Development of Ultrafast Fiber Laser Sources

Churin, Dmitriy

January 2015

The development of high average and peak power ultrashort pulsed fiber lasers is important for many critical research, industrial, and defense applications. However, the performance of mode-locked fiber oscillators still lags behind that of solid-state counterparts such as Kerr-lens mode-locked Ti:sapphire lasers. Despite the drawbacks in cost, size and required maintenance, Ti:sapphire remains the workhorse of ultrafast science. One of the remaining challenges for fiber lasers to overcome is their limited set of accessible wavelengths. Unfortunately, readily available ytterbium, erbium and thulium fiber lasers can produce coherent radiation only near 1, 1.55 and 2μm, respectively. There remain a significant number of wavelength regions that fiber lasers cannot address. In this thesis, novel fiber lasers producing ultrashort pulses at wavelengths not currently accessible with established active rare-earth-doped fibers are investigated. Our main approach is to use various nonlinear optical effects to generate new laser wavelengths. First, a watt-level synchronously pumped Raman fiber oscillator generating tens of nanojoules femtosecond pulses is demonstrated. Stimulated Raman scattering in a passive fiber within an oscillator cavity allows formation of Raman pulses that are spectrally redshifted with respect to the pump pulses. World-record output pulse energy and conversion efficiency have been achieved with our femtosecond Raman fiber laser design. We have also demonstrated a high power, widely tunable all-fiber optical parametric oscillator (FOPO) based on four-wave mixing in a passive fiber. The FOPO is synchronously pumped with an Yb³⁺-doped mode-locked fiber laser working at ~1040nm. The FOPO produces ultrashort pulses tunable from 760 to 1560nm. Record pulse energy is generated at the output of the femtosecond FOPO. Depending on the configuration of the FOPO, the duration of produced pulses varies between 170fs and 3ps. This new laser source has similar performance to standard Ti:sa femtosecond lasers so it can potentially replace the latter in many applications. Ultrashort optical pulses in the mid-IR and long-IR range (2-20 μm) have many important applications in gas sensing, counter-measures, etc. The realization of the ultrashort pulses in the mid-IR and long-IR wavelengths requires the use of free-space nonlinear crystals. An efficient mid-IR source based on difference frequency generation (DFG) in an AgGaS₂ crystal using femtosecond erbium/thulium pump fiber laser has been proposed and demonstrated. The photon conversion efficiency of the pump wave (1.55μm) to idler wave (9.2μm) has been measured to be 16%, which is today a record for conversion of near-IR light radiation from fiber lasers to 9μm spectral range. Potentially the photon conversion efficiency can be increased up to 60% by using pump pulses having higher peak power. Finally, generation of supercontinuum (SC) light in the mid-IR spectral range is also demonstrated. It is well known that SC produced in standard optical fibers is limited to ~6μm by material absorption. The liquid core optical fiber platform has been proposed to address this matter. Several highly nonlinear liquids have minimal absorption in the mid-IR wavelength range, which potentially allows us to create broadband SC light in this spectral region. SC generation up to 2.4μm in an integrated hollow core optical fiber filled with CS₂ has been demonstrated. Further development of the liquid core optical fiber platform should allow generation of the SC covering wavelengths beyond 6μm.

Laser physics

Nonlinear optics

Optical Sciences

Fiber optics

Ανάλυση των εξελίξεων και των μελλοντικών προοπτικών με βάση τα ερευνητικά δεδομένα στη χρήση των δικτύων υψηλής τάσης για τηλεπικοινωνιακούς σκοπούς

Κατσαούνης, Ιωάννης

03 March 2008

Αντικείμενο αυτής της διπλωματικής εργασίας είναι η ανάλυση των εξελίξεων και των μελλοντικών προοπτικών με βάση ερευνητικά δεδομένα στη χρήση των δικτύων υψηλής τάσης για τηλεπικοινωνιακούς σκοπούς. / Purpose of this paper is the analysis of the development and the future perspectives based on research information and papers on the use of high voltage network for telecommunication reasons.

Υψηλή τάση

Οπτικές ίνες

621.382 75

High voltage

Fiber optics

Propagation and loss characteristics of cladded optical fibers

Martucci, Joseph

January 1973

No description available.

Fiber optics

Wave guides

Glass fibers

Laser communication systems

Chaotic communication with erbium-doped fiber ring lasers

VanWiggeren, Gregory D.

05 1900

No description available.

Telecommunication systems

Chaotic behavior in systems

Synchronization

Lasers

Fiber optics

Alignment tolerant, single-fiber, bi-directional link

Wang, Shih-Cheng

05 1900

No description available.

Tolerance (Engineering)

Optical communications

Fiber optics

Light emitting diodes

Error detection capability and coding schemes for fiber optic communication

Chih, Samuel C. M.

05 1900

No description available.

Fiber optics

Optical communications

Development of MMIC-based modules for RF/Optical subcarrier multiplexed communications

Han, SangWoo

05 1900

No description available.

Microwave integrated circuits

Fiber optics

Optical communications

Multiplexing

Integrated optical tapped-delay-lines : design, analysis and implementation

Bao, Yufei

08 1900

No description available.

Fiber optics

Optical wave guides

Electric power distribution

Long-period fiber gratings fabricated with focused CO₂ laser pulses

Davis, Donald D., Jr.

05 1900

No description available.

Carbon dioxide lasers

Integrated optics

Fiber optics

Optical communications

All-fiber modulators for laser applications

Malmström, Mikael

January 2012

The objective of this thesis was to explore the usefulness of all-fiber modulators for laser applications. The modulators were all based on refractive index change achieved in the core of the studied fiber- components, exploiting either the elasto-optic effect or the electro-optic effect. This was realized with the aid of electrodes inside the fiber cladding close to the core that provided either thermal stress in the core, or an electric field across the core. The electrodes consisted of low melting-point alloys, such as BiSn and AuSn, which were pushed into the hole-fiber, in the liquid state, which then solidified to form solid electrodes filling the entire hole. Together with an analyzer such as a polarizer or an interferometer the achieved refractive index modulation in the core could then be translated into an amplitude modulation of the guided light, which was subsequently utilized for switching fiber-lasers to generate cavity dumped, Q-switched, or mode-locked pulses. The fast rise/fall-time of a few nanoseconds for the elasto-optic devices was due to the fast thermal expansion of the electrodes. The maximum repetition rate, however, was limited to a few tens of kHz, due to the slow thermal processes for dissipation of the applied energy. The electro-optic fiber components, which displayed similar rise/fall-times on the other hand, showed a much higher cut-off frequency of 16 MHz. The electro-optic, all-fiber switch was also employed to select single pulses at 1 MHz repetition rate out of a 7 MHz train of pulses. Additionally, simulations using the finite element method were performed in order to gain insight and to explain the underlying processes of the observed response of a long-period grating written in a 2-hole fiber with electrodes, when applying HV-pulses to one of these. The thesis shows that the studied fiber-components show great potential of becoming complementary devices with high damage threshold for all-fiber laser applications in the future. / <p>QC 20121129</p>

All-fiber

fiber optics

modulation

q-switching

mode-locking