Performance guarantees of light-cone variational quantum algorithms for the maximum cut problem

Variational quantum algorithms (VQAs) are promising to demonstrate the advantage of near-term quantum computing over classical computing in practical applications, such as the maximum cut (MaxCut) problem. However, current VQAs such as the quantum approximate optimization algorithm (QAOA) have lower performance guarantees compared to the best-known classical algorithm, and suffer from hard optimization processes due to the barren plateau problem. We propose a light-cone VQA by choosing an optimal gate sequence of the standard VQAs, which enables a significant improvement in solution accuracy while avoiding the barren plateau problem. Specifically, we prove that the light-cone VQA with one round achieves an approximation ratio of 0.7926 for the MaxCut problem in the worst case of $3$-regular graphs, which is higher than that of the 3-round QAOA, and can be further improved to 0.8333 by an angle-relaxation procedure. Finally, these performance guarantees are verified by numerical simulations and hardware demonstrations on IBM quantum devices. In a 72-qubit demonstration, the single-round light-cone VQA achieves the exact MaxCut solution whereas the $p$-round QAOA with $p=1,2,3$ only obtains approximate solutions. Furthermore, the single-round light-cone VQA derives solutions surpassing the hardness threshold in a 148-qubit demonstration while QAOA with $p=1,2,3$ does not. Our work highlights a promising route towards solving practical and classically hard problems on near-term quantum devices.