Quantum computing provides a promising approach for solving the real-time dynamics of systems consist of quarks and gluons from first-principle calculations that are intractable with classical computers. In this work, we start with an initial problem of the ultra-relativistic quark-nucleus scattering and present an efficient and precise approach to quantum simulate the dynamics on the light front. This approach employs the eigenbasis of the asymptotic scattering system and implements the compact scheme for basis encoding. It exploits the operator structure of the light-front Hamiltonian of the scattering system, which enables the Hamiltonian input scheme that utilizes the quantum Fourier transform for efficiency. It utilizes the truncated Taylor series for the dynamics simulations. The qubit cost of our approach scales logarithmically with the Hilbert space dimension of the scattering system. The gate cost has optimal scaling with the simulation error and near optimal scaling with the simulation time. These scalings make our approach advantageous for large-scale dynamics simulations on future fault-tolerant quantum computers. We demonstrate our approach with a simple scattering problem and benchmark the results with those from the Trotter algorithm and the classical calculations, where good agreement between the results is found.
Comment: 27 pages, 11 figures. Comments are welcome