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Thermo-optical effects in high-power end-pumped vanadate lasersStrauss, Hencharl Johan 03 1900 (has links)
Thesis (PhD (Physics))--University of Stellenbosch, 2010. / ENGLISH ABSTRACT: The output power of end-pumped lasers is mainly limited by thermal effects in the bulk
crystal gain material. The thermal effects either fracture the crystal or cause degradation
in the laser beam quality and output power. This is especially pronounced in Nd:YVO4
and Nd:GdVO4 which exhibit strong thermal lensing. These two Nd3+ vanadate materials
are of great value because of their high emission cross sections which makes them excellent
gain materials for mode-locked, high repetition rate Q-switched and intra-cavity frequency
doubled lasers.
The two Nd3+ vanadates have very similar spectral properties but many publications claim
that the more expensive Nd:GdVO4 is thermo-optically superior to Nd:YVO4. However, a
debate ensued after theoretical calculations as well as measurements of the thermal conductivity
and thermo-optical coefficients indicated that the opposite is true. To our knowledge
there has never been a direct comparison of the thermal lensing of these two materials under
identical pumping and lasing conditions. In order to contribute to the debate we did such
measurements for different crystals of these two materials with equal low doping using three
different measurement methods. We subsequently determined that Nd:YVO4 has slightly
lower thermal lensing for the stronger gain -polarisation.
One of the measurement methods we used is a novel more reproducible one that we
developed for this purpose. It is more reproducible because it selectively measures only
the focal length of the central, relatively unaberrated part of the thermal lens. Another
measurement, utilising a probe beam through the laser crystal, found that there was almost
no increase in the temperature when lasing is interrupted. This indicated that there is almost
no upconversion present in the crystals which is probably due to their optimally chosen low doping.
A further consequence of the vanadate debate is that there is still confusion about the
value of the important thermo-optical coefficient for the higher gain -polarisation (dne/dT )
of Nd:YVO4. This parameter is of great importance in thermal calculations since the strength
of the thermal lens is largely dependent on it. We therefore numerically modelled the thermal
lensing in our crystals using different dne/dT values and found that the value given by Sato
& Taira (2007) matches our experimental results the best.
Our measurements also indicated that the thermal lens dioptric power increased nonlinearly
with pump power. This appeared to contradict theory of thermal lensing since we
knew that there was no upconversion in the crystals (which is the standard explanation for
the nonlinear increase). We proceeded to use our numerical modelling to identify the main
source of the nonlinear increase as the varying spectral output of the diode pump laser.
The findings in this thesis therefore extend knowledge of the thermo-optical properties of
the vanadates and increase understanding of the strongly aberrated thermal lenses formed inside
them. Furthermore, the findings now enable the power-scaling of end-pumped vanadates
lasers to higher levels. / AFRIKAANSE OPSOMMING: Die uitset drywing van longitudinale-gepompte vaste-toestand lasers word hoofsaaklik
beperk deur termiese effekte in die laser kristal. Die kristal word of gekraak of die laser
se bundel kwaliteit en uitset drywing verminder. Dit is veral ’n problem in Nd:YVO4 en
Nd:GdVO4 kristalle waarin sterk termiese lense voorkom. Hierdie twee Nd3+ vanadaat
kristalle is waardevol vanwee hulle ho¨e emissie deursnitte wat hulle uitstekend maak as versterkings
materiale vir modus-gesinkroniseerde, ho¨e repitisie, Q-geskakelde en binne-resonator
frekwensie-verdubbelde lasers.
Die twee vanadate het baie soortgelyke spektrale eienskappe, maar verskeie publikasies
beweer dat die duurder Nd:GdVO4 materiaal termo-opties beter is as Nd:YVO4. Onlangse
teoretiese berekeninge asook metings van die termiese en termo-optiese kwaliteite van die twee
kristalle toon egter die teenoorgestelde. Sover ons weet is daar nog geen direkte vergelyking
van die termiese lens in hierdie twee materiale onder identiese kondisies gedoen nie. Ons het
dus so ’n meting aangepak vir kristalle met identiese lae konsentrasie van die Nd3+ ioon deur
drie verskillende meet metodes te gebruik.
Een van die meet metodes is ’n nuwe, meer reproduseerbare metode wat ons ontwikkel
het vir hierdie doel. Dit is meer reproduseerbaar omdat dit slegs die binneste deel van die
termiese lens meet wat min sferiese aberrasie het. ’n Ander meeting, wat ’n toets-bundel
deur die kristal stuur, het getoon dat daar byna geen verhoging in die die temperatuur van
die kristal was toe ossilasie in die resonator onderbreek was nie. Dit is ’n aanduiding dat
dat daar byna geen op-omskepping teenwoordig is in die kristalle nie wat te danke is aan hul
optimale lae konsentrasie van die Nd3+ ioon.
’n Verdere gevolg van die debat is dat daar nog verwarring in die literatuur bestaan oor die waarde van Nd:YVO4 se termo-optiese dne/dT koeffisi¨ent. Hierdie parameter is van groot
belang in berekinge van die termiese lens se fokale lengte vir die ho¨er wins -polarisasie. Deur
numeriese modellering te gebruik het ons bevind dat die waarde wat verskaf word deur Sato
& Taira (2007) ons eksperimentele data die beste pas.
Ons metings het ook aangedui dat die dioptriese krag van die termiese lens nie linie¨er
toeneem ten opsigte van die geabsorbeerde pomp krag nie. Dit was o¨enskynlik teenstryding
met teorie oor termiese lense. Dit is omdat ons bevestig het dat daar geen op-omskepping in
die kristalle teenwoordig was nie, wat die standaard verklaring vir die nie linie¨eriteit is. Ons
het dus ons numeriese modellering gebruik om die hoofbron van die nie-lini¨ere toename te
identifiseer as die veranderende spektrale uitset van die diode pomp laser.
Die bevindings in hierdie tesis bou dus kennis op oor die termo-optiese eienskappe van
die vanadate en versterk begrip van die sterk termiese lense binne hulle. Verder stel die
bevindings ons nou in staat om die uitset drywing van longitudinale-gepompte vanadaat
lasers na ho¨er vlakke te skaal.
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On diode-pumped solid-state lasersHellström, Jonas January 2007 (has links)
The research that is presented in this thesis can be divided into two major parts. The first part concerns longitudinally pumped, bulk Er-Yb lasers. In these lasers, the main limitation is the thermal shortcomings of the phosphate glass host material. From the laser experiments and the spectroscopic measurements on crystalline host materials, as well as an investigation to bring further light to the physical background of the involved dynamics, the thesis presents some novel results that contribute to the search for a crystalline replacement. The second part concerns novel laser concepts applied to Yb-doped double tungstate lasers. Different crystal orientations are investigated, such as an athermal orientation for reduced thermal lensing and a conical refraction orientation for complete polarization tuning. Furthermore, the introduction of volume Bragg gratings in the cavity enables wide spectral tuning ranges and extremely low quantum defects. Regarding the first part, the main results are the achievement of 15 % slope efficiency in a monolithic, continuous-wave Yb:GdCOB laser and the achievement of Q-switching of the same laser. The Q-switched pulse durations were around 5-6 ns and the Q-switched slope efficiency was 11.6 %. For both lasers, a maximum output power of 90 mW was obtained, which is close to ordinary glass lasers under similar conditions. A spectroscopic investigation into the Er,Yb-codoped double tungstates was also performed and the results have enabled mathematical modeling of the fluorescence dynamics in these materials. Finally, the temperature dependence of the dynamics in Er,Yb:YAG was studied and the results have given some insight into the physical background of the mechanisms involved. Regarding the second part, different end-pumped Yb:KReW laser cavities were constructed to demonstrate the different concepts. With a laser crystal cut for propagation along the athermal direction at 17º angle clockwise from the dielectric direction Nm, the thermal lens could be reduced by 50 %. In these experiments the maximum output power was 4 W at 60 % slope efficiency. In another cavity incorporating a volume Bragg grating in a retroreflector set-up, the wavelength could be continuously tuned between 997 - 1050 nm. The spectral bandwidth was 10 GHz and the peak output power was 3 W. The same output power could also be obtained at 1063 nm with the grating positioned as an output coupler instead. If, on the other hand, the grating was positioned as an input coupler, 3.6 W output power at 998 nm was obtained at a quantum defect of only 1.6 %. Furthermore, using a crystal oriented for propagation along an optic axis, internal conical refraction could be used to establish arbitrary control of the polarization direction as well as the extinction ratio. Even unpolarized light could be enforced despite the highly anisotropic medium. With this configuration, the maximum output power was 8.6 W at 60 % slope efficiency which equals the performance of a reference crystal with standard orientation. The completely novel concepts of laser tuning with Bragg grating retroreflectors, of low quantum defect through Bragg grating input couplers and of polarization tuning by internal conical refraction can all easily be applied to several other laser materials as well. / QC 20100713
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