Influence de l’énergie d’interface sur les transitions de phase sous pression : étude de nanoparticules d’oxydes fonctionnels / Influence of interface energy on high-pressure phase transitions : study of functional oxides nanoparticles

Piot, Lucas

27 November 2013

La modification des diagrammes de phase sous pression dans les nanomatériaux en comparaison de matériaux massifs est généralement reliée de façon univoque à l'énergie de surface. L'objectif de ce travail a consisté à étudier l'influence de l'énergie d'interface, définie par l'état de surface (défauts cristallins et chimie de surface) et l'énergie de surface, sur le comportement à haute pression de différents nanomatériaux pour lesquels un effet de taille est fréquemment rapporté. Le contrôle et la caractérisation de l'état de surface de nanoparticules d'Y2O3 nous ont permis de montrer que l'amorphisation sous pression rapportée dans la littérature n'est pas uniquement due à la réduction de la taille de grain mais nécessite une densité de défauts initiale, généralement non contrôlée. Une forte dépendance en taille de la pression de transition dans ZnO est avancée dans la littérature. L'étude sous pression de différents échantillons nanométriques de ZnO (issus de diverses voies de synthèse) a été effectuée par spectroscopie Raman et diffraction de rayons X. La qualité cristalline de ces derniers a été estimée par Photoluminescence, XPS, Raman et IR. Tandis que les échantillons présentant une forte densité de défauts conduisent à une augmentation de la pression de transition, le comportement d'un échantillon "sans défauts" ne diffère que peu de celui de ZnO massif. Différentes approches et extensions de modèles thermodynamiques sont proposées: modèles de Gibbs, Landau et Ginzburg-Landau. Ces derniers ouvrent la voie à la définition d'un protocole expérimental permettant d'obtenir des données fiables pour étudier les transitions de phase de nanomatériaux sous pression / The modification of phase diagrams under pressure into nanosized materials in comparison with bulk ones is usually attributed to surface energy. The goal of this work has consisted into studying the influence of interface energy, which includes both the surface state (crystalline defects and surface chemistry) and surface energy, on the high-pressure behavior of several nanomaterials for which size effects has been reported. The control and characterization of the surface state for Y2O3 nanoparticles has enabled us to show that the pressure induced amorphization reported into literature is not only linked to size reduction but require an initial density of defects A strong size dependence of ZnO transition pressure is claimed into literature. The high-pressure study of different ZnO nanometric samples (obtained through several ways of synthesis) has been performed by Raman spectroscopy and X-ray diffraction. The crystalline quality of our samples has been investigated by photoluminescence, XPS, Raman and IR. Whereas samples exhibiting a high density of defects lead to an increase of pressure transition, the behaviour of “defect free” nanoparticles is rather equivalent to bulk one. Several approaches and extensions of thermodynamic models are submitted: model of Gibbs, Landau and Ginzburg-Landau. Those models open the way to the definition of an experimental protocol which allow to obtain reliable data in order to study phase transitions of nanomaterials under pressure

Nanoparticules

Haute Pression

Oxyde de Zinc

Oxyde d’Yttrium

Raman

Ginzburg- Landau

Transitions structurales

État de surface

Nanoparticles

High-Pressure

Zinc Oxide

Yttrium Oxide

Raman

Ginzburg- Landau

Structural transitions

Surface State

620.115

Compact Superconducting Dual-Log Spiral Resonator with High Q-Factor and Low Power Dependence.

Excell, Peter S., Hejazi, Z.M.

January 2002

No / A new dual-log spiral geometry is proposed for microstrip resonators, offering substantial advantages in performance and size reduction at subgigahertz frequencies when realized in superconducting materials. The spiral is logarithmic in line spacing and width such that the width of the spiral line increases smoothly with the increase of the current density, reaching its maximum where the current density is maximum (in its center for ¿/2 resonators). Preliminary results of such a logarithmic ten-turn (2 × 5 turns) spiral, realized with double-sided YBCO thin film, showed a Q.-factor seven times higher than that of a single ten-turn uniform spiral made of YBCO thin film and 64 times higher than a copper counterpart. The insertion loss of the YBCO dual log-spiral has a high degree of independence of the input power in comparison with a uniform Archimedian spiral, increasing by only 2.5% for a 30-dBm increase of the input power, compared with nearly 31% for the uniform spiral. A simple approximate method, developed for prediction of the resonant frequency of the new resonators, shows a good agreement with the test results.

Quaternary compound

Copper oxide

Barium oxide

Yttrium oxide

Experimental study

Resonance frequency

Insertion loss

Current density

Logarithmic function

Low-power electronics

Spiral shape

High temperature superconductor

Superconducting thin films

Superconducting microwave devices

Superconducting resonator

High Q factor

Photoluminescence et cristallochimie des polyphosphates de formule Na1-xAgxM(PO3)4 (M : la, Y) à l’état cristallisé ou vitreux / Photoluminescence and crystallochemistry of crystallized or vitreous polyphosphates Na1-x AgxM(PO3)4 (M : la, Y)

El Masloumi, Mohamed

15 December 2008

Ce travail s’inscrit dans le cadre d’une étude systématique des propriétés physico-chimiques de polyphosphates à l’argent permettant d’avancer sur de nouvelles voies pour les dispositifs tels que l’éclairage, les lasers accordables dans le visible, la radiophotoluminescence. L'objectif de ce travail vise la compréhension des mécanismes de luminescence de l’ion Ag+ dans les composés Na1-xAgxLn(PO3)4 (Ln = La et Y) dont la structure a été parfaitement déterminée. La luminescence des monocristaux provient des ions Ag+, dans des sites isolés et proches de lacunes positives (Ag2+) résultant de la photosensibilité aux UV pour les cristaux au lanthane. La luminescence des verres Na1-xAgxLa(PO3)4 (seuls vitrifiables) a été élucidée grâce à une étude après irradiation et à celle des verres Na2-xAgxZnP2O7. Elle est due aussi aux ions Ag+ dans des sites isolés. / This work focuses on keeping with the general pattern of investigations of physical-chemical properties of silver-polyphosphates to find new ways for devices such as lighting, visible range laser applications and radiophotoluminescence. The goal of this study aims at understanding the processes of Ag+ luminescence in Na1-xAgxLn(PO3)4 (Ln = La et Y) compounds which structure has been completely determinated. The luminescence of the single crystals is induced by Ag+ ions in isolated sites and close to hole centers (Ag2+) resulting in UV photosensitivity for the lanthanum crystals. The photoluminescence of the Na1-xAgxLa(PO3)4 glasses (glass-forming only) has been resolved owing to UV irradiation investigations and comparison with the luminescence of Na2-xAgxZnP2O7 glass. Both are also due to Ag+ ions in isolated sites.

Verres

Monocristaux

Radiation laser

Spectroscopie de photoluminescence

Propriétés physicochimiques

Photoluminescence spectroscopy

Transmission electronic microscopy

Physicochemical properties

Glasses

Single crystals

Laser radiations

Mise en oeuvre et utilisation de la méthode de l'échangeur thermique (HEM) pour l'obtention de monocristaux à applications spécifiques et de céramiques supraconductrices orientées

Oçafrain, Arlette

12 April 1995

L' étude d'une technique originale de croissance cristalline, basée sur l'utilisation d'un échangeur thermique et nommée HEM (Heat Exchanger Method), a été entreprise. Un dispositif expérimental a été développé et optimisé. La modélisation des échanges thermiques a conduit a l'élaboration d'un code de calcul numérique. Ce dernier est valide par confrontation des résultats de la simulation aux données expérimentales obtenues lors de la croissance d'un matériau école, le germanium. Le champ d'application de la technique HEM a alors été étendu à l'obtention de céramiques texturées du supraconducteur à haute température critique YBa2Cu3O7-x. Après une étude de la microstructure des textures, un mécanisme de texturation est proposé. Enfin, des cristaux du compose NaMgF3 (perovskite) sont obtenus par HEM. Leur étude en température, par observation des domaines ferroélastiques et par spectroscopie Raman, révèle l'existence d' une seule transition de phase.

Etude expérimentale

Etude théorique

Modélisation

Appareillage

Croissance cristalline en phase fondue

Solidification dirigée

Monocristal

Echangeur chaleur

Céramique oxyde

Composé quaternaire

Supraconducteur haute température

Yttrium oxyde

Baryum oxyde

Cuivre oxyde

Matériau semiconducteur

Germanium

Texture

Composé ternaire

Sodium fluorure

Magnésium fluorure

YBa2Cu3O7-x

Ba Cu O Y

Ge

NaMgF3

F Mg Na

Mikrostruktur und Wachstum bei der ionenstrahlunterstützten Deposition von Yttrium-stabilisierten Zirkonoxid-Filmen / Microstructure and growth of yttria-stabilized zirconia films fabricated by ion-beam-assisted deposition

Kautschor, Lars-Oliver

22 November 2002

No description available.

530 Physik

Mathematics and Computer Science

dünne Filme

Yttrium-stabilisiertes Zirkonoxid

YSZ

ionenstrahlunterstützte Deposition

IBAD

YBCO

TEM

HREM

Mikrostruktur

biaxial texturiert

in-plane

out-of-plane

Textur

thin films

yttria-stabilized zirconia

YSZ

ion-beam-assisted deposition

IBAD

YBCO

TEM

HREM

microstructure

biaxially textured

in-plane

out-of-plane

texture

33.61

33.68

RVS 700: Mikrostruktur Gefüge- {Physik}

Estudo compartimental e dosimétrico do anti-CD20 marcado com 188Re / Compartmental and dosimetric studies of anti-CD20 labelled with 188Re

KURAMOTO, GRACIELA B.

25 August 2016

Submitted by Marco Antonio Oliveira da Silva (maosilva@ipen.br) on 2016-08-25T11:05:49Z No. of bitstreams: 0 / Made available in DSpace on 2016-08-25T11:05:49Z (GMT). No. of bitstreams: 0 / A radioimunoterapia (RIT) faz uso de anticorpos monoclonais conjugados com radionuclídeos emissores α ou β-, ambos para terapia. O tratamento baseia-se na irradiação e destruição do tumor, preservando os órgãos normais quanto ao excesso de radiação. Radionuclídeos emissores β- como 90Y, 131I, 177Lu e 188Re, são úteis para o desenvolvimento de radiofármacos terapêuticos e, quando associados a AcM como o Anti-CD20 são importantes principalmente para o tratamento de Linfomas Não Hodgkins (LNH). 188Re (Eβ- = 2,12 MeV; Eγ= 155 keV; t1/2 = 16,9 h) é um radionuclídeo atrativo para RIT. O Centro de Radiofarmácia do IPEN possui um projeto que visa a produção do radiofármaco 188Re-Anti-CD20. Com isso,este estudo foi proposto para avaliar a eficácia desta técnica de marcação para tratamento em termos compartimentais e dosimétricos. O objetivo deste trabalho consistiu na compararação da marcação do AcM anti-CD20 com 188Re com a marcação do anticorpo com 90Y, 131I, 177Lu e 99mTc (pelas suas características químicas similares) e 211At, 213Bi, 223Ra e 225Ac. Através do estudo de técnicas de marcação relatadas em literatura, foi proposto um modelo compartimental para avaliação de sua farmacocinética e estudos dosimétricos, de alto interesse para a terapia. A revisão de dados publicados na literatura, possibilitou demonstrar diferentes procedimentos de marcação, rendimentos de marcação, tempo de reação, impurezas e estudos de biodistribuição. O resultado do estudo mostra uma cinética favorável para o 188Re, pelas suas características físicas e químicas frente aos demais radionuclídeos avaliados. O estudo compartimental proposto descreve o metabolismo do 188Re-anti-CD20 através de um modelo compartimental mamilar, que pela sua análise farmacocinética, realizada em comparação aos produtos marcados com emissores β-: 131I-antiCD20, 177Lu-anti-CD20, o emissor γ 99mTc-anti-CD20 e o emissor α 211At-Anti-CD20, apresentou uma constante de eliminação de aproximadamente 0,05 horas-1 no sangue do animal. A avaliação dosimétrica do 188Re-Anti-CD20 foi realizada através de duas metodologias: pelo método de Monte Carlo e pelo uso de uma fonte pontual β- através da Fórmula de Loevinger via programa Excel. Através da Fórmula de Loevinger fez-se a validação do método de Monte Carlo para a dosimetria do 188Re-Anti-CD20 e dos demais produtos. As doses e as taxas de doses obtidas pelos dois métodos foram avaliadas em comparação à dosimetria do 90Y-Anti-CD20, 131I-Anti-CD20 e do 177Lu-Anti-CD20, obtidas pela mesma metodologia. O estudo de dose foi realizado utilizando modelos matemáticos considerando um camundongo nude de 25g, simulando diferentes tamanhos de tumor e diferentes formas de distribuição do produto dentro do animal. De acordo com os resultados obtidos, pela energia de emissão β-, 188Re-Anti-CD20 apresenta maior deposição de energia para tumores volumosos em relação aos demais produtos avaliados. Em uma simulação com 100% do produto captado pelo tumor, 89% da dose total manteve-se absorvida pelo tumor, preservando a integridade de ógãos críticos como coração (2%), pulmões (5%), coluna (4%), fígado (0,014%) e rins (0,0007%). Em uma simulação onde há uma biodistribuição do produto no organismo do animal, 38% da dose total é absorvida pelo tumor e >3% é absorvida pela coluna. Nessa situação mais próxima da realidade, a extrapolação dos dados para um humano de 70kg, mostrou que a dose absorvida no tumor corresponde a cerca de 33%; na coluna 7% e o coração receberia uma dose de 35% do total. A análise compartimental e dosimétrica apresentada neste trabalho, realizada através do uso de um modelo animal para o 188Re-Anti-CD20 mostra que o produto desenvolvido e apresentado em literatura é candidato promissor para a RIT. / Tese (Doutorado em Tecnologia Nuclear) / IPEN/T / Instituto de Pesquisas Energeticas e Nucleares - IPEN-CNEN/SP

antigens

antigen-antibody reactions

rhenium 188

yttrium 90

iodine 131

lutetium 177

technetium 99

astatine 211

bismuth 213

radium 223

actinium 225

physical chemistry

labelled compounds

radiation dose distributions

dose limits

dosimetry

monte carlo method

calculation methods

tumor cells

neoplasms

radioterapy

immunotherapy

radioimmunotherapy

radionuclide kinetics

Atomistic and finite element modeling of zirconia for thermal barrier coating applications

Zhang, Yi

January 2014

Indiana University-Purdue University Indianapolis (IUPUI) / Zirconia (ZrO2) is an important ceramic material with a broad range of applications. Due to its high melting temperature, low thermal conductivity, and high-temperature stability, zirconia based ceramics have been widely used for thermal barrier coatings (TBCs). When TBC is exposed to thermal cycling during real applications, the TBC may fail due to several mechanisms: (1) phase transformation into yttrium-rich and yttrium-depleted regions, When the yttrium-rich region produces pure zirconia domains that transform between monoclinic and tetragonal phases upon thermal cycling; and (2) cracking of the coating due to stress induced by erosion. The mechanism of erosion involves gross plastic damage within the TBC, often leading to ceramic loss and/or cracks down to the bond coat. The damage mechanisms are related to service parameters, including TBC material properties, temperature, velocity, particle size, and impact angle. The goal of this thesis is to understand the structural and mechanical properties of the thermal barrier coating material, thus increasing the service lifetime of gas turbine engines. To this end, it is critical to study the fundamental properties and potential failure mechanisms of zirconia. This thesis is focused on investigating the structural and mechanical properties of zirconia. There are mainly two parts studied in this paper, (1) ab initio calculations of thermodynamic properties of both monoclinic and tetragonal phase zirconia, and monoclinic-to-tetragonal phase transformation, and (2) image-based finite element simulation of the indentation process of yttria-stabilized zirconia. In the first part of this study, the structural properties, including lattice parameter, band structure, density of state, as well as elastic constants for both monoclinic and tetragonal zirconia have been computed. The pressure-dependent phase transition between tetragonal (t-ZrO2) and cubic zirconia (c-ZrO2) has been calculated using the density function theory (DFT) method. Phase transformation is defined by the band structure and tetragonal distortion changes. The results predict a transition from a monoclinic structure to a fluorite-type cubic structure at the pressure of 37 GPa. Thermodynamic property calculations of monoclinic zirconia (m-ZrO2) were also carried out. Temperature-dependent heat capacity, entropy, free energy, Debye temperature of monoclinic zirconia, from 0 to 1000 K, were computed, and they compared well with those reported in the literature. Moreover, the atomistic simulations correctly predicted the phase transitions of m-ZrO2 under compressive pressures ranging from 0 to 70 GPa. The phase transition pressures of monoclinic to orthorhombic I (3 GPa), orthorhombic I to orthorhombic II (8 GPa), orthorhombic II to tetragonal (37 GPa), and stable tetragonal phases (37-60 GPa) are in excellent agreement with experimental data. In the second part of this study, the mechanical response of yttria-stabilized zirconia under Rockwell superficial indentation was studied. The microstructure image based finite element method was used to validate the model using a composite cermet material. Then, the finite element model of Rockwell indentation of yttria-stabilized zirconia was developed, and the result was compared with experimental hardness data.

zirconia

indentation

finite element

thermal barrier coating

first principles

Rockwell hardness -- Testing

Coatings -- Thermal properties

Ceramic coating

Heat resistant materials

Metals -- Testing

Hardness -- Testing

Ceramics -- Fracture

Gas-turbines

Yttrium

Strength of materials

Heat -- Transmission

Finite element method -- Research

The Influence of Alloying Additions on Diffusion and Strengthening of Magnesium

Kammerer, Catherine

01 January 2015

Magnesium alloys are being developed as advanced materials for structural applications where reduced weight is a primary motivator. Alloying can enhance the properties of magnesium without significantly affecting its density. Essential to alloy development, inclusive of processing parameters, is knowledge of thermodynamic, kinetic, and mechanical behavior of the alloy and its constituents. Appreciable progress has been made through conventional development processes, but to accelerate development of suitable wrought Mg alloys, an integrated Materials Genomic approach must be taken where thermodynamics and diffusion kinetic parameters form the basis of alloy design, process development, and properties-driven applications. The objective of this research effort is twofold: first, to codify the relationship between diffusion behavior, crystal structure, and mechanical properties; second, to provide fundamental data for the purpose of wrought Mg alloy development. Together, the principal deliverable of this work is an advanced understanding of Mg systems. To that end, the objective is accomplished through an aggregate of studies. The solid-to-solid diffusion bonding technique is used to fabricate combinatorial samples of Mg-Al-Zn ternary and Mg-Al, Mg-Zn, Mg-Y, Mg-Gd, and Mg-Nd binary systems. The combinatorial samples are subjected to structural and compositional characterization via Scanning Electron Microscopy with X-ray Energy Dispersive Spectroscopy, Electron Probe Microanalysis, and analytical Transmission Electron Microscopy. Interdiffusion in binary Mg systems is determined by Sauer-Freise and Boltzmann-Matano methods. Kirkaldy*s extension of the Boltzmann-Matano method, on the basis of Onsager*s formalism, is employed to quantify the main- and cross-interdiffusion coefficients in ternary Mg solid solutions. Impurity diffusion coefficients are determined by way of the Hall method. The intermetallic compounds and solid solutions formed during diffusion bonding of the combinatorial samples are subjected to nanoindentation tests, and the nominal and compositionally dependent mechanical properties are extracted by the Oliver-Pharr method. In addition to bolstering the scantly available experimental data and first-principles computations, this work delivers several original contributions to the state of Mg alloy knowledge. The influence of Zn concentration on Al impurity diffusion in binary Mg(Zn) solid solution is quantified to impact both the pre-exponential factor and activation energy. The main- and cross-interdiffusion coefficients in the ternary Mg solid solution of Mg-Al-Zn are reported wherein the interdiffusion of Zn is shown to strongly influence the interdiffusion of Mg and Al. A critical examination of rare earth element additions to Mg is reported, and a new phase in thermodynamic equilibrium with Mg-solid solution is identified in the Mg-Gd binary system. It is also demonstrated that Mg atoms move faster than Y atoms. For the first time the mechanical properties of intermetallic compounds in several binary Mg systems are quantified in terms of hardness and elastic modulus, and the influence of solute concentration on solid solution strengthening in binary Mg alloys is reported. The most significant and efficient solid solution strengthening is achieved by alloying Mg with Gd. The Mg-Nd and Mg-Gd intermetallic compounds exhibited better room temperature creep resistance than intermetallic compounds of Mg-Al. The correlation between the concentration dependence of mechanical properties and atomic diffusion is deliberated in terms of electronic nature of the atomic structure.

Engineering

A Radio Frequency Quadrupole Instrument for use with Accelerator Mass Spectrometry: Application to Low Kinetic Energy Reactive Isobar Suppression and Gas–phase Anion Reaction Studies

Eliades, John Alexander

21 August 2012

A radio frequency (rf) quadrupole instrument, currently known as an Isobar Separator for Anions (ISA), has been integrated into an Accelerator Mass Spectrometry (AMS) system to facilitate anion–gas reactions before the tandem accelerator. An AMS Cs+ sputter source provided > 15 keV ions that were decelerated in the prototype ISA to < 20 eV for reaction in a single collision cell and re-accelerated for AMS analysis. Reaction based isobar suppression capabilities were assessed for smaller AMS systems and a new technique for gas–phase reaction studies was developed. Isobar suppression of 36S– and 12C3– for 36Cl analysis, and YF3– and ZrF3– for 90Sr analysis were studied in NO2 with deceleration to < 12 eV. Observed attenuation cross sections, σ [x 10^–15 cm^2], were σ(S– + NO2) = 6.6, σ(C3– + NO2) = 4.2, σ(YF3– + NO2) = 7.6, σ(ZrF3– + NO2) = 19. With 8 mTorr NO2, relative attenuations of S–/Cl– ~ 10^–6, C3–/Cl– ~ 10^–7, YF3–/SrF3– ~ 5 x 10^–5 and ZrF3–/SrF3– ~ 4 x 10^–6 were observed with Cl– ~ 30% and SrF3– > 90% transmission. Current isobar attenuation limits with < 1.75 MV accelerator terminal voltage and ppm impurity levels were calculated to be 36S–/Cl– ~ 4 x 10^–16, 12C3–/Cl– ~ 1.2 x 10^–16, 90YF3–/SrF3– ~ 10^–15 and 90ZrF3–/SrF3– ~ 10^–16. Using 1.75 MV, four 36Cl reference standards in the range 4 x 10^–13 < 36Cl/Cl < 4 x 10^–11 were analyzed with 8 mTorr NO2. The measured 36Cl/Cl ratios plotted very well against the accepted values. A sample impurity content S/Cl < 6 x 10^–5 was measured and a background level of 36S–/Cl < 9 x 10^–15 was determined. Useful currents of a wide variety of anions are produced in AMS sputter sources and molecules can be identified relatively unambiguously by stripping fragments from tandem accelerators. Reactions involving YF3–, ZrF3–, S– and SO– + NO2 in the ISA analyzed by AMS are described, and some interesting reactants are identified.

radio frequency quadrupole

rf quadrupole

accelerator mass spectrometry

AMS

gas-phase reactions

isobar suppression

anion

negative ion

chlorine

Cl

36Cl

carbon trimer

C3

sulphur

sulfur

sulphur oxide

sulfur oxide

SO

methane

CH4

nitrogen dioxide

NO2

nitrous oxide

N2O

oxygen

O2

argon

Ar

strontium

Sr

90Sr

SrF3

yttrium

Y

zirconium

Zr

ZrF3

trace isotope analysis

superhalogen anion

secondary ion mass spectrometry

SIMS

Cs sputter ion source

rf quadrupole ion trajectory simulation

anion gas reactions

negative ion gas reactions

gas-phase anion reactions

S- + NO2

SO- + NO2

S- + N2O

S- + O2

S- + Ar

Cl- + NO2

Cl- + Ar

Cl- + CH4

SrF3- + NO2

YF3- + NO2

ZrF3- + NO2

C3- + NO2

0768

0494

0605

A Radio Frequency Quadrupole Instrument for use with Accelerator Mass Spectrometry: Application to Low Kinetic Energy Reactive Isobar Suppression and Gas–phase Anion Reaction Studies

Eliades, John Alexander

21 August 2012

A radio frequency (rf) quadrupole instrument, currently known as an Isobar Separator for Anions (ISA), has been integrated into an Accelerator Mass Spectrometry (AMS) system to facilitate anion–gas reactions before the tandem accelerator. An AMS Cs+ sputter source provided > 15 keV ions that were decelerated in the prototype ISA to < 20 eV for reaction in a single collision cell and re-accelerated for AMS analysis. Reaction based isobar suppression capabilities were assessed for smaller AMS systems and a new technique for gas–phase reaction studies was developed. Isobar suppression of 36S– and 12C3– for 36Cl analysis, and YF3– and ZrF3– for 90Sr analysis were studied in NO2 with deceleration to < 12 eV. Observed attenuation cross sections, σ [x 10^–15 cm^2], were σ(S– + NO2) = 6.6, σ(C3– + NO2) = 4.2, σ(YF3– + NO2) = 7.6, σ(ZrF3– + NO2) = 19. With 8 mTorr NO2, relative attenuations of S–/Cl– ~ 10^–6, C3–/Cl– ~ 10^–7, YF3–/SrF3– ~ 5 x 10^–5 and ZrF3–/SrF3– ~ 4 x 10^–6 were observed with Cl– ~ 30% and SrF3– > 90% transmission. Current isobar attenuation limits with < 1.75 MV accelerator terminal voltage and ppm impurity levels were calculated to be 36S–/Cl– ~ 4 x 10^–16, 12C3–/Cl– ~ 1.2 x 10^–16, 90YF3–/SrF3– ~ 10^–15 and 90ZrF3–/SrF3– ~ 10^–16. Using 1.75 MV, four 36Cl reference standards in the range 4 x 10^–13 < 36Cl/Cl < 4 x 10^–11 were analyzed with 8 mTorr NO2. The measured 36Cl/Cl ratios plotted very well against the accepted values. A sample impurity content S/Cl < 6 x 10^–5 was measured and a background level of 36S–/Cl < 9 x 10^–15 was determined. Useful currents of a wide variety of anions are produced in AMS sputter sources and molecules can be identified relatively unambiguously by stripping fragments from tandem accelerators. Reactions involving YF3–, ZrF3–, S– and SO– + NO2 in the ISA analyzed by AMS are described, and some interesting reactants are identified.

radio frequency quadrupole

rf quadrupole

accelerator mass spectrometry

AMS

gas-phase reactions

isobar suppression

anion

negative ion

chlorine

Cl

36Cl

carbon trimer

C3

sulphur

sulfur

sulphur oxide

sulfur oxide

SO

methane

CH4

nitrogen dioxide

NO2

nitrous oxide

N2O

oxygen

O2

argon

Ar

strontium

Sr

90Sr

SrF3

yttrium

Y

zirconium

Zr

ZrF3

trace isotope analysis

superhalogen anion

secondary ion mass spectrometry

SIMS

Cs sputter ion source

rf quadrupole ion trajectory simulation

anion gas reactions

negative ion gas reactions

gas-phase anion reactions

S- + NO2

SO- + NO2

S- + N2O

S- + O2

S- + Ar

Cl- + NO2

Cl- + Ar

Cl- + CH4

SrF3- + NO2

YF3- + NO2

ZrF3- + NO2

C3- + NO2

0768

0494

0605