Physics From Breit-Frame Regularization Of a Lattice Hamiltonian
Abstract
We suggest a Hamiltonian formulation on a momentum lattice using a physically motivated regularization using the Breit-frame which links the maximal parton number to the lattice size. This scheme restricts parton momenta to positive values in each spatial direction. This leads to a drastic reduction of degrees of freedom compared to a regularization in the rest frame (center at zero momentum). We discuss the computation of physical observables like (i) mass spectrum in the critical region, (ii) structure and distribution functions, (iii) S-matrix, (iv) finite temperature and finite density thermodynamics in the Breit-frame regularization. For the scalar φ43+1 theory we present numerical results for the mass spectrum in the critical region. We observe scaling behavior for the mass of the ground state and for some higher lying states. We compare our results with renormalization group results by L\"uscher and Weisz. Using the Breit-frame, we calculate for QCD the relation between the Wμ tensor, structure functions (polarized and unpolarized) and quark distribution functions. We use the improved parton-model with a scale dependence and take into account a non-zero parton mass. In the Bjorken limes we find the standard relations between F1, F2, g1 and the quark distribution functions. We discuss the r\ole of helicity. We present numerical results for parton distribution functions in the scalar model. For the φ4-model we find no bound state with internal parton structure. For the φ3-model we find a distribution function with parton structure similar to Altarelli-Parisi behavior of QCD.
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