Abstract
Abstract
In single-particle Madelung mechanics, the single-particle quantum state
Ψ
(
x
→
,
t
)
=
R
(
x
→
,
t
)
e
i
S
(
x
→
,
t
)
/
ℏ
is interpreted as comprising an entire conserved fluid of classical point particles, with local density
R
(
x
→
,
t
)
2
and local momentum
∇
→
S
(
x
→
,
t
)
(where R and S are real). The Schrödinger equation gives rise to the continuity equation for the fluid, and the Hamilton–Jacobi equation for particles of the fluid, which includes an additional density-dependent quantum potential energy term
Q
(
x
→
,
t
)
=
−
ℏ
2
2
m
∇
→
R
(
x
→
,
t
)
R
(
x
→
,
t
)
, which is all that makes the fluid behavior nonclassical. In particular, the quantum potential can become negative and create a nonclassical boost in the kinetic energy. This boost is related to superoscillations in the wavefunction, where the local frequency of Ψ exceeds its global band limit. Berry showed that for states of definite energy E, the regions of superoscillation are exactly the regions where
Q
(
x
→
,
t
)
<
0
. For energy superposition states with band-limit
E
+
, the situation is slightly more complicated, and the bound is no longer
Q
(
x
→
,
t
)
<
0
. However, the fluid model provides a definite local energy for each fluid particle which allows us to define a local band limit for superoscillation, and with this definition, all regions of superoscillation are again regions where
Q
(
x
→
,
t
)
<
0
for general superpositions. An alternative interpretation of these quantities involving a reduced quantum potential is reviewed and advanced, and a parallel discussion of superoscillation in this picture is given. Detailed examples are given which illustrate the role of the quantum potential and superoscillations in a range of scenarios.