Simple-layer potential

An expression

$$ \tag{1 } u ( x) = \int\limits _ { S } h ( | x - y | ) f ( y) \ d \sigma ( y) , $$

where $ S $ is a closed Lyapunov surface (of class $ C ^ {1 , \lambda } $, cf. Lyapunov surfaces and curves) in the Euclidean space $ \mathbf R ^ {n} $, $ n \geq 2 $, separating $ \mathbf R ^ {n} $ into an interior domain $ D ^ {+} $ and an exterior domain $ D ^ {-} $; $ h ( | x - y | ) $ is a fundamental solution of the Laplace operator:

$$ h ( | x - y | ) = \ \left \{ $ \omega _ {n} = 2 \pi ^ {n/2} / \Gamma ( n / 2 ) $ is the area of the unit sphere in $ \mathbf R ^ {n} $; $ | x - y | $ is the distance between two points $ x $ and $ y $; and $ d \sigma ( y) $ is the area element on $ S $. If $ f \in C ^ {(} 0) ( S) $, then $ u $ is everywhere defined on $ \mathbf R ^ {n} $. A simple-layer potential is a particular case of a [[Newton potential|Newton potential]], generated by masses distributed on $ S $ with surface density $ f $, and with the following properties. In $ D ^ {+} $ and $ D ^ {-} $ a simple-layer potential $ u $ has derivatives of all orders, which can be calculated by differentiation under the integral sign, and satisfies the [[Laplace equation|Laplace equation]], $ \Delta u = 0 $, i.e. it is a [[Harmonic function|harmonic function]]. For $ n \geq 3 $ it is a function regular at infinity, $ u ( \infty ) = 0 $. A simple-layer potential is continuous throughout $ \mathbf R ^ {n} $, and $ u \in C ^ {( 0 , \nu ) } ( \mathbf R ^ {n} ) $ for any $ \nu $, $ 0 < \nu < \lambda $. When passing through the surface $ S $, the derivative along the outward normal $ \mathbf n _ {0} $ to $ S $ at a point $ y _ {0} \in S $ undergoes a discontinuity. The limit values of the normal derivative from $ D ^ {+} $ and $ D ^ {-} $ exist, are everywhere continuous on $ S $, and can be expressed, respectively, by the formula: $$ \tag{2 } \left . \lim\limits _ {x \rightarrow y _ {0} } \

\frac{du}{d \mathbf n _ {0} }

\right | _ {i} = \

\frac{d u ( y _ {0} ) }{d \mathbf n _ {0} }

-

\frac{f ( y _ {0} ) }{2}

,\  x \in D  ^ {+} ,

$$ $$ \left . \lim\limits _ {x \rightarrow y _ {0} } \frac{du}{d \mathbf n _ {0} }

\right | _ {e}  =  

\frac{d u ( y _ {0} ) }{d \mathbf n _ {0} }

+ 

\frac{f ( y _ {0} ) }{2}

,\  x \in D  ^ {-} ,

$$ where $$ \tag{3 }

\frac{d u ( y _ {0} ) }{d \mathbf n _ {0} }

 = \ 

\int\limits _ { S }

\frac \partial {\partial \mathbf n _ {0} }

h ( | y - y _ {0} | ) f ( y) d \sigma ( y ) $$ is the so-called direct value of the normal derivative of a simple-layer potential at a point $ y _ {0} \in S $. Moreover, $ ( d u / d \mathbf n _ {0} ) ( y _ {0} ) \in C ^ {( 0 , \nu ) } ( S) $ for all $ \nu $, $ 0 < \nu < \lambda $. If $ f( y) \in C ^ {( 0 , \nu ) } ( S) $, then the partial derivatives of $ u( x ) $ can be continuously extended to $ \overline{ {D ^ {+} }}\; $ and $ \overline{ {D ^ {-} }}\; $ as functions of the classes $ C ^ {( 0 , \nu ) } ( \overline{ {D ^ {+} }}\; ) $ and $ C ^ {( 0 , \nu ) } ( \overline{ {D ^ {-} }}\; ) $, respectively. In this case one also has $$

\frac{d u }{d \mathbf n _ {0} }

( y _ {0} )
\in  C ^ {( 0 , \lambda ) } ( S ) .

$$ These properties can be generalized in various directions. E.g., if $ f \in L _ {1} ( S) $, then $ u \in L _ {1} $ inside and on $ S $, formulas (2) hold almost everywhere on $ S $, and the integral in (3) is summable on $ S $. One has also studied properties of simple-layer potentials understood as integrals with respect to arbitrary Radon measures $ \mu $ concentrated on $ S $: $$ u ( x) = \int\limits h ( | x - y | ) \ d \mu ( y ) . $$ Here, also, $ u $ is a harmonic function outside $ S $, and formulas (2) hold almost everywhere on $ S $ with respect to the Lebesgue measure, where $ f ( y _ {0} ) $ is replaced by the derivative $ \mu ^ \prime ( y _ {0} ) $ of the measure. In definition (1) one can replace the fundamental solution of the Laplace equation by an arbitrary Lewy function of a general second-order elliptic operator with variable coefficients of class $ C ^ {( 0 , \lambda ) } $, replacing the normal derivative $ d / d \mathbf n _ {0} $ by the derivative along the co-normal. The properties listed remain true in this case (cf. [[#References|[2]]], [[#References|[3]]], [[#References|[4]]]). Simple-layer potentials are used in solving boundary value problems for elliptic equations. The solution of a second boundary value problem with prescribed normal derivative is represented as a simple-layer potential with unknown density $ f $; the use of (2) and (3) leads to a Fredholm integral equation of the second kind on $ S $ for $ f $( cf. [[#References|[2]]]–[[#References|[5]]]). In solving boundary value problems for parabolic equations one uses simple-layer heat potentials, of the form $$ v ( x , t ) = \ \int\limits _ { 0 } ^ { t } \int\limits _ { S } G ( x , t ; y , \tau ) f ( y , \tau ) d \sigma ( y) d \tau , $$ where $$ G ( x , t ; y , \tau ) = \

\frac{1}{( 2 \sqrt \pi ) ^ {n} ( t - \tau ) ^ {n/2} }

\mathop{\rm exp} \ 

\left [

\frac{- | x - y | ^ {2} }{4 ( t - \tau ) }

\right ] $$

is the fundamental solution of the heat equation in the $ n $- dimensional space, and $ f ( y , \tau ) $ is the density. The function $ v $ and its generalization to arbitrary second-order parabolic equations have properties analogous to those indicated for $ u $( cf. [3], [4], [6]).

References

Comments

See [a1] for simple-layer potentials on more general open sets in $ \mathbf R ^ {n} $.

References