PROBLEM CONCERNING THE FUNDAMENTAL EQUATIONS OF THE RELATIVISTIC QUANTUM THEORY OF THE FIELD

Declassified in Part - Sanitized Copy Approved for Release 2012/05/10: CIA-RDP82-00039R000100230012-3 STAT Problem Concerning the Fundamental Equations of the Relativistic Quantum Theory of the Field N. N. Bogolyubov (Corresponding Member of Academy of Sciences USSR);, Doklady Akademii Nauk SSSR, Volume LIKKI, No 5, pages 757-760. Moscow/Leningrad: 11 December 1951. Declassified in Part - Sanitized Copy Approved for Release 2012/05/10: CIA-RDP82-00039R000100230012-3 Declassified in Part - Sanitized Copy Approved for Release 2012/05/10 : CIA-RDP82-00039R000100230012-3 tos "Problem Concerning the Ftindamental Equations of the Relativistic Quantum Theory of the Field" N. N. Bogolyubov /gote: The following report appeared in the regular Mathematical Physics *section of the thrice-monthly journal Doklady Akademii Nauk SSSR, Volume 81, No 5, 11 December 1951, pages 757-760,7 In present works on the quantum theory, fields proceed from the representation for the interaction in which the wave vector M is considered assumes the form: as a functional of the spatially similar surface a- andSchr8dinger's equation ina do- 1 x I It is very clear, however, from considerations of covaancy that the introduction of arbitrary spatially similar surfaces is in general superfluous and that it is limited completely sufficiently by the class of spatially similar hyperplanes. Such hyperplanes can be given by the equation xt L. = x00 with unit temporally similar vectorrtl by characterizing them by the scalar T and by the three spatial components (IF- In this way the wave vector becomes a function of the four variables indicate . If we desire to preserve the most characteristic features of the present theory -- the strict determinization of the evolution of the wave vector and the preservation of its norm during transition from one hyperplane to another -- then we must write the fundamental wave equations, for example, in the following form: . . aM(T = am(TA) ih = H (r,O(TA) oc= af C4 C)( 1) in which the operators H, H must be Hermitian. Here we can consider, as is usual, that H, H, are exprehions depending upon the operators of generation and annihilation of rree particles. The conditions governing the compatibility of the system of equations (1) will be: ? it15H HH = qco( (2) a or r3 HigHot In order to formulate the requirement of the relativistic covariancy of these equations, we introduce the unitary operator UT with whose aid we transform the operators of the free particles during transformgtion of spaces by the Lorentz transformation L = ;obit, (Ltr x = x+a). This condition then can be written down in the following form: *6.0 U H(T tft oN tA ? 1.$ 0 4 r' + UTH( ??.0, LsLk H (t )(gL Tit 0(4,3 ) r r ot, .4.4.V41 '41 Declassified in Part - Sanitized Copy Approved for Release 2012/05/10: CIA-RDP82-00039R000100230012-3 (3) 1'4 Declassified in Part - Sanitized Copy Approved for Release 2012/05/10: CIA-RDP82-00039R000100230012-3 This remark, however, is vitiated.. ,by the fact that in all physically interesting cases such an operator asIS(T,t) does not exist. More accurately, if such an operator does exist, then all energy levels of the considered system will with the presence of interaction be the same as during the complete absence of interaction. We can attempt to bypass the indicated dif4culj,I by noting that we do not need at all that there should exist an operator,...itselfr?Vywhich reduces the wave vector of free nor1,74Kterp:0,q&particles to11011(T;E); it-ii-only necessary that the symbolic product 18(TA.)S(r,Oshould possess meaning, which repFesnts the operator of the transformatro-fi"the-wave vector with the hyperplanel(Tlf, ,)?to the hyper- plane t&,t). Let us condider the formal expansion: 1 1 n Tti-S(T,t) 460 Sn(r,) ? ? (7) such that and Then the expressions following satisfy formally our conditions as 1 as as .+ 1 H = ?I + .?(-2_ ?18 ) + at if. 'at at a. i ! H = ..........? 2(2. -----?'i)k .4.s i) N , 0 aft (X in ? ? ? ? ? 4 (. )11 2: (Iler.n)5r n-k 1,n as L (1/4Kn)at. n-k )n7-1( ? 0 0 The expressions for H, H are thus obtained in the form of series,, even ordinary equations, however, the quantum theory of fields contain expansions of a number of quantities, for example field mass and charge, which are employed for renormalization. Now arises the problem of selectingS ()such that the series (10) should possess meaning and the following seri6sn shOuld converge s(-1.7,,)s(T,t) = 1 ? ? ? )31 li(-1)n-ksk( T1 31 An_k(T4) 1 (Mtn) (a) if only ferit',t1 sufficiently close tok,t.' This latter condition would ensure 1 thepossibilityoftheintegration of the amental equations (1). Mathematical Institute imeni V. A. Steklov, Academy of Sciences USSR. -E N D- -3. Submitted 15 October 1951. Declassified in Part - Sanitized Copy Approved for Release 2012/05/10: CIA-RDP82-00039R000100230012-3