Belinski–Zakharov transform explained

The Belinski–Zakharov (inverse) transform is a nonlinear transformation that generates new exact solutions of the vacuum Einstein's field equation. It was developed by Vladimir Belinski and Vladimir Zakharov in 1978.^[1] The Belinski–Zakharov transform is a generalization of the inverse scattering transform. The solutions produced by this transform are called gravitational solitons (gravisolitons). Despite the term 'soliton' being used to describe gravitational solitons, their behavior is very different from other (classical) solitons.^[2] In particular, gravitational solitons do not preserve their amplitude and shape in time, and up to June 2012 their general interpretation remains unknown. What is known however, is that most black holes (and particularly the Schwarzschild metric and the Kerr metric) are special cases of gravitational solitons.

Introduction

The Belinski–Zakharov transform works for spacetime intervals of the form

ds²=f(-d(x⁰⁾²+d(x¹⁾²⁾+g_abdx^adx^b

where we use Einstein's summation convention for

a,b=2,3

. It is assumed that both the function

and the matrix

g=g_ab

depend on the coordinates

x⁰

and

x¹

only. Despite being a specific form of the spacetime interval that depends only on two variables, it includes a great number of interesting solutions as special cases, such as the Schwarzschild metric, the Kerr metric, Einstein–Rosen metric, and many others.

In this case, Einstein's vacuum equation

R_\mu\nu=0

decomposes into two sets of equations for the matrix

g=g_ab

and the function

. Using light-cone coordinates

\zeta=x⁰+x^1,η=x⁰-x¹

, the first equation for the matrix

(\alphag_,\zetag^-1)_,η+(\alphag_,ηg^-1)_,\zeta=0

where

\alpha

is the square root of the determinant of

, namely

\detg=\alpha²

The second set of equations is

(lnf)_,\zeta=

	(ln\alpha)_,\zeta\zeta
	(ln\alpha)_,\zeta

	\alpha
	4\alpha_,\zeta

\operatorname{tr}(g_,\zetag^-1g_,\zetag^-1)

(lnf)_,η=

	(ln\alpha)_,ηη
	(ln\alpha)_,η

	\alpha
	4\alpha_,η

\operatorname{tr}(g_,ηg^-1g_,ηg^-1)

Taking the trace of the matrix equation for

reveals that in fact

\alpha

satisfies the wave equation

\alpha_,\zetaη=0

The Lax pair

Consider the linear operators

D_1,D₂

defined by

D₁=\partial_\zeta+

	2\alpha_,\zetaλ
	λ-\alpha

\partial_λ

D₂=\partial_η-

	2\alpha_,ηλ
	λ+\alpha

\partial_λ

where

is an auxiliary complex spectral parameter.A simple computation shows that since

\alpha

satisfies the wave equation,

\left[D_1,D_2\right]=0

. This pair of operators commute, this is the Lax pair.

The gist behind the inverse scattering transform is rewriting the nonlinear Einstein equation as an overdetermined linear system of equation for a new matrix function

\psi=\psi(\zeta,η,λ)

. Consider the Belinski–Zakharov equations:

D₁\psi=

	A
	λ-\alpha

\psi

D₂\psi=

	B
	λ+\alpha

\psi

By operating on the left-hand side of the first equation with

D₂

and on the left-hand side of the second equation with

D₁

and subtracting the results, the left-hand side vanishes as a result of the commutativity of

D₁

and

D₂

. As for the right-hand side, a short computation shows that indeed it vanishes as well precisely when

satisfies the nonlinear matrix Einstein equation.

This means that the overdetermined linear Belinski–Zakharov equations are solvable simultaneously exactly when

solves the nonlinear matrix equation . Actually, one can easily restore

from the matrix-valued function

\psi

by a simple limiting process. Taking the limit

λ → 0

in the Belinski-Zakharov equations and multiplying by

\psi^-1

from the right gives

\psi_,\zeta\psi^-1=g_,\zetag^-1

\psi_,η\psi^-1=g_,ηg^-1

Thus a solution of the nonlinear

equation is obtained from a solution of the linear Belinski–Zakharov equation by a simple evaluation

g(\zeta,η)=\psi(\zeta,η,0)

Notes and References

V. . Belinskii . V. . Zakharov . Integration of the Einstein Equations by Means of the Inverse Scattering Problem Technique and Construction of Exact Soliton Solutions . Sov. Phys. JETP . 48 . 6 . 1978 . 985–994 . 0038-5646 .
Book: Belinski, V. . E. . Verdaguer . Gravitational Solitons . Cambridge Monographs on Mathematical Physics . 2001 .