Free Fermion Fields Research Articles

Quantum-field-theory calculation of the two-dimensional Ising model correlation function

The equivalence between the two-dimensional Ising model and a free fermion field theory is used to rederive various results for the two-spin correlation function in the critical region.

Spinor-inverted solution to thirring model and its generalization to U( n) symmetry

Using the properties of massless free Fermi fields in (1-1) dimensions, it is shown that the spinor inverted form of Klaiber's operator solution to Thirring model is also a scale-invariant solution of the model. But unlike the former it admits a nonvanishing SU( n) current coupling in the generalization of the model to include U( n) symmetry. The value of this coupling constant is fixed and equals Dashen-Frishman number −4π (n + 1) . The general form of the 2 m-point function is given and operates product expansions are exhibited in terms of composite local operators. Scale dimensions of all the bilinear and quadrilinear local operators with U( n) symmetry are computed and are found to depend on n. However, different parts of a composite local operator belonging to different irreducible U( n) representations have the same dimension.

On the orthonormalization of generalized free Fermi-field-functionals

Dynamics of quantum field theory can be formulated by functional equations. To develop a complete functional quantum theory the physical information has to be given by functional operations only. In order to calculate the global physical observables in the functional map a functional scalar product has to be defined. This has been done in preceding papers by Stumpf. It is shown that the free Fermi fields are orthonormalized with this scalar product.

The free fermion field as a Markov field

A definition of a Markov field is given which allows for noncommuting fields. In the commutative case, we recover Nelson's definition ( E. Nelson, Construction of quantum fields from Markoff fields, J. Functional Analysis 12 (1973) , 97–112). Conditional expectations are shown to exist in a regular probability gage space, and, using an independence property of these in the free fermion gage space, it is shown that the free fermion field over H −1( R d ) is a Markov field.

Exact Nonperturbative Solution of a Nonlinear Fermion-Field Equation of Motion

We construct an infinite-component free neutral fermion field ${\ensuremath{\psi}}^{h}$, of type (\textonehalf{},$j$) or ($j$, \textonehalf{}), carrying compounds lying on a Regge trajectory, as a nonperturbative solution of the non-linear fermion-field equation of motion introduced in a previous paper. The compounds are considered to be strongly interacting. It can be shown that the Reggeization and instability of the compounds lead to a propagator which is much less singular than a classical field with the same spin components but without these features. The solution can be tested in two complementary ways in the equation of motion. First, by applying a compounding technique developed in a previous paper, the corresponding spectral-function equation can be discussed in the limit of high mass-squared values, and its convergence and the necessary scale factor can be determined. The scale factor is related to the role of the effective line width in the scattering theory involved in this technique. Second, by applying the Wick normal-ordering theorem to the infinite-component free-field operators in the equation of motion, an exact nonlinear equation of motion for the field propagator is derived, effectively as a spectral-function equation. A sufficient and exact condition for the existence of this solution is derived and is in fact a linear integral equation for the momentum transform of the propagator. The convergence of this condition of solution is discussed. The condition for the existence of the nonperturbative solution ${\ensuremath{\psi}}^{h}$ is formally exactly the same as that for the existence of the lepton solution ${\ensuremath{\psi}}^{l}$ and is related to the ${\ensuremath{\gamma}}^{5}$ invariance of the primitive field equation of motion (effectively the lepton-field equation of motion), and can be put in a form showing a weak coupling of the two solutions each to a corresponding appropriate massless-fermion propagator and a massive-boson propagator. This form of the exact condition of solution also leads to an interpretation of the lepton solution ${\ensuremath{\psi}}^{l}$, discussed in a previous paper, in terms of a single free massless spin-\textonehalf{} observable fermion field ${\ensuremath{\psi}}^{\ensuremath{\nu}}$, completely satisfying unitarity. ${\ensuremath{\psi}}^{\ensuremath{\nu}}$ couples weakly and effectively nonlocally to ${\ensuremath{\psi}}^{l}$ which has an indefinite metric, and to a massive boson field, both of which are not observable, at least not in the present form of the solution where isosymmetry is not introduced and broken. In this form the Hilbert spaces corresponding to ${\ensuremath{\psi}}^{\ensuremath{\nu}}$ and ${\ensuremath{\psi}}^{h}$ are completely orthogonal.

Theory of fermion field with zero mass

A theory is constructed for a free fermion field with spin 1/2 and zero mass, on the basis of the equation (d+aγ5-b)ψ(x) = 0, wherea2 = b2 = 1. The theory is invariant against continuous Lorentz transformation. It is also invariant against combined Landau reflection, time reversal, and the Schwinger strong space-time inversion, but is not invariant against space reflection or change transformation. An important role is played in this theory by the appearance of projectors. The latter arise as a result of the presence of a zero divisor in the mass term of the equation. They enter in the normalization conditions for the solutions of the equation, and hence in all the conserved operators and their eigenfunctions. Results of the analogous researches by Tokuoka [20] and Gupta [21] are also discussed.

Functional Quantum Theory of Free Relativistic Fermi Fields

Functional quantum theory of free Fermi fields is treated for the special case of a free Dirac field. All other cases run on the same pattern. Starting with the Schwinger functionals of the free Dirac field, functional equations and corresponding many particle functionals can be derived. To establish a functional quantum theory, a physical interpretation of the functionals is required. It is provided by a mapping of the physical Hilbert space into an appropriate functional Hilbert space, which is introduced here. Mathematical details, especially the problems connected with anticommuting functional sources are treated in the appendices.

On the simplicity of the even CAR algebra and free field models

An example of a local rings system where the quasilocal algebra is a simple countably generatedC*-algebra with unit is provided by the “local observables” for the free Fermi field.

Relativistische funktionale Methode zur Behandlung stark verkoppelter Fermionenfelder†

A practical method for the calculation of GREEN’S functions from the Lagrangian of a fermionfield is developed (in close analogy to 3), which is working in a LORENTZ-invariant manner and allows to treat also strong couplings (or nonlinearities). The essential point is the use of the values for functional integrals over the fermion-field calculated in lattice space. It is considered, how the anticommutativity of the fermion-field appears in the result. There are two controls in our calculations: First the result of the integration must fulfill some functional differential equations. Secondly the result should coincide in one trivial, well-known example (free field) with the well-known exact result. Our result fits both controls. Explicitly we present here only the general aspects of the problem and apply them (in order to illustrate and to controle the scheme) to the calculation of the 2-point-function of a free fermion-field, in which the mass-term has been split artificially into two parts, one of them is handled together with the free Lagrangian, the other one is treated as an “interaction”. The use of certain graphs also here proves to be very useful. The application to more interesting cases is in preparation.

A one-dimensional field theory with degenerate vacuum

A one-dimensional field theory is considered corresponding to the continuous limit of a spin chain. The vacuum degeneracy of this theory is explored. Besides, it is shown that the theory can equivalently be formulated in terms of an interacting Fermi field or of a Bose field without interaction. Finally, a theory is briefly discussed which can either be treated as an interacting Bose field or as a free Fermi field.

Interferences among feynman graphs of different topology

A given graph or partial sum of graphs, although usually regarded for computational purposes as a compact expression, is in fact a sum of contributions arising from all the individual modes of the free Fermion fields; these contributions may be partly or totally cancelled by others that belong, in the graphical picture, to diagrams which are disregarded by the approximation chosen. Therefore, total antisymmeterization of graphs of special classes does not necessarily ensure the validity of the exclusion principle. It is demonstrated that this principle requires cancellations among terms which belong to graphs of different topology. (L.N.N.)