Physical/thermal activation process mechanisms

Creep-rupture represents, ultimately, the thermally activated breaking of bonds. Russian authors, in particular, have tried to describe it as a mechanically aided chemical process rather than a physical one. So far, however, there has been no widely used combined description of degradation by chemical and mechanical means. 

The unique mechanical and structural properties of crystals necessitate the application of special experimental methods for the investigation of thd chemical kinetics of solids. In principle, all the physical parameters of substances involved in a chemical process can be used to follow the kinetics. These processes normally occur at high temperatures since they need thermal activation. Conventionally, the outcome of a solid state reaction experiment is inspected only after quenching. However, the quenching process is prone to alter many properties of the system, which explains the ambiguous results often found in the studies of solid state kinetics. 

Small solute atoms in the interstices between the larger host atoms in a relaxed metallic glass diffuse by the direct interstitial mechanism (see Section 8.1.4). The host atoms can be regarded as immobile. A classic example is the diffusion of H solute atoms in glassy Pd8oSi2o- For this system, a simplified model that retains the essential physics of a thermally activated diffusion process in disordered systems is used to interpret experimental measurements [20-22]. 

DIN EN ISO 8044 defines wear as the progressive loss of material from the surface of a solid body due to mechanical causes, i. e., contact with solid, liquid, or gaseous bodies and relative motion. Wear is manifested in the presence of loosened particles (wear particles) and in the change in material and shape of the surface layer. Thermal, physical, and chemical processes are activated in the case of most wear processes (triboreactions). Wear is fundamentally caused by mechanically transferred energy. 

Activation always involves some form of chemical attack. However, chemical activation is a term often used to indicate the prior impregnation of the precursor with a chemical agent such as phosphoric acid or zinc chloride before heat treatment. Physical activation, on the other hand, signifies the heat treatment of the char in a mildly reactive atmosphere such as steam or carbon dioxide. This type of process is preferably referred to as thermal activation (Baker, 1992). The apparent distinction between chemical and physical is somewhat unsatisfactory for two reasons first, it implies a fundamental difference in the mechanism of activation and second, it does not allow for the many procedures which involve both types of treatment. 

It has been reported that silver ion-exchanged zeolites exhibit antibacterial activity [32]. The mechanism of antibacterial action of the zeolite is initiated when moisture or liquid film comes into contact with the ion exchange material and silver ions are exchanged with sodium (Na) or other cations from the environment [33]. The released silver ions attach to the bacteria by forming chelate complexes with deoxyribonucleic acid, which blocks the transport processes in the cell [34]. The use of zeolite as a filler in polymeric materials has been reported in the literature and it has been proved that they enhance the antibacterial activity of the polymer [35]. Furthermore, the effect of zeolite content on the physical and thermal properties of the polymer was also examined [35] increasing the silver/zeolite ratio in the polymer led to an increased antimicrobial activity (due to the higher silver ion concentration), but depending upon the application the zeolite content may influence physical, thermal and/or chemical properties of the polymeric material. 

At elevated temperatures, the behaviour of polymers is much more complex because thermally activated rearrangements and movements within and between the chains can occur, which are frequently reversible. These processes are mainly responsible for the physical and mechanical properties of polymers. They are called relaxation processes and are the topic of this section. Their name is due to the fact that they may cause a relaxation i.e., a reduction of applied stresses, as we will see later. 

Electrochemistry, organic, structure and mechanism in, 12, 1 Electrode processes, physical parameters for the control of, 10, 155 Electron donor-acceptor complexes, electron transfer in the thermal and photochemical activation of, in organic and organometallic reactions. 29, 185 Electron spin resonance, identification of organic free radicals, 1, 284 Electron spin resonance, studies of short-lived organic radicals, 5, 23 Electron storage and transfer in organic redox systems with multiple electrophores, 28, 1 Electron transfer, 35, 117... 

Electrochemistry, organic, structure and mechanism in, 12, 1 Electrode processes, physical parameters for the control of, 10, 155 Electron donor-acceptor complexes, electron transfer in the thermal and photochemical activation of, in... 

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