High-Fidelity Artificial Quantum Thermal State Generation Using Encoded Coherent States

IF 4.6

IEEE Transactions on Quantum Engineering Pub Date : 2025-08-06 DOI:10.1109/TQE.2025.3596491

Haley A. Weinstein;Bruno Avritzer;Christine M. Kinzfogl;Todd A. Brun;Jonathan L. Habif

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引用次数: 0

Abstract

Quantum steganography is a powerful method for information security where communication between a sender and receiver is disguised as naturally occurring noise in a channel. A candidate resource state required for implementing quantum steganography is a weak coherent state engineered with modulated phase and amplitude values drawn from probability distributions that result in a mixed state indistinguishable from a thermal state. We experimentally demonstrate the construction of this resource state by encoding the phase and amplitude of weak coherent laser states such that a third party monitoring the communication channel, measuring the flow of optical states through the channel, would see an amalgamation of states indistinguishable from thermal noise light such as that from spontaneous emission. Using quantum state tomography, we experimentally reconstructed the density matrices for the artificially engineered thermal states and spontaneous emission from an optical amplifier and verified a mean state fidelity

$F=0.98$

when compared with theoretical thermal states.

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利用编码相干态生成高保真人工量子热态

量子隐写术是一种强大的信息安全方法，发送方和接收方之间的通信被伪装成信道中自然发生的噪声。实现量子隐写术所需的候选资源状态是一个弱相干状态，其调制相位和振幅值来自概率分布，导致混合状态与热状态无法区分。我们通过实验证明了通过编码弱相干激光状态的相位和振幅来构建这种资源状态，这样第三方监控通信通道，测量光状态通过通道的流动，将看到与热噪声光（如自发发射光）无法区分的状态合并。利用量子态层析成像技术，实验重建了人工热态和光放大器自发发射的密度矩阵，并验证了与理论热态相比的平均态保真度F=0.98。

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来源期刊

IEEE Transactions on Quantum Engineering

CiteScore

8.00

自引率

0.00%

发文量