Two-body Dirac equations

In quantum field theory, and in the significant subfields of quantum electrodynamics (QED) and quantum chromodynamics (QCD), the two-body Dirac equations (TBDE) of constraint dynamics provide a three-dimensional yet manifestly covariant reformulation of the Bethe–Salpeter equation[1] for two spin-1/2 particles. Such a reformulation is necessary since without it, as shown by Nakanishi,[2] the Bethe–Salpeter equation possesses negative-norm solutions arising from the presence of an essentially relativistic degree of freedom, the relative time. These "ghost" states have spoiled the naive interpretation of the Bethe–Salpeter equation as a quantum mechanical wave equation. The two-body Dirac equations of constraint dynamics rectify this flaw. The forms of these equations can not only be derived from quantum field theory [3][4] they can also be derived purely in the context of Dirac's constraint dynamics [5][6] and relativistic mechanics and quantum mechanics.[7][8][9][10] Their structures, unlike the more familiar two-body Dirac equation of Breit,[11][12][13] which is a single equation, are that of two simultaneous quantum relativistic wave equations. A single two-body Dirac equation similar to the Breit equation can be derived from the TBDE.[14] Unlike the Breit equation, it is manifestly covariant and free from the types of singularities that prevent a strictly nonperturbative treatment of the Breit equation.[15] In applications of the TBDE to QED, the two particles interact by way of four-vector potentials derived from the field theoretic electromagnetic interactions between the two particles. In applications to QCD, the two particles interact by way of four-vector potentials and Lorentz invariant scalar interactions, derived in part from the field theoretic chromomagnetic interactions between the quarks and in part by phenomenological considerations. As with the Breit equation a sixteen-component spinor Ψ is used.

Equations

edit

For QED, each equation has the same structure as the ordinary one-body Dirac equation in the presence of an external electromagnetic field, given by the 4-potential  . For QCD, each equation has the same structure as the ordinary one-body Dirac equation in the presence of an external field similar to the electromagnetic field and an additional external field given by in terms of a Lorentz invariant scalar  . In natural units:[16] those two-body equations have the form.

  where, in coordinate space, pμ is the 4-momentum, related to the 4-gradient by (the metric used here is  )   and γμ are the gamma matrices. The two-body Dirac equations (TBDE) have the property that if one of the masses becomes very large, say   then the 16-component Dirac equation reduces to the 4-component one-body Dirac equation for particle one in an external potential.

In SI units:   where c is the speed of light and  

Natural units will be used below. A tilde symbol is used over the two sets of potentials to indicate that they may have additional gamma matrix dependencies not present in the one-body Dirac equation. Any coupling constants such as the electron charge are embodied in the vector potentials.

Constraint dynamics and the TBDE

edit

Constraint dynamics applied to the TBDE requires a particular form of mathematical consistency: the two Dirac operators must commute with each other. This is plausible if one views the two equations as two compatible constraints on the wave function. (See the discussion below on constraint dynamics.) If the two operators did not commute, (as, e.g., with the coordinate and momentum operators  ) then the constraints would not be compatible (one could not e.g., have a wave function that satisfied both   and  ). This mathematical consistency or compatibility leads to three important properties of the TBDE. The first is a condition that eliminates the dependence on the relative time in the center of momentum (c.m.) frame defined by  . (The variable   is the total energy in the c.m. frame.) Stated another way, the relative time is eliminated in a covariant way. In particular, for the two operators to commute, the scalar and four-vector potentials can depend on the relative coordinate   only through its component   orthogonal to   in which    

This implies that in the c.m. frame  , which has zero time component.

Secondly, the mathematical consistency condition also eliminates the relative energy in the c.m. frame. It does this by imposing on each Dirac operator a structure such that in a particular combination they lead to this interaction independent form, eliminating in a covariant way the relative energy.  

In this expression   is the relative momentum having the form   for equal masses. In the c.m. frame ( ), the time component   of the relative momentum, that is the relative energy, is thus eliminated. in the sense that  .

A third consequence of the mathematical consistency is that each of the world scalar   and four vector   potentials has a term with a fixed dependence on   and   in addition to the gamma matrix independent forms of   and   which appear in the ordinary one-body Dirac equation for scalar and vector potentials. These extra terms correspond to additional recoil spin-dependence not present in the one-body Dirac equation and vanish when one of the particles becomes very heavy (the so-called static limit).

More on constraint dynamics: generalized mass shell constraints

edit

Constraint dynamics arose from the work of Dirac [6] and Bergmann.[17] This section shows how the elimination of relative time and energy takes place in the c.m. system for the simple system of two relativistic spinless particles. Constraint dynamics was first applied to the classical relativistic two particle system by Todorov,[18][19] Kalb and Van Alstine,[20][21] Komar,[22][23] and Droz–Vincent.[24] With constraint dynamics, these authors found a consistent and covariant approach to relativistic canonical Hamiltonian mechanics that also evades the Currie–Jordan–Sudarshan "No Interaction" theorem.[25][26] That theorem states that without fields, one cannot have a relativistic Hamiltonian dynamics. Thus, the same covariant three-dimensional approach which allows the quantized version of constraint dynamics to remove quantum ghosts simultaneously circumvents at the classical level the C.J.S. theorem. Consider a constraint on the otherwise independent coordinate and momentum four vectors, written in the form  . The symbol  is called a weak equality and implies that the constraint is to be imposed only after any needed Poisson brackets are performed. In the presence of such constraints, the total Hamiltonian   is obtained from the Lagrangian   by adding to the Legendre Hamiltonian   the sum of the constraints times an appropriate set of Lagrange multipliers  .  

This total Hamiltonian is traditionally called the Dirac Hamiltonian. Constraints arise naturally from parameter invariant actions of the form  

In the case of four vector and Lorentz scalar interactions for a single particle the Lagrangian is  

The canonical momentum is   and by squaring leads to the generalized mass shell condition or generalized mass shell constraint  

Since, in this case, the Legendre Hamiltonian vanishes   the Dirac Hamiltonian is simply the generalized mass constraint (with no interactions it would simply be the ordinary mass shell constraint)  

One then postulates that for two bodies the Dirac Hamiltonian is the sum of two such mass shell constraints,   that is   and that each constraint   be constant in the proper time associated with    

Here the weak equality means that the Poisson bracket could result in terms proportional one of the constraints, the classical Poisson brackets for the relativistic two-body system being defined by  

To see the consequences of having each constraint be a constant of the motion, take, for example  

Since   and   and   one has  

The simplest solution to this is   which leads to (note the equality in this case is not a weak one in that no constraint need be imposed after the Poisson bracket is worked out)   (see Todorov,[19] and Wong and Crater [27] ) with the same   defined above.

Quantization

edit

In addition to replacing classical dynamical variables by their quantum counterparts, quantization of the constraint mechanics takes place by replacing the constraint on the dynamical variables with a restriction on the wave function    

The first set of equations for i = 1, 2 play the role for spinless particles that the two Dirac equations play for spin-one-half particles. The classical Poisson brackets are replaced by commutators  

Thus   and we see in this case that the constraint formalism leads to the vanishing commutator of the wave operators for the two particles. This is the analogue of the claim stated earlier that the two Dirac operators commute with one another.

Covariant elimination of the relative energy

edit

The vanishing of the above commutator ensures that the dynamics is independent of the relative time in the c.m. frame. In order to covariantly eliminate the relative energy, introduce the relative momentum   defined by

  (1)
  (2)

The above definition of the relative momentum forces the orthogonality of the total momentum and the relative momentum,   which follows from taking the scalar product of either equation with  . From Eqs.(1) and (2), this relative momentum can be written in terms of   and   as  

where     are the projections of the momenta   and   along the direction of the total momentum  . Subtracting the two constraints   and  , gives

  (3)

Thus on these states      

The equation   describes both the c.m. motion and the internal relative motion. To characterize the former motion, observe that since the potential   depends only on the difference of the two coordinates  

(This does not require that   since the  .) Thus, the total momentum   is a constant of motion and   is an eigenstate state characterized by a total momentum  . In the c.m. system   with   the invariant center of momentum (c.m.) energy. Thus

  (4)

and so   is also an eigenstate of c.m. energy operators for each of the two particles,    

The relative momentum then satisfies   so that    

The above set of equations follow from the constraints   and the definition of the relative momenta given in Eqs.(1) and (2). If instead one chooses to define (for a more general choice see Horwitz),[28]       independent of the wave function, then

  (5)
  (6)

and it is straight forward to show that the constraint Eq.(3) leads directly to:

  (7)

in place of  . This conforms with the earlier claim on the vanishing of the relative energy in the c.m. frame made in conjunction with the TBDE. In the second choice the c.m. value of the relative energy is not defined as zero but comes from the original generalized mass shell constraints. The above equations for the relative and constituent four-momentum are the relativistic analogues of the non-relativistic equations  

Covariant eigenvalue equation for internal motion

edit

Using Eqs.(5),(6),(7), one can write   in terms of   and  

 

  (8)

where

 

Eq.(8) contains both the total momentum   [through the  ] and the relative momentum  . Using Eq. (4), one obtains the eigenvalue equation

  (9)

so that   becomes the standard triangle function displaying exact relativistic two-body kinematics:

 

With the above constraint Eqs.(7) on   then   where  . This allows writing Eq. (9) in the form of an eigenvalue equation  

having a structure very similar to that of the ordinary three-dimensional nonrelativistic Schrödinger equation. It is a manifestly covariant equation, but at the same time its three-dimensional structure is evident. The four-vectors   and   have only three independent components since   The similarity to the three-dimensional structure of the nonrelativistic Schrödinger equation can be made more explicit by writing the equation in the c.m. frame in which      

Comparison of the resultant form

  (10)

with the time independent Schrödinger equation

  (11)

makes this similarity explicit.

The two-body relativistic Klein–Gordon equations

edit

A plausible structure for the quasipotential   can be found by observing that the one-body Klein–Gordon equation   takes the form   when one introduces a scalar interaction and timelike vector interaction via  and  . In the two-body case, separate classical [29][30] and quantum field theory [4] arguments show that when one includes world scalar and vector interactions then   depends on two underlying invariant functions   and   through the two-body Klein–Gordon-like potential form with the same general structure, that is   Those field theories further yield the c.m. energy dependent forms   and   ones that Tododov introduced as the relativistic reduced mass and effective particle energy for a two-body system. Similar to what happens in the nonrelativistic two-body problem, in the relativistic case we have the motion of this effective particle taking place as if it were in an external field (here generated by   and  ). The two kinematical variables   and   are related to one another by the Einstein condition   If one introduces the four-vectors, including a vector interaction         and scalar interaction  , then the following classical minimal constraint form   reproduces

  (12)

Notice, that the interaction in this "reduced particle" constraint depends on two invariant scalars,   and  , one guiding the time-like vector interaction and one the scalar interaction.

Is there a set of two-body Klein–Gordon equations analogous to the two-body Dirac equations? The classical relativistic constraints analogous to the quantum two-body Dirac equations (discussed in the introduction) and that have the same structure as the above Klein–Gordon one-body form are       Defining structures that display time-like vector and scalar interactions         gives     Imposing   and using the constraint  , reproduces Eqs.(12) provided

 

      The corresponding Klein–Gordon equations are     and each, due to the constraint   is equivalent to  

Hyperbolic versus external field form of the two-body Dirac equations

edit

For the two body system there are numerous covariant forms of interaction. The simplest way of looking at these is from the point of view of the gamma matrix structures of the corresponding interaction vertices of the single particle exchange diagrams. For scalar, pseudoscalar, vector, pseudovector, and tensor exchanges those matrix structures are respectively   in which   The form of the Two-Body Dirac equations which most readily incorporates each or any number of these intereractions in concert is the so-called hyperbolic form of the TBDE.[31] For combined scalar and vector interactions those forms ultimately reduce to the ones given in the first set of equations of this article. Those equations are called the external field-like forms because their appearances are individually the same as those for the usual one-body Dirac equation in the presence of external vector and scalar fields.

The most general hyperbolic form for compatible TBDE is  

  (13)

where   represents any invariant interaction singly or in combination. It has a matrix structure in addition to coordinate dependence. Depending on what that matrix structure is one has either scalar, pseudoscalar, vector, pseudovector, or tensor interactions. The operators   and   are auxiliary constraints satisfying  

  (14)

in which the   are the free Dirac operators

  (15)

This, in turn leads to the two compatibility conditions   and   provided that   These compatibility conditions do not restrict the gamma matrix structure of  . That matrix structure is determined by the type of vertex-vertex structure incorporated in the interaction. For the two types of invariant interactions   emphasized in this article they are      

For general independent scalar and vector interactions   The vector interaction specified by the above matrix structure for an electromagnetic-like interaction would correspond to the Feynman gauge.

If one inserts Eq.(14) into (13) and brings the free Dirac operator (15) to the right of the matrix hyperbolic functions and uses standard gamma matrix commutators and anticommutators and   one arrives at    

  (16)

in which           The (covariant) structure of these equations are analogous to those of a Dirac equation for each of the two particles, with   and   playing the roles that   and   do in the single particle Dirac equation   Over and above the usual kinetic part   and time-like vector and scalar potential portions, the spin-dependent modifications involving   and the last set of derivative terms are two-body recoil effects absent for the one-body Dirac equation but essential for the compatibility (consistency) of the two-body equations. The connections between what are designated as the vertex invariants   and the mass and energy potentials   are         Comparing Eq.(16) with the first equation of this article one finds that the spin-dependent vector interactions are     Note that the first portion of the vector potentials is timelike (parallel to   while the next portion is spacelike (perpendicular to  . The spin-dependent scalar potentials   are    

The parametrization for   and   takes advantage of the Todorov effective external potential forms (as seen in the above section on the two-body Klein Gordon equations) and at the same time displays the correct static limit form for the Pauli reduction to Schrödinger-like form. The choice for these parameterizations (as with the two-body Klein Gordon equations) is closely tied to classical or quantum field theories for separate scalar and vector interactions. This amounts to working in the Feynman gauge with the simplest relation between space- and timelike parts of the vector interaction. The mass and energy potentials are respectively     so that    

Applications and limitations

edit

The TBDE can be readily applied to two body systems such as positronium, muonium, hydrogen-like atoms, quarkonium, and the two-nucleon system.[32][33][34] These applications involve two particles only and do not involve creation or annihilation of particles beyond the two. They involve only elastic processes. Because of the connection between the potentials used in the TBDE and the corresponding quantum field theory, any radiative correction to the lowest order interaction can be incorporated into those potentials. To see how this comes about, consider by contrast how one computes scattering amplitudes without quantum field theory. With no quantum field theory one must come upon potentials by classical arguments or phenomenological considerations. Once one has the potential   between two particles, then one can compute the scattering amplitude   from the Lippmann–Schwinger equation [35]   in which   is a Green function determined from the Schrödinger equation. Because of the similarity between the Schrödinger equation Eq. (11) and the relativistic constraint equation (10), one can derive the same type of equation as the above   called the quasipotential equation with a   very similar to that given in the Lippmann–Schwinger equation. The difference is that with the quasipotential equation, one starts with the scattering amplitudes   of quantum field theory, as determined from Feynman diagrams and deduces the quasipotential Φ perturbatively. Then one can use that Φ in (10), to compute energy levels of two particle systems that are implied by the field theory. Constraint dynamics provides one of many, in fact an infinite number of, different types of quasipotential equations (three-dimensional truncations of the Bethe–Salpeter equation) differing from one another by the choice of  .[36] The relatively simple solution to the problem of relative time and energy from the generalized mass shell constraint for two particles, has no simple extension, such as presented here with the   variable, to either two particles in an external field [37] or to 3 or more particles. Sazdjian has presented a recipe for this extension when the particles are confined and cannot split into clusters of a smaller number of particles with no inter-cluster interactions [38] Lusanna has developed an approach, one that does not involve generalized mass shell constraints with no such restrictions, which extends to N bodies with or without fields. It is formulated on spacelike hypersurfaces and when restricted to the family of hyperplanes orthogonal to the total timelike momentum gives rise to a covariant intrinsic 1-time formulation (with no relative time variables) called the "rest-frame instant form" of dynamics,[39][40]

See also

edit

References

edit
  1. ^ Bethe, Hans A.; Edwin E. Salpeter (2008). Quantum mechanics of one- and two-electron atoms (Dover ed.). Mineola, N.Y.: Dover Publications. ISBN 978-0486466675.
  2. ^ Nakanishi, Noboru (1969). "A General Survey of the Theory of the Bethe-Salpeter Equation". Progress of Theoretical Physics Supplement. 43. Oxford University Press (OUP): 1–81. Bibcode:1969PThPS..43....1N. doi:10.1143/ptps.43.1. ISSN 0375-9687.
  3. ^ Sazdjian, H. (1985). "The quantum mechanical transform of the Bethe-Salpeter equation". Physics Letters B. 156 (5–6). Elsevier BV: 381–384. Bibcode:1985PhLB..156..381S. doi:10.1016/0370-2693(85)91630-2. ISSN 0370-2693.
  4. ^ a b Jallouli, H; Sazdjian, H (1997). "The Relativistic Two-Body Potentials of Constraint Theory from Summation of Feynman Diagrams". Annals of Physics. 253 (2): 376–426. arXiv:hep-ph/9602241. Bibcode:1997AnPhy.253..376J. doi:10.1006/aphy.1996.5632. ISSN 0003-4916. S2CID 614024.
  5. ^ P.A.M. Dirac, Can. J. Math. 2, 129 (1950)
  6. ^ a b P.A.M. Dirac, Lectures on Quantum Mechanics (Yeshiva University, New York, 1964)
  7. ^ P. Van Alstine and H.W. Crater, Journal of Mathematical Physics 23, 1697 (1982).
  8. ^ Crater, Horace W; Van Alstine, Peter (1983). "Two-body Dirac equations". Annals of Physics. 148 (1): 57–94. Bibcode:1983AnPhy.148...57C. doi:10.1016/0003-4916(83)90330-5.
  9. ^ Sazdjian, H. (1986). "Relativistic wave equations for the dynamics of two interacting particles". Physical Review D. 33 (11): 3401–3424. Bibcode:1986PhRvD..33.3401S. doi:10.1103/PhysRevD.33.3401. PMID 9956560.
  10. ^ Sazdjian, H. (1986). "Relativistic quarkonium dynamics". Physical Review D. 33 (11): 3425–3434. Bibcode:1986PhRvD..33.3425S. doi:10.1103/PhysRevD.33.3425. PMID 9956561.
  11. ^ Breit, G. (1929-08-15). "The Effect of Retardation on the Interaction of Two Electrons". Physical Review. 34 (4). American Physical Society (APS): 553–573. Bibcode:1929PhRv...34..553B. doi:10.1103/physrev.34.553. ISSN 0031-899X.
  12. ^ Breit, G. (1930-08-01). "The Fine Structure of HE as a Test of the Spin Interactions of Two Electrons". Physical Review. 36 (3). American Physical Society (APS): 383–397. Bibcode:1930PhRv...36..383B. doi:10.1103/physrev.36.383. ISSN 0031-899X.
  13. ^ Breit, G. (1932-02-15). "Dirac's Equation and the Spin-Spin Interactions of Two Electrons". Physical Review. 39 (4). American Physical Society (APS): 616–624. Bibcode:1932PhRv...39..616B. doi:10.1103/physrev.39.616. ISSN 0031-899X.
  14. ^ Van Alstine, Peter; Crater, Horace W. (1997). "A tale of three equations: Breit, Eddington—Gaunt, and Two-Body Dirac". Foundations of Physics. 27 (1): 67–79. arXiv:hep-ph/9708482. Bibcode:1997FoPh...27...67A. doi:10.1007/bf02550156. ISSN 0015-9018. S2CID 119326477.
  15. ^ Crater, Horace W.; Wong, Chun Wa; Wong, Cheuk-Yin (1996). "Singularity-Free Breit Equation from Constraint Two-Body Dirac Equations". International Journal of Modern Physics E. 05 (4): 589–615. arXiv:hep-ph/9603402. Bibcode:1996IJMPE...5..589C. doi:10.1142/s0218301396000323. ISSN 0218-3013. S2CID 18416997.
  16. ^ Crater, Horace W.; Peter Van Alstine (1999). "Two-Body Dirac Equations for Relativistic Bound States of Quantum Field Theory". arXiv:hep-ph/9912386.
  17. ^ Bergmann, Peter G. (1949-02-15). "Non-Linear Field Theories". Physical Review. 75 (4). American Physical Society (APS): 680–685. Bibcode:1949PhRv...75..680B. doi:10.1103/physrev.75.680. ISSN 0031-899X.
  18. ^ I. T. Todorov, " Dynamics of Relativistic Point Particles as a Problem with Constraints", Dubna Joint Institute for Nuclear Research No. E2-10175, 1976
  19. ^ a b I. T. Todorov, Annals of the Institute of H. Poincaré' {A28},207 (1978)
  20. ^ M. Kalb and P. Van Alstine, Yale Reports, C00-3075-146 (1976), C00-3075-156 (1976),
  21. ^ P. Van Alstine, Ph.D. Dissertation Yale University, (1976)
  22. ^ Komar, Arthur (1978-09-15). "Constraint formalism of classical mechanics". Physical Review D. 18 (6). American Physical Society (APS): 1881–1886. Bibcode:1978PhRvD..18.1881K. doi:10.1103/physrevd.18.1881. ISSN 0556-2821.
  23. ^ Komar, Arthur (1978-09-15). "Interacting relativistic particles". Physical Review D. 18 (6). American Physical Society (APS): 1887–1893. Bibcode:1978PhRvD..18.1887K. doi:10.1103/physrevd.18.1887. ISSN 0556-2821.
  24. ^ Droz-Vincent, Philippe (1975). "Hamiltonian systems of relativistic particles". Reports on Mathematical Physics. 8 (1). Elsevier BV: 79–101. Bibcode:1975RpMP....8...79D. doi:10.1016/0034-4877(75)90020-8. ISSN 0034-4877.
  25. ^ Currie, D. G.; Jordan, T. F.; Sudarshan, E. C. G. (1963-04-01). "Relativistic Invariance and Hamiltonian Theories of Interacting Particles". Reviews of Modern Physics. 35 (2). American Physical Society (APS): 350–375. Bibcode:1963RvMP...35..350C. doi:10.1103/revmodphys.35.350. ISSN 0034-6861.
  26. ^ Currie, D. G.; Jordan, T. F.; Sudarshan, E. C. G. (1963-10-01). "Erratum: Relativistic Invariance and Hamiltonian Theories of Interacting Particles". Reviews of Modern Physics. 35 (4). American Physical Society (APS): 1032. Bibcode:1963RvMP...35.1032C. doi:10.1103/revmodphys.35.1032.2. ISSN 0034-6861.
  27. ^ Wong, Cheuk-Yin; Crater, Horace W. (2001-03-23). "RelativisticN-body problem in a separable two-body basis". Physical Review C. 63 (4). American Physical Society (APS): 044907. arXiv:nucl-th/0010003. Bibcode:2001PhRvC..63d4907W. doi:10.1103/physrevc.63.044907. ISSN 0556-2813. S2CID 14454082.
  28. ^ Horwitz, L. P.; Rohrlich, F. (1985-02-15). "Limitations of constraint dynamics". Physical Review D. 31 (4). American Physical Society (APS): 932–933. Bibcode:1985PhRvD..31..932H. doi:10.1103/physrevd.31.932. ISSN 0556-2821. PMID 9955776.
  29. ^ Crater, Horace W.; Van Alstine, Peter (1992-07-15). "Restrictions imposed on relativistic two-body interactions by classical relativistic field theory". Physical Review D. 46 (2). American Physical Society (APS): 766–776. Bibcode:1992PhRvD..46..766C. doi:10.1103/physrevd.46.766. ISSN 0556-2821. PMID 10014987.
  30. ^ Crater, Horace; Yang, Dujiu (1991). "A covariant extrapolation of the noncovariant two particle Wheeler–Feynman Hamiltonian from the Todorov equation and Dirac's constraint mechanics". Journal of Mathematical Physics. 32 (9). AIP Publishing: 2374–2394. Bibcode:1991JMP....32.2374C. doi:10.1063/1.529164. ISSN 0022-2488.
  31. ^ Crater, H. W.; Van Alstine, P. (1990). "Extension of two‐body Dirac equations to general covariant interactions through a hyperbolic transformation". Journal of Mathematical Physics. 31 (8). AIP Publishing: 1998–2014. Bibcode:1990JMP....31.1998C. doi:10.1063/1.528649. ISSN 0022-2488.
  32. ^ Crater, H. W.; Becker, R. L.; Wong, C. Y.; Van Alstine, P. (1992-12-01). "Nonperturbative solution of two-body Dirac equations for quantum electrodynamics and related field theories". Physical Review D. 46 (11). American Physical Society (APS): 5117–5155. Bibcode:1992PhRvD..46.5117C. doi:10.1103/physrevd.46.5117. ISSN 0556-2821. PMID 10014894.
  33. ^ Crater, Horace; Schiermeyer, James (2010). "Applications of two-body Dirac equations to the meson spectrum with three versus two covariant interactions, SU(3) mixing, and comparison to a quasipotential approach". Physical Review D. 82 (9): 094020. arXiv:1004.2980. Bibcode:2010PhRvD..82i4020C. doi:10.1103/PhysRevD.82.094020. S2CID 119089906.
  34. ^ Liu, Bin; Crater, Horace (2003-02-18). "Two-body Dirac equations for nucleon-nucleon scattering". Physical Review C. 67 (2). American Physical Society (APS): 024001. arXiv:nucl-th/0208045. Bibcode:2003PhRvC..67b4001L. doi:10.1103/physrevc.67.024001. ISSN 0556-2813. S2CID 12939698.
  35. ^ J. J. Sakurai, Modern Quantum Mechanics, Addison Wesley (2010)
  36. ^ Yaes, Robert J. (1971-06-15). "Infinite Set of Quasipotential Equations from the Kadyshevsky Equation". Physical Review D. 3 (12). American Physical Society (APS): 3086–3090. Bibcode:1971PhRvD...3.3086Y. doi:10.1103/physrevd.3.3086. ISSN 0556-2821.
  37. ^ Bijebier, J.; Broekaert, J. (1992). "The two-body plus potential problem between quantum field theory and relativistic quantum mechanics (two-fermion and fermion-boson cases)". Il Nuovo Cimento A. 105 (5). Springer Science and Business Media LLC: 625–640. Bibcode:1992NCimA.105..625B. doi:10.1007/bf02730768. ISSN 0369-3546. S2CID 124035381.
  38. ^ Sazdjian, H (1989). "N-body bound state relativistic wave equations". Annals of Physics. 191 (1). Elsevier BV: 52–77. Bibcode:1989AnPhy.191...52S. doi:10.1016/0003-4916(89)90336-9. ISSN 0003-4916.
  39. ^ Lusanna, Luca (1997-02-10). "The N- and 1-Time Classical Descriptions of N-Body Relativistic Kinematics and the Electromagnetic Interaction". International Journal of Modern Physics A. 12 (4): 645–722. arXiv:hep-th/9512070. Bibcode:1997IJMPA..12..645L. doi:10.1142/s0217751x9700058x. ISSN 0217-751X. S2CID 16041762.
  40. ^ Lusanna, Luca (2013). "From Clock Synchronization to Dark Matter as a Relativistic Inertial Effect". Springer Proceedings in Physics. Vol. 144. Heidelberg: Springer International Publishing. pp. 267–343. arXiv:1205.2481. doi:10.1007/978-3-319-00215-6_8. ISBN 978-3-319-00214-9. ISSN 0930-8989. S2CID 117404702.