Multichannel wavelength-division multiplexing with thermally fixed Bragg gratings in photorefractive lithium niobate crystals

Ingo Nee; Oliver Beyer; Manfred Müller; Karsten Buse

doi:10.1364/JOSAB.20.001593

Journal of the Optical Society of America B
Vol. 20,
Issue 8,
pp. 1593-1602
(2003)
•https://doi.org/10.1364/JOSAB.20.001593

Multichannel wavelength-division multiplexing with thermally fixed Bragg gratings in photorefractive lithium niobate crystals

Ingo Nee, Oliver Beyer, Manfred Müller, and Karsten Buse

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Ingo Nee, Oliver Beyer, Manfred Müller, and Karsten Buse, "Multichannel wavelength-division multiplexing with thermally fixed Bragg gratings in photorefractive lithium niobate crystals," J. Opt. Soc. Am. B 20, 1593-1602 (2003)

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Abstract

The transmission capacity of fiber communication networks is enhanced by usage of dense wavelength division multiplexing (WDM). This technique requires wavelength filters for multiplexing of the channels. We report on the realization of a multiplexer device based on superimposed volume-phase gratings in a single lithium niobate crystal. The gratings are recorded through the photorefractive effect by interference of two green laser beams. Thermal fixing is employed to increase the lifetime of the gratings. Each grating diffracts light of a certain WDM channel (wavelengths of ∼1500 nm). Simultaneous multiplexing of many channels is achieved by suitable arrangement of the gratings in the crystal. We present the basic concept of this technology as well as recent advances: (1) refined experimental methods about tailored recording of many-channel multiplexers, (2) characterization of the multiplexers for up to sixteen WDM channels (1-dB bandwidth up to 0.1 nm, channel spacing down to 0.4 nm), and (3) construction of a two-channel multiplexer device.

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Notation	Dimensions (mm)			$c_{Fe}$	$c_{{Fe}^{2 +}}$	$c_{{Fe}^{2 +}} / c_{{Fe}^{3 +}}$
Notation	a	b	c	$(10^{24} m^{- 3})$		$c_{{Fe}^{2 +}} / c_{{Fe}^{3 +}}$
DT2-3	10.1	5.4	10.1	51	1.0	0.02
DT4-14	10.1	4.3	20.0	19	1.0	0.05
DT4-15	10.1	4.3	20.0	19	1.0	0.05

Grating #	$λ^{set}$ (nm)	$β^{set}$ (deg)	$γ^{L}$ (deg)	$γ^{R}$ (deg)	$η_{B}$ (%)	$λ^{act}$ (nm)	$β^{act}$ (deg)
1	1550.92	4.5	43.598	50.979	35	1551.06	4.57
2	1551.72	-4.5	50.157	44.263	53	1551.89	-4.34
3	1552.52	3.5	44.238	50.133	36	1552.64	3.54
4	1553.33	-3.5	49.325	44.910	53	1553.48	-3.32
5	1554.13	2.5	44.884	49.299	37	1554.21	2.54
6	1554.94	-2.5	48.504	45.564	49	1555.02	-2.34
7	1555.75	1.5	45.537	48.475	38	1555.79	1.50
8	1556.55	-1.5	47.693	46.225	38	1556.58	-1.39

Grating #	$λ^{set}$ (nm)	$β^{set}$ (deg)	$γ^{L}$ (deg)	$γ^{R}$ (deg)	$η_{B}$ (%)	$λ^{act}$ (nm)	$β^{act}$ (deg)
1	1550.92	4.0	44.263	50.170	18	1551.05	3.95
2	1551.72	-4.0	50.137	44.232	17	1551.84	-4.00
3	1552.52	3.0	44.911	49.335	21	1552.62	2.93
4	1553.33	-3.0	49.302	48.880	18	1553.42	-2.99
5	1554.13	2.0	45.566	48.511	25	1554.19	2.00
6	1554.94	-2.0	48.479	45.535	21	1554.99	-2.00
7	1555.75	1.0	46.227	47.698	22	1555.74	0.90
8	1556.55	-1.0	47.666	46.196	17	1556.54	-0.99

Notation	Dimensions (mm)			$c_{Fe}$	$c_{{Fe}^{2 +}}$	$c_{{Fe}^{2 +}} / c_{{Fe}^{3 +}}$
Notation	a	b	c	$(10^{24} m^{- 3})$		$c_{{Fe}^{2 +}} / c_{{Fe}^{3 +}}$
DT2-3	10.1	5.4	10.1	51	1.0	0.02
DT4-14	10.1	4.3	20.0	19	1.0	0.05
DT4-15	10.1	4.3	20.0	19	1.0	0.05

Grating #	$λ^{set}$ (nm)	$β^{set}$ (deg)	$γ^{L}$ (deg)	$γ^{R}$ (deg)	$η_{B}$ (%)	$λ^{act}$ (nm)	$β^{act}$ (deg)
1	1550.92	4.5	43.598	50.979	35	1551.06	4.57
2	1551.72	-4.5	50.157	44.263	53	1551.89	-4.34
3	1552.52	3.5	44.238	50.133	36	1552.64	3.54
4	1553.33	-3.5	49.325	44.910	53	1553.48	-3.32
5	1554.13	2.5	44.884	49.299	37	1554.21	2.54
6	1554.94	-2.5	48.504	45.564	49	1555.02	-2.34
7	1555.75	1.5	45.537	48.475	38	1555.79	1.50
8	1556.55	-1.5	47.693	46.225	38	1556.58	-1.39

Abstract

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Tables (3)

Journal of the Optical Society of America B