du flux de photons dans la zone d'interaction par stockage de lumière en cavité optique. Les avancées réalisées ouvrent de nouvelles perspectives sur les études fondamentales et les applications techniques liées aux ions négatifs. / The core of the work of our group is the photodetachment reaction, which consists in the expulsion of the extra electron of a negative ion by the absorption of a photon. This thesis work is organised around two projects: the photodetachment microscopy, an electron interferometric technique which produces spectroscopic data on negative ions; and the SIPHORE project which considers the neutralization of a fast negative ions beam by the help of the photodetachment process, for the purpose of controlled thermonuclear fusion. The evolutions of these two projects are overlapping in the need of increasing the number of photodetachment events produced per unit of time. This work has led to the study and the implementation of several experimental techniques to realise the amplification of the photodetachment reaction. Our setup permits to produce this reaction in an interaction area formed by the intersection of a negative ions beam with a laser beam. On the one hand we investigate the modification of the photodetachment cross section when the reaction is produced under a magnetic field. On the other hand we consider the amplification of the photon flux inside the interaction region using light storage with optical cavities. The results obtained pave the way towards new prospects for the fundamental studies and the technical applications affiliated with negative ions.
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SYNTHESIS AND CHARACTERIZATION OF NEODYMIUM SULFIDE BULK SAMPLES AND THIN FILMSTHACHERY, JUGUL RAVINDRAN 11 March 2002 (has links)
No description available.
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ANALYSIS OF HIGH-FREQUENCY CHARACTERISTICS OF PLANAR COLD CATHODESKRISHNAN, RAJESH 02 September 2003 (has links)
No description available.
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