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A systematic rigorous analysis of both massless fermion fields in the mass spectra of superstring theory is carried out. Our interest is in dynamical aspects of these fields. An explicit novel expression for the propagator of the massless Rarita-Schwinger field (the gravitino), in the mass spectrum involving massless fermions in superstring theory in 10 dimensions, is derived. The analysis is carried in the presence of a non-constrained external source so that the full expression of the propagator emerges. The number of associated degrees of freedom is also obtained. We work in a Coulomb-like gauge. The massless Dirac field (the dilatino), the other massless fermion field in the mass spectra of superstring theory in 10 dimensions, is first investigated to this end.

This work is involved with a systematic rigorous analysis of all the massless fermion fields in superstring theory. The two massless fermion fields arising in the mass spectrum in superstring theory are the Dirac (the dilatino) and the Rarita-Schwinger (the gravitino) fields in 10 dimensions (cf. [1,2]). What is remarkable about string theory is that the fundamental fields that are required to describe the dynamics of elementary particles arise naturally in the mass spectra of oscillating springs and are not, a priori, assumed to exist or put in by hand in the underlying theories. At present only the massless fields string modes are really physically relevant because of the enormous masses of the massive fields string-excitation modes. In this paper, we are interested in both massless fermionic field excitations in superstring theory. We are interested, particularly, in dynamical aspects of the gravitino field which is the main challenge here. To this end, we are concerned about the underlying constraints, the explicit expressions of its propagator, its inherit degrees of freedom. We work in the celebrated Coulomb gauge. For a systematic analysis of all the massless bosonic fields in superstring theory see [

To carry out the analysis involving the massless RaritaSchwinger field in ten dimensions, it is necessary first to review briefly and introduce, in the process, the following 8 gamma matrices:

which are anti-commuting in pairs, and, in turn, introduce the product

has the structure

All of the 16 by 16 matrices are pure imaginary and satisfy the conditions:

A simple way to derive the Dirac equation in ten dimensions, is to multiply the equation:

by to obtain

where p is 9 dimensional. Equation (7) may be re-written as

Simply call the combination to be, i.e., define

Upon multiplying the latter by and using (7), (8), and (9) again, lead simply to

The two Equations (9) and (10), may be now readily combined into the elegant form

Thus we have an explicit representation of all the gamma matrices in 10 dimensions. They are all pure imaginary, and satisfy

where

Using, in the process, Equation (13), one may define the chirality matrix by

For the two equations in (9), (10) decouple. From the expression of in (16), we may select a spinor with a definite chirality, say one with positive chirality

referred to as a Weyl spinor of positive chirality. From the structure of in (12), this amounts in selecting which, from (9), satisfies the equation

where has 16 components, and this equation projects out further half of the components, leaving 8 independent components.

The Lagrangian density for the Rarita-Schwinger field for is given by (cf. [5,6])

The Lagrangian density is, up to a total derivative, invariant under a gauge transformation

We work in a Coulomb-like gauge

summing over i from 1 to 9. Now we add external sources to the Lagrangian density in (20) obtaining

Due to the constraint in (21), the field components may not be varied independently. We may, however, express the field in terms of fields that may be varied independently as follows:

where

satisfying

and is a projection operator, with and a summation over repeated indices is understood.

With given in (23), we may now vary the fields, which, as seen below, not only lead to the field equations but to additional (derived) constraints.

To the above end, we note, in particular, that we may write

Using the above expression and by varying the Lagrangian density with respect to lead after some labor, to the equations

From these equations, we note that only may propagate. Also if constraints are, a priori, imposed on, the right-hand sides of these equations are changed and the equations would not provide the full expression of the propagator.

We see from Equation (29), that the Coulomb-like condition in (21) is automatically satisfied. In the absence of the external sources, the above other two equations give also the constraints, and

That is, for a given spinor index, the number of states is reduced from a factor of 10 to 7. This is rigorously established by explicitly evaluating the contraction of in (24):

Hence from (19), for a given chirality, the number of total independent components would be

Since no constraints were imposed on the external sources we may vary each of their components independently, otherwise the full expression of the propagator does not follow from the right-hand sides of (28), (29). Upon taking the vacuum expectation values of (28), (29), and setting

and integrating with respect to the sources, we obtain

where the propagator is given by

and is explicitly worked out to be

as the novel expressions of the components of the propagator.

A systematic rigorous analysis of both massless fermion fields in superstring theory in 10 dimensions was developed, emphasizing dynamical aspects, the constraints and the inherit non-trivial number of independent degrees of freedom, and a novel expression for the propagator of the Rarita-Schwinger was derived. For the treatment of all the massless bosonic fields of superstring theory see [3,4]. The investigations of the dynamical aspects of all these fields in superstring theory, are expected to be useful in finding connections between string theory and field theory for computations and for the generation of non-trivial effective actions. These points will be taken up in subsequent reports.

The author would like to thank his colleagues at the Institute for Fundamental Study of Naresuan University for the interest they have shown in this work and for their support. The author would like also to thank Professor T. Vijaktanawudhi for converting the manuscript from Latex to MS-word, and Professor N. Yongram for additional details to this end.