748 lines
22 KiB
Plaintext
748 lines
22 KiB
Plaintext
arXiv:physics/9906004v1 [physics.hist-ph] 2 Jun 1999
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Mechanics. - On the analytic expression that must be given to the gravitational tensor in Einstein’s theory †
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Note by the Fellow
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T. Levi-Civita
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translation and foreword by S. Antoci∗ and A. Loinger∗∗
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Foreword. While most textbooks of general relativity and research articles discuss at length the relative merits of the pseudo tensors proposed by Einstein and by other authors for representing the energy of the gravitational field, Levi Civita’s definition of a true gravitational energy tensor has succumbed to Einstein’s authority and is nearly forgotten. It seems however worthy of a careful re-examination, due to its unquestionable logical soundness and to the unique manner of propagation for gravitational energy that it entails.
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In the present Note, after having recalled, for the reader’s convenience, the leading idea and the mathematical framework of general relativity, I show how some identities (involving the derivatives of the Riemann symbols) discovered by Bianchi offer a sure criterion for introducing the so called gravitational tensor. From the analytic standpoint one has to do with a double symmetric system Aik (i, k = 0, 1, 2, 3), whose ten elements completely define the gravitational contribution to the local mechanical behaviour. In fact they determine the stresses as well as the energy flow and the energy density (of gravitational origin). The mechanical meaning of the system requires an analytic structure endowed with convenient invariance properties with respect to co-ordinate transformations. Such is actually the (covariant) form of the Aik yielded by the above mentioned criterion. Furthermore this form provides a very expressive extension of d’Alembert’s principle.
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The idea of a gravitational tensor belongs to the great construction by Einstein. However its definition as given by the Author cannot be considered final. First of all, from the mathematical standpoint, it lacks the invariant character that it should instead necessarily enjoy according to the spirit of general relativity. Even worse is the fact, perceived with keen intuition by Einstein himself (1), that from such a definition it follows a clearly unacceptable consequence about the gravitational waves. For this point he however finds a way out in quantum theory.
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The solution is however less remote: everything depends on the incorrect form assumed for the gravitational tensor. We shall see that with our determination any possibility for paradox automatically disappears.
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1. Generalities. - In ordinary mechanics the physical space is taken to be strictly Euclidean, and the analytical representation of phenomena is, let us say, subordinated to the (ternary) quadratic differential form dl2 that expresses the square of the line element.
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In the restricted theory of relativity one persists in considering space as Euclidean; however the equations of mechanics are no longer invariant with respect to the form dl2; they are invariant
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† Rendiconti della Reale Accademia dei Lincei 26, 381 (1917).
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∗ Dipartimento di Fisica “A. Volta”, Universit`a di Pavia, Via Bassi 6 - 27100 Pavia (Italy). ∗∗ Dipartimento di Fisica, Universit`a di Milano, Via Celoria 16 - 20133 Milano (Italy).
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(1) N¨aherungweise Integration der Feldgleichungen der Gravitation, Sitzungsberichte der Kgl. Preussis-
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chen Ak. der Wiss., 1916, p. 696.
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1
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with respect to a quaternary form ds2 that implies also the time t. Notoriously it has the expression
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(1)
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ds2 = c2dt2 − dl2
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(c universal constant to be interpreted as velocity of light in vacuo). It is clear that, with reference to Cartesian co-ordinates, one has again
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dl2 = dx2 + dy2 + dz2.
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In general relativity - new and more comprehensive conception of the natural laws, again due to
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Einstein - space and time do not provide a plain localisation, inert and immutable, of phenomena. They are instead affected by the latter and they react in such a way as to change the nature of ds2.
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Instead of (1), one has the fundamental form
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3
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(2)
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ds2 = ik gikdxidxk,
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0
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which, with appropriate choice of the parameters x0, x1, x2, x3, reduces itself exactly to the form (1) in the limit case, when any physically perceptible action (either presence or motion of matter, of electricity, more generally of some form of energy) is lacking. As a rule, although quantitatively very close to the type (1), (2) must be considered as not given a priori, but intrinsically definable according to the factual circumstances. Among these it obviously appears also the universal gravitation, which, according to Einstein, deserves the privilege of depending exclusively on the coefficients gik (and on their derivatives).
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The equations of the new mechanics as a whole are invariant with respect to that well determined form (2) that pertains to the specific case. In this new mechanics the theory for a given class of phenomena necessarily entails, together with relations that have their counterpart in the previous formulations (classical and relativistic of the first manner), further relations whose scope is the determination of ds2. These are Einstein’s gravitational equations (in number of 10 like the coefficients gik), that we shall consider explicitly in § 6.
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2. Energy tensor. - The mechanics of continuous systems - also according to the ordinary scheme - leads to conclude that a mechanical phenomenon (occurring in a given range of values for x, y, z, t) is well known when the following elements: stresses, momentum, energy flow and energy density, are assigned (as functions of position and of time).
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In relativistic mechanics the vector q, that represents the momentum density, is linked to the energy flow χ by the relation
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q
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=
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1 c2
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χ.
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It is convenient to avail of the single vector
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(3)
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−f
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=
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cq
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=
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1 c
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χ,
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that can be considered as the energy flow occurring in a light-second (time interval during which light travels the length unit). Let us notice, to avoid any misunderstanding, that we do not mean to fix in this way the time unit: it remains generic, like the other two fundamental units.
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Let us write for short
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2
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(4)
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y0 = ct, y1 = x, y2 = y, y3 = z.
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With reference to these variables, let us introduce a symmetric tensor Tik defined in this way: for i, k = 1, 2, 3, Tik is the component along the yk axis of the specific stress exerted on a surface element normal to the yi axis (2) (or vice versa, by exchanging i and k); Ti0 = T0i is identified with the component fi of the vector f ; T00 is finally the energy density.
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3. Reference to arbitrary co-ordinates. - If four arbitrary (independent) combinations x0, x1, x2, x3 are substituted for the yi, the form
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(1′)
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ds2 = c2dy02 − (dy12 + dy22 + dy32)
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takes the general expression (2). However the qualitative restrictions
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(5)
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g00 > 0, gii < 0 (i = 1, 2, 3),
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shall hold whenever the parameter x0 (individually varied) is apt to reflect the intuitive notion of time, while the remaining xi can in some way be interpreted as actual space co-ordinates.
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When this holds, we shall interpret as energy tensor in arbitrary co-ordinates xi that double covariant system Tik which, when referred to the y, is specified in the way shown above.
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From the very covariance formulae that define the elements of the system Tik one derives, for each of them, an interpretation in general co-ordinates x. And precisely one finds (3) that:
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√gTiiikgkk = √gTikigi kk (i, k = 1, 2, 3)
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represents the (orthogonal) component along the line xi (the one along which only xi varies) of the stress exerted on a surface element normal to the line xk (or vice versa, by exchanging i and k);
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√−Tgi000gii = √−Tg00i0gii (i = 1, 2, 3)
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represents the component of f along the line xi (when one imagines decomposing the vector f with respect to the trihedron of the co-ordinate lines); finally
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T00 g00
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is the density of the energy distribution in the space (x1, x2, x3), [to which the metric determination corresponding to −ds2 for dx0 = 0 is attributed].
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4. Linear invariant and divergence of the energy tensor. - We adhere to the usual notation of the absolute differential calculus. Therefore we represent with g(ik) the elements reciprocal to the coefficients gik, and with Tikl (i, k, l = 0, 1, 2, 3) the system covariantly derived from Tik according to the fundamental form. At present, as already in the previous §, we shall
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(2) with the convention (usual in hydrodynamics) that a positive normal stress corresponds to pressure. (3) Dwelling here on the way of deduction would be out of place. However I allow myself to notice that
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there is no need of actual calculations: one can avail of an appropriate adjustment of the methods of the
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absolute differential calculus to the indefinite ds2 that encompass space and time.
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3
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assume this form to be (1’) which, when referred to arbitrary co-ordinates x, takes the generic expression (2).
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By setting
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3
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(6)
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T = ik g(ik)Tik,
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0
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one defines an invariant, that is just called linear invariant or scalar of the energy tensor. One calls instead divergence of the same energy tensor the simple covariant system (or four-
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dimensional vector)
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3
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(7)
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Fi = kl g(kl)Tikl (i = 0, 1, 2, 3).
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0
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The mechanical meaning of the divergence (like the meaning of T , which I neglect to notice,
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because it is immediate) becomes clear when one goes back to the variables y. With respect to such variables g(ik) = 0 (i = k), g(00) = 1, g(ii) = −1 (i = 1, 2, 3), and the covariant differentiation
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coincides with the ordinary one.
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Then one has
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Fi
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=
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∂Ti0 ∂y0
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−
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3 1
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k
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∂Tik ∂yk
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(i = 1, 2, 3),
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F0
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=
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∂T00 ∂y0
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−
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3 1
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k
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∂T0k ∂yk
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.
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Let us remind of § 2 and notice that, due to (3), the components Ti0 are identical with −cqi
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(qi components of the momentum density q). Therefore it obviously appears from the first three
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equations written above (when ct is substituted for y0) that −Fi (i = 1, 2, 3) are components of the external force F applied to the system (per unit volume). The last equation, when [always
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according
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to
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(3)]
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the
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T0k
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are
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taken
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in
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the
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form
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−
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1 c
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χk
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(χk
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components
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of
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the
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energy
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flow
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χ),
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finally
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shows that cF0 is the power density, i.e. the energy given from outside to the system per time
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and volume units. One can also say, if desired, that F0 represents the energy given to the system
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per volume unit in a light-second. Hence it turns out in particular that for an isolated system the
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divergence is vanishing.
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When one avails as reference of arbitrary co-ordinates xi, the covariant character of the simple
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system Fi immediately allows one to interpret
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√−F1 −g11
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,
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√−F2 −g22
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,
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√−F3 −g33
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as components of F along the co-ordinate lines x1, x2, x3;
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√Fg000
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as energy given in one light-second to the unit volume of the system.
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5. Transition to general relativity. - Despite the reference to general co-ordinates, up to now we have supposed to deal with a Euclidean ds2. Formally the situation happens to be the same also with a ds2 essentially not reducible to the type (1’), if however:
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4
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a) x0 can be interpreted as time and the other three co-ordinates as space parameters since, in keeping with this, the inequalities (5) hold true;
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b) the usual mechanical intuitions are preserved (at an infinitesimal scale), hence it is possible to attribute a definite meaning to local measurements of force, stresses, energy flow and energy density. In such conditions the energy tensor is uniquely defined through the ratios
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√gTikigi kk
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(i, k = 1, 2, 3) ; √−Tg00i0gii
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(i = 1, 2, 3) ;
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T00 g00
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,
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given in § 3. We shall hereafter assume our ds2 to be a priori arbitrary (apart from the restrictions given
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above); naturally one shall take this ds2 as fundamental form.
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6. The equations of the gravitational field. - Let gij,hk (i, j, h, k = 0, 1, 2, 3) indicate the Riemann symbols of the first kind belonging to a generic quaternary ds2 like (2). Due to their covariance, the positions
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3
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(8)
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Gik = jh g(jh)gij,hk (i, k = 0, 1, 2, 3)
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0
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define a double covariant system. Let us remind of the formulae (4)
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3
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gij,hk = ν gjν {iν, hk},
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0
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{iν, hk}
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=
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∂ ∂xk
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ih ν
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−
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∂ ∂xh
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ik ν
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+
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3
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l
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0
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ih l
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lk
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ik
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−
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ν
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l
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lh
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,
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ν
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that connect the Riemannian symbols of the first kind with those of the second kind, and the latter with the Christoffel symbols (again of the second kind). One immediately recognises that (8) are equivalent to
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3
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Gik = h {ih, hk} =
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(8′)
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0
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=
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3
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h
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0
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∂ ∂xk
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ih h
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−
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∂ ∂xh
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ik h
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3
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+ hl
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0
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ih l
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kl
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ik
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−
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h
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l
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lh
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.
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h
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The linear invariant of the double system Gik
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3
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(9)
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G = ik g(ik)Gik
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0
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(4) Bianchi, Lezioni di geometria differenziale, vol. I [Pisa, Spoerri, 1902], p. 72.
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5
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will be called average curvature of our ds2 (5). With these positions, Einstein’s gravitational equations are:
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(10)
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Gik
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−
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1 2
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gik
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G
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=
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−κTik ,
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where κ depends on the constant f of universal gravitation and on c according to the formula
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(11)
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κ
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=
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8πf c4
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.
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I remark in passing that the homogeneity of both sides of (10) can be checked if one imagines
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referring to mutually homogeneous parameters x0, x1, x2, x3, e.g. lengths, like (for the Euclidean ds2) the y defined by the positions (4). The coefficients gik are then pure numbers, and the lefthand sides have clearly the dimensions l−2. On the other hand all the Tik (specific stresses apart from numerical factors, etc.) have in this case the same dimensions, and precisely ml−1t−2. One
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has further
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[f ] = m−1l3t−2 , [κ] = m−1l−1t2,
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hence also the right-hand sides have actually the dimensions l−2.
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7. Formal validation derived from the Bianchi identities. - The covariant derivatives of the Riemann symbols are linked by very remarkable relations due to Bianchi (6), that can be resumed in the formula
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gij,hkl + gjl,hki + gli,hkj = 0 (i, j, h, k, l = 0, 1, 2, 3), or, due to well known properties of the Riemann symbols, in the equivalent formula
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gij,hkl + gil,khj − glj,hki = 0.
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Let
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us
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multiply
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by
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1 2
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g(kl) g(j h)
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and
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sum
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with
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respect
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to
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k,
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l,
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j,
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h;
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when
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the
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sum
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is
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accomplished,
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let us exchange in the second term j with l and h with k. The second term thus becomes identical
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with the first, and one gets
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3
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kljh
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g(kl) g(j h) gij,hkl
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−
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1 2
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3
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kljh g(kl)g(jh)glj,hki = 0
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(i = 0, 1, 2, 3).
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0
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0
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On the other hand, the covariant differentiation of (8) - by reminding of Ricci’s lemma, according to which the coefficients of the fundamental form have vanishing covariant derivative - yields
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3
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Gikl = jh g(jh)gij,hkl.
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0
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From the expression (9) of G, that can be written as
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(5) This name is obviously derived from the geometric meaning that G would take, if ds2 would be positive
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definite.
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(6) see loc. cit., p. 351.
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6
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by covariant differentiation one gets
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3
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G = kl g(kl)Glk,
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0
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∂G ∂xi
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=
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Gi
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=
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3
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kl g(kl)Glki =
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0
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3
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kljh g(kl)g(jh)glj,hki.
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0
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The resulting combinations of the Bianchi identities thus become
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(12)
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3
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kl
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g(kl) Gikl
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−
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1 2
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Gi
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=
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0
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(i = 0, 1, 2, 3).
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0
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They contain the validation of the gravitational equations (10) from the mathematical standpoint.
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Here is why: the right-hand sides of (10) constitute a double system with vanishing divergence (7). If one requires the system (10) to be complete [i.e. no condition is imposed on ds2 beyond
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the exterior circumstances resumed in Tik], also the divergence of the first-hand sides, hence of the system
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Gik
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−
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1 2
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gik
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G,
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must identically vanish. This fact is just expressed by the equations (12).
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8. Gravitational (or inertial) tensor. - Generalisation of d’Alembert’s principle. - If we set for short
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(13)
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Aik
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=
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1 κ
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Gik
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−
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1 2
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gik
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G
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,
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the gravitational equations (10) read
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(10′ )
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Tik + Aik = 0 (i, k = 0, 1, 2, 3).
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In them we interpret Aik as components of an energy tensor due to the space-time environment, i.e. exclusively dependent on the coefficients of ds2. Such a tensor can be equally well named either gravitational or inertial (8) because both gravitation and inertia depend on ds2. Therefore (10’)
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give rise to the following proposition: The nature of ds2 is always such as to balance all mechanical actions; in fact the sum of the
|
||
energy tensor and of the inertial one identically vanishes.
|
||
|
||
(7) In fact Tik include the contribution of all the phenomena that occur at the considered place and time
|
||
(apart from gravitation). One deals anyway with an isolated system in the ordinary sense of the word.
|
||
Therefore force and power must vanish within each of its elementary portions.
|
||
(8) See for instance W. De Sitter, On the relativity of rotation in Einstein’s theory, Proc. of K. Ak. van
|
||
Wet. te Amsterdam, vol. XIX, 1916, p. 530 (in footnote).
|
||
|
||
7
|
||
|
||
One is naturally led to associate this proposition with d’Alembert’s principle “the lost forces (i.e. directly applied forces and inertial ones) balance each other”. The equilibrium expressed by (10’) is just the most complete occurrence that can be conceived from the mechanical standpoint. In fact, not only the total force applied to each single element comes to vanish, but also stresses, energy flow and energy density (by taking inertia into account through Aik) behave in this way.
|
||
It is clear that this total lack of mechanical entities pertains to isolated systems. Let us introduce in the field of such a system for instance a bit of matter (and for simplicity the ensuing alteration of the field is supposed negligible); several external actions coming from the system are exerted on the extra matter. In the ideal case of the mass point, these can be summarised in a law of motion (geodesic with respect to the four-dimensional ds2). It contains in particular the ordinary dynamics of a point subjected to conservative forces.
|
||
It must be remarked that Einstein’s fundamental equations, connected here with d’Alembert’s principle, have been already derived, by Einstein himself and, in a more complete way, by Lorentz and by Hilbert (9), from the appropriate variation of a unique integral. In this way also Hamilton’s principle is extended to the new mechanics.
|
||
9. Einstein’s misunderstanding about the gravitational tensor. - I remember, although it may be superfluous, that by setting
|
||
|
||
3
|
||
A(ij) = k g(jk)Aik (i, j = 0, 1, 2, 3),
|
||
0
|
||
|
||
from any double covariant system Aik one immediately gets a mixed system A(ij) (covariant with respect to the index i and contravariant with respect to the index j). It follows that, in order
|
||
|
||
to identify the gravitational tensor with respect to certain variables, it makes no difference if one
|
||
|
||
fixes either the explicit
|
||
|
||
the elements Aik or their linear combinations A(ij). With expressions proposed by Einstein (10) for the A(ij), and by
|
||
|
||
this him
|
||
|
||
proviso let called √−g
|
||
|
||
us tji
|
||
|
||
come to (g is the
|
||
|
||
discriminant of ds2).
|
||
|
||
They are
|
||
|
||
(14)
|
||
|
||
√ −g
|
||
|
||
tji
|
||
|
||
=
|
||
|
||
1 2
|
||
|
||
G∗εji −
|
||
|
||
3 0
|
||
|
||
′
|
||
hk
|
||
|
||
∂G∗ ∂gj(hk)
|
||
|
||
gi(hk)
|
||
|
||
(i, j = 0, 1, 2, 3).
|
||
|
||
Here εji is as usual either zero or one according to whether the indices are different or equal; gj(hk) stands for ∂g(hk)/∂xj ; the summation 30′hk must be extended to all the combinations with repetition of the indices h and k; finally the function
|
||
|
||
(15)
|
||
|
||
3
|
||
|
||
3
|
||
|
||
G∗ = − ik g(ik) hl
|
||
|
||
ih
|
||
|
||
kl
|
||
|
||
ik
|
||
|
||
−
|
||
|
||
lh
|
||
.
|
||
|
||
0
|
||
|
||
0
|
||
|
||
l
|
||
|
||
h
|
||
|
||
l
|
||
|
||
h
|
||
|
||
(9) See for instance pp. 707-709 of De Sitter’s report, On Einstein’s theory of gravitation..., Monthly
|
||
Notices, vol. LXXVI, 1916.
|
||
(10) Firstly with reference to special variables, then by extending their validity; eventually by attributing
|
||
to them a general character. See in particular the recent Note: Hamiltonsches Prinzip und allgemeine
|
||
Relativit¨atstheorie, Sitzungsberichte der Kgl. Preussischen Ak. der Wiss., 1916, pp. 1111-1116.
|
||
|
||
8
|
||
|
||
must be understood (as it is obviously allowed) as reduced to depend only on the arguments g(hk), gj(hk) before being subjected to partial differentiation with respect to the latter.
|
||
The inappropriateness of the positions (14) from the mathematical standpoint is easily ac-
|
||
knowledged. It is sufficient for instance to derive from them the expression that should be assumed
|
||
by the linear invariant, i.e.
|
||
|
||
√ −g
|
||
|
||
3 0
|
||
|
||
i
|
||
|
||
tii =
|
||
|
||
1 2
|
||
|
||
3
|
||
4G∗ − i
|
||
0
|
||
|
||
3 0
|
||
|
||
′
|
||
hk
|
||
|
||
∂G∗ ∂gi(hk)
|
||
|
||
gi(hk)
|
||
|
||
.
|
||
|
||
Since G∗, according to (15), is quadratic and homogeneous with respect to the Christoffel symbols, hence also with respect to gi(hk), by virtue of Euler’s theorem
|
||
|
||
3
|
||
i
|
||
0
|
||
|
||
3 0
|
||
|
||
′
|
||
hk
|
||
|
||
∂G∗ ∂gi(hk)
|
||
|
||
gi(hk)
|
||
|
||
=
|
||
|
||
2G∗,
|
||
|
||
and the invariant in question should reduce itself to G∗. Now it is well known (11) that differential invariants of the 10 order which are intrinsic i.e.,
|
||
like G∗, exclusively formed with the coefficients of ds2 and with their first derivatives, do not exist. This is enough to render, at least in general, not admissible the form of the gravitational tensor taken by Einstein. The latter however had already felt some uneasiness, in particular when (12), after having outlined with genial simplicity the theory of the gravitational waves, he was led to the unacceptable result that also spontaneous waves should as a rule give rise to dispersion of energy through irradiation.
|
||
“Since this fact” - these are his words - “should not happen in nature, it seems likely that quantum theory should intervene by modifying not only Maxwell’s electrodynamics, but also the new theory of gravitation”.
|
||
Actually there is no need of reaching to quanta. It is enough to correct the formal expression of the gravitational tensor in the way shown here. Then the possibility of being confronted with consequences not corresponding to the physical intuition is a priori excluded, in the case either of free waves or of another purely gravitational phenomenon. In fact, by virtue of (10’) or, if one likes, of the generalised d’Alembert’s principle, when the energy tensor Tik vanishes, the same occurrence must happen to the gravitational tensor Aik. This fact entails total lack of stresses, of energy flow, and also of a simple localisation of energy.
|
||
|
||
(11) See for instance Ricci et Levi-Civita, M´ethodes de calcul diff´erentiel absolu et leurs applications,
|
||
Matematische Annalen, B. 54, 1900, p. 162.
|
||
(12) In the Note already cited at the beginning.
|
||
9
|
||
|