TY - JOUR
T1 - Superluminal tunnelling times as weak values
AU - Aharonov, Yakir
AU - Erez, Noam
AU - Reznik, Benni
N1 - Funding Information:
The research was supported in part by grant 62/01-1 of the Israel Science Foundation, established by the Israel Academy of Sciences and Humanities, NSF grant PHY-9971005, and ONR grant N00014-00-0383.
PY - 2003
Y1 - 2003
N2 - We consider the tunnelling particle as a pre- and post-selected system and prove that the tunnelling time is the expectation value of the position of a ‘clock’ degree of freedom weakly coupled to it. Such a value, called a ‘weak value’, typically falls outside the eigenvalue spectrum of the operator. The appearance of unusual weak values has been associated with a unique interference structure called ‘superoscillations’ (band-limited functions which on a finite interval, approximate functions with spectra well outside their band). It is proposed that superoscillations play an important role in the interferences which give rise to superluminal effects. To demonstrate that, we consider a certain simple tunnelling barrier which allows a wave packet to travel in zero time and negligible distortion, a distance arbitrarily longer than the width of the wave packet. The peak is shown to result from a superoscillatory superposition at the tail. Similar reasoning applies to the dwell time. For this system, both the Wigner time (related to the group velocity) and a clock time correspond to superluminal velocities.
AB - We consider the tunnelling particle as a pre- and post-selected system and prove that the tunnelling time is the expectation value of the position of a ‘clock’ degree of freedom weakly coupled to it. Such a value, called a ‘weak value’, typically falls outside the eigenvalue spectrum of the operator. The appearance of unusual weak values has been associated with a unique interference structure called ‘superoscillations’ (band-limited functions which on a finite interval, approximate functions with spectra well outside their band). It is proposed that superoscillations play an important role in the interferences which give rise to superluminal effects. To demonstrate that, we consider a certain simple tunnelling barrier which allows a wave packet to travel in zero time and negligible distortion, a distance arbitrarily longer than the width of the wave packet. The peak is shown to result from a superoscillatory superposition at the tail. Similar reasoning applies to the dwell time. For this system, both the Wigner time (related to the group velocity) and a clock time correspond to superluminal velocities.
UR - http://www.scopus.com/inward/record.url?scp=1542276687&partnerID=8YFLogxK
U2 - 10.1080/09500340308234558
DO - 10.1080/09500340308234558
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AN - SCOPUS:1542276687
SN - 0950-0340
VL - 50-6
SP - 1139
EP - 1149
JO - Journal of Modern Optics
JF - Journal of Modern Optics
IS - 7
ER -