This is shown in Figure 3 where the tunneling time is plotted as

This result shows that in this kind of systems, the presumption of a generalized Hartman effect is incorrect. Figure 3 The tunneling VRT752271 time τ 6 as a function of reduced barrier separation and fixed barrier width. The tunneling time τ 6 as a function of reduced barrier separation

a/λ for fixed barrier width b, number of cells n=6 and electron energy E=0.15 eV with the corresponding de Broglie wavelength λ. The Hartman effect as a consequence of varying the number of cells was already discussed in [7]. In Figure 4 we show three qualitatively different examples on the behavior of the tunneling time as a function of n. In Figure 4a for energies in the gap (E=0.15 eV and E=0.2 eV), the saturation of the tunneling time exhibits

the well-known Hartman effect. In Figure 4b, the energy lies at the edge of a resonant region. The phase time τ n resonates for multiples of n=21. This behavior is clearly understood if we consider Equations 4 and 5. Equation 4 implies that the same resonance energy is found for different number of cells as long as the ratio ν/n is constant. This means that . From Equation 5, it is also evident the linear dependence of τ n on n. Figure 4 The tunneling time τ n as the number of cells n in a SL is varied. (a) Saturation of τ n for electron energies E=0.15 eV and E=0.2 eV in the gap. (b) The energy is close to a resonant band-edge. In this case, more resonances appear as n is increased with the energy fixed. No Hartman effect can be inferred www.selleckchem.com/products/lazertinib-yh25448-gns-1480.html from this figure. The Hartman effect and the electromagnetic waves Electromagnetic

waves have been used for discussions on the Hartman effect [9]. For a superlattice L(H/L) n made of alternating layers with refractive indices n L and n H , the phase time (PT) for each frequency component of a Gaussian wave packet PX-478 solubility dmso through a SL of length n ℓ c −a is also obtained from Equation 2 with k L,H =ω n L,H /c and with [7] (8) (9) To see the effect of varying the size of the SL on the PT, one has to be sure that such variation will still keep the wavelength inside a photonic band gap. It was shown until that by increasing the number of cells, for fixed thicknesses of layers and wavelength in a gap, the PT exhibits [7] the observed Hartman effect [2, 3]. However, this condition will not be possible by varying arbitrarily the thicknesses of the layers. The reason is that there is only a small range of thicknesses that one can use to keep the chosen wavelength to lie in a gap before going out of it and may even reach resonances, as shown in Figure 5 where the PT oscillates (with a band structure) and grows as a function of the reduced thicknesses a/λ and b/λ. This is analogous to the electron tunneling time shown in Figure 3. Figure 5 The phase times τ n as functions of the reduced thicknesses.

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