Abstract
We outline a strategy to compute deeply inelastic scattering structure functions using a hybrid quantum computer. Our approach takes advantage of the representation of the fermion determinant in the QCD path integral as a quantum mechanical path integral over 0+1-dimensional fermionic and bosonic worldlines. The proper time evolution of these worldlines can be determined on a quantum computer. While extremely challenging in general, the problem simplifies in the Regge limit of QCD, where the interaction of the worldlines with gauge fields is strongly localized in proper time and the corresponding quantum circuits can be written down. As a first application, we employ the Color Glass Condensate effective theory to construct the quantum algorithm for a simple dipole model of the $F_2$ structure function. We outline further how this computation scales up in complexity and extends in scope to other real-time correlation functions.
Highlights
From its early role in the discovery of partons and asymptotic freedom, deeply inelastic scattering (DIS) of electrons off protons and heavier nuclei has been a fundamental tool in studying the quark-gluon structure of matter [1,2,3,4,5]
Computing structure functions from first principles is an outstanding problem in quantum chromodynamics (QCD) because they are proportional to nucleon/nuclear matrix elements of products of electromagnetic currents that are lightlike separated in Minkowski spacetime
Monte Carlo computations in lattice QCD are robust in Euclidean spacetime
Summary
From its early role in the discovery of partons and asymptotic freedom, deeply inelastic scattering (DIS) of electrons off protons and heavier nuclei has been a fundamental tool in studying the quark-gluon structure of matter [1,2,3,4,5]. We will outline in this paper a digitization strategy whereby progress can be made constructing the Hilbert space of a relativistic quantum field theory from “worldline/single particle” states.
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