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We experimentally investigate a mechanical squeezed state realized in a parametrically modulated membrane resonator embedded in an optical cavity. We demonstrate that a quantum characteristic of the squeezed dynamics can be revealed and quantified even in a moderately warm oscillator, through the analysis of motional sidebands. We provide a theoretical framework for quantitatively interpreting the observations and present an extended comparison with the experiment. A notable result is that the spectral shape of each motional sideband provides a clear signature of a quantum mechanical squeezed state without the necessity of absolute calibrations, in particular in the regime where residual fluctuations in the squeezed quadrature are reduced below the zero-point level.

Quantum motion of a squeezed mechanical oscillator attained via an optomechanical experiment

Vezio P;Chowdhury A;Bonaldi M;Borrielli A;Marino F;Morana B;Prodi GA;Sarro PM;Serra E;Marin F

2020

Abstract

We experimentally investigate a mechanical squeezed state realized in a parametrically modulated membrane resonator embedded in an optical cavity. We demonstrate that a quantum characteristic of the squeezed dynamics can be revealed and quantified even in a moderately warm oscillator, through the analysis of motional sidebands. We provide a theoretical framework for quantitatively interpreting the observations and present an extended comparison with the experiment. A notable result is that the spectral shape of each motional sideband provides a clear signature of a quantum mechanical squeezed state without the necessity of absolute calibrations, in particular in the regime where residual fluctuations in the squeezed quadrature are reduced below the zero-point level.

Scheda breve

Scheda completa

Scheda completa (DC)

	Anno
	
				2020
			
	Strutture organizzative
	
				Istituto dei Materiali per l'Elettronica ed il Magnetismo - IMEM
Istituto Nazionale di Ottica - INO
			
	Lingua/e
	
				Inglese
			
	Rivista
	
				PHYSICAL REVIEW, A PRINT
			
	Codice Web of Science
	
				WOS:000587490100009
			
	Volume
	
				102
			
	Fascicolo
	
				5
			
	Da pagina
	
				053505-1
			
	Numero di pagine
	
				24
			
	Codice DOI
	
				https://dx.doi.org/10.1103/PhysRevA.102.053505
			
	Codice Scopus
	
				2-s2.0-85096306875
			
	URL
	
				https://journals.aps.org/pra/abstract/10.1103/PhysRevA.102.053505
			
	Referee
	
				Sì, ma tipo non specificato
			
	Parole chiave
	
				quantum technologies
			
	Numero autori
	
				10
			
	Tipologia
	
				info:eu-repo/semantics/article
			
	Tipologia Login Miur
	
				262
			
	Tutti gli autori
	
						Vezio, P; Chowdhury, A; Bonaldi, M; Borrielli, A; Marino, F; Morana, B; Prodi, Ga; Sarro, Pm; Serra, E; Marin, F
					
	Tipologia
	
				01 Contributo su Rivista::01.01 Articolo in rivista
			
	Fulltext
	
				restricted
			
	Identificativo progetto
	
	Titolo Progetto
	
									QuantERA ERA-NET Cofund in Quantum Technologies
								
	Acronimo
	
									QuantERA
								
	Finanziamento
	
									H2020
								
	N. Contratto
	
									731473
								
	Appare nelle tipologie:
	
				01.01 Articolo in rivista

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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/20.500.14243/421952

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