Temperature insensitive multi-channel light amplification systems on SOI platform

Junhu Zhou; Jie You; Hao Ouyang; Runlin Miao; Xiang’ai Cheng; Tian Jiang

doi:10.3788/COL202220.081301

Journals >Chinese Optics Letters >Volume 20 >Issue 8 >Page 081301 > Article

Chinese Optics Letters
Vol. 20, Issue 8, 081301 (2022)

Temperature insensitive multi-channel light amplification systems on SOI platform

Junhu Zhou¹, Jie You^2、**, Hao Ouyang¹, Runlin Miao¹, Xiang’ai Cheng¹, and Tian Jiang^1、3、*

Author Affiliations

¹College of Advanced Interdisciplinary Studies, National University of Defense Technology, Changsha 410073, China

²Defense Innovation Institute, Academy of Military Sciences PLA China, Beijing 100071, China

³Beijing Institute for Advanced Study, National University of Defense Technology, Beijing 100020, China

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DOI: 10.3788/COL202220.081301 Cite this Article Set citation alerts

Junhu Zhou, Jie You, Hao Ouyang, Runlin Miao, Xiang’ai Cheng, Tian Jiang. Temperature insensitive multi-channel light amplification systems on SOI platform[J]. Chinese Optics Letters, 2022, 20(8): 081301 Copy Citation Text

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Multi-channel Si photonic system. CHi represents the corresponding pump light λi and Stokes light λsi. Si wire waveguide height h = 220 nm, width w = 450 nm.

Fig. 1. Multi-channel Si photonic system. CH_i represents the corresponding pump light λ_i and Stokes light λ_si. Si wire waveguide height h = 220 nm, width w = 450 nm.

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$Dispersion coefficients of wire waveguides. (a) Propagation constant. (b) First-order dispersion coefficient. (c) Second-order dispersion coefficient. (d) Group refractive index.$

Fig. 2. Dispersion coefficients of wire waveguides. (a) Propagation constant. (b) First-order dispersion coefficient. (c) Second-order dispersion coefficient. (d) Group refractive index.

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Fig. 3. Four-channel SRS effect. (a) The propagation of pump lights. (b) The propagation of Stokes lights. (c) Input (dash line) and output (solid line) profiles of CH1 pump pulse. (d) Input (dash line) and output (solid line) profiles of CH1 Stokes pulse.

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Fig. 4. Transmission in the wire waveguide. (a) The propagation of 1435.68 nm pump pulse. (b) The propagation of 1551.60 nm Stokes pulse. (c) The transmission of the enlarged four-channel Stokes lights at 300 K and 400 K, respectively.

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Fig. 5. Temperature sensitive de-multiplexer. (a) The two-stage cascaded Mach–Zehnder wavelength filter. (b) Electric field intensity profile for the DC at a wavelength of 1.55 µm. (c) Transmission of de-multiplexer displayed in (a) at 300 K. (d) Transmission of de-multiplexer displayed in (a) at 400 K.

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Fig. 6. Transmission of the enlarged Stokes light through the four-channel de-multiplexer. (a) CH1 output port. (b) CH2 output port. (c) CH3 output port. (d) CH4 output port.

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Fig. 7. Proposed temperature insensitive flat pass-band filter. (a) Single cell of the cascaded Mach–Zehnder-like lattice filters. (b) The anti-thermal four-channel wavelength splitting filters.

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$(a) Simulated TO coefficients and effective refractive index. (b) Transmission of the designed temperature insensitive flat pass-band filter.$

Fig. 8. (a) Simulated TO coefficients and effective refractive index. (b) Transmission of the designed temperature insensitive flat pass-band filter.

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Fig. 9. Transmission of the enlarged Stokes lights through the anti-thermal four-channel de-multiplexer. (a) CH1 output port. (b) CH2 output port. (c) CH3 output port. (d) CH4 output port.

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