Error-mitigated photonic variational quantum eigensolver using a single-photon ququart

Variational quantum algorithms, a representative class of modern quantum algorithms, provide practical uses of near-term quantum processors. The size of the problem that can be encoded and solved on a quantum processor is limited by the dimension of the Hilbert space associated with the processor. One common approach for increasing the system dimension is to utilize a larger number of quantum systems. Here, we adopt an alternative approach to utilize multiple degrees of freedom of individual quantum systems to experimentally resource-efficiently increase the Hilbert space. We report experimental implementation of the variational quantum eigensolver (VQE) using four-dimensional photonic quantum states of single photons. The four-dimensional quantum states are implemented by utilizing polarization and path degrees of freedom of a single photon. Our photonic VQE is equipped with a quantum error mitigation protocol that efficiently reduces the effects of Pauli noise in the quantum processing unit. We apply our photonic VQE to estimate the ground state energy of the He - H+ cation. Simulation and experimental results demonstrate that our experimental resource-efficient photonic VQE can accurately estimate the bond dissociation curve, even in the presence of large noise in the quantum processing unit. We also discuss further possible resource-efficient enhancement of the Hilbert space in photonic quantum processors. Our results propose that photonic systems utilizing multiple degrees of freedom can provide a resource-efficient avenue to implement practical near-term quantum processors. (C) 2022 Optical Society of America under the terms of the OSA Open Access Publishing Agreement

Automated summary

Variational quantum algorithms, a representative class of modern quantum algorithms, offer practical uses of near-term quantum processors. This study presents an alternative approach to increase the Hilbert space by utilizing multiple degrees of freedom in individual quantum systems. They experimentally implement a variational quantum eigensolver (VQE) using four-dimensional photonic quantum states and employ a quantum error mitigation protocol to reduce noise effects. Their photonic VQE accurately estimates the bond dissociation curve of the He - H+ cation, even in the presence of large noise in the quantum processing unit. The study also discusses potential resource-efficient enhancements in photonic quantum processors.