Corrosion Behavior of Buried Pipeline in Presence of AC Stray Current in Controlled Environment

Ghanbari, Elmira

January 2016

No description available.

Engineering

Materials Science

Chemical Engineering

Use Diffusion Multiples to Investigate Diffusion and Precipitation Behavior in Binary Systems

Zhang, Qiaofu

08 August 2017

No description available.

Materials Science

Coupling agent effects on the interfacial adhesion in a sheath/core type bicomponent fiber

Li, Jian-xing

January 1989

No description available.

Engineering, Chemical

Coupling Agent Effects

Interfacial Adhesion

Sheath/Core

Bicomponent Fiber

Co-deformation and bonding of multi-component billets with application to Nb-Sn based superconductor processing

Peng, Xuan

10 October 2005

No description available.

Engineering, Materials Science

Interfacial bonding

co-drawing bonding

FEM

superconductor fabrication

The Importance of Contacts and Interfaces in Carbon-based Molecular Electronic Junctions

Yan, Haijun

January 2009

No description available.

Chemistry

molecular electronics

contacts and interfaces

filamentary conductance switching

Interfacial energetics

energy level alignment

electrode work function.

Soluble Surfactant and Nanoparticle Effects on Lipid Monolayer Assembly and Stability

Nilsen, Matthew David

01 November 2010

No description available.

Chemical Engineering

Surfactant

anomalous

interfacial

nanoparticle

lipid monolayer

self-assembly

molecular dynamics

Estimates of Interfacial Properties in Cu/Ni Multilayer Thin Films using Hardness and Internal Stress Data

Carpenter, John Stuart

02 November 2010

No description available.

Materials Science

Cu/Ni Multilayer Thin Films

Line Energy

Interfacial Properties

Micropillar Compression

Confined Layer Slip

Structure and Dynamics at the Electrode Interface of Ionic Liquids Studied Using Electrochemical Surface Plasmon Resonance / 電気化学表面プラズモン共嗚法を用いるイオン液体｜電極界面における構造およびダイナミクスの研究

ZHANG, SHIWEI

23 March 2022

京都大学 / 新制・課程博士 / 博士(工学) / 甲第23913号 / 工博第5000号 / 新制||工||1780(附属図書館) / 京都大学大学院工学研究科物質エネルギー化学専攻 / (主査)教授 作花 哲夫, 教授 安部 武志, 教授 阿部 竜 / 学位規則第4条第1項該当 / Doctor of Philosophy (Engineering) / Kyoto University / DGAM

Electric double layer

Ionic liquids

Interfacial relaxation

Static differential capacitance

Electrodeposition

500

Ultrafast Vibrational Spectroscopy and Dynamics of Water at Interfaces

Eftekharibafrooei, Ali

January 2011

Over the past two decades, vibrational sum-frequency generation (VSFG) has been applied as a versatile technique for probing the structure and dynamics of molecules at surfaces and interfaces. The excellent surface specificity of the SFG allows for probing different kinds of liquid interfaces with no or negligible contribution from adjacent and much deeper bulk phase. VSFG spectroscopy has provided evidence that the structure of the water at interfaces is different from the bulk. With the ultrafast pulses, VSFG can also be used as a probe of ultrafast vibrational dynamics at interfaces. However, apart from a few pioneering studies, the extension of VSFG into time domain has not been explored extensively. Here VSFG is used as a probe of ultrafast vibrational dynamics of water at silica interfaces. Silica is an excellent model system for the solid phase where one can systematically vary the surface charge via bulk pH adjustment. The extension of the surface electric field, the interfacial thickness and surface accumulation of ions at a charged silica surface were studied using IR pump-VSFG probe spectroscopy. A vibrational lifetime (T1) of about 250 fs, similar to bulk H2O, was observed for the O-H stretch of H2O/silica interface when the silica surface is negatively charged. At the neutral surface, where the thickness of interfacial water is smaller than at the charged surface, the vibrational lifetime of O-H stretch becomes more than two times longer (T1~ 600 fs) due to the decreased number of neighboring water molecules, probed by SFG. The fast T1 at negatively charged surface begins to slow down by screening of the penetration of surface electric field via adding salt which suggests the primary reason for similar vibrational dynamics of water at charged interface with bulk water is the penetration of electric field. By decoupling of OH of HDO in D2O, a frequency dependent vibrational lifetime is observed with faster T1 at the red compared to the blue side of the hydrogen bond spectral region. This correlates with the redshift of the SFG spectra with increasing charged surface and is consistent with a theoretical model that relates the vibrational lifetime to the strength of the hydrogen bond network. / Chemistry

Chemistry, Physical

Charged Surface

Interfacial Water

Silica

Sum-frequency Generation

Surface Spectroscopy

Vibrational Dynamics

IONS AND THE STRUCTURE AND DYNAMICS OF INTERFACIAL WATER AT CHARGED SURFACES

Dewan, Shalaka

January 2015

The distinct structure and dynamics of interfacial water are due to a break in the extended hydrogen bonding network present in bulk water. At solid-aqueous interfaces, the presence of surface charge, which induces a static electric field, and the electrolytes, which are present in most naturally relevant systems, can additionally perturb the hydrogen bonding environment due to polarization. The interplay between the surface-charge-induced electric field and the ions in changing the structure of interfacial water has important consequences in the chemistry of processes ranging from protein-water interactions to mineral-water reactivity in oil recovery. Accessing information about the first few layers of water at buried interfaces is challenging. Vibrational sum-frequency generation (vSFG) spectroscopy is a powerful technique to study exclusively the interfacial region and is used here to investigate the role of interfacial solvent structure on surface reactivity. It is known that the rate of quartz dissolution increases on addition of salt at neat water pH. The reason for this enhancement was hypothesized to be a consequence of perturbations in interfacial water structure. The vSFG spectra, which is a measure of ordering in the interfacial water structure, shows an enhanced effect of salt (NaCl) at neat pH 6~8. The trend in the effect of salt on vSFG spectra versus the bulk pH is remarkably consistent with the enhancement of rate of quartz dissolution, providing the first experimental correlation between interfacial water structure and silica dissolution. If salt alters the structure of interfacial water, it must affect the vibrational energy transfer pathways of water, which is extremely fast in bulk water (~130 fs). Thus far, the role of ions on the vibrational dynamics of water at charged surfaces has been limited to the screening effects and reduction in the depth of the region that contributes to vSFG. Here, we measure the ultrafast vibrational relaxation of the O-H stretch of water at silica at different bulk pH, using time-resolved (TR-vSFG). The fast vibrational dynamics of water (~200 fs) observed at charged silica surfaces (pH 6 and pH 12), slows down (~600 fs) on addition of NaCl only at pH 6 and not at pH 12. On the other hand at pH 2 (neutral surface), the vibrational relaxation shows an acceleration at high ionic strengths (0.5 M NaCl). The TR-vSFG results suggest that there is a surface-charge dependence on the sensitivity of the interfacial dynamics to ions and that reduction in the probe depth of vSFG alone cannot explain the changes in the vibrational lifetime of interfacial O-H. This is further supported by the cation specific effects observed in the TR-vSFG of the silica/water interface. While the vibrational relaxation of O-H stretch slows on addition of all salts (LiCl, NaCl, RbCl, and CsCl), the degree of slowing down is sensitive to the cation identity. The vibrational lifetime of O-H stretch in the presence of different cations follows the order: Li+ < Na+ < Rb+, consistent with previous Hofmeister effect reported in vSFG spectroscopy as well as AFM measurements at silica/water interface. To provide molecular insight on the effect of surface charge density and ionic strength on the changes in interfacial water structure, Molecular Dynamics (MD) simulations were performed on water at different types of surfaces. It was shown that the properties of water near the interface, e.g., a net orientation and the depth to which this persists, depend on the degree of specific adsorption of the counter ions. Our vSFG results, along with the insights from MD simulations, highlight the importance of considering the role of ions on the solvent structure within the electric double layer region, beyond the screening effects predicted by classical electrochemical models. / Chemistry

Chemistry

Chemistry, Physical

Interfacial Chemistry

Nonlinear Optics

Salt Effect

Sum-frequency Generation Spectroscopy

Vibrational Dynamics

Water