APPROXIMATE GRAVITATIONAL FIELD OF A ROTATING DEFORMED MASS 6 J.L. Hern´andez-Pastora∗ 0 0 2 n Abstract a J A new approximate solution of vacuum and stationary Einstein field 6 equations is obtained. This solution is constructed by means of a power 2 series expansion of the Ernst potential in terms of two independent and dimensionless parameters representing the quadrupole and the angular 1 momentum respectively. The main feature of the solution is a suitable v description of small deviations from spherical symmetry through pertur- 3 bations of the static configuration and the massive multipole structure 1 by using those parameters. This quality of the solution might eventually 1 provide relevant differences with respect to the description provided by 1 the Kerrsolution. 0 6 0 / c q PACS numbers: 04.25.Nx, 04.20.Cv, 04.20.-q - r g : v i X r a ∗Departamento deMatema´ticaAplicada. E.T.S.Ingenier´ıa IndustrialdeB´ejar. Universi- daddeSalamanca. Salamanca, Espan˜a. 1 1 Introduction Within the context of axisymmetric Einstein vacuum field equations, the good qualities of the Kerr solution [1] are well known and indeed this solution is the essential reference in the stationary domain, as is the Schwarzschild solution in the static one. We are dealing with an exact solution which is very simple and has a very interesting multipole moment structure in order to describe the gravitational field of compact bodies. The Kerr solution is written in terms of onlyoneparameter,namelya,whichrepresentstheangularmomentum(J)per unit mass. M being the mass - i.e. the order zero of the multipole moments-, all the other moments are proportionalto a power of this parameter a equal to each multipole order, [2], [4] M =M(ia)k (1) k It is worthwhile mentioning that all multipole moments of the Kerr solution equal the corresponding coefficient appearing in the expansion of its Ernst po- tential on the symmetry axis. This characteristic makes it easier to calculate the multipole moments of the solution by using the FHP algorithm [4]. All these reasons,among others, have led to this solution becoming the one most used for a broad range of purposes concerning the physical behaviour of test particles or properties of the gravitationalfields of celestial sources. By means of the multipole moments of any solution one can obtain relevant information about the physical properties of the gravitational field, and, for instance, the multipole structure (1) allows one to estimate the relative impor- tance of the successive multipole moments in terms of the parameter a, mainly for the sub-extreme case (J <<M). Nevertheless, since the Kerr solution is defined with only one arbitrary pa- rameter, it is not possible to distinguish the different contributions from the quadrupoleand angularmomentumterms, respectively,to any kind ofphysical eventdescribedbythis space-time. Itwouldbe veryuseful toquestionhowdif- ferent a solution is with respect to the Schwarzschild solution in order to know which different contributions (or the new physics involved) are introduced by a new solution when this has no spherical symmetry and this space-time is no longer static. To make such a description, a solution with more than one pa- rameter, themselves themselves related to different multipole moments, allows one to handle them independently. In this sense, some authors [6], [7] have supplied static and stationary solu- tionsoftheEinsteinvacuumfieldequations,withprescribedmultipolemoments, that attempt to describe slight deviations from the space-time with spherical symmetry. TheMonopole-QuadrupolesolutionMQ[6]isanexactaxisymmetric and static solution constructed in power series of a parameter q (dimensionless quadrupole moment), whereas the MJ solution [7] is a stationary approximate solution describing the space-time of a mass with angular momentum and is obtainedby anexpansiononthe symmetryaxisofthe Ernstpotentialinpower series of a dimensionless parameter . This solution represents successive cor- J 2 rections to the spherical symmetry due to the rotation, the sum of the series being the pure Monopole-Dynamic dipole vacuum solution. Onewayto providethe physicalcontenttothese solutionsconsistsinestab- lishing a link between their multipole moments and quantities measured from well defined and physically reasonable experiments. This was the purpose of paper[8],inwhichweestablishedsuchalinkbycalculatingthetotalprecession per revolution of gyroscopes circumventing the symmetry axis. As a second result, the possibility emerges of comparing different axisym- metricsolutionsintermofanobservablequantity(angleprecessedbythegyro- scope). In particular,differences in the contributionof the quadrupole moment and the angular momentum for the Erez-Rosen solution [9] and Kerr solution [1] were obtained with respect to the MQ(1) (see [6], [8] or a brief comment below) and MJ solutions respectively. Some works [10] have addressed the description of non-spherical collapse and the relevance of this circumstance on the fate of the collapse; and other works [24] study the influence of thermal conduction on the evolution of a self- gravitingsystemoutofhydrostaticequilibrium. Mostofthelifeofastar(atany stage of evolution), may be described on the basis of the quasi-static approxi- mation(slowlyevolvingregime),andthisis so,becausemostrelevantprocesses in star interiors take place on time scales that are usually much longer than the hydrostatic time scale [25], [26]. Instead of following the evolution of the system a long time after its departure from equilibrium, the system is evalu- ated inmediately after such a departure. Here ’ inmediately’ means on a time scaleof the orderofthe thermalrelaxationtime, before the stablishmentof the steady-state resistiveflow. In doing so, it is avoidedthe introduction of numer- ical procedures which might lead to model-dependent conclusions, and for that evaluationofthesystem,ananalyticsolutionbecomesfundamentaltomakeuse ofsuitableapproximations;inparticular,itisveryimportanttohaveasolution constructed in a suitable way to describe the contributions to these scenarios of both the rotation and the quadrupole deformation separately. On the other hand,however,itis onlyobtainedindicationsabouttendency ofthe objectand not a complete description of its evolution. Then, it should be clear that, for sure, the numerical methods used to solve the complicated mathematical prob- lem arising at the study of non-spherical colapse scenarios are much better to obtain a complete description. As iswellknwon,the Weylmetrics[13]arestaticaxysymmetricsolutionsto vacuum Einstein equations which are given by the line element, ds2 = e2Ψdt2+e−2Ψ(e2γ(dρ2+dz2)+ρ2dφ2) (2) − where metric functions have to satisfy Ψ +ρ−1Ψ +Ψ =0 (3) ,ρρ ,ρ ,zz and γ =ρ(Ψ2 Ψ2) , γ =2ρΨ Ψ . (4) ,ρ ,ρ− ,z ,z ,ρ ,z 3 Observe that (3) is just the Laplace equation for Ψ (in the Euclidean space), and furthermore it represents the integrability condition for (4), implying that for any”Newtonian” potential we have a specific Weyl metric. Another inter- esting way ofwritting the generalsolutionof Laplaceequation, representingan asymptoticallyflatbehaviour,wasobtainedbyErez-Rosen[9]andQuevedo[12], integrating equations (3), (4) in prolate spheroidal coordinates. A sub-family of Weyl solutions has been obtained by Gutsunayev and Manko [11], starting from the Schwarzschildsolution as a seed solution. In [6], [21] the MQ solution was presented in the following way ∞ ΨM−Q =Ψq0 +qΨq1 +q2Ψq2 +...= XqαΨqα , (5) α=0 where the zeroth order Ψq0 corresponds to the Schwarzschild solution, and Ψqi are series that can be summed to obtain exact solutions of the Gutsunayev- Manko family [11] and the Erez-Rosenfamily as well [12]. It appears that each power in q adds a quadrupole correction to the spherically symmetric solution, the first one being referred to as MQ(1) [6]. It should be observed that due to the linearity of Laplace equation, these corrections give rise to a series of exact solutions,andso,the powerseriesofq maybe cut atanyorder,andthe partial summatory,uptothatorder,givesanexactsolutionrepresentingaquadrupolar correction to the Schwarzschild solution. The existence ofso many different (physicallydistinguishable [27]) Weyl so- lutionsgivesrisetothequestion: whichamongWeylsolutionsisbetter entitled to describe small deviations from spherical symmetry?. Although it should be obvious that such a question does not have a unique answer ( there is an in- finite number of ways of being non-spherical, so to speak), we shall invoke a verysimple criterion,emergingfromNewtoniangravity,inordertochoosethat solution: for example, massive multipole moments of an ellipsoid of rotation, with homogeneous density, mass M and axes (a,a,b) read: ( 2)n3Ma2nǫn(1 ǫ/2)n M = − − , ǫ (a b)/a, (6) 2n (2n+1)(2n+3) ≡ − M = 0 (7) 2n+1 becauseofthefactorǫn,thisequationclearlyexhibitstheprogressivedecreasing of the relevance of multipole moments as n increases. Same conclusion can be obtained for the multipole moments of rotation associated to a homogeneous distribution of charge, with total charge Q and ellipsoidal geometry with axes (a,a,b) [16]: J = 0 (8) 2n ( 2)n3Qa2n+2ǫn(1 ǫ/2)nΩ J = − − (9) 2n+1 (2n+1)(2n+3)(2n+5) Ω being the angular velocity of the rigid rotating distribution. 4 Thus, in order to describe small departures from sphericity, by means of a solutionofEinsteinequations,itwouldbe requieredasolutionwhosemultipole structure shares the property mentioned above. For that reason, the MQ solu- tionisparticularlysuitableforthestudyofperturbationsofsphericalsymmetry. Themainargumenttosupportthis statementisbasedonthe factthatthe pre- viously known Weyl [12] metrics (e.g. Gutsunayev-Manko, Manko, γ-metric [14], etc) present a drawback when describing quasi-spherical space-times. It consists of the fact that its multipole structure is such that all the moments higher than the quadrupole are of the same order as the quadrupole moment. Instead, as it is intuitively clear and as it is shown above for the classical case, therelevanceofsuchmultipolemomentsshoulddecreaseaswemovefromlower tohighermoments,thequadrupolemomentbeingthemosterelevantforasmall departure from sphericity. In[15],thebehaviourofgeodesicsiscomparedwiththesphericallysymmet- ric situation, throwing light on the sensitivity of the trajectories to deviations from spherical symmetry. The change of sign in the proper radial acceleration of test particles moving radially along the symmetry axis, close to the r =2M surface,andrelatedtothequadrupolemomentofthesourcedeservesparticular attention. The ultimate aim of the above works [6], [7] (see [16] for general expres- sions), and the main contribution of the solution presented here, is to obtain a hierarchy of solutions describing pure multipole moment space-times. Since 1918, when Schwarzschild published its static solution of the Einstein vacuum field equations, one of the more active topics of relativistic scientists is devoted to obtain exact solutions to those equations. So, up to now a lot of works have contributed not only with new solutions but developping several techniques to construct new solutions, specifically in the axial symmetry case, nevertheless with arbitrary, in general, physical content. Afterwards, main aim aroused was to get the correct physical interpretation of the solutions obtained. Some of thesesolutionsarealreadyknownandstudiedbutingeneralthereisnospecific methodwhichallowsus bothtounderstandwhichis the physicalrelevanceofa newsolutionaswellastoconstructsolutionswithprescribedphysicalbehaviour beyond of the symmetry properties of the problem. In [6], [7], a generalization of the classical gravitational field to General Relativity theory was planned, by describing the solution defined as the sum of different pure multipole con- tributions, (following an analogy of the solutions for the classical potential), constructedbymeansofsuitableharmonicsolutionsoftheLaplaceequation. A recentwork,[18],establishesthereciprocalrelationshipbetweenstaticsolutions with axial symmetry and any prescribed multipole structure. The authors in [17], [18] show how to obtain the Weyl moments required for constructing the pure multipole solutions sought. Although these works are highly relevant, we havenotyetageneralizationofthoseresultstothestationarygeneralcase,and this is the motivation of the solution presented here. The followingstepto the MQsolutionisthe pure multipole solution,which has only mass, angular momentum and quadrupole moment, referred to here- after as the MJQ solution. Here we present an approximation to this solution 5 bymeansofanexpansionofthecorrespondingErnstpotential. Itwillbeshown that the resulting solution is a very good candidate to describe corrections to the spherical and static configuration due to the rotation and the quadrupole deformation independently. For this exterior metric that is presented here (MJQ-solution) it would be veryinterestingtoconstructasource. Themotivationforthisistwofold: onthe onehand,itisalwaysinterestingtoproposeboundedandphysicallyreasonable sources of gravitational fields, which may serve as models of compact objects. On the other hand, spherical symmetry is a common assumption in the study of compact self-gravitating objects (white dwarfs, neutron stars, black holes). Therefore it is pertinent to ask, how do small deviations from this assumption , related to any kind of perturbation (e.g. fluctuations of the stellar matter, external perturbations, etc.), affect the properties of the system?. However, for sufficiently strong fields, in order to answer to this question it is necessary to deal with non-spherically symmetric solution of Einstein equations. Work towardsthis wayis inprogress,and, forexample,in[21]aninteriorsolutionfor the MQ(1) solution was already obtained. The paperisorganizedasfollows: Inthe nextsection,allrelevantequations are given; we develop the construction of the approximate MJQ solution and analyze of the behaviour of the solution for limiting cases. Reasons for appre- ciating the physical relevance of this solution and its meaningful contribution to the description of small deviations from spherical symmetry are given. Fi- nally, a discussionof the results is presentedin the last section, as well as some comments on forthcoming works and the proposals therein. 2 The MJQ Solution 2.1 The approximation of the solution In1968Ernst[23]showedasimplificationofthefieldequationsderivedfromthe vacuum stationary and axysymmetric Einstein equations. In order to do that, Ernst made use of a variationalprinciple on the Lagrangefunction constructed with the metric functions f and ω of the line element describing those metrics, which in Weyl canonical coordinates [13] reads as follows: ds2 = f(dt ωdφ)2+f−1[e2γ(dρ2+dz2)+ρ2dφ2] (10) − − being f, ω and γ functions only depending on (ρ,z). A very simple way to obtain the Ernst equations, is by means of a suitable rewrite of the field equations; a redefinition of the metric function ω is made by introducing a scalar function W whose existence is guaranteed by one of the Einstein field equations1. Then, the Ernst potential E is defined as a com- plex function whose real and imaginary part are the metric functions f and W respectively, the real part representing the norm of the Killing vector. 1Itcanbeprovedthatthe gradiantofthisscalarW isexactly theprojectionofthetwist ofthetimeKillingvector,describingstationarity,overthe3-dimensionalquotientmanifold 6 1 E On symmetry axis, the potential ξ, which is the transformation ξ − ≡ 1+E from the original Ernst potential, can be expanded by means of a power series of the inverse Weyl’s canonical coordinate z as follows: ∞ ξ(ρ=0,z)= Xmnz−(n+1) (11) n=0 where ρ represents the Weyl radial coordinate. In [7] a method was proposed for obtaining an approximate solution of the stationary vacuum Einstein field equations (MJ-solution or pure monopole- dynamic dipole solution) by means of an expansion of the Ernst potential ξ in power series of a dimensionless parameter, , directly related to the angular J momentum of the solution. The expansion to describe that solution (MJ) is quiteappropriate,sinceitisknownthatitsErnstpotentialonthesymmetryaxis canbe writtenintermsofsuccessivepowersofthatparameter. Thisconclusion is obtainedfromthe fact thatFodor,HoenselaersandPerj´es[4]havedeveloped an algorithm (FHP) which allows us to calculate the Geroch [3] and Hansen [2]relativisticmultipolemoments,relatedtoavacuumstationaryaxisymmetric solution,intermsofthecoefficients(m )oftheexpansiononthesymmetryaxis n of the Ernst potential ξ (11). Both the result obtained up to multipole order 10 by these authors, as well as the calculations we have carriedout up to order 20 [7], show that the relation between multipole moments and coefficients m n is triangular: that is to say, the multipole moment and the the corresponding coefficient m at every order differ in a certain combination of lesser order m n k coefficients. Therefore,theserelationscanbesuitablyinverted,anditenableus todetermine unequivocallythe coefficientsm whichdefine the Ernstpotential n ξ in terms of the multipole moments for any given solution. For example in [7] was obtained the coefficients which characterize the Ernst potential of the solutionhavingonlymassivemonopole(themass)anddynamicdipole(angular momentum). We are now looking for the stationary axisymmetric space-time whose mul- tipole moment structure only has angular momentum and quadrupole moment in addition to the mass. By imposing this condition on the coefficients of the series expansionof the Ernst potential along the symmetry axis (11) we obtain the following expressions (only the fists ones are shown, but they have been calculated up to order 20): m = M 0 m = iJ 1 m = Q 2 m = 0 3 1 1 m = MJ2+ M2Q 4 7 7 i 8 m = J3 i MJQ 5 −21 − 21 7 1 1 51 23 m = M4Q+ M3J2 MQ2 QJ2 (12) 6 21 21 − 231 − 231 J, Q and M being the angular momentum, the quadrupole moment and the mass of the solution respectively. This result leads to the Ernst potential ξ on the symmetry axis of the following type ∞ ∞ ξ(ρ=0,z)= X nXqkF(n,k) , (13) J n=0 k=0 J Q where i and q , and the double index function F(n,k) is a se- J≡ M2 ≡ M3 ries that contains information about the dependence on the Weyl coordinate, z, along the axis with the corresponding numerical factor derived from the M coefficients m (13). For instance, it can be seen that F(0,0) = and n z M2 F(1,0) = . Furthermore, by considering only k = 0 in the double sum z2 of (13), then the expression for the MJ solution can be obtained. Since we are interested in the description of slight deviations from spherical symmetry, we shall take into account the leading terms in the expansion (13) assuming that q, << 1, and neglecting terms involving powers or products J of both parameters. Thus, with these considerations the approximate solution up to order q and , describing the space-time with mass, angular momentum and quadrupole J moment, is given by the following Ernst potential on the symmetry axis: ξ(ρ=0,z)=ξ (ρ=0,z)+ξ (ρ=0,z) +ξ (ρ=0,z)q , (14) 0 1 2 J where M ξ (ρ=0,z) = (15) 0 z M2 ξ (ρ=0,z) = (16) 1 z2 ∞ ∞ F(0,1)≡ ξ2(ρ=0,z) =Xm2jz−(2j+1) =Xλˆ2j+1F2qj , (17) j=1 j=1 M 15 withλˆ andFq = becauseweknowfromtheFHP ≡ z 2j (2j+3)(2j+1)(2j 1) − algorithm (see coefficients m of (13)) that the MJQ solution, up to order q n and , is defined by the following coefficients: J m =0 , m =Fq M2j+1q , j 1 . (18) 2j+1 2j 2j ∀ ≥ Now, in what follows, and according to the scheme developed in [7], we proceed to solve the Ernst equation [23], (ξξ⋆ 1) ξ =2ξ⋆( ξ)2 (19) − △ ∇ 8 to each order in and q for the full Ernst potential ξ, with the following form J ξ =ξ +ξ +ξ q (20) 0 1 2 J Thesetofconstantsappearinginthegeneralsolutionof(19)toeachorder,will bedeterminedbyrestrictingthesolutiononthesymmetryaxisandcomparison with expression (14). The zero order in and q gives J (ξ2 1) ξ =2ξ ( ξ )2 , (21) 0 − △ 0 0 ∇ 0 and we take ξ to be the Ernst potential corresponding to the Schwarzschild 0 solution. The first order in parameter , i.e., ξ is already obtained in [7] by solving 1 J the equation (ξ2 1) ξ 4ξ ξ ξ +2ξ ( ξ )2 =0 , (22) 0 − △ 1− 0∇ 0∇ 1 1 ∇ 0 and by imposing as a neighbourhood condition the known behaviour of the solution on the symmetry axis (16). It should be noted that the approximate solution to this order, which in prolate coordinates is written 1 y ξ =ξ +ξ = + , (23) 0 1J x x2J isthesameasthatarisingfromtheexpansionoftheKerrsolutiononparameter a =i up to first order. J M The first order in parameter q (ξ ) must fullfils the following equation: 2 ξ2+1 (ξ2 1) ξ 4ξ ξ ξ +2ξ ( ξ )2 0 =0 . (24) 0 − △ 2− 0∇ 0∇ 2 2 ∇ 0 ξ2 1 0 − This homogeneous equation can be simplified by means of the following redefi- nition of the function ξ : 2 ξ 2 ζ , (25) 2 ≡ ξ2 1 0 − whichleadstotheLaplaceequationforthefunctionζ . Itcanbeeasilychecked 2 that, as is known, the equation ζ = 0 is separable and the general solu- 2 △ tion with regular behaviour on the symmetry axis (y = 1) as well as in the ± neighbourhood of infinity, affords: ∞ ζ2 = XhqnQn(x)Pn(y) , (26) n=0 and therefore: ∞ 1 x2 ξ2 = −x2 XhqnQn(x)Pn(y) , (27) n=0 where x,y areprolatecoordinates;hq areconstantsofintegration,andQ (x), { } n n P (y) are associatedLegendre functions of the secondkind and Legendre poly- n nomials respectively. 9 In order to compare the restriction on the symmetry axis of this result (27) with expression (17), we rewrite (17) as follows: M2 z2 1 ξ (ρ=0,z)= − ξ (ρ=0,z) , (28) 2 z2 (cid:2)λˆ2 1 2 (cid:3) − and by carrying out an expansion on the parameter λˆ we have: ∞ ∞ ∞ z2 M2 z2 M ξ2(ρ=0,z)= −z2 (cid:2)Xλˆ2iXλˆ2j+1F2qj]= z−2 [Xλˆ2j+1Ijq(cid:3) , (29) i=0 j=1 j=1 j with the definition Ijq ≡ XF2qi. By using Lemma 4 of the Appendix in [7] we i=1 rewrite this expression in terms of associated Legendre functions of the second kind as follows: ∞ ∞ z2 M2 ξ2(ρ=0,z)= −z2 XIjqX(4i+1)L2i,2jQ2i(1/λˆ) , (30) j=1 i=j L being the coefficient of the Legendre polynomial of order 2i, with the 2i,2j power 2j of the variable. Reordering the sums, we obtain: z2 M2 ∞ i ξ2(ρ=0,z)= −z2 XQ2i(1/λˆ)(4i+1)XIjqL2i,2j . (31) i=1 j=1 We now calculate Iq for our case: j 5j(j2+2) 5 15 1 15 1 Iq = = + (32) j (2j+3)(2j+1) 4 − 8 2j+1 8 2j+3 z andby comparingexpression(27)onthe symmetryaxis(y = 1,x= ) with ± M (31), we conclude that: hq =0 n 0 (33) 2n+1 ∀ ≥ hq =0 0 n hq2n =−(4n+1)XIjqL2n,2j ∀n≥1 . j=1 Using (32), it can be verified that in the expression for the constants hq , i.e., 2n n n n 5 15L 15L hq2n =−(4n+1)[X4L2n,2j −X 8 2j2n+,21j +X 8 2j2n+,23j] , (34) j=0 j=0 j=0 for n 2 the two last terms are equal to zero (see Lemma 2 of the appendix in ≥ [7]), and taking into account the orthonormality of Legendre’s polynomials we have: 5 hq = (4n+1) , n 2 , (35) 2n −4 ∀ ≥ 10