Photon angular momentum and geometric gauge
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Transcript Photon angular momentum and geometric gauge
Photon angular momentum and
geometric gauge
Margaret Hawton, Lakehead University
Thunder Bay, Ontario, Canada
William Baylis, U. of Windsor, Canada
Outline
photon r operators and their localized
eigenvectors
leads to transverse bases and geometric
gauge transformations,
then to orbital angular momentum of the
bases, connection with optical beams
conclude
Notation: momentum space
zˆ
pz or z
q
f
px
ˆ
p
ˆ
θ
py
ˆ
φ
ˆ ~ zˆ pˆ ; θˆ φ
ˆ pˆ
φ
Use CP basis vectors:
e(0)
1
2
θˆ iφˆ
e0 pˆ
is the p-space gradient.
(Will use and when in r-space.)
Is the position of the photon an observable?
In quantum mechanics, any observable
requires a Hermitian operator
1948, Pryce obtained a photon position operator,
pˆ S
a
a
rP i p p
p
• a =1/2 for F=E+icB ~ p1/2 as in QED to normalize
• last term maintains transversality of rP(F)
• but the components of rP don’t commute!
• thus “the photon is not localizable”?
A photon is asymptotically localizable
1) Adlard, Pike, Sarkar, PRL 79, 1585 (1997)
a
ˆ
A ~q r
a is an arbitrarily large integer; power law
2) Bialynicki-Birula, PRL 80, 5247 (1998)
ˆ exp (r / r0 )
Z~m
1 to satisfy Paley-Wiener theorem,
r0 arbitrarily small; exponentially localized
Is there a photon position operator with commuting
components and exactly localized eigenvectors?
It has been claimed that since the early day of
quantum mechanics that there is not.
Surprisingly, we found a family of r operators,
Hawton, Phys. Rev. A 59, 954 (1999).
Hawton and Baylis, Phys. Rev. A 64, 012101 (2001).
and, not surprisingly, some are sceptical!
Euler angles of basis
De
pz
q
p
f
ˆ
θ
ˆ
φ
py
iS p
e
iS zf
e
iS yq
O DOD 1
F DF
i r( ) D i D1
px
i is the position operator for m>0; ri , p j i ij
etc. are preserved by above unitary transformation.
New position operator becomes:
r
( )
a
a
(0)
( )
( )
rP a S p where S p pˆ .S
cos
q
ˆ for θˆ / φ
ˆ basis
φ
p sin q
a
( 0)
• its components commute
• eigenvectors are exactly localized states
• it depends on “geometric gauge”, , that is
on choice of transverse basis
Like a gauge transformation in E&M
A A
a a
a p A r
2
a p pˆ + string so this looks
exactly like the B-field of a magnetic
monopole, complete with the Dirac
string singularity to return the flux.
Topology: You can’t comb the hair on a fuzz
ball without creating a screw dislocation.
Phase discontinuity at
origin gives -function
string when differentiated.
Geometric gauge transformation
0, a
(0)
cos q
ˆ
φ
p sin q
eg =-f
f , a
( f )
cos q 1
ˆ
φ
p sin q
no +z singularity
ˆ
ˆ
θ
φ
ˆ
since p
p
p q
p sin q f
( )
e
e
e
is rotation by about pˆ :
θˆ iφˆ cos f i sin f
cos fθˆ sin fφˆ
ˆ
i sin f θˆ cos f φ
e(f )
i (0)
1
2
1
2
qp
1
2
Rotated about zˆ by
f pˆ .zˆ f cos q
f at q =0, =f at q =p
φˆ
f
q0
θˆ
Is the physics -dependent?
Localized basis states depend on choice of , e.g.
e(0) or e(-f) localized eigenvectors look physically
different in terms of their vortices.
This has been given as a reason that our position
operator may be invalid.
The resolution lies in understanding the role of
angular momentum (AM). Note: orbital AM rxp
involves photon position.
“Wave function”, e.g.
F=E+icB
Any field can be expanded in plane wave
using the transverse basis determined by :
F r, t
3
d p
2p
3
f p e e
( ) i p.r pct /
f(p) will be called the (expansion) coefficient. For
F describing a specific physical state, change of
e() must be compensated by change in f.
For an exactly localized state f p Np e
a ipr '
Optical angular momentum (AM)
Helicity : e( )
Spin sz : e( ) ~
1
2
xˆ isz yˆ
2
1
Usual orbital AM: Lz i
If coefficient f p ~ e
ˆ e i
θˆ iφ
p z
i
f
ilzf
Lz eilzf lz eilzf and lz is OAM
Interpretation for helicity 1, single
valued, dislocation on -ve z-axis
( f )
1
e
cos q 1 xˆ iyˆ
2
sz=1, lz= 0
2
cos q 1 xˆ iyˆ
exp
2
2
1
2 sin q exp if
2if
sz= -1, lz= 2
sz=0, lz= 1
Basis has uncertain spin and orbital AM, definite jz=1.
Position space
e
ipr /
2p
0
imf
;l
pr
4p i Yl , Yl q , f jl
l 0;n l
l
n
n*
Yl n* q , f eimf df ~ n ,m eim
im
e dependence in p-space e in r-space
There is a similar transfer of q dependence,
and the factor jl (pr / ) is picked up.
Beams
Any Fourier expansion of the fields must make use
of some transverse basis to write
F r, t
3
d p
2p
3
f p e e
( ) i p.r pct /
and the theory of geometric gauge transformations
presented so far in the context of exactly localized
states applies - in particular it applies to optical
beams.
Some examples involving beams follow:
Bessel beam, fixed q 0 , azimuthal and radial (jz =0):
Volke-Sepulveda et al, J. Opt. B 4 S82 (2002).
A has zˆ and zˆ terms.
e1(0) e(0)
1
φˆ
i 2
xˆ iyˆ if 1 xˆ iyˆ if
1
i 2
e i 2
e
2
2
ˆθ 1 cos q xˆ iyˆ eif 1 cos q xˆ iyˆ e if sin q zˆ
2
2
2
2
The basis vectors contribute orbital AM.
e1( f ) and e(f1) have same l z 1
Nonparaxial optical beams
Barnett&Allen, Opt. Comm. 110, 670 (1994) get
xˆ iyˆ
1 zˆ sin q eif
co
s
q
2
2
1 2if ( f )
( f )
cos
q
1
cos
q
e1 +
e e 1
2
2
Elimination of e2if term requires linear combination of
RH and LH helicity basis states.
Partition of J between basis and coefficient
( ) ( )
r e 0 since eigenvector at r ' 0.
L( ) r ( ) p, L( )e( ) =0, L( ) acts only on coefficient.
S
( )
( )
J L
a
( )
p pˆ S p gives AM of basis.
J S ( ) L( ) is invariant under geometric gauge
( )
( ) imf
transformations, e.g. e e e
and f fe
for a fixed F describing a physical state.
to rotate axis is also possible, but inconvenient.
imf
Commutation relations
L(i ) , L(j ) i ijk L(k ) ;
r, L( ) 0
( )
Si
( )
( )
J i , rj i ijk rk i
p j
J z r
( )
j
( )
S
1
z
2 p j
0 since S
( )
z
= m
L() is a true angular momentum.
Confirms that localized photon has a definite
z-component of total angular momentum.
Summary
• Localized photon states have orbital AM and
integral total AM, jz, in any chosen direction.
• These photons are not just fuzzy balls, they
contain a screw phase dislocation.
• A geometric gauge transformation redistributes
orbital AM between basis and coefficient, but
leave jz invariant.
• These considerations apply quite generally, e.g.
to optical beam AM. Position and orbital AM
related through L=rxp.