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Liquids polar

One more experimental result, which is important for PT is as follows. Only polar liquids fill conical capillaries from both sides. We used various penetrants to fill conical defects Pion , LZh-6A , LZhT , LUM-9 etc. It was established that only the penetrants containing polar liquid as the basic liquid component (various alcohols, water and others) manifest two-side filling phenomenon. This result gives one more confirmation of the physical mechanism of the phenomenon, based on liquid film flow, because the disjoining pressure strongly depends just on the polarity of a liquid. [Pg.618]

The heat of immersion is measured calorimetrically with finely divided powders as described by several authors [9,11-14] and also in Section XVI-4. Some hi data are given in Table X-1. Polar solids show large heats of immersion in polar liquids and smaller ones in nonpolar liquids. Zetdemoyer [15] noted that for a given solid, hi was essentially a linear function of the dipole moment of the wetting liquid. [Pg.349]

Fig. X-9. Zisman plots of the contact angles of various homologous series on Teflon O, RX , alkylbenzenes (f), n-alkanes , dialkyl ethers , siloxanes A, miscellaneous polar liquids. (Data from Ref. 78.)... Fig. X-9. Zisman plots of the contact angles of various homologous series on Teflon O, RX , alkylbenzenes (f), n-alkanes , dialkyl ethers , siloxanes A, miscellaneous polar liquids. (Data from Ref. 78.)...
Pedersen J E and Keiding S R 1992 THz time-domain spectroscopy of non-polar liquids IEEE J. Quantum. Electron. 28 2518-22... [Pg.1991]

Hard-sphere models lack a characteristic energy scale and, hence, only entropic packing effects can be investigated. A more realistic modelling has to take hard-core-like repulsion at small distances and an attractive interaction at intennediate distances into account. In non-polar liquids the attraction is of the van der Waals type and decays with the sixth power of the interparticle distance r. It can be modelled in the fonn of a Leimard-Jones potential Fj j(r) between segments... [Pg.2365]

Detailed x-ray diffraction studies on polar liquid crystals have demonstrated tire existence of multiple smectic A and smectic C phases [M, 15 and 16]. The first evidence for a smectic A-smectic A phase transition was provided by tire optical microscopy observations of Sigaud etal [17] on binary mixtures of two smectogens. Different stmctures exist due to tire competing effects of dipolar interactions (which can lead to alternating head-tail or interdigitated stmctures) and steric effects (which lead to a layer period equal to tire molecular lengtli). These... [Pg.2546]

Bigelow WC, Piokett D L and Zisman W A 1946 Oleophobio monolayers. 1. Films adsorbed from solution in non-polar liquids J. Colloid Interface Scl. 1 513-38... [Pg.2635]

The polymer may be plasticised by polar liquids capable of forming hydrogen bonds with the hydroxyl groups. Glycerin has been used for this purpose. [Pg.391]

Aniline and mixed aniline point (DIN 51 775 modified). It is similar to the cloud point test except that the solvent is aniline, a very polar liquid. The aniline point is defined as the temperature at which a mixture of equal parts of aniline and the resin show the beginning of phase separation (i.e. the onset of clouding). Phase separation for aromatic resins occurs between I5°C and below zero for resins with intermediate aromaticity, it lies between 30 and 50°C and for non-aromatic resins, it is 50 to 100°C. Sometimes the mixed aniline point is used. It is similar to the aniline point except that the solvent is a mixture of one part of aniline and one part of w-heptane. The problem of both procedures is that precipitation of resins can be produced before the cloud is generated. [Pg.617]

A gel electrolyte, formed by dissolving a salt in a polar liquid and adding an inactive polymeric material to give the material mechanical stability. [Pg.499]

Guillot B., Bratos S. Theoretical analysis of dielectric properties of polar liquids in the far-infrared spectral range, Phys. Rev. A 16, 424-30 (1977). [Pg.284]

Fig. 51—Dependence of electric current on time for different EEF polarities. Liquid glycerin. Load 4 N. Line (a) and (b) represent the positive and negative cases, respectively. Positive EEF intensities of 518.6 kV/cm during the initial period of 60s then... Fig. 51—Dependence of electric current on time for different EEF polarities. Liquid glycerin. Load 4 N. Line (a) and (b) represent the positive and negative cases, respectively. Positive EEF intensities of 518.6 kV/cm during the initial period of 60s then...
Considerable progress has been made in the last decade in the development of more analytical methods for studying the structural and thermodynamic properties of liquids. One particularly successful theoretical approach is. based on an Ornstein-Zernike type integral equation for determining the solvent structure of polar liquids as well as the solvation of solutes.Although the theory provides a powerful tool for elucidating the structure of liquids in... [Pg.100]

Fedichev, P. O., Men shikov, L. 1., Long-range order and interactions of macroscopic objects in polar liquids. ArXiv Condensed Matter e-prints 0601129, 2006. [Pg.404]

Typical operating conditions by GC and HPLC are listed in Tables 2 and 3, respectively. Anilides are separated using a weakly polar liquid-phase capillary column, such as SPB-1 or HP-5, which is prepared based on 5% diphenyl-95% dimethylpolysilox-ane for GC. For HPLC, ODS columns are used. [Pg.332]

The availability of thermodynamically reliable quantities at liquid interfaces is advantageous as a reference in examining data obtained by other surface specific techniques. The model-independent solid information about thermodynamics of adsorption can be used as a norm in microscopic interpretation and understanding of currently available surface specific experimental techniques and theoretical approaches such as molecular dynamics simulations. This chapter will focus on the adsorption at the polarized liquid-liquid interfaces, which enable us to externally control the phase-boundary potential, providing an additional degree of freedom in studying the adsorption of electrified interfaces. A main emphasis will be on some aspects that have not been fully dealt with in previous reviews and monographs [8-21]. [Pg.120]

Thermodynamics of adsorption at liquid interfaces has been well established [22-24]. Of particular interest in view of biochemical and pharmaceutical applications is the adsorption of ionic substances, as many of biologically active compounds are ionic under the physiological conditions. For studying the adsorption of ionic components at the liquid-liquid interface, the polarized liquid-liquid interface is advantageous in that the adsorption of ionic components can be examined by strictly controlling the electrical state of the interface, which is in contrast to the adsorption studies at the air-water or nonpolar oil-water interfaces [25]. [Pg.120]

Every interface is more or less electrically charged, unless special care is exercised experimentally [26]. The energy of the system containing the interface hence depends on its electrical state. The thermodynamics of interfaces that explicitly takes account of the contribution of the phase-boundary potential is called the thermodynamics of electrocapillarity [27]. Thermodynamic treatments of the electrocapillary phenomena at the electrode solution interface have been generalized to the polarized as well as nonpolarized liquid liquid interface by Kakiuchi [28] and further by Markin and Volkov [29]. We summarize the essential idea of the electrocapillary equation, so far as it will be required in the following. The electrocapillary equation for a polarized liquid-liquid interface has the form... [Pg.121]

The case of polarized interfaces is usually described within the context of the metal-electrolyte interface where the metal charge dependence of the SH intensity is dramatic because of the strong interfacial electric field present at the interface [16]. It has long been a real challenge at the polarized liquid-liquid interface but has, however, been observed at charged air-water interfaces [48]. [Pg.143]


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Binary liquid mixtures, polarity

Electronic Nonlinear Polarizations of Liquid Crystals

Ferroelectric liquid crystalline polarization

Ferroelectric liquid crystalline polymers spontaneous polarization

Flammable liquids polarity

General Formalisms for Polarized Light Propagation Through Liquid Crystal Devices

Interactions in Polar Liquids

Ionic liquids polarities

Ionic liquids solvent polarity

Liquid chromatography polarity

Liquid chromatography-mass spectrometry high polarity

Liquid crystals polarized light micrographs

Liquid crystals polarized light microscopy

Liquid polarized backlights

Mercury polar organic liquids

Mobile polar liquids

Non-polar liquids

Polar adsorbents, liquid chromatography

Polar liquid diffusion

Polar liquid phases

Polar liquid, test

Polar liquids, capillary

Polar liquids, capillary action

Polar liquids, molecular orientation

Polar liquids, penetration

Polar liquids, solubility

Polar organic liquids, clays

Polar vapor-liquid equilibria

Polarity of organic liquids and adsorbents

Polarity, liquid membranes

Polarity, of ionic liquids

Polarity,liquid phases

Polarization in Polar Liquids

Polarizer cholesteric liquid crystal

Polarizers/Polarization liquid polarizer

Polarizers/Polarization liquid polarizer

Polarizing light microscopy liquid crystals studied using

Polarizing microscopy liquid crystalline polymer

Reverse phase liquid chromatography most polar solvent

Solvation properties, ionic liquids solvent polarity

Solvent polarity, ionic liquids constant

Solvent polarity, ionic liquids partitioning

Spontaneous Polarization Behavior of FLCPs (Ferroelectric Liquid Crystal Polymers)

The Ion-Continuum Interaction in Polar Liquids

The Solvated Electron in Alcohols and Other Polar Liquids

What Constitutes a Polar Liquid

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