Several conventions have been used to define the VSH.[ 1] [ 2] [ 3] [ 4] [ 5]
We follow that of Barrera et al. . Given a scalar spherical harmonic Yℓm (θ , φ ) , we define three VSH:
Y
ℓ
m
=
Y
ℓ
m
r
^
,
{\displaystyle \mathbf {Y} _{\ell m}=Y_{\ell m}{\hat {\mathbf {r} }},}
Ψ
ℓ
m
=
r
∇
Y
ℓ
m
,
{\displaystyle \mathbf {\Psi } _{\ell m}=r\nabla Y_{\ell m},}
Φ
ℓ
m
=
r
×
∇
Y
ℓ
m
,
{\displaystyle \mathbf {\Phi } _{\ell m}=\mathbf {r} \times \nabla Y_{\ell m},}
with
r
^
{\displaystyle {\hat {\mathbf {r} }}}
being the unit vector along the radial direction in spherical coordinates and
r
{\displaystyle \mathbf {r} }
the vector along the radial direction with the same norm as the radius, i.e.,
r
=
r
r
^
{\displaystyle \mathbf {r} =r{\hat {\mathbf {r} }}}
. The radial factors are included to guarantee that the dimensions of the VSH are the same as those of the ordinary spherical harmonics and that the VSH do not depend on the radial spherical coordinate.
The interest of these new vector fields is to separate the radial dependence from the angular one when using spherical coordinates, so that a vector field admits a multipole expansion
E
=
∑
ℓ
=
0
∞
∑
m
=
−
ℓ
ℓ
(
E
ℓ
m
r
(
r
)
Y
ℓ
m
E
ℓ
m
(
1
)
(
r
)
Ψ
ℓ
m
E
ℓ
m
(
2
)
(
r
)
Φ
ℓ
m
)
.
{\displaystyle \mathbf {E} =\sum _{\ell =0}^{\infty }\sum _{m=-\ell }^{\ell }\left(E_{\ell m}^{r}(r)\mathbf {Y} _{\ell m} E_{\ell m}^{(1)}(r)\mathbf {\Psi } _{\ell m} E_{\ell m}^{(2)}(r)\mathbf {\Phi } _{\ell m}\right).}
The labels on the components reflect that
E
ℓ
m
r
{\displaystyle E_{\ell m}^{r}}
is the radial component of the vector field, while
E
ℓ
m
(
1
)
{\displaystyle E_{\ell m}^{(1)}}
and
E
ℓ
m
(
2
)
{\displaystyle E_{\ell m}^{(2)}}
are transverse components (with respect to the radius vector
r
{\displaystyle \mathbf {r} }
).
Like the scalar spherical harmonics, the VSH satisfy
Y
ℓ
,
−
m
=
(
−
1
)
m
Y
ℓ
m
∗
,
Ψ
ℓ
,
−
m
=
(
−
1
)
m
Ψ
ℓ
m
∗
,
Φ
ℓ
,
−
m
=
(
−
1
)
m
Φ
ℓ
m
∗
,
{\displaystyle {\begin{aligned}\mathbf {Y} _{\ell ,-m}&=(-1)^{m}\mathbf {Y} _{\ell m}^{*},\\\mathbf {\Psi } _{\ell ,-m}&=(-1)^{m}\mathbf {\Psi } _{\ell m}^{*},\\\mathbf {\Phi } _{\ell ,-m}&=(-1)^{m}\mathbf {\Phi } _{\ell m}^{*},\end{aligned}}}
which cuts the number of independent functions roughly in half. The star indicates complex conjugation .
The VSH are orthogonal in the usual three-dimensional way at each point
r
{\displaystyle \mathbf {r} }
:
Y
ℓ
m
(
r
)
⋅
Ψ
ℓ
m
(
r
)
=
0
,
Y
ℓ
m
(
r
)
⋅
Φ
ℓ
m
(
r
)
=
0
,
Ψ
ℓ
m
(
r
)
⋅
Φ
ℓ
m
(
r
)
=
0.
{\displaystyle {\begin{aligned}\mathbf {Y} _{\ell m}(\mathbf {r} )\cdot \mathbf {\Psi } _{\ell m}(\mathbf {r} )&=0,\\\mathbf {Y} _{\ell m}(\mathbf {r} )\cdot \mathbf {\Phi } _{\ell m}(\mathbf {r} )&=0,\\\mathbf {\Psi } _{\ell m}(\mathbf {r} )\cdot \mathbf {\Phi } _{\ell m}(\mathbf {r} )&=0.\end{aligned}}}
They are also orthogonal in Hilbert space:
∫
Y
ℓ
m
⋅
Y
ℓ
′
m
′
∗
d
Ω
=
δ
ℓ
ℓ
′
δ
m
m
′
,
∫
Ψ
ℓ
m
⋅
Ψ
ℓ
′
m
′
∗
d
Ω
=
ℓ
(
ℓ
1
)
δ
ℓ
ℓ
′
δ
m
m
′
,
∫
Φ
ℓ
m
⋅
Φ
ℓ
′
m
′
∗
d
Ω
=
ℓ
(
ℓ
1
)
δ
ℓ
ℓ
′
δ
m
m
′
,
∫
Y
ℓ
m
⋅
Ψ
ℓ
′
m
′
∗
d
Ω
=
0
,
∫
Y
ℓ
m
⋅
Φ
ℓ
′
m
′
∗
d
Ω
=
0
,
∫
Ψ
ℓ
m
⋅
Φ
ℓ
′
m
′
∗
d
Ω
=
0.
{\displaystyle {\begin{aligned}\int \mathbf {Y} _{\ell m}\cdot \mathbf {Y} _{\ell 'm'}^{*}\,d\Omega &=\delta _{\ell \ell '}\delta _{mm'},\\\int \mathbf {\Psi } _{\ell m}\cdot \mathbf {\Psi } _{\ell 'm'}^{*}\,d\Omega &=\ell (\ell 1)\delta _{\ell \ell '}\delta _{mm'},\\\int \mathbf {\Phi } _{\ell m}\cdot \mathbf {\Phi } _{\ell 'm'}^{*}\,d\Omega &=\ell (\ell 1)\delta _{\ell \ell '}\delta _{mm'},\\\int \mathbf {Y} _{\ell m}\cdot \mathbf {\Psi } _{\ell 'm'}^{*}\,d\Omega &=0,\\\int \mathbf {Y} _{\ell m}\cdot \mathbf {\Phi } _{\ell 'm'}^{*}\,d\Omega &=0,\\\int \mathbf {\Psi } _{\ell m}\cdot \mathbf {\Phi } _{\ell 'm'}^{*}\,d\Omega &=0.\end{aligned}}}
An additional result at a single point
r
{\displaystyle \mathbf {r} }
(not reported in Barrera et al, 1985) is, for all
ℓ
,
m
,
ℓ
′
,
m
′
{\displaystyle \ell ,m,\ell ',m'}
,
Y
ℓ
m
(
r
)
⋅
Ψ
ℓ
′
m
′
(
r
)
=
0
,
Y
ℓ
m
(
r
)
⋅
Φ
ℓ
′
m
′
(
r
)
=
0.
{\displaystyle {\begin{aligned}\mathbf {Y} _{\ell m}(\mathbf {r} )\cdot \mathbf {\Psi } _{\ell 'm'}(\mathbf {r} )&=0,\\\mathbf {Y} _{\ell m}(\mathbf {r} )\cdot \mathbf {\Phi } _{\ell 'm'}(\mathbf {r} )&=0.\end{aligned}}}
Vector multipole moments
edit
The orthogonality relations allow one to compute the spherical multipole moments of a vector field as
E
ℓ
m
r
=
∫
E
⋅
Y
ℓ
m
∗
d
Ω
,
E
ℓ
m
(
1
)
=
1
ℓ
(
ℓ
1
)
∫
E
⋅
Ψ
ℓ
m
∗
d
Ω
,
E
ℓ
m
(
2
)
=
1
ℓ
(
ℓ
1
)
∫
E
⋅
Φ
ℓ
m
∗
d
Ω
.
{\displaystyle {\begin{aligned}E_{\ell m}^{r}&=\int \mathbf {E} \cdot \mathbf {Y} _{\ell m}^{*}\,d\Omega ,\\E_{\ell m}^{(1)}&={\frac {1}{\ell (\ell 1)}}\int \mathbf {E} \cdot \mathbf {\Psi } _{\ell m}^{*}\,d\Omega ,\\E_{\ell m}^{(2)}&={\frac {1}{\ell (\ell 1)}}\int \mathbf {E} \cdot \mathbf {\Phi } _{\ell m}^{*}\,d\Omega .\end{aligned}}}
The gradient of a scalar field
edit
Given the multipole expansion of a scalar field
ϕ
=
∑
ℓ
=
0
∞
∑
m
=
−
ℓ
ℓ
ϕ
ℓ
m
(
r
)
Y
ℓ
m
(
θ
,
ϕ
)
,
{\displaystyle \phi =\sum _{\ell =0}^{\infty }\sum _{m=-\ell }^{\ell }\phi _{\ell m}(r)Y_{\ell m}(\theta ,\phi ),}
we can express its gradient in terms of the VSH as
∇
ϕ
=
∑
ℓ
=
0
∞
∑
m
=
−
ℓ
ℓ
(
d
ϕ
ℓ
m
d
r
Y
ℓ
m
ϕ
ℓ
m
r
Ψ
ℓ
m
)
.
{\displaystyle \nabla \phi =\sum _{\ell =0}^{\infty }\sum _{m=-\ell }^{\ell }\left({\frac {d\phi _{\ell m}}{dr}}\mathbf {Y} _{\ell m} {\frac {\phi _{\ell m}}{r}}\mathbf {\Psi } _{\ell m}\right).}
For any multipole field we have
∇
⋅
(
f
(
r
)
Y
ℓ
m
)
=
(
d
f
d
r
2
r
f
)
Y
ℓ
m
,
∇
⋅
(
f
(
r
)
Ψ
ℓ
m
)
=
−
ℓ
(
ℓ
1
)
r
f
Y
ℓ
m
,
∇
⋅
(
f
(
r
)
Φ
ℓ
m
)
=
0.
{\displaystyle {\begin{aligned}\nabla \cdot \left(f(r)\mathbf {Y} _{\ell m}\right)&=\left({\frac {df}{dr}} {\frac {2}{r}}f\right)Y_{\ell m},\\\nabla \cdot \left(f(r)\mathbf {\Psi } _{\ell m}\right)&=-{\frac {\ell (\ell 1)}{r}}fY_{\ell m},\\\nabla \cdot \left(f(r)\mathbf {\Phi } _{\ell m}\right)&=0.\end{aligned}}}
By superposition we obtain the divergence of any vector field:
∇
⋅
E
=
∑
ℓ
=
0
∞
∑
m
=
−
ℓ
ℓ
(
d
E
ℓ
m
r
d
r
2
r
E
ℓ
m
r
−
ℓ
(
ℓ
1
)
r
E
ℓ
m
(
1
)
)
Y
ℓ
m
.
{\displaystyle \nabla \cdot \mathbf {E} =\sum _{\ell =0}^{\infty }\sum _{m=-\ell }^{\ell }\left({\frac {dE_{\ell m}^{r}}{dr}} {\frac {2}{r}}E_{\ell m}^{r}-{\frac {\ell (\ell 1)}{r}}E_{\ell m}^{(1)}\right)Y_{\ell m}.}
We see that the component on Φ ℓm is always solenoidal .
For any multipole field we have
∇
×
(
f
(
r
)
Y
ℓ
m
)
=
−
1
r
f
Φ
ℓ
m
,
∇
×
(
f
(
r
)
Ψ
ℓ
m
)
=
(
d
f
d
r
1
r
f
)
Φ
ℓ
m
,
∇
×
(
f
(
r
)
Φ
ℓ
m
)
=
−
ℓ
(
ℓ
1
)
r
f
Y
ℓ
m
−
(
d
f
d
r
1
r
f
)
Ψ
ℓ
m
.
{\displaystyle {\begin{aligned}\nabla \times \left(f(r)\mathbf {Y} _{\ell m}\right)&=-{\frac {1}{r}}f\mathbf {\Phi } _{\ell m},\\\nabla \times \left(f(r)\mathbf {\Psi } _{\ell m}\right)&=\left({\frac {df}{dr}} {\frac {1}{r}}f\right)\mathbf {\Phi } _{\ell m},\\\nabla \times \left(f(r)\mathbf {\Phi } _{\ell m}\right)&=-{\frac {\ell (\ell 1)}{r}}f\mathbf {Y} _{\ell m}-\left({\frac {df}{dr}} {\frac {1}{r}}f\right)\mathbf {\Psi } _{\ell m}.\end{aligned}}}
By superposition we obtain the curl of any vector field:
∇
×
E
=
∑
ℓ
=
0
∞
∑
m
=
−
ℓ
ℓ
(
−
ℓ
(
ℓ
1
)
r
E
ℓ
m
(
2
)
Y
ℓ
m
−
(
d
E
ℓ
m
(
2
)
d
r
1
r
E
ℓ
m
(
2
)
)
Ψ
ℓ
m
(
−
1
r
E
ℓ
m
r
d
E
ℓ
m
(
1
)
d
r
1
r
E
ℓ
m
(
1
)
)
Φ
ℓ
m
)
.
{\displaystyle \nabla \times \mathbf {E} =\sum _{\ell =0}^{\infty }\sum _{m=-\ell }^{\ell }\left(-{\frac {\ell (\ell 1)}{r}}E_{\ell m}^{(2)}\mathbf {Y} _{\ell m}-\left({\frac {dE_{\ell m}^{(2)}}{dr}} {\frac {1}{r}}E_{\ell m}^{(2)}\right)\mathbf {\Psi } _{\ell m} \left(-{\frac {1}{r}}E_{\ell m}^{r} {\frac {dE_{\ell m}^{(1)}}{dr}} {\frac {1}{r}}E_{\ell m}^{(1)}\right)\mathbf {\Phi } _{\ell m}\right).}
The action of the Laplace operator
Δ
=
∇
⋅
∇
{\displaystyle \Delta =\nabla \cdot \nabla }
separates as follows:
Δ
(
f
(
r
)
Z
ℓ
m
)
=
(
1
r
2
∂
∂
r
r
2
∂
f
∂
r
)
Z
ℓ
m
f
(
r
)
Δ
Z
ℓ
m
,
{\displaystyle \Delta \left(f(r)\mathbf {Z} _{\ell m}\right)=\left({\frac {1}{r^{2}}}{\frac {\partial }{\partial r}}r^{2}{\frac {\partial f}{\partial r}}\right)\mathbf {Z} _{\ell m} f(r)\Delta \mathbf {Z} _{\ell m},}
where
Z
ℓ
m
=
Y
ℓ
m
,
Ψ
ℓ
m
,
Φ
ℓ
m
{\displaystyle \mathbf {Z} _{\ell m}=\mathbf {Y} _{\ell m},\mathbf {\Psi } _{\ell m},\mathbf {\Phi } _{\ell m}}
and
Δ
Y
ℓ
m
=
−
1
r
2
(
2
ℓ
(
ℓ
1
)
)
Y
ℓ
m
2
r
2
Ψ
ℓ
m
,
Δ
Ψ
ℓ
m
=
2
r
2
ℓ
(
ℓ
1
)
Y
ℓ
m
−
1
r
2
ℓ
(
ℓ
1
)
Ψ
ℓ
m
,
Δ
Φ
ℓ
m
=
−
1
r
2
ℓ
(
ℓ
1
)
Φ
ℓ
m
.
{\displaystyle {\begin{aligned}\Delta \mathbf {Y} _{\ell m}&=-{\frac {1}{r^{2}}}(2 \ell (\ell 1))\mathbf {Y} _{\ell m} {\frac {2}{r^{2}}}\mathbf {\Psi } _{\ell m},\\\Delta \mathbf {\Psi } _{\ell m}&={\frac {2}{r^{2}}}\ell (\ell 1)\mathbf {Y} _{\ell m}-{\frac {1}{r^{2}}}\ell (\ell 1)\mathbf {\Psi } _{\ell m},\\\Delta \mathbf {\Phi } _{\ell m}&=-{\frac {1}{r^{2}}}\ell (\ell 1)\mathbf {\Phi } _{\ell m}.\end{aligned}}}
Also note that this action becomes symmetric , i.e. the off-diagonal coefficients are equal to
2
r
2
ℓ
(
ℓ
1
)
{\textstyle {\frac {2}{r^{2}}}{\sqrt {\ell (\ell 1)}}}
, for properly normalized VSH.
First vector spherical harmonics
edit
ℓ
=
0
{\displaystyle \ell =0}
.
Y
00
=
1
4
π
r
^
,
Ψ
00
=
0
,
Φ
00
=
0
.
{\displaystyle {\begin{aligned}\mathbf {Y} _{00}&={\sqrt {\frac {1}{4\pi }}}{\hat {\mathbf {r} }},\\\mathbf {\Psi } _{00}&=\mathbf {0} ,\\\mathbf {\Phi } _{00}&=\mathbf {0} .\end{aligned}}}
ℓ
=
1
{\displaystyle \ell =1}
.
Y
10
=
3
4
π
cos
θ
r
^
,
Y
11
=
−
3
8
π
e
i
φ
sin
θ
r
^
,
{\displaystyle {\begin{aligned}\mathbf {Y} _{10}&={\sqrt {\frac {3}{4\pi }}}\cos \theta \,{\hat {\mathbf {r} }},\\\mathbf {Y} _{11}&=-{\sqrt {\frac {3}{8\pi }}}e^{i\varphi }\sin \theta \,{\hat {\mathbf {r} }},\end{aligned}}}
Ψ
10
=
−
3
4
π
sin
θ
θ
^
,
Ψ
11
=
−
3
8
π
e
i
φ
(
cos
θ
θ
^
i
φ
^
)
,
{\displaystyle {\begin{aligned}\mathbf {\Psi } _{10}&=-{\sqrt {\frac {3}{4\pi }}}\sin \theta \,{\hat {\mathbf {\theta } }},\\\mathbf {\Psi } _{11}&=-{\sqrt {\frac {3}{8\pi }}}e^{i\varphi }\left(\cos \theta \,{\hat {\mathbf {\theta } }} i\,{\hat {\mathbf {\varphi } }}\right),\end{aligned}}}
Φ
10
=
−
3
4
π
sin
θ
φ
^
,
Φ
11
=
3
8
π
e
i
φ
(
i
θ
^
−
cos
θ
φ
^
)
.
{\displaystyle {\begin{aligned}\mathbf {\Phi } _{10}&=-{\sqrt {\frac {3}{4\pi }}}\sin \theta \,{\hat {\mathbf {\varphi } }},\\\mathbf {\Phi } _{11}&={\sqrt {\frac {3}{8\pi }}}e^{i\varphi }\left(i\,{\hat {\mathbf {\theta } }}-\cos \theta \,{\hat {\mathbf {\varphi } }}\right).\end{aligned}}}
ℓ
=
2
{\displaystyle \ell =2}
.
Y
20
=
1
4
5
π
(
3
cos
2
θ
−
1
)
r
^
,
Y
21
=
−
15
8
π
sin
θ
cos
θ
e
i
φ
r
^
,
Y
22
=
1
4
15
2
π
sin
2
θ
e
2
i
φ
r
^
.
{\displaystyle {\begin{aligned}\mathbf {Y} _{20}&={\frac {1}{4}}{\sqrt {\frac {5}{\pi }}}\,(3\cos ^{2}\theta -1)\,{\hat {\mathbf {r} }},\\\mathbf {Y} _{21}&=-{\sqrt {\frac {15}{8\pi }}}\,\sin \theta \,\cos \theta \,e^{i\varphi }\,{\hat {\mathbf {r} }},\\\mathbf {Y} _{22}&={\frac {1}{4}}{\sqrt {\frac {15}{2\pi }}}\,\sin ^{2}\theta \,e^{2i\varphi }\,{\hat {\mathbf {r} }}.\end{aligned}}}
Ψ
20
=
−
3
2
5
π
sin
θ
cos
θ
θ
^
,
Ψ
21
=
−
15
8
π
e
i
φ
(
cos
2
θ
θ
^
i
cos
θ
φ
^
)
,
Ψ
22
=
15
8
π
sin
θ
e
2
i
φ
(
cos
θ
θ
^
i
φ
^
)
.
{\displaystyle {\begin{aligned}\mathbf {\Psi } _{20}&=-{\frac {3}{2}}{\sqrt {\frac {5}{\pi }}}\,\sin \theta \,\cos \theta \,{\hat {\mathbf {\theta } }},\\\mathbf {\Psi } _{21}&=-{\sqrt {\frac {15}{8\pi }}}\,e^{i\varphi }\,\left(\cos 2\theta \,{\hat {\mathbf {\theta } }} i\cos \theta \,{\hat {\mathbf {\varphi } }}\right),\\\mathbf {\Psi } _{22}&={\sqrt {\frac {15}{8\pi }}}\,\sin \theta \,e^{2i\varphi }\,\left(\cos \theta \,{\hat {\mathbf {\theta } }} i\,{\hat {\mathbf {\varphi } }}\right).\end{aligned}}}
Φ
20
=
−
3
2
5
π
sin
θ
cos
θ
φ
^
,
Φ
21
=
15
8
π
e
i
φ
(
i
cos
θ
θ
^
−
cos
2
θ
φ
^
)
,
Φ
22
=
15
8
π
sin
θ
e
2
i
φ
(
−
i
θ
^
cos
θ
φ
^
)
.
{\displaystyle {\begin{aligned}\mathbf {\Phi } _{20}&=-{\frac {3}{2}}{\sqrt {\frac {5}{\pi }}}\sin \theta \,\cos \theta \,{\hat {\mathbf {\varphi } }},\\\mathbf {\Phi } _{21}&={\sqrt {\frac {15}{8\pi }}}\,e^{i\varphi }\,\left(i\cos \theta \,{\hat {\mathbf {\theta } }}-\cos 2\theta \,{\hat {\mathbf {\varphi } }}\right),\\\mathbf {\Phi } _{22}&={\sqrt {\frac {15}{8\pi }}}\,\sin \theta \,e^{2i\varphi }\,\left(-i\,{\hat {\mathbf {\theta } }} \cos \theta \,{\hat {\mathbf {\varphi } }}\right).\end{aligned}}}
Expressions for negative values of m are obtained by applying the symmetry relations.
The VSH are especially useful in the study of multipole radiation fields . For instance, a magnetic multipole is due to an oscillating current with angular frequency
ω
{\displaystyle \omega }
and complex amplitude
J
^
=
J
(
r
)
Φ
ℓ
m
,
{\displaystyle {\hat {\mathbf {J} }}=J(r)\mathbf {\Phi } _{\ell m},}
and the corresponding electric and magnetic fields, can be written as
E
^
=
E
(
r
)
Φ
ℓ
m
,
B
^
=
B
r
(
r
)
Y
ℓ
m
B
(
1
)
(
r
)
Ψ
ℓ
m
.
{\displaystyle {\begin{aligned}{\hat {\mathbf {E} }}&=E(r)\mathbf {\Phi } _{\ell m},\\{\hat {\mathbf {B} }}&=B^{r}(r)\mathbf {Y} _{\ell m} B^{(1)}(r)\mathbf {\Psi } _{\ell m}.\end{aligned}}}
Substituting into Maxwell equations, Gauss's law is automatically satisfied
∇
⋅
E
^
=
0
,
{\displaystyle \nabla \cdot {\hat {\mathbf {E} }}=0,}
while Faraday's law decouples as
∇
×
E
^
=
−
i
ω
B
^
⇒
{
ℓ
(
ℓ
1
)
r
E
=
i
ω
B
r
,
d
E
d
r
E
r
=
i
ω
B
(
1
)
.
{\displaystyle \nabla \times {\hat {\mathbf {E} }}=-i\omega {\hat {\mathbf {B} }}\quad \Rightarrow \quad {\begin{cases}{\dfrac {\ell (\ell 1)}{r}}E=i\omega B^{r},\\{\dfrac {dE}{dr}} {\dfrac {E}{r}}=i\omega B^{(1)}.\end{cases}}}
Gauss' law for the magnetic field implies
∇
⋅
B
^
=
0
⇒
d
B
r
d
r
2
r
B
r
−
ℓ
(
ℓ
1
)
r
B
(
1
)
=
0
,
{\displaystyle \nabla \cdot {\hat {\mathbf {B} }}=0\quad \Rightarrow \quad {\frac {dB^{r}}{dr}} {\frac {2}{r}}B^{r}-{\frac {\ell (\ell 1)}{r}}B^{(1)}=0,}
and Ampère–Maxwell's equation gives
∇
×
B
^
=
μ
0
J
^
i
μ
0
ε
0
ω
E
^
⇒
−
B
r
r
d
B
(
1
)
d
r
B
(
1
)
r
=
μ
0
J
i
ω
μ
0
ε
0
E
.
{\displaystyle \nabla \times {\hat {\mathbf {B} }}=\mu _{0}{\hat {\mathbf {J} }} i\mu _{0}\varepsilon _{0}\omega {\hat {\mathbf {E} }}\quad \Rightarrow \quad -{\frac {B^{r}}{r}} {\frac {dB^{(1)}}{dr}} {\frac {B^{(1)}}{r}}=\mu _{0}J i\omega \mu _{0}\varepsilon _{0}E.}
In this way, the partial differential equations have been transformed into a set of ordinary differential equations.
Alternative definition
edit
Angular part of magnetic and electric vector spherical harmonics. Red and green arrows show the direction of the field. Generating scalar functions are also presented, only the first three orders are shown (dipoles, quadrupoles, octupoles).
In many applications, vector spherical harmonics are defined as fundamental set of the solutions of vector Helmholtz equation in spherical coordinates.[ 6] [ 7]
In this case, vector spherical harmonics are generated by scalar functions, which are solutions of scalar Helmholtz equation with the wavevector
k
{\displaystyle \mathbf {k} }
.
ψ
e
m
n
=
cos
m
φ
P
n
m
(
cos
ϑ
)
z
n
(
k
r
)
ψ
o
m
n
=
sin
m
φ
P
n
m
(
cos
ϑ
)
z
n
(
k
r
)
{\displaystyle {\begin{array}{l}{\psi _{emn}=\cos m\varphi P_{n}^{m}(\cos \vartheta )z_{n}({k}r)}\\{\psi _{omn}=\sin m\varphi P_{n}^{m}(\cos \vartheta )z_{n}({k}r)}\end{array}}}
here
P
n
m
(
cos
θ
)
{\displaystyle P_{n}^{m}(\cos \theta )}
are the associated Legendre polynomials , and
z
n
(
k
r
)
{\displaystyle z_{n}({k}r)}
are any of the spherical Bessel functions .
Vector spherical harmonics are defined as:
longitudinal harmonics
L
o
e
m
n
=
∇
ψ
o
e
m
n
{\displaystyle \mathbf {L} _{^{e}_{o}mn}=\mathbf {\nabla } \psi _{^{e}_{o}mn}}
magnetic harmonics
M
o
e
m
n
=
∇
×
(
r
ψ
o
e
m
n
)
{\displaystyle \mathbf {M} _{^{e}_{o}mn}=\nabla \times \left(\mathbf {r} \psi _{^{e}_{o}mn}\right)}
electric harmonics
N
o
e
m
n
=
∇
×
M
o
e
m
n
k
{\displaystyle \mathbf {N} _{^{e}_{o}mn}={\frac {\nabla \times \mathbf {M} _{^{e}_{o}mn}}{k}}}
Here we use harmonics real-valued angular part, where
m
≥
0
{\displaystyle m\geq 0}
, but complex functions can be introduced in the same way.
Let us introduce the notation
ρ
=
k
r
{\displaystyle \rho =kr}
. In the component form vector spherical harmonics are written as:
M
e
m
n
(
k
,
r
)
=
−
m
sin
(
θ
)
sin
(
m
φ
)
P
n
m
(
cos
(
θ
)
)
z
n
(
ρ
)
e
θ
−
cos
(
m
φ
)
d
P
n
m
(
cos
(
θ
)
)
d
θ
z
n
(
ρ
)
e
φ
{\displaystyle {\begin{aligned}{\mathbf {M} _{emn}(k,\mathbf {r} )=\qquad {{\frac {-m}{\sin(\theta )}}\sin(m\varphi )P_{n}^{m}(\cos(\theta ))}z_{n}(\rho )\mathbf {e} _{\theta }}\\{{}-\cos(m\varphi ){\frac {dP_{n}^{m}(\cos(\theta ))}{d\theta }}}z_{n}(\rho )\mathbf {e} _{\varphi }\end{aligned}}}
M
o
m
n
(
k
,
r
)
=
m
sin
(
θ
)
cos
(
m
φ
)
P
n
m
(
cos
(
θ
)
)
z
n
(
ρ
)
e
θ
−
sin
(
m
φ
)
d
P
n
m
(
cos
(
θ
)
)
d
θ
z
n
(
ρ
)
e
φ
{\displaystyle {\begin{aligned}{\mathbf {M} _{omn}(k,\mathbf {r} )=\qquad {{\frac {m}{\sin(\theta )}}\cos(m\varphi )P_{n}^{m}(\cos(\theta ))}}z_{n}(\rho )\mathbf {e} _{\theta }\\{{}-\sin(m\varphi ){\frac {dP_{n}^{m}(\cos(\theta ))}{d\theta }}z_{n}(\rho )\mathbf {e} _{\varphi }}\end{aligned}}}
N
e
m
n
(
k
,
r
)
=
z
n
(
ρ
)
ρ
cos
(
m
φ
)
n
(
n
1
)
P
n
m
(
cos
(
θ
)
)
e
r
cos
(
m
φ
)
d
P
n
m
(
cos
(
θ
)
)
d
θ
1
ρ
d
d
ρ
[
ρ
z
n
(
ρ
)
]
e
θ
−
m
sin
(
m
φ
)
P
n
m
(
cos
(
θ
)
)
sin
(
θ
)
1
ρ
d
d
ρ
[
ρ
z
n
(
ρ
)
]
e
φ
{\displaystyle {\begin{aligned}{\mathbf {N} _{emn}(k,\mathbf {r} )=\qquad {\frac {z_{n}(\rho )}{\rho }}\cos(m\varphi )n(n 1)P_{n}^{m}(\cos(\theta ))\mathbf {e} _{\mathbf {r} }}\\{{} \cos(m\varphi ){\frac {dP_{n}^{m}(\cos(\theta ))}{d\theta }}}{\frac {1}{\rho }}{\frac {d}{d\rho }}\left[\rho z_{n}(\rho )\right]\mathbf {e} _{\theta }\\{{}-m\sin(m\varphi ){\frac {P_{n}^{m}(\cos(\theta ))}{\sin(\theta )}}}{\frac {1}{\rho }}{\frac {d}{d\rho }}\left[\rho z_{n}(\rho )\right]\mathbf {e} _{\varphi }\end{aligned}}}
N
o
m
n
(
k
,
r
)
=
z
n
(
ρ
)
ρ
sin
(
m
φ
)
n
(
n
1
)
P
n
m
(
cos
(
θ
)
)
e
r
sin
(
m
φ
)
d
P
n
m
(
cos
(
θ
)
)
d
θ
1
ρ
d
d
ρ
[
ρ
z
n
(
ρ
)
]
e
θ
m
cos
(
m
φ
)
P
n
m
(
cos
(
θ
)
)
sin
(
θ
)
1
ρ
d
d
ρ
[
ρ
z
n
(
ρ
)
]
e
φ
{\displaystyle {\begin{aligned}\mathbf {N} _{omn}(k,\mathbf {r} )=\qquad {\frac {z_{n}(\rho )}{\rho }}\sin(m\varphi )n(n 1)P_{n}^{m}(\cos(\theta ))\mathbf {e} _{\mathbf {r} }\\{} \sin(m\varphi ){\frac {dP_{n}^{m}(\cos(\theta ))}{d\theta }}{\frac {1}{\rho }}{\frac {d}{d\rho }}\left[\rho z_{n}(\rho )\right]\mathbf {e} _{\theta }\\{} {m\cos(m\varphi ){\frac {P_{n}^{m}(\cos(\theta ))}{\sin(\theta )}}}{\frac {1}{\rho }}{\frac {d}{d\rho }}\left[\rho z_{n}(\rho )\right]\mathbf {e} _{\varphi }\end{aligned}}}
There is no radial part for magnetic harmonics. For electric harmonics, the radial part decreases faster than angular, and for big
ρ
{\displaystyle \rho }
can be neglected. We can also see that for electric and magnetic harmonics angular parts are the same up to permutation of the polar and azimuthal unit vectors, so for big
ρ
{\displaystyle \rho }
electric and magnetic harmonics vectors are equal in value and perpendicular to each other.
Longitudinal harmonics:
L
o
e
m
n
(
k
,
r
)
=
∂
∂
r
z
n
(
k
r
)
P
n
m
(
cos
θ
)
sin
cos
m
φ
e
r
1
r
z
n
(
k
r
)
∂
∂
θ
P
n
m
(
cos
θ
)
sin
cos
m
φ
e
θ
∓
m
r
sin
θ
z
n
(
k
r
)
P
n
m
(
cos
θ
)
cos
sin
m
φ
e
φ
{\displaystyle {\begin{aligned}\mathbf {L} _{^{e}_{o}{mn}}(k,\mathbf {r} ){}=\qquad &{\frac {\partial }{\partial r}}z_{n}(kr)P_{n}^{m}(\cos \theta ){^{\cos }_{\sin }}{m\varphi }\mathbf {e} _{r}\\{} {}&{\frac {1}{r}}z_{n}(kr){\frac {\partial }{\partial \theta }}P_{n}^{m}(\cos \theta ){^{\cos }_{\sin }}m\varphi \mathbf {e} _{\theta }\\{}\mp {}&{\frac {m}{r\sin \theta }}z_{n}(kr)P_{n}^{m}(\cos \theta ){^{\sin }_{\cos }}m\varphi \mathbf {e} _{\varphi }\end{aligned}}}
The solutions of the Helmholtz vector equation obey the following orthogonality relations:[ 7]
∫
0
2
π
∫
0
π
L
o
e
m
n
⋅
L
o
e
m
n
sin
ϑ
d
ϑ
d
φ
=
(
1
δ
m
,
0
)
2
π
(
2
n
1
)
2
(
n
m
)
!
(
n
−
m
)
!
k
2
{
n
[
z
n
−
1
(
k
r
)
]
2
(
n
1
)
[
z
n
1
(
k
r
)
]
2
}
∫
0
2
π
∫
0
π
M
o
e
m
n
⋅
M
o
e
m
n
sin
ϑ
d
ϑ
d
φ
=
(
1
δ
m
,
0
)
2
π
2
n
1
(
n
m
)
!
(
n
−
m
)
!
n
(
n
1
)
[
z
n
(
k
r
)
]
2
∫
0
2
π
∫
0
π
N
o
e
m
n
⋅
N
o
e
m
n
sin
ϑ
d
ϑ
d
φ
=
(
1
δ
m
,
0
)
2
π
(
2
n
1
)
2
(
n
m
)
!
(
n
−
m
)
!
n
(
n
1
)
{
(
n
1
)
[
z
n
−
1
(
k
r
)
]
2
n
[
z
n
1
(
k
r
)
]
2
}
∫
0
π
∫
0
2
π
L
o
e
m
n
⋅
N
o
e
m
n
sin
ϑ
d
ϑ
d
φ
=
(
1
δ
m
,
0
)
2
π
(
2
n
1
)
2
(
n
m
)
!
(
n
−
m
)
!
n
(
n
1
)
k
{
[
z
n
−
1
(
k
r
)
]
2
−
[
z
n
1
(
k
r
)
]
2
}
{\displaystyle {\begin{aligned}\int _{0}^{2\pi }\int _{0}^{\pi }\mathbf {L} _{^{e}_{o}mn}\cdot \mathbf {L} _{^{e}_{o}mn}\sin \vartheta d\vartheta d\varphi &=(1 \delta _{m,0}){\frac {2\pi }{(2n 1)^{2}}}{\frac {(n m)!}{(n-m)!}}k^{2}\left\{n\left[z_{n-1}(kr)\right]^{2} (n 1)\left[z_{n 1}(kr)\right]^{2}\right\}\\[3pt]\int _{0}^{2\pi }\int _{0}^{\pi }\mathbf {M} _{^{e}_{o}mn}\cdot \mathbf {M} _{^{e}_{o}mn}\sin \vartheta d\vartheta d\varphi &=(1 \delta _{m,0}){\frac {2\pi }{2n 1}}{\frac {(n m)!}{(n-m)!}}n(n 1)\left[z_{n}(kr)\right]^{2}\\[3pt]\int _{0}^{2\pi }\int _{0}^{\pi }\mathbf {N} _{^{e}_{o}mn}\cdot \mathbf {N} _{^{e}_{o}mn}\sin \vartheta d\vartheta d\varphi &=(1 \delta _{m,0}){\frac {2\pi }{(2n 1)^{2}}}{\frac {(n m)!}{(n-m)!}}n(n 1)\left\{(n 1)\left[z_{n-1}(kr)\right]^{2} n\left[z_{n 1}(kr)\right]^{2}\right\}\\[3pt]\int _{0}^{\pi }\int _{0}^{2\pi }\mathbf {L} _{^{e}_{o}mn}\cdot \mathbf {N} _{^{e}_{o}mn}\sin \vartheta d\vartheta d\varphi &=(1 \delta _{m,0}){\frac {2\pi }{(2n 1)^{2}}}{\frac {(n m)!}{(n-m)!}}n(n 1)k\left\{\left[z_{n-1}(kr)\right]^{2}-\left[z_{n 1}(kr)\right]^{2}\right\}\end{aligned}}}
All other integrals over the angles between different functions or functions with different indices are equal to zero.
Rotation and inversion
edit
Illustration of the transformation of vector spherical harmonics under rotations. One can see that they are transformed in the same way as the corresponding scalar functions.
Under rotation, vector spherical harmonics are transformed through each other in the same way as the corresponding scalar spherical functions , which are generating for a specific type of vector harmonics. For example, if the generating functions are the usual spherical harmonics , then the vector harmonics will also be transformed through the Wigner D-matrices [ 8] [ 9] [ 10]
D
^
(
α
,
β
,
γ
)
Y
J
M
(
s
)
(
θ
,
φ
)
=
∑
M
′
=
−
J
J
[
D
M
M
′
(
J
)
(
α
,
β
,
γ
)
]
∗
Y
J
M
′
(
s
)
(
θ
,
φ
)
,
{\displaystyle {\hat {D}}(\alpha ,\beta ,\gamma )\mathbf {Y} _{JM}^{(s)}(\theta ,\varphi )=\sum _{M'=-J}^{J}[D_{MM'}^{(J)}(\alpha ,\beta ,\gamma )]^{*}\mathbf {Y} _{JM'}^{(s)}(\theta ,\varphi ),}
The behavior under rotations is the same for electrical, magnetic and longitudinal harmonics.
Under inversion, electric and longitudinal spherical harmonics behave in the same way as scalar spherical functions, i.e.
I
^
N
J
M
(
θ
,
φ
)
=
(
−
1
)
J
N
J
M
(
θ
,
φ
)
,
{\displaystyle {\hat {I}}\mathbf {N} _{JM}(\theta ,\varphi )=(-1)^{J}\mathbf {N} _{JM}(\theta ,\varphi ),}
and magnetic ones have the opposite parity:
I
^
M
J
M
(
θ
,
φ
)
=
(
−
1
)
J
1
M
J
M
(
θ
,
φ
)
,
{\displaystyle {\hat {I}}\mathbf {M} _{JM}(\theta ,\varphi )=(-1)^{J 1}\mathbf {M} _{JM}(\theta ,\varphi ),}
In the calculation of the Stokes' law for the drag that a viscous fluid exerts on a small spherical particle, the velocity distribution obeys Navier–Stokes equations neglecting inertia, i.e.,
0
=
∇
⋅
v
,
0
=
−
∇
p
η
∇
2
v
,
{\displaystyle {\begin{aligned}0&=\nabla \cdot \mathbf {v} ,\\\mathbf {0} &=-\nabla p \eta \nabla ^{2}\mathbf {v} ,\end{aligned}}}
with the boundary conditions
v
=
{
0
r
=
a
,
−
U
0
r
→
∞
.
{\displaystyle \mathbf {v} ={\begin{cases}\mathbf {0} &r=a,\\-\mathbf {U} _{0}&r\to \infty .\end{cases}}}
where U is the relative velocity of the particle to the fluid far from the particle. In spherical coordinates this velocity at infinity can be written as
U
0
=
U
0
(
cos
θ
r
^
−
sin
θ
θ
^
)
=
U
0
(
Y
10
Ψ
10
)
.
{\displaystyle \mathbf {U} _{0}=U_{0}\left(\cos \theta \,{\hat {\mathbf {r} }}-\sin \theta \,{\hat {\mathbf {\theta } }}\right)=U_{0}\left(\mathbf {Y} _{10} \mathbf {\Psi } _{10}\right).}
The last expression suggests an expansion in spherical harmonics for the liquid velocity and the pressure
p
=
p
(
r
)
Y
10
,
v
=
v
r
(
r
)
Y
10
v
(
1
)
(
r
)
Ψ
10
.
{\displaystyle {\begin{aligned}p&=p(r)Y_{10},\\\mathbf {v} &=v^{r}(r)\mathbf {Y} _{10} v^{(1)}(r)\mathbf {\Psi } _{10}.\end{aligned}}}
Substitution in the Navier–Stokes equations produces a set of ordinary differential equations for the coefficients.
Here the following definitions are used:
Y
e
m
n
=
cos
m
φ
P
n
m
(
cos
θ
)
Y
o
m
n
=
sin
m
φ
P
n
m
(
cos
θ
)
{\displaystyle {\begin{aligned}Y_{emn}&=\cos m\varphi P_{n}^{m}(\cos \theta )\\Y_{omn}&=\sin m\varphi P_{n}^{m}(\cos \theta )\end{aligned}}}
X
o
e
m
n
(
k
k
)
=
∇
×
(
k
Y
e
o
m
n
(
k
k
)
)
{\displaystyle \mathbf {X} _{^{e}_{o}mn}\left({\frac {\mathbf {k} }{k}}\right)=\nabla \times \left(\mathbf {k} Y_{^{o}_{e}mn}\left({\frac {\mathbf {k} }{k}}\right)\right)}
Z
e
o
m
n
(
k
k
)
=
i
k
k
×
X
o
e
m
n
(
k
k
)
{\displaystyle \mathbf {Z} _{^{o}_{e}mn}\left({\frac {\mathbf {k} }{k}}\right)=i{\frac {\mathbf {k} }{k}}\times \mathbf {X} _{^{e}_{o}mn}\left({\frac {\mathbf {k} }{k}}\right)}
In case, when instead of
z
n
{\displaystyle z_{n}}
are spherical Bessel functions , with help of plane wave expansion one can obtain the following integral relations:[ 11]
N
p
m
n
(
1
)
(
k
,
r
)
=
i
−
n
4
π
∫
Z
p
m
n
(
k
k
)
e
i
k
⋅
r
d
Ω
k
{\displaystyle \mathbf {N} _{pmn}^{(1)}(k,\mathbf {r} )={\frac {i^{-n}}{4\pi }}\int \mathbf {Z} _{pmn}\left({\frac {\mathbf {k} }{k}}\right)e^{i\mathbf {k} \cdot \mathbf {r} }d\Omega _{k}}
M
p
m
n
(
1
)
(
k
,
r
)
=
i
−
n
4
π
∫
X
p
m
n
(
k
k
)
e
i
k
⋅
r
d
Ω
k
{\displaystyle \mathbf {M} _{pmn}^{(1)}(k,\mathbf {r} )={\frac {i^{-n}}{4\pi }}\int \mathbf {X} _{pmn}\left({\frac {\mathbf {k} }{k}}\right)e^{i\mathbf {k} \cdot \mathbf {r} }d\Omega _{k}}
In case, when
z
n
{\displaystyle z_{n}}
are spherical Hankel functions, one should use the different formulae.[ 12] [ 11] For vector spherical harmonics the following relations are obtained:
M
p
m
n
(
3
)
(
k
,
r
)
=
i
−
n
2
π
k
∬
−
∞
∞
d
k
‖
e
i
(
k
x
x
k
y
y
±
k
z
z
)
k
z
X
p
m
n
(
k
k
)
{\displaystyle \mathbf {M} _{pmn}^{(3)}(k,\mathbf {r} )={\frac {i^{-n}}{2\pi k}}\iint _{-\infty }^{\infty }dk_{\|}{\frac {e^{i\left(k_{x}x k_{y}y\pm k_{z}z\right)}}{k_{z}}}\mathbf {X} _{pmn}\left({\frac {\mathbf {k} }{k}}\right)}
N
p
m
n
(
3
)
(
k
,
r
)
=
i
−
n
2
π
k
∬
−
∞
∞
d
k
‖
e
i
(
k
x
x
k
y
y
±
k
z
z
)
k
z
Z
p
m
n
(
k
k
)
{\displaystyle \mathbf {N} _{pmn}^{(3)}(k,\mathbf {r} )={\frac {i^{-n}}{2\pi k}}\iint _{-\infty }^{\infty }dk_{\|}{\frac {e^{i\left(k_{x}x k_{y}y\pm k_{z}z\right)}}{k_{z}}}\mathbf {Z} _{pmn}\left({\frac {\mathbf {k} }{k}}\right)}
where
k
z
=
k
2
−
k
x
2
−
k
y
2
{\textstyle k_{z}={\sqrt {k^{2}-k_{x}^{2}-k_{y}^{2}}}}
, index
(
3
)
{\displaystyle (3)}
means, that spherical Hankel functions are used.
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^ D. A. Varhalovich, A. N. Moskalev, and V. K. Khersonskii, Quantum Theory of Angular Momentum [in Russian], Nauka, Leningrad (1975)
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