Manipulating Beam Propagation in Slow-Light Media

Hogan, Ryan

28 September 2023

Materials with resonant features can have a rapidly changing refractive index spectrally or temporally that gives rise to a changing group index. Depending on the wavelength of the input light, this light can see regimes of normal or anomalous dispersion. Within these regions, the group index can become large, depending on the optical effect used, and give rise to slow or fast light effects. This thesis covers two platforms that exhibit the use of slow and fast light. Slow and fast light are used to manipulate and enhance other optical effects in question. As the focus of this thesis, we examine a rotating ruby rod and spaceplates based on multilayer stacks, both considered as slow- and fast-light media. Light propagation through each platform is modelled and simulated to compare to the experiment. The simulation results for both platforms match well with the measured experimental effects and show the feasibility and utility of slow or fast light to manipulate or enhance optical effects. We simulate light propagation in a rotating ruby rod as a rotating, anisotropic medium with thermal nonlinearity using generalized nonlinear Schrodinger equations, modelling the interplay of many optical effects, including nonlinear refraction, birefringence, and a nonlinear group index. The results are fit to experimentally measured results, revealing two key relationships: The photon drag effect can have a nonlinear component that is dependent on the motion of the medium, and the temporal dynamics of the moving birefringent nonlinear medium create distorted figure-eight-like transverse trajectories at the output. We observe light propagation through a rotating ruby rod where the light is subject to drag. Light drag is often negligible due to the linear refractive index but can be enhanced by slow or fast light, i.e., a large group index. We find that the nonlinear refractive index can also play a crucial role in the propagation of light in moving media and results in a beam deflection. An experiment is performed on the crystal that exhibits a very large negative group index and a positive nonlinear refractive index. The negative group index drags the light opposite to the motion of the medium. However, the positive nonlinear refractive index deflects the beam along with the motion of the medium and hinders the observation of the negative drag effect. Therefore, it is deemed necessary to measure not only the transverse shift of the beam but also its output angle to discriminate the light-drag effect from beam deflection. This work could be applied to dynamic control of light trajectories, for example, beam steering and velocimetry. For the following two chapters, we will focus on a different slow-light platform. This platform focuses on optics that we developed and tested that compress the amount of free-space propagation using multilayered stacks of thin films known as spaceplates. We design and characterize four multilayer stack-based spaceplates based on two design philosophies: coupled resonators and gradient descent. Using the transfer-matrix method, we simulate and extract the angular and wavelength dependence of the transmission phase and transmittance to extract and predict compression factors for each device. A brief theoretical investigation is developed to predict resonance positions, spacing, and bandwidth. We measure the transverse walk-off to extract the compression factor of four multilayer stack-based spaceplates as a function of angle and wavelength. One of the devices was found to have a compression factor of $R=176\pm14$, more than ten times larger than previous experimental records. We increased the numerical aperture of one of the devices by ten times, and we still observed a compression factor of $R=30\pm3$, two times larger than the most recent experimental measurements. We also measured focal shifts up to 800 microns, more than 40 times the device size, typically 10-12 microns thick. The multilayer stack-based spaceplates we studied here show great promise for ultrathin flat optical systems that can easily be integrated into a modern-day imaging system.

Slow light

Light propagation

Photon drag

Spaceplates

Nonlinear Schrodinger equations

Dynamique ultrarapide de lasers à cascade quantique Terahertz - le graphène comme émetteur Terahertz / Ultrafast dynamics of Terahertz quantum cascade lasers - graphene as Terahertz emitter

Maysonnave, Jean

19 June 2014

La gamme des ondes terahertz (THz) se situe à l'interface des domaines électronique et optique. Malgré un potentiel d'applications élevé, elle souffre d'un manque de dispositifs performants. Dans ce cadre, cette thèse se concentre sur l'étude fondamentale et la réalisation de nouvelles fonctionnalités associées à différentes sources THz, en utilisant la spectroscopie THz dans le domaine temporel (TDS). Cet outil puissant permet de mesurer le profil temporel d'un champ électrique THz et est utilisé pour explorer l'émission THz de lasers à cascade quantique (LCQ) et de graphène.Dans une première partie, la réponse ultrarapide de LCQs est étudiée. Un contrôle de la phase du champ électrique de LCQs THz via la technique "d'injection seeding" est réalisé puis optimisé. Il nous permet de mesurer le profil temporel de l'émission laser. A l'appui de cette expérience et de simulations, une description quantitative de la dynamique du gain est faite. Ces informations sont critiques pour la production d'impulsions courtes. Une modulation rapide du gain de LCQ est ensuite réalisée et conduit à la génération d'impulsions courtes (durée ~ 15 ps) en régime de blocage de modes. Ces études permettent notamment d'envisager les LCQs comme sources puissantes pour la TDS. Dans une seconde partie, nous montrons que le graphène peut émettre un rayonnement THz sous excitation optique par un effet non linéaire d'ordre 2. Cette émission résulte d'un transfert de quantité de mouvement des photons aux électrons du graphène ("photon drag"). Elle permet ainsi d'explorer des propriétés subtiles du graphène, telles que de très faibles différences de comportement entre les électrons et trous photogénérés. / The terahertz (THz) range is a region of the electromagnetic spectrum which lies at the limit between the electronic and optical domain. Currently, THz applications suffer from the lack of sources and detectors. In this context, this thesis focuses on the fundamental study and the development of new functionalities of different THz sources, usingTHz time-domain spectroscopy (TDS) as a base. This powerful tool enables to acquire the temporal profile of a THz electric field and is used to explore the THz emission properties of quantum cascade lasers (QCLs) and graphene.In the first part, the ultrafast response of QCLs is investigated. A phase control of the electric field of THz QCLs via injection seeding is realised and optimised. This enables the measurement of the amplitude and temporal profile of the laser emission. Throughthese experiments and simulations, a quantitative description of the gain dynamics can be accessed. This information is critical for modelocking. Finally, a fast modulation of the gain of QCLs is realized and leads to short pulses generation (15 ps) in a modelocked regime. These studies open the way for using QCLs as powerful sources in TDS.In the second part, THz radiation generation from graphene under optical excitation is demonstrated by a second order non-linear process. The THz emission results from themomentum transfer from the photons to the electrons of graphene (photon drag). As well as broadband THz generation, novel bandstructure properties of graphene can be explored such as the different dynamics between the photogenerated electrons and holes.

Terahertz

Lasers à cascade quantique Terahertz

Graphène

Blocage de modes

Photon drag

Quantum cascade laser

Terahertz time- domain spectroscopy

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