High-gain Al2O3:Nd3+ channel waveguide amplifiers at 880 nm, 1060 nm, and 1330 nm

Yang, Jing; Dalfsen, K. van; Wörhoff, Kerstin; Ay, F.; Pollnau, Markus

doi:10.1007/s00340-010-4001-2

Cited by 55 publications

(42 citation statements)

References 33 publications

(55 reference statements)

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“…5a shows the measured laser power as a function of the diode pump current. Due to the misalignment of WDM fiber with respect to the waveguide the measured laser power is much lower than what is actually emitted out of the waveguide [22]. The beat frequency as a function of diode pump current is shown in Fig.…”

Section: Dual Frequency Laser Characteristicmentioning

confidence: 97%

Carrier generation using a dual-frequency distributed feedback waveguide laser for phased array antenna (PAA)

Khan

Islam

Sarowar

et al. 2017

J. Eur. Opt. Soc.-Rapid Publ.

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Background: Carrier generation based on optical heterodyning techniques where a beat signal is generated from the mixing of two light sources can be interesting solution due to ease on tunability. The free running heterodyning scheme benefits with a very wide tuning capability and the generated carrier can be freely adjusted. However, the drawbacks come in the form of frequency stability. Heterodyning of two optical frequencies coming from a single laser cavity has shown its potential on improvement of frequency stability. Methods: The impact of the laser parameters (i.e., optical power and linewidth) on the quality of the generated carrier (i.e., phase/frequency stability and carrier-to-noise ratio) is analyzed for a 25 × 64 elements PAA system. An optically generated carrier signal using a dual-frequency distributed feedback waveguide laser in ytterbium doped aluminum oxide (Al 2 O 3 :Yb 3+ ) is analyzed and experimentally demonstrated in this paper. The carrier signal is used for downconversion of the signal received from a phased array antenna (PAA) of a DVB-S (Digital Video Broadcasting-Satellite) system. Results: An optical frequency locked loop (OFLL) to stabilize the generated carrier is implemented which results in a microwave frequency at ∼14 GHz with a phase noise of -75 dBc/Hz at 1 MHz offset from the center frequency and gives a loop settling time of 12 μs. By using the proposed OFLL, the long term and the short term frequency stability of the generated carrier has an Allan deviation of more than 1 × 10 −10 for an averaging time of 1000 s and a standard deviation of 39.4 kHz, respectively. The lasers linewidth should be in the order of tens of Hz, with a maximum relative intensity noise (RIN) of -107 dB/Hz and a minimum optical power of 0.94 mW. Conclusions: The optical carrier generation by OFLL using a DFL to comply with the requirements of the standard carrier used in commercial LNBs has been investigated. The detailed analysis of the OFLL scheme is presented. Specifications requirement on carrier power, linewidth and relative intensity noise of the optically generated carrier have been addressed. The optical carrier generation is experimentally demonstrated and the requirements on CNR have been determined by measuring the noise floor and the optical carrier power. The measured values are compared with the calculated values and found to be very close.

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Section: Dual Frequency Laser Characteristicmentioning

confidence: 97%

Carrier generation using a dual-frequency distributed feedback waveguide laser for phased array antenna (PAA)

Khan

Islam

Sarowar

et al. 2017

J. Eur. Opt. Soc.-Rapid Publ.

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“…3(a)). These emitted wavelengths correspond to stimulated emission from the 4 F 5/2 energy level to the 4 I 9/2 and 4 I 11/2 levels, respectively [4,5]. It is important to note that the number of observed lasing peaks (hence, the number of lasing modes) depends on many factors, including the coupling, input power, dopant concentration, device materials, and geometry.…”

Section: Effects Of Alumina Concentration On Quality Factor and Micromentioning

confidence: 99%

“…First, using a single pump source, it is possible to generate a wide range of emission wavelengths due to the multiple excitation and decay pathways of rare earth ions. For example, when neodymium is pumped near 800nm, lasing near 900-940nm, 1050-1150nm, and ~1330nm can be observed [4][5][6]. Second, rare earth ions have very large absorption cross sections for excitation.…”

Section: Introductionmentioning

confidence: 99%

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Nanowatt threshold, alumina sensitized neodymium laser integrated on silicon

Maker

Armani

2013

Opt. Express

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Low threshold lasers based on rare-earth elements have enabled numerous scientific discoveries and innovations in industry. However, pushing the threshold into the sub-microwatt regime has been stymied by a fundamental material phenomenon. Specifically, rare earth dopants form clusters which quench emission and reduce efficiency. Here, we fabricate resonant cavity lasers from neodymium-doped silica films containing alumina. The alumina prevents the clustering of the Neodymium, enabling the lasers to achieve thresholds of 530nanoWatts at room temperature.

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“…Energy-transfer upconversion (ETU), often assisted by energy migration (both described in Chapter 2), has a significant impact on the amplifier or laser performance of a number of rare-earth-ion-doped compounds by depleting the population of the longlived upper state of the corresponding luminescence transition, thereby diminishing the available optical gain [69][70][71][72][73][74][75][76][77][78]. ETU can also be exploited to deplete the lower laser level [79][80][81][82] or generate upconversion luminescence and lasing [83][84][85][86][87].…”

Section: Chapter 4 Energy-transfer Upconversionmentioning

confidence: 99%

Spectroscopic excitation and quenching processes in rare-earth-ion-doped AI203 and their impact on amplifier and laser performance

Agazzi¹

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High-gain Al2O3:Nd3+ channel waveguide amplifiers at 880 nm, 1060 nm, and 1330 nm

Cited by 55 publications

References 33 publications

Carrier generation using a dual-frequency distributed feedback waveguide laser for phased array antenna (PAA)

Carrier generation using a dual-frequency distributed feedback waveguide laser for phased array antenna (PAA)

Nanowatt threshold, alumina sensitized neodymium laser integrated on silicon

Spectroscopic excitation and quenching processes in rare-earth-ion-doped AI203 and their impact on amplifier and laser performance

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