Optimal photon-pair single-mode coupling in narrow-band spontaneous parametric downconversion with arbitrary pump profile

Jean-Loup Smirr; Matthieu Deconinck; Robert Frey; Imad Agha; Eleni Diamanti; Isabelle Zaquine

doi:10.1364/JOSAB.30.000288

Journal of the Optical Society of America B
Vol. 30,
Issue 2,
pp. 288-301
(2013)
•https://doi.org/10.1364/JOSAB.30.000288

Optimal photon-pair single-mode coupling in narrow-band spontaneous parametric downconversion with arbitrary pump profile

Jean-Loup Smirr, Matthieu Deconinck, Robert Frey, Imad Agha, Eleni Diamanti, and Isabelle Zaquine

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Jean-Loup Smirr, Matthieu Deconinck, Robert Frey, Imad Agha, Eleni Diamanti, and Isabelle Zaquine, "Optimal photon-pair single-mode coupling in narrow-band spontaneous parametric downconversion with arbitrary pump profile," J. Opt. Soc. Am. B 30, 288-301 (2013)

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Abstract

A theoretical investigation of the performance of single-mode coupled spontaneous parametric downconversion sources is proposed, which only requires very few assumptions of practical interest: quasi-degenerate collinear generation and narrow bandwidth obtained through spectral filtering. Other assumptions, such as pump-beam spatial and temporal envelopes, target single-mode profile and size, and nonlinear susceptibility distribution, are only taken into account in the final step of the computation, thus making the theory general and flexible. Figures of merit for performance include absolute coupled brightness and conditional coupling efficiency. Their optimization is investigated using functions that only depend on dimensionless parameters, so that the results provide the best experimental configuration for a whole range of design choices (e.g., crystal length, pump power, etc.). A particular application of the theory is validated by an experimental optimization obtained under compatible assumptions. A comparison with other works and proposals for numerically implementing the theory under less stringent assumptions is also provided.

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Equations (69)

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$f_{i}$ (mm)	$N_{A}$ (Hz)	$N_{B}$ (Hz)	$N_{C}$ (Hz)	$P_{A} \times 10^{- 3}$	$P_{B} \times 10^{- 3}$	$P_{A B} \times 10^{- 5}$
Used in Fig. 9(a)
6.2	2681	2653	20.12	1.18	1.20	0.85
	4281	4269	38.66	2.03	2.06	1.52
	6155	6131	60.27	3.07	3.09	2.15
8	2563	2544	25.98	1.12	1.14	1.16
	3222	3197	34.91	1.46	1.48	1.53
	5967	5925	74.47	2.97	2.98	2.97
11	3255	3239	48.21	1.48	1.51	2.21
	5700	5685	92.87	2.82	2.84	4.02
	2099	2065	27.38	0.87	0.89	1.29
	5405	5395	85.47	2.65	2.68	3.71
	3050	3027	44.18	1.37	1.39	2.03
	1505	1460	16.77	0.57	0.58	0.80
15	1794	1750	23.48	0.71	0.73	1.11
	4152	4123	65.72	1.96	1.98	2.97
	4267	4237	69.59	2.02	2.04	3.15
	6373	6340	107.20	3.20	3.21	4.58
19	2817	2781	35.72	1.25	1.26	1.63
	4528	4491	63.51	2.17	2.18	2.77
	6367	6336	92.81	3.19	3.21	3.81
25	2678	2637	28.78	1.18	1.19	1.29
	4162	4132	48.14	1.97	1.99	2.05
	5693	5653	69.61	2.81	2.83	2.79
Used in Fig. 9(b)
11	5496	5296	64.00	2.70	2.64	2.58
	4196	4030	45.77	1.99	1.94	1.93
	3068	2934	30.48	1.38	1.35	1.33
15	6085	5868	94.15	3.03	2.95	4.01
	4023	3868	58.11	1.90	1.85	2.61
	1986	1888	23.98	0.82	0.81	1.13
19	6431	6227	111.24	3.23	3.16	4.81
	4096	3951	64.47	1.93	1.90	2.92
	2063	1964	28.54	0.86	0.85	1.35
25	6131	5947	103.93	3.06	3.00	4.51
	5133	4961	86.29	2.50	2.45	3.85
	3082	2965	47.06	1.39	1.37	2.19
30	6537	6299	95.01	3.29	3.20	3.92
	4883	4704	66.93	2.36	2.31	2.89
	3126	3006	40.91	1.41	1.39	1.86

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Figures (9)

Tables (1)

Equations (69)

Journal of the Optical Society of America B