Physical mechanism for apparent superluminality in barrier tunneling

Author

Winful, Herbert G.

Author_Institution

Dept. of Electr. Eng. & Comput. Sci., Univ. of Michigan, Ann Arbor, MI, USA

Volume

9

Issue

1

fYear

2003

Firstpage

17

Lastpage

29

Abstract

Tunneling without distortion is not a propagation phenomenon but a quasistatic process in which the slowly varying envelope of the input pulse modulates the amplitude of a standing wave in the barrier. Because the envelope has a bandwidth that is small compared to the cutoff frequency of the barrier it does not propagate; it merely stands and waves. The envelope of the reflected and transmitted fields can adiabatically follow the envelope of the input pulse with only a small delay proportional to the energy stored in the barrier. The Hartman effect, in which the delay becomes independent of barrier length, is explained on the basis of saturation of stored energy with increasing length. Because the delay is not a propagation delay, it should not be linked to a velocity of propagation. True evanescent waves have zero speed and not infinite velocity as often asserted.

Keywords

electromagnetic wave reflection; electromagnetic wave transmission; photonic band gap; tunnelling; Hartman effect; amplitude modulation; apparent superluminality; bandwidth; barrier length; barrier tunneling; cutoff frequency; input pulse slowly varying envelope; photonic bandgap structure; physical mechanism; propagation velocity; quasistatic process; reflected fields; small delay; stored energy saturation; transmitted fields; true evanescent waves; zero speed; Amplitude modulation; Bandwidth; Cutoff frequency; Delay effects; Energy storage; Optical modulation; Photonic band gap; Propagation delay; Pulse modulation; Tunneling;

fLanguage

English

Journal_Title

Selected Topics in Quantum Electronics, IEEE Journal of

Publisher

ieee

ISSN

1077-260X

Type

jour

DOI

10.1109/JSTQE.2002.807972

Filename

1193070