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/library/oar/handle/123456789/95710| Title: | Time-evolution of nonlinear optomechanical systems : interplay of mechanical squeezing and non-gaussianity |
| Authors: | Qvarfort, Sofia Serafini, Alessio Xuereb, Andre Braun, Daniel ¸éä³Ù³ú±ð±ô,&#³æ20;¶Ù±ð²Ô²Ô¾±²õ Edward Bruschi, David |
| Keywords: | Optomechanics Nonlinear optics Quantum optics Dynamical systems |
| Issue Date: | 2020 |
| Publisher: | Institute of Physics Publishing Ltd. |
| Citation: | ²Ï±¹²¹°ù´Ú´Ç°ù³Ù,&#³æ20;³§.,&#³æ20;³§±ð°ù²¹´Ú¾±²Ô¾±,&#³æ20;´¡.,&#³æ20;³Ý³Ü±ð°ù±ð²ú,&#³æ20;´¡.,&#³æ20;µþ°ù²¹³Ü²Ô,&#³æ20;¶Ù.,&#³æ20;¸éä³Ù³ú±ð±ô,&#³æ20;¶Ù.,&#³æ20;&²¹³¾±è;&#³æ20;µþ°ù³Ü²õ³¦³ó¾±,&#³æ20;¶Ù.&#³æ20;·¡.&#³æ20;(2020).&#³æ20;°Õ¾±³¾±ð-±ð±¹´Ç±ô³Ü³Ù¾±´Ç²Ô&#³æ20;´Ç´Ú&#³æ20;²Ô´Ç²Ô±ô¾±²Ô±ð²¹°ù&#³æ20;´Ç±è³Ù´Ç³¾±ð³¦³ó²¹²Ô¾±³¦²¹±ô&#³æ20;²õ²â²õ³Ù±ð³¾²õ:&#³æ20;±õ²Ô³Ù±ð°ù±è±ô²¹²â&#³æ20;´Ç´Ú&#³æ20;³¾±ð³¦³ó²¹²Ô¾±³¦²¹±ô&#³æ20;²õ±ç³Ü±ð±ð³ú¾±²Ô²µ&#³æ20;²¹²Ô»å&#³æ20;²Ô´Ç²Ô-²µ²¹³Ü²õ²õ¾±²¹²Ô¾±³Ù²â.&#³æ20;´³´Ç³Ü°ù²Ô²¹±ô&#³æ20;´Ç´Ú&#³æ20;±Ê³ó²â²õ¾±³¦²õ&#³æ20;´¡:&#³æ20;²Ñ²¹³Ù³ó±ð³¾²¹³Ù¾±³¦²¹±ô&#³æ20;²¹²Ô»å&#³æ20;°Õ³ó±ð´Ç°ù±ð³Ù¾±³¦²¹±ô,&#³æ20;53(7),&#³æ20;075304. |
| Abstract: | We solve the time evolution of a nonlinear optomechanical Hamiltonian with arbitrary time-dependent mechanical displacement, mechanical single-mode squeezing and a time-dependent optomechanical coupling up to the solution of two second-order differential equations. The solution is based on identifying a minimal and finite Lie algebra that generates the time-evolution of the system. This reduces the problem to considering a finite set of coupled ordinary differential equations of real functions. To demonstrate the applicability of our method, we compute the degree of non-Gaussianity of the time-evolved state of the system by means of a measure based on the relative entropy of the non-Gaussian state and its closest Gaussian reference state. We find that the addition of a constant mechanical squeezing term to the standard optomechanical Hamiltonian generally decreases the overall non-Gaussian character of the state. For sinusoidally modulated squeezing, the two second-order differential equations mentioned above take the form of the Mathieu equation. We derive perturbative solutions for a small squeezing amplitude at parametric resonance and show that they correspond to the rotating-wave approximation at times larger than the scale set by the mechanical frequency. We find that the non-Gaussianity of the state increases with both time and the squeezing parameter in this specific regime. |
| URI: | https://www.um.edu.mt/library/oar/handle/123456789/95710 |
| Appears in Collections: | Scholarly Works - FacSciPhy |
Files in This Item:
| File | Description | Size | Format | |
|---|---|---|---|---|
| Time_evolution_of_nonlinear_optomechanical_systems_Interplay_of_mechanical_squeezing_and_non_Gaussianity(2020).pdf | 3.51 MB | Adobe PDF | View/Open |
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