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Boltzmann transport

This completes the heuristic derivation of the Boltzmann transport equation. Now we trim to Boltzmaim s argument that his equation implies the Clausius fonn of the second law of thennodynamics, namely, that the entropy of an isolated system will increase as the result of any irreversible process taking place in the system. This result is referred to as Boltzmann s H-theorem. [Pg.683]

The same k p scheme has been extended to the study of transport properties of CNTs. The conductivity calculated in the Boltzmann transport theory has shown a large positive magnetoresistance [18], This positive magnetoresistance has been confirmed by full quantum mechanical calculations in the case that the mean free path is much larger than the circumference length [19]. When the mean free path is short, the transport is reduced to that in a 2D graphite, which has also interesting characteristic features [20]. [Pg.74]

In its more advanced aspects, kinetic theory is based upon a description of the gas in terms of the probability of a particle having certain values of coordinates and velocity, at a given time. Particle interactions are developed by the ordinary laws of mechanics, and the results of these are averaged over the probability distribution. The probability distribution function that is used for a given macroscopic physical situation is determined by means of an equation, the Boltzmann transport equation, which describes the space, velocity, and time changes of the distribution function in terms of collisions between particles. This equation is usually solved to give the distribution function in terms of certain macroscopic functions thus, the macroscopic conditions imposed upon the gas are taken into account in the probability function description of the microscopic situation. [Pg.2]

Shizgal et al. start with the Boltzmann transport equation and after a number of standard approximations write it in the space-independent form as follows ... [Pg.261]

About Rep, it decreases as temperature decreases, due to the fact that the number of phonons decreases. A full treatment of the problem, however, can only be obtained by solving the Boltzmann transport equation, which has only been solved for the case of quasi-free electrons. Further information and approximate solutions can be found in ref. [7,106,107], The general result of these calculations shows that at low temperature T < 0D/1O), the thermal resistance Rep is of the form b- T2. [Pg.94]

Instead of the usual Boltzmann transport equation approach, we will present a more phenomenological method of attaining the desired results (Bube, 1974). The hope here is that the physics will not so easily be obscured in the... [Pg.127]

See also Boltzmann s Distribution Law and Boltzmann Transport Equation. [Pg.250]

BOLTZMANN TRANSPORT EQUATION. The fundamental equa tion describing the conservation of particles which are diffusing in a scattering, absorbing, and multiplying medium. It states that the lime rate of change of particle density is equal to the rate of production, minus the rate of leakage and the rate of absorption, in the form of a partial differential equation sucli as... [Pg.251]

Since Boltzmann transport equation (BTE), which is derived to LBKE, is particle assumption-based theory, an SRS model can be implemented to BTE as follows ... [Pg.91]

The diffusive transport phenomena in nanowires can be described by a semiclassical model based on the Boltzmann transport equation. For carriers in a one-dimensional subband, important transport coefficients, such as the electrical conductivity, a, the Seebeck coefficient, S, and the thermal conductivity, Ke, are derived as (Sun et al., 1999b Ashcroft and Mermin, 1976a)... [Pg.192]

In order to simulate the experimental data, we calculated Apc(0, 6) using the Shockley-Chambers tube-integral form of the Boltzmann transport... [Pg.17]

Plasmas typical of C02 laser discharges operate over a pressure range from 1 Torr to several atmospheres with degrees of ionization, that is, nJN (the ratio of electron density to neutral density) in the range from 10-8 to 10-8. Under these conditions the electron energy distribution function is highly non-Maxwellian. As a consequence it is necessary to solve the Boltzmann transport equation based on a detailed knowledge of the electron collisional channels in order to establish the electron distribution function as a function of the ratio of the electric field to the neutral gas density, E/N, and species concentration. Development of the fundamental techniques for solution of the Boltzmann equation are presented in detail by Shkarofsky, Johnston, and Bachynski [44] and Holstein [45]. [Pg.429]

Up to now we have discussed two extreme limits, the band picture on the one hand, and strong localization associated with interruptions in the metallic chains on the other. In fact, from work on thin metallic films and metallic glasses it is known that there is an intermediate region, that of weak localization. This occurs when the mean free path for elastic scattering (Lel) is only somewhat larger than, or comparable with, that for inelastic processes (Lin). In the first approximation there are corrections to the Boltzmann transport formula which depend on the ratio Lin/Lel in different ways for one-, two-, and three-dimensional materials. Weak localization... [Pg.396]

In principle, the Boltzmann transport equation (BTE) can cover the regime where die lengdi and time scales are larger than carrier mean free time rand mean free length A. However, tremendous computational efforts are required in practice when the system length scale L and the process time scale t are getting larger. The BTE is, thus, usually... [Pg.292]

The self-consistent theoretical models based on the Boltzmann transport theory are used to characterize the microscale heat transfer mechanism by explaining mutual interactions among lattice temperature, and number density and temperature of carriers [12]. Especially, a new parameter related with non-equilibrium durability is introduced and its characteristics for various laser pulses and fluences are discussed. This study also investigates the temporal characteristics of carrier temperature distribution, such as the one- and two-peak structures, according to laser pulses and fluences, and establishes a regime criterion between one-peak and two-peak sttuctures for picosecond laser pulses. [Pg.293]

In the relaxation time approximation, the Boltzmann transport equation (BTE) takes the form [22,33] ... [Pg.381]

Narumanchi, S.V.J., J.Y. Murthy, and C.H. Amon. Boltzmann Transport Equation-based Thermal Modeling Approaches for Microelectronics, in 2nd International Thermal Sciences Seminar. 2004. Bled, Slovenia. [Pg.398]

Ladd, A., B. Moran, and W.G. Hoover, Lattice Thermal Conductivity A Comparison of Molecular Dynamics andAnharmonic Lattice Dynamics. Physical Review B, 1986. 34 p. 5058-5064. McGaughey, A.J. and M. Kaviany, Quantitative Validation of the Boltzmann Transport Equation Phonon Thermal Conductivity Model Under the Single-Mode Relaxation Time Approximation. Physical Review B, 2004. 69(9) p. 094303(1)-094303(11). [Pg.400]

See other pages where Boltzmann transport is mentioned: [Pg.569]    [Pg.673]    [Pg.676]    [Pg.42]    [Pg.28]    [Pg.333]    [Pg.52]    [Pg.298]    [Pg.216]    [Pg.273]    [Pg.170]    [Pg.57]    [Pg.88]    [Pg.118]    [Pg.186]    [Pg.394]    [Pg.39]    [Pg.292]    [Pg.293]    [Pg.379]    [Pg.380]    [Pg.381]    [Pg.396]    [Pg.398]    [Pg.106]   
See also in sourсe #XX -- [ Pg.65 ]



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