Structural and depositional evolution, KH field, West Natuna Basin, offshore Indonesia

Meirita, Maria Fransisca

30 September 2004

This study describes the structural and depositional evolution in the KH field in West Natuna Basin, Indonesia. Data for the study were acquired by three-dimensional (3D) seismic reflection volume and a complete suite of well logs. The regional basin underwent transtensional, sinistral shear during the rift phase that reactivated during the early to middle Miocene inversion as a traspressional, dextral shear. The study identified four periods of tectonic activity in the area which are extension, quiescence, compression and another period of quiescence. A structural closure developed along a series of north-south trending, normal splay faults defines the area's trap play. Understanding how this structural play fits into the regional tectonic picture may suggest new approaches to hydrocarbon exploration in the area.

west natuna

structural evolution

depositional evolution

Geology of the Deseret Peak East 7.5' Quadrangle, Tooele County, Utah, and Impacts for Hydrology of the Region

Copfer, Torrey J.

01 May 2003

Detailed geologic mapping of the Deseret Peak East 7.5' Quadrangle yields new interpretations regarding the stratigraphy of the Oquirrh Basin, fault and fold geometry, and structural evolution of the region. The Stansbury Range consists of the north-southtrending Deseret anticline. Basal Mississippian units rest unconformably on Cambrian beds in the central part of the range. Paleozoic uplift, Mesozoic contraction, and Cenozoic extension have created a series of broad folds, large thrust faults, and several normal faults. The area is dominated by bedrock springs, with the presence of abundant and thick Quaternary deposits unrelated to Pleistocene glaciation, burying drainages, and mantling hillslopes. The influence of bedrock on groundwater flow paths and stream baseflow is suggested by local anecdotal reports that high snowfall in the Deseret Peak region generates high discharge ten miles south in Clover Creek, though they are not in the same drainage basin.

geology

hydrology

geologic mapping

stratigraphy

structural evolution

Geology

The Quaternary Tectonic and Structural Evolution of the San Felipe Hills, California

Kirby, Stefan M.

01 May 2005

We examine the transition between extension and strike-s lip in the San Felipe Hills, western Salton Trough, southern California using new and compiled geologic mapping, measured stratigraphic sections, magnetostratigraphy, and structural analysis. A 625 m measured section describes the Borrego, Ocotillo , and Brawley formations in the SE San Felipe Hills and constrains a regional disconformity and correlative angular unconformity at ~ 1 Ma. Sedimentation rates for the Brawley Formation above the disconformity range from 1.0 to 1.2 mm/yr, palcoflow was to the ENE. The Brawley Formation consists of three interbeddcd lithofac ics; (I) fluvial and fluvio-d eltaic, (2) lacustrinc, (3) and eolian depo sits. Changes in facies, provenance , and paleoflow , with deposition of Ocotillo and Brawley formations record onset and evolution of cross cutting strike- slip faults other than the San Jacinto fault zone in the western Salton Trough at ~ 1 Ma. Since deposition of the Brawley Formation (~ 0.5 Ma), rocks of the San Felipe hills have been uplifted and complexly deformed. new data suggest that strands of the Clark fault persist SE of its previously mapped termination, transferring slip into folded rocks in the central and southern San Felipe Hills. Equivalent right lateral slip form folding for the Clark fault in the San Felipe Hills is 5.6 km. Minimum slip rates for the Clark strand are between 9 and 11 mm/year. Since ~ 0.5 Ma, evolving strands of the San Jacinto fault zone, including the Coyote Creek and Clark faults, have deformed rocks of the San Felipe Hills.

quaternary

tectonic

structural evolution

San Felipe Hills

California

Geology

CONTROLLING THE SURFACE ACTIVE SITE GEOMETRY FOR ELECTROCHEMICAL CATALYTIC REACTIONS

Wei Hong (13040772)

14 July 2022

<p>Proton exchange membrane fuel cells (PEMFCs) are considered as one of the most promising alternative clean and sustainable energy sources to fossil fuels. In general, PEMFC is consisted of anodic and cathodic electrode assembly, electrolyte, and proton-exchange membrane. While renewable fuels, such as hydrogen gas and formic acid, get oxidized at the anode to produce protons, oxygen molecules are reduced to form water at the cathode. Platinum has been widely used for both anodic and cathodic reactions due to its excellent catalytic reactivity.</p> <p><br></p> <p>Significant effort has been devoted to improving the reactivity and selectivity of Pt-based catalysts by alloying with a second metal. AuPt alloy nanoparticles have been studied extensively for electrochemical formic acid oxidation reaction, and isolated Pt species are recognized as the most active sites. While the majority body of literature focuses on structure-reactivity relationships</p> <p>based on as-synthesized materials, less attention is paid to the structural evolution during electrochemical catalysis. In this work, we develop a colloidal synthetic method to deposit Pt shell onto Au nanoparticles with variable thickness to study the microstructural evolution under electrocatalytic formic oxidation. We find that Pt atoms are submerged from the surface to form isolated Pt species in the first 100 cycles, which show enhanced FAO activity by shifting the reaction pathway. Additional CV scanning causes further depletion of Pt from the surface, resulting in the deactivation of the catalyst.</p> <p><br></p> <p>Despite the high activity of Pt-based catalysts, the use of these materials is limited by its high cost. Recently, transition metal sulfides such as cobalt sulfides have been found to show comparable activity to Pt-based catalysts in pH 7 ORR. However, it is challenging to isolate the role of coordination environment amidst multiple geometries and oxidation states that exist within any given phase. In this effort, we synthesize isolated Co atoms supported on colloidal WS₂nanosheets. By doing post synthetic treatment on these nanosheets, we are able to achieve a range of Co-S coordination number. Correlating Co-S CN to their ORR activities, we find the optimal active sites for ORR in neutral media possess a Co-S coordination number of 3-4.</p>

Electrochemistry

Nanomaterials

Nanomaterials

Structural evolution

Electrochemistry

Contribuição ao estudo por SAXS da estrutura e cinética de formação de híbridos orgânico/sílica / Contribution to the study by SAXS of the structure and kinetic formation of organic/silica hybrids

Awano, Carlos Miranda

12 April 2017

Neste trabalho, estudam-se por espalhamento de raios-X a baixo ângulo (SAXS) a estrutura e a cinética de formação de materiais híbridos orgânico/inorgânico, preparados por processo sol-gel a partir da hidrólise de misturas de organometálicos de silício funcionalizados. Num primeiro sistema, a evolução estrutural de uma mistura hidrolisada 2:1 molar de Tetraetoxisilano (TEOS) e 3-Glicidoxipropiltrimetoxisilano (GPTS) foi estuda em função do tempo in situ por SAXS, nas temperaturas de 25&deg;C, 43&deg;C e 60&deg;C. Os resultados são compatíveis com o crescimento de domínios ricos em sílica (clusters) formados a partir de um número fixo de partículas primárias. O raio de giração, Rg , dos clusters e a intensidade de SAXS extrapolada a zero, I(0), crescem com o tempo t seguindo leis de potência da forma Rg &prop; (t-t0)&alpha; e I(0) = B(t-t0)&beta;, sendo &alpha; e &beta; e independentes da temperatura e B uma medida da constante de velocidade k = &beta;B1/ &beta; do processo, uma função de Arrhenius da temperatura. A energia de ativação &Delta;E = 67,7 &plusmn; 1,1 kJ/mol foi estimada para o processo. A intensidade I(0) também escala experimentalmente com Rg na forma I(0) &prop; RgD com D = 1,71 &plusmn; 0,01, em boa concordância com o valor &beta;/&alpha; = 1,79 &plusmn; 0,07 obtido do estudo cinético. O crescimento de macromoléculas com dimensionalidade de 1,7 é típico de macromoléculas diluídas ou semidiluídas em condições de bom solvente. Os resultados de SAXS ainda sugerem que o sistema exibe propriedades dinâmicas de escala limitadas pelo tamanho das partículas primárias. Num segundo sistema, a evolução estrutural de uma mistura hidrolisada 1:1 molar de 3-Aminopropiltrietoxisilano (APTS) e 3-Glicidoxipropiltrimetoxisilano (GPTS) foi estuda em função do tempo in situ por SAXS, em temperatura ambiente. Os resultados são compatíveis com a formação de partículas primárias e crescimento de clusters com características de fractal de massa (1 < D< 3). No estágio inicial, a população de partículas primárias não fractais (D = 3) aumenta em função do tempo. O crescimento de clusters com características fractais de massa (D < 3) a partir da agregação das partículas primárias aumenta gradativamente o raio médio de giração Rg do sistema. Nos estágios mais avançados de agregação, o crescimento dos clusters ocorre por aumento do número de partículas por cluster (enquanto o número de clusters diminui), de forma que o volume de correlação Vc dos clusters satisfaz a relação Vc &prop; RgD, mesmo que os valores de D cresçam lenta e regularmente de 1,22 a 1,57 dentro do intervalo estudado, em concordância com o carácter fractal de massa dos clusters. Esses resultados suportam um mecanismo de agregação cluster-cluster controlado por difusão. / In this work, the structure and the kinetics of formation of organic/inorganic hybrid materials, prepared by sol-gel process from the hydrolysis of mixtures of functionalized silicon organometallics, are studied by small-angle X-ray scattering (SAXS). In a first system, the structural evolution of a 2:1 molar hydrolyzed mixture of Tetraethoxysilane (TEOS) and 3-Glycidoxypropyltrimethoxysilane (GPTS) was studied in situ as a time function by SAXS, at 25&deg;C, 43&deg;C and 60&deg;C. The results are compatible with the growth of silica rich domains (clusters) from a fixed number of primary particles. The gyration radius, Rg, of the clusters and the intensity extrapolated to zero, I(0), increase in power laws with time t as Rg &prop; (t-t0)&alpha; and I(0) = B(t-t0)&beta;, being &alpha; and &beta; independents on temperature while B is a measure of the process rate constant k = &beta;B1/&beta;, an Arrhenius function of temperature. The activation energy &Delta;E = 67.7 &plusmn; 1.1 kJ/mol was evaluated for the process. The extrapolated intensity I(0) also scales experimentally with Rg as I(0) &prop; RgD with D = 1.71 &plusmn; 0.01, in good agreement with the value &beta;/&alpha; = 1.79 &plusmn; 0.07 from the kinetic study. The growth of macromolecules with dimensionality 1.7 is typical of diluted or semi-diluted macromolecules in good-solvent conditions. The SAXS results yet suggest that the system exhibits dynamic scaling properties limited by the primary particle size. In a second system, the structural evolution of a 1:1 molar hydrolyzed mixture of 3-Aminopropyltriethoxysilane (APTS) and 3-Glycidoxypropyltrimethoxysilane (GPTS) was studied in situ as a time function by SAXS, at ambient temperature. The results are compatible with formation of primary particles and growth of clusters with mass-fractal characteristics (1 < D < 3). At the initial stage, the population of the non-fractal primary particles (D = 3) increases with time. The growth of the mass-fractal clusters (D < 3) from the aggregation of the primary particles increases gradually the average radius of gyration Rg of the system. At advanced stages of aggregation, the growth of the clusters occurs by the increase of the number of particles per clusters (while the number of clusters diminishes), in such a way that the correlation volume of the clusters Vc fulfills the relationship Vc &prop; RgD, even though the values of D have increased slowly and gradually from 1.22 to 1.57 in the studied range, in agreement with a mass-fractal character of the clusters. These results support a diffusion-controlled cluster-cluster aggregation mechanism.

Cinética de crescimento

Evolução estrutural

Híbridos de sílica

Kinetics growth

SAXS

SAXS

Silica hybrids

Structural evolution

Reaction Kinetics and Structural Evolution for the Formation of Nanocrystalline Silicon Carbide via Carbothermal Reduction

Cheng, Zhe

January 2004

Nanocrystalline beta-silicon carbide (ß-SiC) was synthesized at relatively low temperature (<1300C) by carbothermal reduction (CTR) reaction in fine scale carbon/silica mixtures. The fine scale mixing of the reactants (i.e., carbon and silica) was achieved by solution-based processing and subsequent heat treatment. The mechanism of the CTR reaction in the current system was investigated from different aspects. The condensates of the volatile species generated during the CTR reaction was collected and analyzed. The results supported previous investigations which suggested that the CTR reaction is a multi-step process that involves silicon monoxide (SiO) vapor as a reaction intermediate. The kinetics of the CTR reaction was investigated by isothermal weight loss study and by the study which determined the amount of SiC formed via quantitative X- ray diffraction (QXRD) analysis. The results of kinetic study were consistent with the "shrinking-core" model, in which the reaction between SiO vapor and carbon at the carbon surface to produce SiC is the rate-controlling step. In addition, several techniques, including XRD, gas adsorption analysis, laser diffraction particle size analysis, SEM, TEM, etc., had been used to study the structural evolutions of the reaction product of CTR. It was demonstrated that the evolutions of product structure characteristics such as crystallite size, specific surface area, specific pore volume, pore size distribution, particle size distribution, and powder morphology, etc. were consistent with each other and provided support to the reaction mechanism proposed.

Silica

Silicon carbide

Carbon

Nanocrystalline

Reaction mechanisms

Solution based precursor

Carbothermal reduction reaction

Kinetics

Structural evolution

Effects of Chemistry on Toughness and Temperature on Structural Evolution in Metallic Glasses

Shamimi Nouri, Ali

January 2009

Thesis (Ph.D.)--Case Western Reserve University, 2009 / Department of Materials Science and Engineering Available online via the OhioLINK ETD Center

Contribuição ao estudo por SAXS da estrutura e cinética de formação de híbridos orgânico/sílica / Contribution to the study by SAXS of the structure and kinetic formation of organic/silica hybrids

Carlos Miranda Awano

12 April 2017

Neste trabalho, estudam-se por espalhamento de raios-X a baixo ângulo (SAXS) a estrutura e a cinética de formação de materiais híbridos orgânico/inorgânico, preparados por processo sol-gel a partir da hidrólise de misturas de organometálicos de silício funcionalizados. Num primeiro sistema, a evolução estrutural de uma mistura hidrolisada 2:1 molar de Tetraetoxisilano (TEOS) e 3-Glicidoxipropiltrimetoxisilano (GPTS) foi estuda em função do tempo in situ por SAXS, nas temperaturas de 25&deg;C, 43&deg;C e 60&deg;C. Os resultados são compatíveis com o crescimento de domínios ricos em sílica (clusters) formados a partir de um número fixo de partículas primárias. O raio de giração, Rg , dos clusters e a intensidade de SAXS extrapolada a zero, I(0), crescem com o tempo t seguindo leis de potência da forma Rg &prop; (t-t0)&alpha; e I(0) = B(t-t0)&beta;, sendo &alpha; e &beta; e independentes da temperatura e B uma medida da constante de velocidade k = &beta;B1/ &beta; do processo, uma função de Arrhenius da temperatura. A energia de ativação &Delta;E = 67,7 &plusmn; 1,1 kJ/mol foi estimada para o processo. A intensidade I(0) também escala experimentalmente com Rg na forma I(0) &prop; RgD com D = 1,71 &plusmn; 0,01, em boa concordância com o valor &beta;/&alpha; = 1,79 &plusmn; 0,07 obtido do estudo cinético. O crescimento de macromoléculas com dimensionalidade de 1,7 é típico de macromoléculas diluídas ou semidiluídas em condições de bom solvente. Os resultados de SAXS ainda sugerem que o sistema exibe propriedades dinâmicas de escala limitadas pelo tamanho das partículas primárias. Num segundo sistema, a evolução estrutural de uma mistura hidrolisada 1:1 molar de 3-Aminopropiltrietoxisilano (APTS) e 3-Glicidoxipropiltrimetoxisilano (GPTS) foi estuda em função do tempo in situ por SAXS, em temperatura ambiente. Os resultados são compatíveis com a formação de partículas primárias e crescimento de clusters com características de fractal de massa (1 < D< 3). No estágio inicial, a população de partículas primárias não fractais (D = 3) aumenta em função do tempo. O crescimento de clusters com características fractais de massa (D < 3) a partir da agregação das partículas primárias aumenta gradativamente o raio médio de giração Rg do sistema. Nos estágios mais avançados de agregação, o crescimento dos clusters ocorre por aumento do número de partículas por cluster (enquanto o número de clusters diminui), de forma que o volume de correlação Vc dos clusters satisfaz a relação Vc &prop; RgD, mesmo que os valores de D cresçam lenta e regularmente de 1,22 a 1,57 dentro do intervalo estudado, em concordância com o carácter fractal de massa dos clusters. Esses resultados suportam um mecanismo de agregação cluster-cluster controlado por difusão. / In this work, the structure and the kinetics of formation of organic/inorganic hybrid materials, prepared by sol-gel process from the hydrolysis of mixtures of functionalized silicon organometallics, are studied by small-angle X-ray scattering (SAXS). In a first system, the structural evolution of a 2:1 molar hydrolyzed mixture of Tetraethoxysilane (TEOS) and 3-Glycidoxypropyltrimethoxysilane (GPTS) was studied in situ as a time function by SAXS, at 25&deg;C, 43&deg;C and 60&deg;C. The results are compatible with the growth of silica rich domains (clusters) from a fixed number of primary particles. The gyration radius, Rg, of the clusters and the intensity extrapolated to zero, I(0), increase in power laws with time t as Rg &prop; (t-t0)&alpha; and I(0) = B(t-t0)&beta;, being &alpha; and &beta; independents on temperature while B is a measure of the process rate constant k = &beta;B1/&beta;, an Arrhenius function of temperature. The activation energy &Delta;E = 67.7 &plusmn; 1.1 kJ/mol was evaluated for the process. The extrapolated intensity I(0) also scales experimentally with Rg as I(0) &prop; RgD with D = 1.71 &plusmn; 0.01, in good agreement with the value &beta;/&alpha; = 1.79 &plusmn; 0.07 from the kinetic study. The growth of macromolecules with dimensionality 1.7 is typical of diluted or semi-diluted macromolecules in good-solvent conditions. The SAXS results yet suggest that the system exhibits dynamic scaling properties limited by the primary particle size. In a second system, the structural evolution of a 1:1 molar hydrolyzed mixture of 3-Aminopropyltriethoxysilane (APTS) and 3-Glycidoxypropyltrimethoxysilane (GPTS) was studied in situ as a time function by SAXS, at ambient temperature. The results are compatible with formation of primary particles and growth of clusters with mass-fractal characteristics (1 < D < 3). At the initial stage, the population of the non-fractal primary particles (D = 3) increases with time. The growth of the mass-fractal clusters (D < 3) from the aggregation of the primary particles increases gradually the average radius of gyration Rg of the system. At advanced stages of aggregation, the growth of the clusters occurs by the increase of the number of particles per clusters (while the number of clusters diminishes), in such a way that the correlation volume of the clusters Vc fulfills the relationship Vc &prop; RgD, even though the values of D have increased slowly and gradually from 1.22 to 1.57 in the studied range, in agreement with a mass-fractal character of the clusters. These results support a diffusion-controlled cluster-cluster aggregation mechanism.

Cinética de crescimento

Evolução estrutural

Híbridos de sílica

SAXS

Kinetics growth

SAXS

Silica hybrids

Structural evolution

Structural and Kinematic Evolution of Eocene-Oligocene Grasshopper Extensional Basin, Southwest Montana

Kickham, Julie C.

01 May 2002

The Grasshopper basin of southwest Montana is a complex east-dipping graben containing five unconformity-bounded sequences of Tertiary sedimentary rocks. The Eocene-Oligocene basin lies within the northern Rocky Mountain Basin and Range province. Geologic mapping in five and a half 7.5 minute quadrangles indicates that at least three distinct phases of extension characterize the Cenozoic tectonic evolution of Grasshopper basin from approximately 46 Ma toMa. The significant phases of extension in Grasshopper basin were phases 1 and 3. During the first phase of extension (46-27 Ma) the nonplanar Muddy-Grasshopper fault was initiated and 90% of the basin fill was deposited. At least 7 km of dip-slip displacement along this fault controlled the deposition of the Medicine Lodge beds (3.5 km thick) and development of a transverse fold train and a longitudinal anticline. The second phase of extension (late Eocene-early Oligocene) resulted in northwest-southeast trending extensional structures and was probably coincident with deformation along the Lemhi Pass fault (20 km to the southwest). The third phase of deformation (early Oligocene-middle Miocene) dismembered the once larger protobasin into smaller subbasins and tilted the northwest-dipping limb of the longitudinal anticline. The structures formed during this phase have north-south and northeast trends. Little sediment was deposited during phases 2 and 3. Overall >85% E-W extension accrued. Extensional folds are common in Grasshopper basin and formed during all three phases of extension. One orthogonal fold set was recorded. Two-dimensional kinematic analysis of the longitudinal Bachelor Mountain anticline shows that this fold is a double-­rollover that probably developed above a longitudinal ramp in the Muddy-Grasshopper fault. The transverse folds are the result of the changing strike of the downward­-flattening Muddy-Grasshopper fault. A transverse syncline developed above a convex up part of the fault whereas a transverse anticline formed above a concave up part of the fault that reflects changes in the strike of the fault. Three-dimensional inclined shear probably created this geometry.

structural evolution

kinematic evolution

eocene

oligocene

grasshopper extensional basin

montana

Geology

THE　EVOLVING DIVERSITY OF CORPORATE SYSTEMS: A COMPARATIVE STUDY ON THE TOYOTA GROUP AND THE HYUNDAI MOTOR GROUP / 企業システムの多様性とその進化：トヨタグループと現代自動車グループの比較研究

Woojin, Kim

24 September 2015

京都大学 / 0048 / 新制・課程博士 / 博士(経済学) / 甲第19258号 / 経博第523号 / 新制||経||275(附属図書館) / 32260 / 京都大学大学院経済学研究科経済学専攻 / (主査)教授 宇仁 宏幸, 教授 黒澤 隆文, 准教授 田中 彰 / 学位規則第4条第1項該当 / Doctor of Economics / Kyoto University / DGAM

Diversity of corporate systems

Structural evolution

Automobile industry

Toyota Group

Hyundai Motor Group

330