2011
DOI: 10.1142/s0217984911026322
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Transmission Properties of the One-Dimensional Array of Delta Potentials

Abstract: The problem of one-dimensional quantum wire along which a moving particle interacts with a linear array of N delta-function potentials is studied. Using a quantum waveguide approach, the transfer matrix is calculated to obtain the transmission probability of the particle. Results for arbitrary N and for specific regular arrays are presented. Some particular symmetries and invariances of the delta-function potential array for the N = 2 case are analyzed in detail. It is shown that perfect transmission can take … Show more

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Cited by 9 publications
(8 citation statements)
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“…Otherwise we can expect maximal values in the transmitivitty but not perfect tunnelling. Considering the cells as potential barriers, the arbitrary separation between the two cells (in the example 150 nm) can create resonances for different incident energies, but never perfect tunnelling, unless the two cells are equal, as it was shown in [39].…”
Section: Results For Arbitrary Nmentioning
confidence: 94%
See 3 more Smart Citations
“…Otherwise we can expect maximal values in the transmitivitty but not perfect tunnelling. Considering the cells as potential barriers, the arbitrary separation between the two cells (in the example 150 nm) can create resonances for different incident energies, but never perfect tunnelling, unless the two cells are equal, as it was shown in [39].…”
Section: Results For Arbitrary Nmentioning
confidence: 94%
“…From this result, it is easy to see that if the two δ-function potential have the same strength (λ 1 = λ 2 = λ), then for E 2 E 1 = −z/z * one obtains T = 1 for any λ (for graphical representation and other details see [39]). This can also be expressed as…”
Section: Two-δ-function Potential Arraymentioning
confidence: 94%
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“…An alternative initial state with the anti-parallel impurity spins (|↑ 1 and |↓ 2 or |↓ 1 and |↑ 2 ) add an extra asymmetry in the system. Although this asymmetry does not eliminate all the resonant effects, it restricts the constructive quantum interference [34]. It also affects the indistinguishability of the Feynmann paths of the scattered electron, decreasing the level of entanglement created [26,25].…”
Section: A Two-impurity Scattering Modelmentioning
confidence: 98%