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Relaxation properties

The initial elastic response in this case is o = fie. Similar to the creep compliance, a linear viscoelastic polymer has a relaxation modulus T(t), which is a characteristic material property. [Pg.40]


J. W. Freeman and H. Voorhees, Relaxation Properties of Steels and Superstrength Mlloys at ElevatedTemperatures, ASTM STP 187, ASTM, Philadelphia, Pa., 1956, p. 7 Metals Handbook, Vol. 1, 10th ed., ASM, Materials Park, Ohio, p. 631. [Pg.133]

J.R. Asay, G.R. Fowles, and Y.M. Gupta, Determination of Material Relaxation Properties from Measurements on Decaying Elastic Shock Fronts, J. Appl. Phys. 43, 744-746 (1972). [Pg.257]

A number of examples have been studied in recent years, including liquid sulfur [1-3,8] and selenium [4], poly(o -methylstyrene) [5-7], polymer-like micelles [9,11], and protein filaments [12]. Besides their importance for applications, EP pose a number of basic questions concerning phase transformations, conformational and relaxational properties, dynamics, etc. which distinguish them from conventional dead polymers in which the reaction of polymerization has been terminated. EP motivate intensive research activity in this field at present. [Pg.510]

Condensation of p-chlorobenzaldehyde with 3-mercaptopropionic acid in the presence of ammonium carbonate leads to the thiazi-none, 179. The reaction very probably proceeds by the intermediacy of the carbonyl addition product, I7S lactamization completes formation of the observed product. Oxidation of 179 to the sulfone by means of potassium permanganate in acetic acid gives chlormezanone (180), a minor tranquilizer with muscle-relaxant properties. [Pg.280]

The possibility of conformational changes in chains between chemical junctions for weakly crosslinked CP in ionization is confirmed also by the investigation of the kinetic mobility of elements of the reticular structure by polarized luminescence [32, 33]. Polarized luminescence is used for the study of relaxation properties of structural elements with covalently bonded luminescent labels [44,45]. For a microdisperse form of a macroreticular MA-EDMA (2.5 mol% EDMA) copolymer (Fig. 9 a, curves 1 and 2), as compared to linear PM A, the inner structure of chain parts is more stable and the conformational transition is more distinct. A similar kind of dependence is also observed for a weakly crosslinked AA-EDMA (2.5 mol%) copolymer (Fig. 9b, curves 4 and 5). [Pg.14]

Data of Figs 8-10 give a simple pattern of yield stress being independent of the viscosity of monodisperse polymers, indicating that yield stress is determined only by the structure of a filler. However, it turned out that if we go over from mono- to poly-disperse polymers of one row, yield stress estimated by a flow curve, changes by tens of times [7]. This result is quite unexpected and can be explained only presumably by some qualitative considerations. Since in case of both mono- and polydisperse polymers yield stress is independent of viscosity, probably, the decisive role is played by more fine effects. Here, possibly, the same qualitative differences of relaxation properties of mono- and polydisperse polymers, which are known as regards their viscosity properties [1]. [Pg.79]

Ethylene is an anesthetic gas with a rapid onset of action and a rapid recovery from its anesthetic effects. It provides adequate analgesia but has poor muscle-relaxant properties. The advantages of ethylene include minimal bronchospasm, laryngospasm, and postanesthesia vomiting. A disadvantage of ethylene is hypoxia. This gas is supplied in red cylinders. Mixtures of ethylene and oxygen are flammable and explosive. [Pg.321]

In this section, the characteristics of the spectra displayed by the different types of iron—sulfur centers are presented, with special emphasis on how they depend on the geometrical and electronic structure of the centers. The electronic structure is only briefly recalled here, however, and interested readers are referred to the excellent standard texts published on this topic (3, 4). Likewise, the relaxation properties of the centers are described, but the nature of the underlying spin-lattice relaxation processes is not analyzed in detail. However, a short outline of these processes is given in the Appendix. The aim of this introductory section is therefore mainly to describe the tools used in the practical applications presented in Sections III and IV. It ends in a discussion about some of the issues that may arise when EPR spectroscopy is used to identify iron-sulfur centers. [Pg.423]

With trinuclear clusters, we are now dealing with systems whose electronic structure depends on multiple intersite interactions that may differ from one iron pair to another. As a result, the separation between adjacent energy levels depends, not on the magnitude of these interactions, but on their difference. This may give rise to low-lying excited levels, which may have far-reaching effects on both the EPR spectrum and the relaxation properties. [Pg.436]

Generally speaking, the spin-lattice relaxation properties of a given paramagnetic center depend on several factors ... [Pg.486]

In many products, the spin-relaxation properties of the components can be different due to molecular sizes, local viscosity and interaction with other molecules. Macromolecules often exhibit rapid FID decay and short T2 relaxation time due to its large molecular weight and reduced rotational dynamics [18]. Mobile water protons, on the other hand, are often found to have long relaxation times due to their small molecular weight and rapid diffusion. As a result, relaxation properties, such as T2, have been used extensively to quantify water/moisture content, fat contents, etc. [20]. For example, oil content in seeds is determined via the spin-echo technique as described according to international standards [64]. [Pg.176]

NMR signals are highly sensitive, via a number of different mechanisms, to the physical and chemical properties of porous materials. Using the set of NMR-based measurement methods that we have developed, it is possible to non-invasively and non-destructively characterize both the microstructural properties of the materials and relaxation properties of fluids imbibed into these materials. [Pg.319]

W. E. Kenyon, P. I. Day, C. Straley, J. F. Willemsen 1988, (A three-part study of NMR longitudinal relaxation properties of water-saturated sandstones), SPEFE September, 622-636. [Pg.339]

The synthesis of organotin oligosteracrylate i.e. dimethylstannyl dimethacrylate, and the production of the cross-linked homopolymers on its basis have been reported. Morphology, mechanical and relaxation properties of poly(dimethyl-stannyl dimethacrylate) have been investigated 67). [Pg.120]

Proton NMR has the advantage of relative experimental ease due mainly to its intrinsic high sensitivity, though the relaxation properties of the proton resonances are generally more difficult to interpret in terms of dynamics than are those from protonated carbon nuclei. The widths of the proton resonances can conveniently be used as a qualitative measure of some of the motional properties. [Pg.503]


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See also in sourсe #XX -- [ Pg.136 ]

See also in sourсe #XX -- [ Pg.96 ]

See also in sourсe #XX -- [ Pg.240 ]




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Catalytic properties structural relaxation

Control of relaxation properties in oligomer curing

Dielectric relaxation general properties

Dispersion mechanisms structural relaxation properties

EPR Characteristics and Relaxation Properties of the Centers

Mechanical properties relaxation

NMR Relaxivity Properties Applications of Sol-Gel Procedures in MRI Contrast Agents

Physical properties dielectric relaxation

Poly relaxation properties

Properties relaxation frequency, bulk

Relaxation and Properties of ZnS (110) Surface

Relaxation bulk properties

Relaxation dielectric properties

Relaxation of Properties

Relaxation properties differences

Relaxation properties, change

Relaxation time correlation with dielectric properties

Relaxation ultrasonic properties

Relaxation viscoelastic properties

Relaxation, cross equilibrium properties

Stress Relaxation (Viscoelastic Properties)

Structural relaxation time basic properties

Symmetry Properties of the Relaxation Equations

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