Solid surfaces and interfaces

EXAFS is a nondestructive, element-specific spectroscopic technique with application to all elements from lithium to uranium. It is employed as a direct probe of the atomic environment of an X-ray absorbing element and provides chemical bonding information. Although EXAFS is primarily used to determine the local structure of bulk solids (e.g., crystalline and amorphous materials), solid surfaces, and interfaces, its use is not limited to the solid state. As a structural tool, EXAFS complements the familiar X-ray diffraction technique, which is applicable only to crystalline solids. EXAFS provides an atomic-scale perspective about the X-ray absorbing element in terms of the numbers, types, and interatomic distances of neighboring atoms. 

JKR type mea.surement.s on monolayers depo.sited on. soft elastomers. The recent interest in the JKR experiments has been stimulated by the work of Chaudhury and coworkers [47-50J. In a 1991 paper, Chaudhury and White-sides [47] reported their extensive studies on the measurement of interfacial work of adhesion and surface energies of elastomeric solids. The motivation for this work was to study the physico-organic chemistry of solid surfaces and interfaces. 

In the last 40 years, modern surface science techniques have been developed to provide information about solid surfaces and interfaces on the atomic or molecular level [1]. Surface Science studies have revealed adsorption sites, electronic structure... 

SIMS and SNMS are versatile analytical techniques for the compositional characterization of solid surfaces and interfaces in materials research.92-94 As one of the most important applications, both surface analytical techniques allow depth profile analysis (concentration profile as a function of the depth analyzed) to be performed in materials science and the semiconductor industry with excellent depth resolution in the low nm range. For depth profiling in materials science, dynamic SIMS and SNMS using high primary ion beam doses are applied. Both techniques permit the analysis of light elements such as H, , C and N, which are difficult to measure with other analytical techniques. 

The nature of organic molecular solid surfaces and interfaces with metals. This is a summary containing a digest of the results of the investigations, where our view of polymer surfaces and interfaces , in the context of polymer-based LEDs, is summarized in a direct way. Sub-divisions include polymer surfaces polymer-on-metal interfaces and polymer-polymer interfaces. Different (ideal) models of the interfaces are outlined. 

The nature of organic and molecular solid surfaces and interfaces with metals... 

The solid surfaces and interfaces are investigated using surface profiler or imaging equipments such as scanning tunneling microscopy (STM), atomic force microscopy (AFM), scanning electron microscopy (SEM) and TEM in order to quantity the... 

X-ray photoelectron spectroscopy (XPS) has been recognized as one of the best analytical methods for probing composition and electronic structure of solid surfaces and interfaces. However, it is based on monitoring emitted photoelectrons, which imposes a limitation on the operating pressures consequently, substantial time has passed before this technique was applied in reaction experiments in the near-atmospheric pressure range. 

Explore new types of chemistry associated with superconducting solids, surfaces and interfaces. 

As it was introduced in Sect. 29.2.3, neutrons of sufficiently long wavelength can bring about optical phenomena when encountering boundaries of condensed phases they, as waves, interact with the continuous potential represented by densely packed atoms. Reflection does occur (although only for very small incident angles, due to the very nearly unity value of the refractive index of most materials for neutrons), which can be exploited for studying Uquid (and solid) surfaces (and interfaces) by neutron reflectometry. 

This article describes the current capabilities for predicting materials properties using atomistic computational approaches. The focus is on inorganic materials including metals, semiconductors, and insulators in the form of bulk solids, surfaces, and interfaces. Properties of isolated molecules, liquids. and organic polymers are treated as separate entries. Besides a computational approach based on physical laws, materials properties can also be predicted by empirical rules and statistical correlations between chemical composition, bonding topology, and macroscopic properties. These very useful and quick approaches, which include so-called quantitative structure-property relationship (QSPR) methods, are covered in other entries of this encyclopedia (see Quantitative Structure-Property Relationships (QSPR)). 

The cleaning process proceeds by one of three primary mechanisms solubilization, emulsification, and roll-up [229]. In solubilization the oily phase partitions into surfactant micelles that desorb from the solid surface and diffuse into the bulk. As mentioned above, there is a body of theoretical work on solubilization [146, 147] and numerous experimental studies by a variety of spectroscopic techniques [143-145,230]. Emulsification involves the formation and removal of an emulsion at the oil-water interface the removal step may involve hydrodynamic as well as surface chemical forces. Emulsion formation is covered in Chapter XIV. In roll-up the surfactant reduces the contact angle of the liquid soil or the surface free energy of a solid particle aiding its detachment and subsequent removal by hydrodynamic forces. Adam and Stevenson s beautiful photographs illustrate roll-up of lanoline on wood fibers [231]. In order to achieve roll-up, one requires the surface free energies for soil detachment illustrated in Fig. XIII-14 to obey... 

Luth H 1995 Surfaces and Interfaces of Solid Materials 3rd edn (Beriin Springer)... 

Because of the generality of the symmetry principle that underlies the nonlinear optical spectroscopy of surfaces and interfaces, the approach has found application to a remarkably wide range of material systems. These include not only the conventional case of solid surfaces in ultrahigh vacuum, but also gas/solid, liquid/solid, gas/liquid and liquid/liquid interfaces. The infonnation attainable from the measurements ranges from adsorbate coverage and orientation to interface vibrational and electronic spectroscopy to surface dynamics on the femtosecond time scale. 

The downward velocity profile u x) where x = 0 at the solid surface and I = 8 at the liquid/gas interface is given by... 

Solid state NMR is a relatively recent spectroscopic technique that can be used to uniquely identify and quantitate crystalline phases in bulk materials and at surfaces and interfaces. While NMR resembles X-ray diffraction in this capacity, it has the additional advantage of being element-selective and inherently quantitative. Since the signal observed is a direct reflection of the local environment of the element under smdy, NMR can also provide structural insights on a molecularlevel. Thus, information about coordination numbers, local symmetry, and internuclear bond distances is readily available. This feature is particularly usefrd in the structural analysis of highly disordered, amorphous, and compositionally complex systems, where diffraction techniques and other spectroscopies (IR, Raman, EXAFS) often fail. 

Unlike linear optical effects such as absorption, reflection, and scattering, second order non-linear optical effects are inherently specific for surfaces and interfaces. These effects, namely second harmonic generation (SHG) and sum frequency generation (SFG), are dipole-forbidden in the bulk of centrosymmetric media. In the investigation of isotropic phases such as liquids, gases, and amorphous solids, in particular, signals arise exclusively from the surface or interface region, where the symmetry is disrupted. Non-linear optics are applicable in-situ without the need for a vacuum, and the time response is rapid. 

Surface SHG [4.307] produces frequency-doubled radiation from a single pulsed laser beam. Intensity, polarization dependence, and rotational anisotropy of the SHG provide information about the surface concentration and orientation of adsorbed molecules and on the symmetry of surface structures. SHG has been successfully used for analysis of adsorption kinetics and ordering effects at surfaces and interfaces, reconstruction of solid surfaces and other surface phase transitions, and potential-induced phenomena at electrode surfaces. For example, orientation measurements were used to probe the intermolecular structure at air-methanol, air-water, and alkane-water interfaces and within mono- and multilayer molecular films. Time-resolved investigations have revealed the orientational dynamics at liquid-liquid, liquid-solid, liquid-air, and air-solid interfaces [4.307]. 

Eq. 3 may also be derived heuristically by making a balance of horizontal forces on a small section of the interline as shown in Fig. 4. This treats the solid surface and the solid-liquid interface as though they were in states of tension given by their respective surface energies. The vertical force ytsin in such a construction is balanced by stresses in the underlying solid. 

The Volta potential is defined as the difference between the electrostatic outer potentials of two condensed phases in equilibrium. The measurement of this and related quantities is performed using a system of voltaic cells. This technique, which in some applications is called the surface potential method, is one of the oldest but still frequently used experimental methods for studying phenomena at electrified solid and hquid surfaces and interfaces. The difficulty with the method, which in fact is common to most electrochemical methods, is lack of molecular specificity. However, combined with modem surface-sensitive methods such as spectroscopy, it can provide important physicochemical information. Even without such complementary molecular information, the voltaic cell method is still the source of much basic electrochemical data. 

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