Realizing Non-Physical Actions through Hermitian-Preserving Map Exponentiation

TL;DR

This paper introduces a novel quantum algorithm to realize Hermitian-preserving maps, including non-physical operations, enabling advanced quantum information processing tasks like entanglement detection and error correction.

Contribution

The authors develop the first efficient method to implement non-physical Hermitian-preserving maps on quantum devices, expanding quantum operation capabilities.

Findings

Algorithm achieves effective realization of Hermitian-preserving maps

Provides exponential advantages in entanglement detection

Enables recovery of noiseless states from noisy copies

Abstract

Quantum mechanics features a variety of distinct properties such as coherence and entanglement, which could be explored to showcase potential advantages over classical counterparts in information processing. In general, legitimate quantum operations must adhere to principles of quantum mechanics, particularly the requirements of complete positivity and trace preservation. Nonetheless, non-physical maps, especially Hermitian-preserving maps, play a crucial role in quantum information science. To date, there exists no effective method for implementing these non-physical maps with quantum devices. In this work, we introduce the Hermitian-preserving map exponentiation algorithm, which can effectively realize the action of an arbitrary Hermitian-preserving map by encoding its output into a quantum process. We analyze the performances of this algorithm, including its sample complexity and robustness, and prove its optimality in certain cases. When combined with algorithms such as the Hadamard test and quantum phase estimation, it allows for the extraction of information and generation of states from outputs of Hermitian-preserving maps, enabling various applications. Utilizing positive but not completely positive maps, this algorithm provides exponential advantages in entanglement detection and quantification compared to protocols based on single-copy operations. In addition, it facilitates the recovery of noiseless quantum states from multiple copies of noisy states by implementing the inverse map of the corresponding noise channel, offering an intriguing approach to handling quantum errors. Our findings present a pathway for systematically and efficiently implementing non-physical actions with quantum devices, thereby boosting the exploration of potential quantum advantages across a wide range of information processing tasks.