Related papers: Calculating potential energy surfaces with quantum computers by measuring only the density along adiabatic transitions

Calculating potential energy surfaces with quantum computers by measuring only the density along adiabatic transitions

URL: http://arxiv.org/abs/2305.08837v2
Date: Fri, 04 Oct 2024 20:53:03 GMT
Title: Calculating potential energy surfaces with quantum computers by measuring only the density along adiabatic transitions
Authors: James Brown,
Abstract summary: In lieu of using phase estimation, the energy is evaluated by performing line-integration using the inverted real-space Time-Dependant Density Functional Theory Kohn-Sham potential. The accuracy of this method depends on the validity of the adiabatic evolution itself and the potential inversion process. It is shown that few accurate measurements can be utilized to obtain chemical accuracy across the full potential energy curve.
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Abstract: We show that chemically-accurate potential energy surfaces (PESs) can be generated from quantum computers by measuring only the density along an adiabatic transition between different molecular geometries. In lieu of using phase estimation, the energy is evaluated by performing line-integration using the inverted real-space Time-Dependant Density Functional Theory Kohn-Sham potential obtained from the geometry-varying densities of the full wavefunction. The accuracy of this method depends on the validity of the adiabatic evolution itself and the potential inversion process (which is theoretically exact but can be numerically unstable), whereas total evolution time is the defining factor for the precision of phase estimation. We examine the method with a one-dimensional system of two electrons for both the ground and first triplet state in first quantization, as well as the ground state of three- and four- electron systems in second quantization. It is shown that few accurate measurements can be utilized to obtain chemical accuracy across the full potential energy curve, with shorter propagation time than may be required using phase estimation for a similar accuracy. We also show that an accurate potential energy curve can be calculated by making many imprecise density measurements (using few shots) along the time evolution and smoothing the resulting density evolution. Finally, it is important to note that the method is able to classically provide a check of its own accuracy by comparing the density resulting from a time-independent Kohn-Sham calculation using the inverted potential, with the measured density. This can be used to determine whether longer adiabatic evolution times are required to satisfy the adiabatic theorem.

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