Novel ultrafast sources on chip: filter driven four wave mixing lasers, from high repetition rate to burst mode operation

Alessia Pasquazi; Marco Peccianti; Sai T. Chu; David J. Moss; Roberto Morandotti

doi:10.1117/12.2211071

Novel ultrafast sources on chip: filter driven four wave mixing lasers, from high repetition rate to burst mode operation

Alessia Pasquazi, Marco Peccianti, Sai T. Chu, David J. Moss, Roberto Morandotti

Department of Physics

Research output: Chapters, Conference Papers, Creative and Literary Works › RGC 32 - Refereed conference paper (with host publication) › peer-review

1 Citation (Scopus)

Abstract

Passive fiber mode-locked lasers enable the excitation of multiple pulses per round trip representing a potential solutions for the increasing demand of practical optical sources with repetition rates of hundreds of GHz or higher. The control of such high repetition rate regimes is however a challenge. To this purpose, linear filters have been used in an "intracavity" configuration to force the repetition rate of the laser. This design is known as dissipative four wave mixing (DFWM) but it is usually unstable and hence marginally suitable for practical applications. We explore the use of nonlinear intracavity filters, such as integrated micro-ring resonators, capable of “driving” the FWM interaction in the laser. We term this approach as Filter-Driven FWM. With a proper choice of the filter properties in terms of free spectral range (FSR) and Q factor, we could observe stable regimes over a wide range of operating conditions, from high repetition rate oscillation at a 200GHz to the formation of two stable spectral comb replicas separated by the FSR of the main cavity (65MHz). High order filters, moreover, allow achieving nonlinear operation over large passbands. With an 11th order filter we achieve low-frequency mode-locking between the main cavity modes that oscillate within each resonance of the filter, producing burst pulsed operation. A stable mode-locked pulse train at 655GHz with an envelope of 42ps at 6.45MHz is achieved.

Original language	English
Title of host publication	Laser Resonators, Microresonators, and Beam Control XVIII
Editors	Alexis V. Kudryashov, Alan H. Paxton, Vladimir S. Ilchenko, Lutz Aschke
Publisher	SPIE
ISBN (Print)	9781628419627
DOIs	https://doi.org/10.1117/12.2211071
Publication status	Published - 2016
Event	SPIE LASE, 2016 (Volume 9727: Laser Resonators, Microresonators, and Beam Control XVIII) - San Francisco, United States Duration: 15 Feb 2016 → 18 Feb 2016 https://www.spiedigitallibrary.org/conference-proceedings-of-spie/9727/972701/Front-Matter-Volume-9727/10.1117/12.2239514.full

Publication series

Name	PROCEEDINGS OF SPIE
Publisher	SPIE
Volume	9727
ISSN (Print)	0277-786X
ISSN (Electronic)	2410-9045

Conference

Conference	SPIE LASE, 2016 (Volume 9727: Laser Resonators, Microresonators, and Beam Control XVIII)
Place	United States
City	San Francisco
Period	15/02/16 → 18/02/16
Internet address	https://www.spiedigitallibrary.org/conference-proceedings-of-spie/9727/972701/Front-Matter-Volume-9727/10.1117/12.2239514.full

Bibliographical note

Full text of this publication does not contain sufficient affiliation information. With consent from the author(s) concerned, the Research Unit(s) information for this record is based on the existing academic department affiliation of the author(s).

Research Keywords

Four wave mixing
Lasers
Mode locking
Pulsed laser operation
Resonators
Linear filtering
Microrings

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Pasquazi, A., Peccianti, M., Chu, S. T., Moss, D. J., & Morandotti, R. (2016). Novel ultrafast sources on chip: filter driven four wave mixing lasers, from high repetition rate to burst mode operation. In A. V. Kudryashov, A. H. Paxton, V. S. Ilchenko, & L. Aschke (Eds.), Laser Resonators, Microresonators, and Beam Control XVIII (PROCEEDINGS OF SPIE; Vol. 9727). SPIE. https://doi.org/10.1117/12.2211071

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title = "Novel ultrafast sources on chip: filter driven four wave mixing lasers, from high repetition rate to burst mode operation",

abstract = "Passive fiber mode-locked lasers enable the excitation of multiple pulses per round trip representing a potential solutions for the increasing demand of practical optical sources with repetition rates of hundreds of GHz or higher. The control of such high repetition rate regimes is however a challenge. To this purpose, linear filters have been used in an {"}intracavity{"} configuration to force the repetition rate of the laser. This design is known as dissipative four wave mixing (DFWM) but it is usually unstable and hence marginally suitable for practical applications. We explore the use of nonlinear intracavity filters, such as integrated micro-ring resonators, capable of “driving” the FWM interaction in the laser. We term this approach as Filter-Driven FWM. With a proper choice of the filter properties in terms of free spectral range (FSR) and Q factor, we could observe stable regimes over a wide range of operating conditions, from high repetition rate oscillation at a 200GHz to the formation of two stable spectral comb replicas separated by the FSR of the main cavity (65MHz). High order filters, moreover, allow achieving nonlinear operation over large passbands. With an 11th order filter we achieve low-frequency mode-locking between the main cavity modes that oscillate within each resonance of the filter, producing burst pulsed operation. A stable mode-locked pulse train at 655GHz with an envelope of 42ps at 6.45MHz is achieved.",

keywords = "Four wave mixing, Lasers, Mode locking, Pulsed laser operation, Resonators, Linear filtering, Microrings",

author = "Alessia Pasquazi and Marco Peccianti and Chu, {Sai T.} and Moss, {David J.} and Roberto Morandotti",

note = "Full text of this publication does not contain sufficient affiliation information. With consent from the author(s) concerned, the Research Unit(s) information for this record is based on the existing academic department affiliation of the author(s).; SPIE LASE, 2016 (Volume 9727: Laser Resonators, Microresonators, and Beam Control XVIII) ; Conference date: 15-02-2016 Through 18-02-2016",

year = "2016",

doi = "10.1117/12.2211071",

language = "English",

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series = "PROCEEDINGS OF SPIE",

publisher = "SPIE",

editor = "Kudryashov, {Alexis V.} and Paxton, {Alan H.} and Ilchenko, {Vladimir S.} and Lutz Aschke",

booktitle = "Laser Resonators, Microresonators, and Beam Control XVIII",

address = "United States",

url = "https://www.spiedigitallibrary.org/conference-proceedings-of-spie/9727/972701/Front-Matter-Volume-9727/10.1117/12.2239514.full",

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Pasquazi, A, Peccianti, M, Chu, ST, Moss, DJ & Morandotti, R 2016, Novel ultrafast sources on chip: filter driven four wave mixing lasers, from high repetition rate to burst mode operation. in AV Kudryashov, AH Paxton, VS Ilchenko & L Aschke (eds), Laser Resonators, Microresonators, and Beam Control XVIII. PROCEEDINGS OF SPIE, vol. 9727, SPIE, SPIE LASE, 2016 (Volume 9727: Laser Resonators, Microresonators, and Beam Control XVIII), San Francisco, United States, 15/02/16. https://doi.org/10.1117/12.2211071

Novel ultrafast sources on chip: filter driven four wave mixing lasers, from high repetition rate to burst mode operation. / Pasquazi, Alessia; Peccianti, Marco; Chu, Sai T. et al.
Laser Resonators, Microresonators, and Beam Control XVIII. ed. / Alexis V. Kudryashov; Alan H. Paxton; Vladimir S. Ilchenko; Lutz Aschke. SPIE, 2016. (PROCEEDINGS OF SPIE; Vol. 9727).

Research output: Chapters, Conference Papers, Creative and Literary Works › RGC 32 - Refereed conference paper (with host publication) › peer-review

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T2 - SPIE LASE, 2016 (Volume 9727: Laser Resonators, Microresonators, and Beam Control XVIII)

AU - Pasquazi, Alessia

AU - Peccianti, Marco

AU - Chu, Sai T.

AU - Moss, David J.

AU - Morandotti, Roberto

N1 - Full text of this publication does not contain sufficient affiliation information. With consent from the author(s) concerned, the Research Unit(s) information for this record is based on the existing academic department affiliation of the author(s).

PY - 2016

Y1 - 2016

N2 - Passive fiber mode-locked lasers enable the excitation of multiple pulses per round trip representing a potential solutions for the increasing demand of practical optical sources with repetition rates of hundreds of GHz or higher. The control of such high repetition rate regimes is however a challenge. To this purpose, linear filters have been used in an "intracavity" configuration to force the repetition rate of the laser. This design is known as dissipative four wave mixing (DFWM) but it is usually unstable and hence marginally suitable for practical applications. We explore the use of nonlinear intracavity filters, such as integrated micro-ring resonators, capable of “driving” the FWM interaction in the laser. We term this approach as Filter-Driven FWM. With a proper choice of the filter properties in terms of free spectral range (FSR) and Q factor, we could observe stable regimes over a wide range of operating conditions, from high repetition rate oscillation at a 200GHz to the formation of two stable spectral comb replicas separated by the FSR of the main cavity (65MHz). High order filters, moreover, allow achieving nonlinear operation over large passbands. With an 11th order filter we achieve low-frequency mode-locking between the main cavity modes that oscillate within each resonance of the filter, producing burst pulsed operation. A stable mode-locked pulse train at 655GHz with an envelope of 42ps at 6.45MHz is achieved.

AB - Passive fiber mode-locked lasers enable the excitation of multiple pulses per round trip representing a potential solutions for the increasing demand of practical optical sources with repetition rates of hundreds of GHz or higher. The control of such high repetition rate regimes is however a challenge. To this purpose, linear filters have been used in an "intracavity" configuration to force the repetition rate of the laser. This design is known as dissipative four wave mixing (DFWM) but it is usually unstable and hence marginally suitable for practical applications. We explore the use of nonlinear intracavity filters, such as integrated micro-ring resonators, capable of “driving” the FWM interaction in the laser. We term this approach as Filter-Driven FWM. With a proper choice of the filter properties in terms of free spectral range (FSR) and Q factor, we could observe stable regimes over a wide range of operating conditions, from high repetition rate oscillation at a 200GHz to the formation of two stable spectral comb replicas separated by the FSR of the main cavity (65MHz). High order filters, moreover, allow achieving nonlinear operation over large passbands. With an 11th order filter we achieve low-frequency mode-locking between the main cavity modes that oscillate within each resonance of the filter, producing burst pulsed operation. A stable mode-locked pulse train at 655GHz with an envelope of 42ps at 6.45MHz is achieved.

KW - Four wave mixing

KW - Lasers

KW - Mode locking

KW - Pulsed laser operation

KW - Resonators

KW - Linear filtering

KW - Microrings

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DO - 10.1117/12.2211071

M3 - RGC 32 - Refereed conference paper (with host publication)

SN - 9781628419627

T3 - PROCEEDINGS OF SPIE

BT - Laser Resonators, Microresonators, and Beam Control XVIII

A2 - Kudryashov, Alexis V.

A2 - Paxton, Alan H.

A2 - Ilchenko, Vladimir S.

A2 - Aschke, Lutz

PB - SPIE

Y2 - 15 February 2016 through 18 February 2016

ER -

Pasquazi A, Peccianti M, Chu ST, Moss DJ, Morandotti R. Novel ultrafast sources on chip: filter driven four wave mixing lasers, from high repetition rate to burst mode operation. In Kudryashov AV, Paxton AH, Ilchenko VS, Aschke L, editors, Laser Resonators, Microresonators, and Beam Control XVIII. SPIE. 2016. (PROCEEDINGS OF SPIE). Epub 2016 Apr 22. doi: 10.1117/12.2211071

Novel ultrafast sources on chip: filter driven four wave mixing lasers, from high repetition rate to burst mode operation

Abstract

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