Hazhir Dolatkhah, Artur Czerwinski, Asad Ali, Saif Al-Kuwari, Saeed Haddadi
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引用次数: 0
摘要
本研究分析了霍金辐射对施瓦兹柴尔德黑洞背景中三方测量不确定性的影响。研究了两种情况。在第一种情况下,量子记忆粒子接近施瓦兹柴尔德黑洞并位于事件穹界附近,而被测粒子则保持在渐近平坦区域。在第二种情况下,被测粒子向黑洞移动,而量子记忆保持在渐平区域。本研究考虑了两种初始量子态,即 GHZ 态和 W 态。我们的研究结果表明,在这两种情况下,测量不确定性都会随着霍金温度的升高而稳步增加。在比较GHZ态和W态时,GHZ态最初在低霍金温度下的测量不确定性比W态低,这表明它对霍金辐射有更强的适应能力。此外,当量子记忆保持在渐近平坦区域,而被测粒子落向黑洞时,GHZ态和W态的不确定性在高温下并不一致。GHZ态始终表现出较低的测量不确定性,展示了它对霍金辐射的卓越鲁棒性。
Tripartite measurement uncertainty in Schwarzschild space-time
The effect of Hawking radiation on tripartite measurement uncertainty in a Schwarzschild black hole background is analyzed in this study. Two scenarios are examined. In the first, quantum memory particles approach a Schwarzschild black hole and are positioned near the event horizon, while the particle being measured remains in the asymptotically flat region. In the second scenario, the measured particle moves toward the black hole, and the quantum memories stay in the asymptotically flat region. This study considers two initial quantum states, namely GHZ and W states. Our findings reveal that in both cases, measurement uncertainty increases steadily with rising Hawking temperature. When comparing the GHZ and W states, the GHZ state initially exhibits lower measurement uncertainty at low Hawking temperatures than the W state, indicating greater resilience to Hawking radiation. Additionally, when the quantum memories remain in the asymptotically flat region while the measured particle falls toward the black hole, the uncertainties for GHZ and W states do not align at high temperatures. The GHZ state consistently demonstrates lower measurement uncertainty, showcasing its superior robustness against Hawking radiation.
期刊介绍:
Experimental Physics I: Accelerator Based High-Energy Physics
Hadron and lepton collider physics
Lepton-nucleon scattering
High-energy nuclear reactions
Standard model precision tests
Search for new physics beyond the standard model
Heavy flavour physics
Neutrino properties
Particle detector developments
Computational methods and analysis tools
Experimental Physics II: Astroparticle Physics
Dark matter searches
High-energy cosmic rays
Double beta decay
Long baseline neutrino experiments
Neutrino astronomy
Axions and other weakly interacting light particles
Gravitational waves and observational cosmology
Particle detector developments
Computational methods and analysis tools
Theoretical Physics I: Phenomenology of the Standard Model and Beyond
Electroweak interactions
Quantum chromo dynamics
Heavy quark physics and quark flavour mixing
Neutrino physics
Phenomenology of astro- and cosmoparticle physics
Meson spectroscopy and non-perturbative QCD
Low-energy effective field theories
Lattice field theory
High temperature QCD and heavy ion physics
Phenomenology of supersymmetric extensions of the SM
Phenomenology of non-supersymmetric extensions of the SM
Model building and alternative models of electroweak symmetry breaking
Flavour physics beyond the SM
Computational algorithms and tools...etc.
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