Global ETD Search

1	The use of novel digital power supply to drive laser systems Doneddu, Daniele January 2010 (has links) Light-based therapies are becoming increasingly important and widely applied within the clinical practice. Their advantages over more traditional therapies have created an expanding market which is driving the development of more efficient and sophisticated devices. These devices allow a more precise control of the characteristics of the optical output to maximise benefits of the treatment. Although many studies have been conducted on light, and more specifically lasers, both from a therapeutic and a technological perspective, there is still much research to be undertaken. Laser systems have been used for more than two decades for the treatment of vascular lesions. Indeed the application of selective photothermolysis utilising the monochromaticity of the laser system has become the treatment of choice. However the treatment of larger blood vessels remains problematic. Many workers have, for theoretical and clinical reasons, elected to choose the YAG laser for the treatment of larger thread veins and vascular lesions containing larger vessels. The therapeutic output has been mixed and the need for further work identified. This thesis describes the design of a novel approach to the control of the temporal profile of the YAG laser. The design aspect of the work includes a computer modelling study which shows that careful control of the temporal parameters can in principle improve the therapeutic output. A novel approach to the digital control of the flashlamps pumping the YAG crystal is also described. The digital control of the flashlamp translates to sensitive control of the temporal profile of the laser output in a way that has not been described to date. The thesis therefore concludes that control of the temporal output of the YAG laser, if possible, should give improved therapeutic output and that the necessary level of control can be achieved by advanced digital techniques. Future clinical work should prove improved therapeutic results. 610
2	Classification of Points Acquired by Airborne Laser Systems Ruhe, Jakob, Nordin, Johan January 2007 (has links) During several years research has been performed at the Department of Laser Systems, the Swedish Defense Research Agency (FOI), to develop methods to produce high resolution 3D environment models based on data acquired with airborne laser systems. The 3D models are used for several purposes, both military and civilian applications, for example mission planning, crisis management analysis and planning of infrastructure. We have implemented a new format to store laser point data. Instead of storing rasterized images of the data this new format stores the original location of each point. We have also implemented a new method to detect outliers, methods to estimate the ground surface and also to divide the remaining data into two classes: buildings and vegetation. It is also shown that it is possible to get more accurate results by analyzing the points directly instead of only using rasterized images and image processing algorithms. We show that these methods can be implemented without increasing the computational complexity. Airborne laser systems LiDAR point clouds outlier detection ground estimation classification Remote sensing Fjärranalys
3	Classification of Points Acquired by Airborne Laser Systems Ruhe, Jakob, Nordin, Johan January 2007 (has links) <p>During several years research has been performed at the Department of Laser Systems, the Swedish Defense Research Agency (FOI), to develop methods to produce high resolution 3D environment models based on data acquired with airborne laser systems. The 3D models are used for several purposes, both military and civilian applications, for example mission planning, crisis management analysis and planning of infrastructure.</p><p>We have implemented a new format to store laser point data. Instead of storing rasterized images of the data this new format stores the original location of each point. We have also implemented a new method to detect outliers, methods to estimate the ground surface and also to divide the remaining data into two classes: buildings and vegetation.</p><p>It is also shown that it is possible to get more accurate results by analyzing the points directly instead of only using rasterized images and image processing algorithms. We show that these methods can be implemented without increasing the computational complexity.</p> Airborne laser systems LiDAR point clouds outlier detection ground estimation classification Remote sensing Fjärranalys
4	External cavity diode lasers and non-linear optical frequency conversion in spectroscopic applications Shah, Anjali January 2006 (has links) Semiconductor diode lasers are successful tools in atomic spectroscopy. They are routinely used in frequency conversion applications to develop devices that access regions of the spectrum not directly available. This thesis describes the practical application of novel violet diode laser systems and their possible inclusion in spectroscopic systems. The design, assembly and successful operation of a doubly resonant optical parametric oscillator is described. There is discussion of the spectral behaviour of the device and the potential for pumping with a violet diode laser. Methods to adapt the output from the solitary diode devices are demonstrated with the use of microlensed diode lasers and extended cavity configurations. Details of the current tuning, linewidth and smooth tuning characteristics of a number of the lasers used are given. A commercial violet diode laser is used within an extended cavity to measure the hyperfine structure of atomic indium from a hollow cathode galvatron source at room temperature. Stabilisation of the diode laser to a line from the indium spectrum is attempted. The remainder of the thesis is concerned with the development of techniques to deliver clearer and more precise spectral information about trace species. Microlensed red and violet diode lasers are used to generate light at 254nm via sum frequency generation for the direct detection and modulation spectroscopy of mercury vapour, with microlensed lasers with modulation allowing more accurate discrimination between spectral features than direct absorption measurements. In addition Raman tweezers modulation spectroscopy is undertaken to investigate polymer microspheres and biological cell samples where the use of the modulation technique demonstrated improvements in the acquisition time and clarity of spectra through increased signal to noise and rejection of background fluorescence effects. A comparison between the direct and modulation techniques for all the systems indicates the greater sensitivity of the modulation technique. 543.5
5	Development of phosphor thermometry systems for use in development gas turbine engines Khalid, Ashiq Hussain January 2011 (has links) The pursuit for improved engine efficiency is driving the demand for accurate temperature measurement inside turbine engines. Accurate measurement can allow engines to be operated closer to their design limits to improve thermal efficiency. It can enable engineers to verify mechanical integrity, provide better prediction of component life, validate CFD and other design tools and aid the development for leaner more efficient engines. Unfortunately, experimentally measuring surface temperatures under harsh rotating conditions is challenging. This EngD study conducted by Ashiq Hussain Khalid at the University of Manchester and Rolls-Royce plc, reviews the rationale of using phosphor thermometry over existing methods, including thermocouples, pyrometry and thermal paints/melts, which lack detail, accuracy, or are too expensive for continuous testing. Although phosphor thermometry exhibits desirable characteristics, the high temperature and fast rotating engine environment presents some challenges that would need to be addressed before a successful measurement system can be implemented. Examples of such issues include: rising blackbody radiation, restricted optical access, fibre optic constraints and limited time period to collect data. These factors will impose measurement limits and greatly influence the design philosophy of the system, including phosphor choice, phosphor lifetime characteristics, bonding technique, excitation/detection methodologies and probe design. Taking these into consideration, the research focuses on the development of phosphor thermometry systems for use in development gas turbine engines, with measurement solutions for specific engine components. The high pressure turbine blade was given research priority. A number of phosphors including YAG:Tb, YAG:Tm. Y2O3:Eu and Mg3F2GeO4:Mn were investigated and characterised in terms of intensity and lifetime decay, with increasing temperature up to 1500oC. Spectral analysis and absolute intensity measurements established emission peaks and permitted comparative quantitative analysis to optimise system setup. The intensity of phosphor emission relative to Planck's blackbody radiation was also performed. YAG:Tm under 355nm illumination was found to exhibit the highest emission intensity at high temperatures, and because its spectral emission peak at 458nm was the lowest, its advantage in terms of blackbody radiation was further amplified. For rotating components, an upper temperature limit is reached based on the emission intensity at rising blackbody radiation levels and the system's ability to detect fast decays. A lower limit is reached based on the quenching temperature, probe design and rotational velocity. There are different methods to correct the distorted decay waveform as it traverses through the acceptance cone of the fibre. A phosphor selection criterion, taking into consideration these limitations, was successfully applied for various rotating engine components. The optical layout was setup and tested on stationary and rotating cases under laboratory conditions using similar design constraints, including fibre choice, maximum permissible lens size and target distances. A series of tests validated design methodologies and assumptions to enable testing on full scale rotating engine components. Mg3F2GeO4:Mn, using 355nm illumination, was found to be the most suitable phosphor for the HP drive cone. The estimated performance under the expected rotational speeds was found to be 624-812°C with a standard uncertainty of ±0.99%. YAG:Tm, illuminated with 355nm, was found to be the most promising phosphor for high pressure turbine blade measurements. The performance under the expected rotational speeds was found to be 1117-1375°C with a standard uncertainty of ±0.97%. This is better than other competing technologies that are currently available for temperature measurement of rotating turbine blades. 620
6	Interférométrie Simultanée avec Deux Espèces Atomiques ⁸⁷Rb/⁸⁵Rb et Applications aux Mesures Inertielles / Simultaneous Interferometry with Two Atomic Species ⁸⁷Rb/⁸⁵Rb and Applications to Inertial Measurements Bonnin, Alexis 23 November 2015 (has links) Dans la problématique émergente des expériences visant à tester le Principe d'Équivalence à l'aide de capteurs inertiels à atomes froids, cette thèse porte sur la réalisation et la caractérisation d'un interféromètre atomique double espèce simultané (⁸⁷Rb et ⁸⁵Rb) qui permet l'obtention d'une mesure extrêmement sensible de l'accélération différentielle. L'interféromètre, de type Mach-Zehnder, repose sur la manipulation simultanée des ondes de matière atomiques à l'aide de transitions Raman stimulées. Le système laser est basé sur le doublage en fréquence d'une unique source laser à 1560 nm. L'ensemble des fréquences lasers requises pour la manipulation des deux isotopes (piégeage, refroidissement, sélection, interférométrie et détection) sont générées par modulation en phase de cette source. Une modélisation détaillée des réponses inertielles de l'interféromètre ainsi que l'analyse d'une méthode d'extraction de la phase différentielle à partir du signal elliptique ont été menées. La mesure de l'accélération différentielle a conduit à un test atomique du Principe d'Équivalence Faible de η(⁸⁷Rb,85Rb) = (1.3 ± 3.2) × 10⁻⁷, à l'état de l'art. L'aspect simultané de la mesure a permis de mettre en évidence la réjection du bruit de vibration par effet de mode commun pour la première fois avec deux espèces différentes, le facteur de réjection étant aujourd'hui de 50 000. Les performances actuelles de l'instrument sur la mesure d'accélération différentielle montrent une sensibilité de 1.23×10⁻⁷g/√Hz et une résolution de 2×10⁻⁹g pour des temps d'intégration inférieurs à quelques heures. Pour finir, des modes de fonctionnement innovants d'interféromètres atomiques double espèce pour la mesure d'accélération embarquée sont explorés. / In the emerging issue of testing the Equivalence Principle with cold atom inertial sensors, this thesis focuses on the realization and the characterization of a simultaneous dual-species atom interferometer (⁸⁷Rb & ⁸⁵Rb) which allows to measure the differential acceleration in an extremely sensitive way. The Mach-Zehnder type atom interferometer relies on the simultaneous handling of atomic wave-packets with stimulated Raman transitions. The laser system is based on the frequency doubling of a single laser source at 1560 nm. All the required laser frequencies for handling both isotopes (trapping, cooling, selection, interferometry and detection) are generated by phase modulating this source. A detailed modeling of the interferometer's inertial responses and an analysis of a method to extract the differential phase were carried out. The differential acceleration measurement led to an atom based test of the Weak Equivalence Principle of η(⁸⁷Rb,85Rb) = (1.3 ± 3.2)×10⁻⁷, at the state-of-the-art. The simultaneous aspect of the experiment allowed to highlight for the first time common mode vibration noise rejection with two different atomic species, a rejection factor of 50 000 being currently achieved. The current performance of the instrument exhibits a sensitivity on the differential acceleration of 1.23 × 10⁻⁷g/√Hz and a resolution of 2 × 10⁻⁹g for integration times lower than few hours. Finally, innovative operating modes of dual-species atom interferometers for on-board acceleration measurements are explored. Interférométrie atomique Capteur inertiel Principe d'équivalence Atomes Froids Systèmes laser Réjection des vibrations Atom interferometry Inertial sensor Equivalence Principle Cold Atoms Laser systems Vibrations rejection
7	Experiments with Bose-Einstein Condensates in Microgravity Grzeschik, Christoph 12 July 2017 (has links) Atominterferometer erlauben es, Beschleunigungen mit bisher nicht erreichter Präzision zu messen. Anwendungen in der Grundlagenforschung beinhalten Gravitationswellendetektoren, die Bestimmung von Naturkonstanten oder Tests des schwachen Äquivalenzprinzips. Die Sensitivität eines Sensors für Tests des schwachen Äquivalenzprinzips skaliert quadratisch mit der Zeit der freien Entwicklung der Atome während der Interferometersequenz. Durch die Verwendung von Bose-Einstein-Kondensaten mit stark reduzierter Ausdehnungsgeschwindigkeit sowie dem Betrieb in Schwerelosigkeit kann die Sensitivität um Größenordnungen verbessert werden. Das QUANTUS-2 Experiment stellt die zweite Generation eines mobilen Atominterferometers dar, welches am Fallturm in Bremen zum Einsatz kommt und dient als Wegbereiter für zukünftige Experimente mit kalten Atomen auf Satelliten. Durch differentielle Messung der Beschleunigung von Rubidium und Kalium mit Hilfe der Atominterferometrie soll das schwache Äquivalenzprinzip getestet werden. Im Rahmen dieser Arbeit wurde das auf mikro-integrierten Diodenlasern sowie einer kompakten Elektronik basierende Rubidiumlasersystem aufgebaut und qualifiziert. Nach erfolgter Integration in die QUANTUS-2 Kapsel, wurden über 200 Abwürfe und Katapultflüge am Fallturm absolviert. Diese demonstrieren die Robustheit des Experimentes unter Beschleunigungen von bis zu 43 g während eines Katapultfluges. Die Dynamik des Kondensates wurde in Schwerelosigkeit untersucht und die Ausbreitungsgeschwindigkeit in allen drei Raumrichtungen mit Hilfe einer magnetischen Linse verringert. Die dabei erreichten Ausbreitungsgeschwindigkeiten entsprechen effektiven Temperaturen von unter 120 pK eines thermischen Ensembles. Dieser stellt den niedrigsten in allen drei Raumrichtungen erreichten Wert dar. Die gezeigten Ergebnisse demonstrieren somit die Verfügbarkeit wichtiger Schlüsselkonzepte zukünftiger hochpräziser Quantensensoren auf Satelliten. / Atom interferometers offer the possibility to measure accelerations with unprecedented precision. Applications in fundamental research include gravitational wave detectors, the determination of physical constants, or tests of the weak equivalence principle. The sensitivity of an atom interferometer testing the weak equivalence principle scales quadratically with the time of free evolution of the atoms during the interferometer sequence. By using Bose-Einstein condensates with ultra-low expansion rates as test masses and operating the experiment in microgravity, one can enhance the sensitivity by orders of magnitude. QUANTUS-2 is the second generation mobile atom interferometer to be operated at the drop tower in Bremen and serves as a pathfinder for future cold atom experiments in space. It is envisaged to test the weak equivalence principle by a differential measurement of the acceleration of rubidium and potassium by means of atom interferometry. Within this thesis, the rubidium laser system was set up and qualified. It is based on micro-integrated laser modules and compact electronics. After integration into the QUANTUS-2 capsule, 200 drops and catapult flights were conducted at the drop tower. These are demonstrating the robustness of the complete experiment when being subjected to accelerations of up to 43 g during a catapult flight. The dynamics of the condensate were analyzed and the mean kinetic energy was reduced in all three dimensions by means of a magnetic lens. Expansion rates equivalent to a thermal ensemble having a temperature below 120 pK have been reached and represent the lowest value ever achieved in all three dimensions. The results prove the availability of relevant key concepts for future high-precision quantum sensors on a satellite platform. Bose-Einstein-Kondensation Delta-Kick Kühlung Atominterferometrie Diodenlasersysteme Bose-Einstein condensation delta-kick cooling atom interferometry diode laser systems 530 Physik UR 2000 UH 8700 ddc:530
8	Measurements of local electric fields by doppler-free laser spectroscopy of hydrogen resonance lines Adamov, Minja Gemisic 04 January 2007 (has links) In dieser Arbeit wurde eine einfache laserspektroskopische Messmethode für lokale elektrische Feldstärken im Hinblick auf ihre Messmöglichkeiten und -grenzen untersucht. Als empfindliche optische Feldsensoren dienen dabei Wasserstoffatome, für die die Stark-Aufspaltung der Spektrallinien im elektrischen Feld wohl bekannt und exakt berechenbar ist. Die experimentellen Untersuchungen wurden an einer Niederdruck-Gaszelle durchgeführt, in der ein elektrisch geheizter Wolframdraht für thermische Dissoziation von Wasserstoffmolekülen sorgte. Die Wasserstoffatome wurden durch zwei gegenläufige Laserstrahlen Doppler-frei angeregt. Die Durchstimmung der schmalbandigen Laserstrahlung über den Wellenlängenbereich der Zwei-Photonen-Resonanz lieferte direkt das vom elektrischen Feld hervorgerufene Stark-Spektrum des angeregten Zustands. Weil die Methode im Gegensatz zu ähnlichen, erheblich aufwendigeren Verfahren nur die niedrigsten Wasserstoff-Energieniveaus benutzt, die mit Zwei-Photonen-Anregung direkt aus dem Grundzustand erreichbar sind, kommt sie mit einem einzigen Laser aus. Für das erste angeregte Niveau mit n = 2 wird Strahlung bei 243 nm benötigt, das nächsthöhere Niveau mit n = 3 erfordert 205 nm. Für n = 2 wurden Untersuchungen an Wasserstoff und Deuterium durchgeführt und Stark-Spektren mittels optogalvanischer Detektion gemessen. Schwerpunkt der Arbeit waren aber die Messungen an Wasserstoff für n = 3, bei denen zusätzlich Balmer-alpha-Fluoreszenz im Sichtbaren zur Detektion eingesetzt werden konnte. Bei elektrischen Feldern bis 200 V/cm wurden Stark-Spektren für drei verschiedene Polarisationszustände der Laserstrahlung aufgenommen. Als Ergebnis konnte jeweils ein Paar isolierter Stark-Komponenten in den Spektren identifiziert werden, dessen gut messbarer Frequenzabstand durch Vergleich mit theoretischen Werten die Bestimmung der elektrischen Feldstärke ermöglicht. / A method for electric field measurements that observes the Stark spectra of the low excited levels n = 2 and n = 3 of atomic hydrogen has been explored in this work. As advantage these levels can be excited Doppler-free from the ground state by a single laser and the highly resolved Stark spectra are easy to understand and to be calculated. Good sensitivity of electric field measurements is achieved with specially designed solid state laser systems, which provide tuneable pulsed UV radiation with a high pulse peak-power and a narrow bandwidth needed for Doppler-free two-photon excitation. Using hydrogen and deuterium the Stark spectra of the n = 2 level are detected as optogalvanic signal. For three different cases of laser polarization the n = 3 spectra of hydrogen are measured simultaneously with optogalvanic and laser induced Balmer alpha fluorescence detection. Electric fields down to 200 V/cm can be determined from the Stark spectra of n = 2 level, while the spectra of n = 3 level enable measurements of electric fields as small as 50 V/cm in each of the three cases of laser polarization. Wasserstoffatom elektrisches Feld Laserspektroskopie UV-Lasersysteme hydrogen atom electric field laser spectroscopy UV-laser systems 530 Physik 29 Physik, Astronomie ddc:530
9	Bradford Non-Lethal Weapons Research Project (BNLWRP). Research Report 1. Lewer, N. January 1997 (has links) yes / The NLW database illustrates the extensive and eclectic literature regarding NLWs which covers the last few decades. It currently contains over 250 entries. It is important to have access not only to the more recent material, but also to earlier sources since many of the general debates and controversies have already been rehearsed, and lessons learnt from them are still relevant today. Yet, it is also vital to follow new developments of NLWs closely because rapidly changing technology is producing weapons whose implications for integration into military and civil police forces have yet to be clearly defined and understood. Of particular interest are not only NLW applications for war fighting, but opportunities for deployment in peace enforcement and peace keeping missions. These technologies span many bases including: psycho-chemicals; unmanned weapons platforms and delivery systems; biogenetics; acoustic and microwave weapons; biological and chemical weapons; laser systems; kinetic energy ballistics; dual purpose (lethal/non-lethal) weapons; and, sprays and foams which inhibit movement. The database will keep up to date on these developments and future reports will highlight new issues and debates surrounding them. With these rapid technological advances come a series of associated dangers and concerns including: the ethics of use; implications for weapons control and disarmament treaties; military doctrine; public accountability and guidelines; dangers of misuse and proliferation; and, research and development strategies. Using the database, and drawing from military and non-military sources, this report will select the main current issues and debates within the non-lethal community. Bearing in mind that many operations undertaken by military forces are now more akin to policing actions (such as peace support operations) there are lessons to be learnt by military units from civil police experience. There still remains a tension between perceived benign and malign intent both in NLW operational use and non-lethal research and development. Non lethal weapons War Peace enforcement Peace keeping missions Kinetic energy ballistics Microwave weapons Acoustic weapons Biogenetics Unmanned weapons platforms Psycho-chemicals Laser systems Dual purpose (lethal/non-lethal) weapons Sprays and foams
10	Broadly Tunable External Cavity Quantum Cascade Laser Matsuoka, Yohei 26 June 2020 (has links) Mitt-Infrarot-Technologie (mid-IR) ist ein äußerst leistungsfähiges Werkzeug für die Anwendung in der Molekülspektroskopie, da die Schwingungsmoden vieler Moleküle in diesem Wellenlängenbereich liegen. Der Quantenkaskadenlaser mit externem Resonator (EC-QCL) kann alle Bereiche dieses Spektrums abdecken. Das Hauptanliegen dieser Arbeit ist die Verbesserung der Leistung des EC-QCL im Hinblick auf die Breite des Wellenlängen-Durchstimmbereichs und die Laserleistung. Theoretische Untersuchungen bestätigen zunächst, dass der QCL die Schlüsselrolle bei EC-Systemen einnimmt: Die Effizienz des EC wird bestimmt durch die Effizienz des QCL und die Güte der Antireflex-Schicht (ARC) der Laserfacette. Die Breite des Durchstimmbereichs wird bestimmt durch das Gain-Spektrum des QCL. Im Rahmen dieser Arbeit wurden die QCL in unserer Gruppe hergestellt und vom QCL-Wachstum selbst bis hin zur Facettenbeschichtung optimiert. Eine der größten Herausforderungen in der Herstellung des EC-Systems ist die Reduktion des Reflexionsvermögens innerhalb der Facetten des Laserchips. Dafür haben wir ein neues ARC-Konzept entwickelt und auf dem beschichteten Substrat demonstriert, dass innerhalb des gesamten, sehr breiten Wellenlängenbereichs von 7–12 μm die Reflexion auf unter 1% reduziert wird. Das Beschichtungsmodell wurde außerdem auf „broad-gain“-QCL-Facetten angewendet, wodurch die Reflexion auf 0,75% über den gesamten Emissions-Wellenlängenbereich reduziert werden konnte. Ein weiterer Schwerpunkt dieser Arbeit ist die Entwicklung und Konstruktion von EC-Lasersystemen. Es wurden zwei kompakte Laser vom Littrow-Typ entwickelt, die von 920 cm-1 bis 1190 cm-1 durchstimmbar sind und die eine Pulsleitung von 0.45 W erreichen. Außerdem wurde eine neue optische Konfiguration des EC-Systems vorgeschlagen um eine höhere Ausgangsleistung zu erzielen. Dieser „Intra-cavity Out-coupling Laser“ erreicht eine Pulsleistung von 1 W und den gleichen Emissionbereich wie die beiden Littrow-Laser. / Mid-infrared (mid-IR) technology is a very powerful tool for molecular spectroscopy since vibration modes of many molecules lie in this wavelength range. The External-Cavity Quantum Cascade Laser (EC-QCL) can cover any part of this spectral range. The main goal of this study is to improve EC-QCL performance in terms of wavelength tunability and laser power. The theoretical study about Quantum Cascade Laser (QCL) and EC systems has confirmed that the QCL plays the core role of EC-QCL systems; the power efficiency of an EC system is determined by the combination of the power efficiency of QCL and AR-coating of the laser facet. The width of the tuning range is determined by the gain spectrum of QCL. During this work, QCLs have been fabricated in our group and the optimization of these factors were carried out with various approaches, from QCL growth to facet coatings. One of the major challenges in making EC systems is to reduce the intra-facet reflectivity of the laser chip, and we first proposed a new anti-reflection (AR) coating concept and demonstrated its performance for the first time to the community, achieving good reduction of reflection of the AR-coated substrate over 7-12 μm range, keeping below R < 1% reflection over the entire spectrum. The coating model was applied on broad-gain QCL facets, and the reflection was reduced to 0.75% over the entire emission wavelength range. Furthermore, this work focused on the development and engineering of laser systems, and two compact Littrow-type lasers and an EC system with a new optical configuration have been developed, achieving good performances; tunable from 920 cm-1 to 1190 cm-1 and 0.45 W pulse power. The new type of laser, an Intra-cavity out-coupling EC laser, was also proposed to enhance the power output and achieved over 1 W pulse power with keeping the same tuning range as the Littrow-type. 量子カスケードレーザー反射防止膜中赤外技術外部共振器型レーザー Quantenkaskadenlaser Mitt-Infrarot-Technologie Antireflex-Beschichtung EC-Lasersystemen Mid-Infrared technology Quantum cascade lasers External cavity quantum cascade lasers Anti-reflection coating External cavity laser systems 530 Physik UH 5616 ddc:530

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