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In physics and mathematics, Green's functions are auxiliary functions in the solution of linear partial differential equations. Green's function is named for the self-taught English mathematician George Green (1793 – 1841), who investigated electricity and magnetism in a thoroughly mathematical fashion. In 1828 Green published a privately printed booklet, introducing what is now called the Green function. This was ignored until William Thomson (Lord Kelvin) discovered it, recognized its great value and had it published nine years after Green's death. Bernhard Riemann gave it the name "Green function".^[1]

Definition

Let L_x be a given linear differential operator in n variables x = (x₁, x₂, ..., x_n), then the Green function of L_x is the function G(x,y) defined by

${\displaystyle L_{\mathbf {x} }G(\mathbf {x} ,\mathbf {y} )=\delta (\mathbf {x} -\mathbf {y} ),}$

where δ(x-y) is the Dirac delta function. Once G(x,y) is known, any differential equation involving L_x is formally solved. Suppose we want to solve,

${\displaystyle L_{\mathbf {x} }\,\phi (\mathbf {x} )=\rho (\mathbf {x} )}$

for a known right hand side ρ(x). The formal solution is

${\displaystyle \phi (\mathbf {x} )=\int \;G(\mathbf {x} ,\mathbf {y} )\;\rho (\mathbf {y} )\;\mathrm {d} \mathbf {y} .}$

The proof is by verification,

${\displaystyle L_{\mathbf {x} }\,\phi (\mathbf {x} )=\int \;L_{\mathbf {x} }\;G(\mathbf {x} ,\mathbf {y} )\;\rho (\mathbf {y} )\;\mathrm {d} \mathbf {y} =\int \;\delta (\mathbf {x} -\mathbf {y} )\;\rho (\mathbf {y} )\mathrm {d} \mathbf {y} =\rho (\mathbf {x} )}$

where in the last step the defining property of the Dirac delta function is used.

The integral operator that has the Green function as kernel may be seen as the inverse of a linear operator,

${\displaystyle L_{\mathbf {x} }\;\phi (\mathbf {x} )=\rho (\mathbf {x} )\quad \Longrightarrow \quad \phi (\mathbf {x} )=L_{\mathbf {x} }^{-1}\;\rho (\mathbf {x} )=\int G(\mathbf {x} ,\mathbf {y} )\rho (\mathbf {y} )\;\mathrm {d} \mathbf {y} .}$

It is illuminating to make the analogy with matrix equations. Let ${\displaystyle \mathbb {L} }$ and ${\displaystyle \mathbb {G} }$ be n×n matrices connected by

${\displaystyle \mathbb {L} \mathbb {G} =\mathbb {E} \quad \Longleftrightarrow \quad \left(\mathbb {L} \mathbb {G} \right)_{ij}=\delta _{ij},\quad {\hbox{i.e.,}}\quad \mathbb {G} =\mathbb {L} ^{-1},}$

then the solution of a matrix-vector equation is

${\displaystyle \mathbb {L} {\boldsymbol {\phi }}={\boldsymbol {\rho }}\quad \Longrightarrow \quad \phi _{i}=\sum _{j}\mathbb {G} _{ij}\rho _{j}.}$

Make the correspondence i ↔ x, j ↔ y, and compare the sum over j with the integral over y, and the correspondence is evident.

Example

We consider a case of three variables, n = 3 with x = (x, y, z).

The Green function of

${\displaystyle \nabla ^{2}\equiv \left({\frac {\partial ^{2}}{\partial x^{2}}}+{\frac {\partial ^{2}}{\partial y^{2}}}+{\frac {\partial ^{2}}{\partial z^{2}}}\right)}$

is

${\displaystyle G(\mathbf {x} ,\mathbf {y} )=-{\frac {1}{4\pi }}{\frac {1}{|\mathbf {x} -\mathbf {y} |}}.}$

As an important example of this Green function we mention that the formal solution of the Poisson equation of electrostatics, reading

${\displaystyle \nabla ^{2}\Phi (\mathbf {x} )=-{\frac {1}{\epsilon _{0}}}\rho (\mathbf {x} ),}$

where ε₀ is the electric constant and ρ is a charge distribution, is given by

${\displaystyle \Phi (\mathbf {x} )={\frac {1}{4\pi \epsilon _{0}}}\iiint \;{\frac {\rho (\mathbf {y} )}{|\mathbf {x} -\mathbf {y} |}}\;\mathrm {d} \mathbf {y} .}$

Indeed,

${\displaystyle \nabla ^{2}\Phi (\mathbf {x} )={\frac {1}{4\pi \epsilon _{0}}}\iiint \;\rho (\mathbf {y} )\nabla ^{2}{\frac {1}{|\mathbf {x} -\mathbf {y} |}}\;\mathrm {d} \mathbf {y} =-{\frac {4\pi }{4\pi \epsilon _{0}}}\iiint \;\rho (\mathbf {y} )\delta (\mathbf {x} -\mathbf {y} )\;\mathrm {d} \mathbf {y} =-{\frac {\rho (\mathbf {x} )}{\epsilon _{0}}}.}$

The integral form of the electrostatic field may be seen as a consequence of Coulomb's law. The field at the point x due to the charge dQ = ρ(y)dy is equal to

${\displaystyle d\Phi (\mathbf {x} )={\frac {dQ}{4\pi \epsilon _{0}|\mathbf {x} -\mathbf {y} |}}.}$

The field is additive in the charges, so integration gives the total field at x.

CC Image
Integration regions: yellow domain is U_ε, large sphere is V_R, small sphere is V_ε

Proof of Green function of ∇²

Without loss of generality we take x as the origin (0, 0, 0) and replace y by r = (x, y, z) in the above formulation. The length of r is indicated by r.

The proof uses Green's theorem:

${\displaystyle \iiint \limits _{V_{a}}{\Big (}\phi \nabla ^{2}{\frac {1}{r}}-{\frac {1}{r}}\nabla ^{2}\phi {\Big )}\,dV=\iint \limits _{S_{a}}{\big (}\phi {\boldsymbol {\nabla }}{\frac {1}{r}}{\big )}\cdot d\mathbf {S} -\iint \limits _{S_{a}}{\big (}{\frac {1}{r}}{\boldsymbol {\nabla }}\phi {\big )}\cdot d\mathbf {S} ,}$

where V_a is a sphere with radius a and S_a is the surface of this sphere. The smooth test function φ and its gradient vanish for large r,

${\displaystyle \phi (x,y,z)=0,\quad {\boldsymbol {\nabla }}\phi (x,y,z)=\mathbf {0} \quad {\hbox{for}}\quad r\geq R\quad {\hbox{with}}\quad r\equiv {\sqrt {x^{2}+y^{2}+z^{2}}}.}$

Further we notice that

${\displaystyle \nabla ^{2}{\frac {1}{r}}=0\quad {\hbox{for}}\quad r\in U_{\epsilon },}$

because r ≠ 0 in that region (see the figure, where the region is indicated in yellow). This result is most easily proved if we recall that in spherical polar coordinates

${\displaystyle \nabla ^{2}{\frac {1}{r}}={\frac {1}{r}}{\frac {\partial ^{2}r}{\partial r^{2}}}{\frac {1}{r}}={\frac {1}{r}}{\frac {\partial ^{2}}{\partial r^{2}}}1=0.}$

First apply Green's theorem to the large sphere of radius R

${\displaystyle \iiint \limits _{V_{R}}\phi \nabla ^{2}{\frac {1}{r}}\,dV=\iiint \limits _{V_{R}}{\frac {1}{r}}\nabla ^{2}\phi \,dV+\iint \limits _{S_{R}}{\big (}\phi {\boldsymbol {\nabla }}{\frac {1}{r}}{\big )}\cdot d\mathbf {S} -\iint \limits _{S_{R}}{\big (}{\frac {1}{r}}{\boldsymbol {\nabla }}\phi {\big )}\cdot d\mathbf {S} =\iiint \limits _{V_{R}}{\frac {1}{r}}\nabla ^{2}\phi \,dV}$

because by assumption φ and its gradient vanish on S_R.

We consider the integral on the right hand side and we will show that

${\displaystyle \iiint \limits _{V_{R}}{\frac {1}{r}}\nabla ^{2}\phi \,dV=-4\pi \phi (\mathbf {0} ),}$

from which the result to be proved follows directly. The main trick is to write

${\displaystyle \iiint \limits _{V_{R}}{\frac {1}{r}}\nabla ^{2}\phi \,dV=\lim _{\epsilon \rightarrow 0}\iiint \limits _{U_{\epsilon }}{\frac {1}{r}}\nabla ^{2}\phi \,dV}$

and to consider first the integral over U_ε (the yellow domain in the figure) for non-zero, but small, ε. After the integral has been evaluated, the limit for zero ε is taken.

Since U_ε has two surfaces, Green's theorem cannot be applied directly, and therefore we write (see the figure),

${\displaystyle \iiint \limits _{U_{\epsilon }}=\iiint \limits _{V_{R}}-\iiint \limits _{V_{\epsilon }}}$

and apply Green's theorem to the two terms. Recalling that we saw already the first term, we get

${\displaystyle {\begin{aligned}\iiint \limits _{U_{\epsilon }}{\frac {1}{r}}\nabla ^{2}\phi \,dV&=\left[\iiint \limits _{V_{R}}\phi \nabla ^{2}{\frac {1}{r}}\,dV-\iiint \limits _{V_{\epsilon }}\phi \nabla ^{2}{\frac {1}{r}}\,dV\right]+\iint \limits _{S_{\epsilon }}{\big (}\phi {\boldsymbol {\nabla }}{\frac {1}{r}}{\big )}\cdot d\mathbf {S} -\iint \limits _{S_{\epsilon }}{\big (}{\frac {1}{r}}{\boldsymbol {\nabla }}\phi {\big )}\cdot d\mathbf {S} \\&=\left[\iiint \limits _{U_{\epsilon }}\phi \nabla ^{2}{\frac {1}{r}}\,dV\right]+\iint \limits _{S_{\epsilon }}{\big (}\phi {\boldsymbol {\nabla }}{\frac {1}{r}}{\big )}\cdot d\mathbf {S} -\iint \limits _{S_{\epsilon }}{\big (}{\frac {1}{r}}{\boldsymbol {\nabla }}\phi {\big )}\cdot d\mathbf {S} \\\end{aligned}}}$

The integral between square brackets is zero because ∇²(1/r) is zero on U_ε. The last integral can be shown to vanish for small ε. Because φ and its gradient are smooth and finite, and r is constant (equal to ε) on the surface, we may write for small ε

${\displaystyle \iint \limits _{S_{\epsilon }}{\big (}{\frac {1}{r}}{\boldsymbol {\nabla }}\phi {\big )}\cdot d\mathbf {S} \approx {\frac {\langle \mathbf {n} \cdot {\boldsymbol {\nabla }}\phi (\epsilon )\rangle }{\epsilon }}\iint \limits _{S_{\epsilon }}dS=4\pi \epsilon \langle \mathbf {n} \cdot {\boldsymbol {\nabla }}\phi (\epsilon )\rangle \rightarrow 0,}$

where we assumed that

${\displaystyle {\boldsymbol {\nabla }}\phi (\mathbf {r} )\cdot d\mathbf {S} ={\boldsymbol {\nabla }}\phi (\mathbf {r} )\cdot \mathbf {n} \;dS\approx \langle {\boldsymbol {\nabla }}\phi (\epsilon )\cdot \mathbf {n} \rangle \;dS}$

and that the value of the gradient averaged over the surface may be taken out of the integral. The remaining surface integral is equal to 4πε².

In order to evaluate the final integral we use

${\displaystyle {\boldsymbol {\nabla }}{\frac {1}{r}}=-{\frac {\mathbf {r} }{r^{3}}}\equiv -{\frac {\mathbf {e} _{r}}{r^{2}}}\qquad {\hbox{and}}\qquad d\mathbf {S} =\mathbf {e} _{r}\;r^{2}\sin \theta \,d\phi d\theta }$

so that

${\displaystyle \iint \limits _{S_{\epsilon }}{\big (}\phi {\boldsymbol {\nabla }}{\frac {1}{r}}{\big )}\cdot d\mathbf {S} =-\iint \limits _{S_{\epsilon }}\phi (\mathbf {r} )\sin \theta \,d\phi d\theta =-\phi (\epsilon )\;4\pi .}$

Here we assumed that the test function φ(r) is constant over the surface (isotropic) for small ε. The limit ε → 0 gives the desired result.

Summarizing,

${\displaystyle \iiint \limits _{V_{R}}\phi \nabla ^{2}{\frac {1}{r}}\,dV=\iiint \limits _{V_{R}}{\frac {1}{r}}\nabla ^{2}\phi \,dV=-4\pi \phi (\mathbf {0} )=-4\pi \iiint \limits _{V_{R}}\delta (\mathbf {r} )\phi (\mathbf {r} )\,dV,}$

and

${\displaystyle \nabla ^{2}{\frac {1}{r}}=-4\pi \delta (\mathbf {r} )}$

References

• P. Roman, Advanced Quantum Theory, Addison-Wesley, Reading, Mass. (1965) Appendix 4.
• I. M. Gel'fand and G. E. Shilov, Generalized Functions, Vol. 1, Academic Press, New York (1964)