Dinâmica da equação de Schrödinger com potencial delta de Dirac em espaço com peso / Dynamics of Schrödinger equation with Dirac delta potential in weighted space

Vieira, Ânderson da Silva

17 July 2014

Nesse trabalho, estudamos a equação de Schrödinger não-linear com uma função potencial delta atrativa. As soluções para essa equação tem uma componente localizada e uma dispersiva. Além de estudar o comportamento das soluções dessa equação em espaços de Sobolev clássicos, mostramos algumas propriedades do grupo unitário em espaços Lp, L2 com peso, Sobolev com peso e assim obtemos alguns resultados de boa colocação local e global das soluções. O ponto central desta tese é mostrarmos a existência de uma variedade invariante centro que irá consistir de órbitas periódicas no tempo. / In this work, we study the nonlinear Schrodinger equation with an attractive delta function potential.The solutions to this equation have a localized and a dispersive component. In addition to studying the behavior of solutions of this equation in classical Sobolev space, we show some properties for the unitary group in Lp, weighted L2 and Sobolev spaces and so we get some results of local and global well-posedness of solutions. The central theme this thesis is to show the existence of a center invariant manifold, which will consist of time-periodic orbits.

Center invariant manifold

Delta Dirac potential

Equação de Schrödinger não-linear

Espaços Lp e de Sobolev com peso

Nonlinear Schrödinger equation

Potencial delta de Dirac

Variedade invariante centro

Weighted Lp and Sobolev spaces

Comparisons between classical and quantum mechanical nonlinear lattice models

Jason, Peter

January 2014

In the mid-1920s, the great Albert Einstein proposed that at extremely low temperatures, a gas of bosonic particles will enter a new phase where a large fraction of them occupy the same quantum state. This state would bring many of the peculiar features of quantum mechanics, previously reserved for small samples consisting only of a few atoms or molecules, up to a macroscopic scale. This is what we today call a Bose-Einstein condensate. It would take physicists almost 70 years to realize Einstein's idea, but in 1995 this was finally achieved. The research on Bose-Einstein condensates has since taken many directions, one of the most exciting being to study their behavior when they are placed in optical lattices generated by laser beams. This has already produced a number of fascinating results, but it has also proven to be an ideal test-ground for predictions from certain nonlinear lattice models. Because on the other hand, nonlinear science, the study of generic nonlinear phenomena, has in the last half century grown out to a research field in its own right, influencing almost all areas of science and physics. Nonlinear localization is one of these phenomena, where localized structures, such as solitons and discrete breathers, can appear even in translationally invariant systems. Another one is the (in)famous chaos, where deterministic systems can be so sensitive to perturbations that they in practice become completely unpredictable. Related to this is the study of different types of instabilities; what their behavior are and how they arise. In this thesis we compare classical and quantum mechanical nonlinear lattice models which can be applied to BECs in optical lattices, and also examine how classical nonlinear concepts, such as localization, chaos and instabilities, can be transfered to the quantum world.

Study of Vortex Ring Dynamics in the Nonlinear Schrödinger Equation Utilizing GPU-Accelerated High-Order Compact Numerical Integrators

Caplan, Ronald Meyer

01 January 2012

We numerically study the dynamics and interactions of vortex rings in the nonlinear Schrödinger equation (NLSE). Single ring dynamics for both bright and dark vortex rings are explored including their traverse velocity, stability, and perturbations resulting in quadrupole oscillations. Multi-ring dynamics of dark vortex rings are investigated, including scattering and merging of two colliding rings, leapfrogging interactions of co-traveling rings, as well as co-moving steady-state multi-ring ensembles. Simulations of choreographed multi-ring setups are also performed, leading to intriguing interaction dynamics. Due to the inherent lack of a close form solution for vortex rings and the dimensionality where they live, efficient numerical methods to integrate the NLSE have to be developed in order to perform the extensive number of required simulations. To facilitate this, compact high-order numerical schemes for the spatial derivatives are developed which include a new semi-compact modulus-squared Dirichlet boundary condition. The schemes are combined with a fourth-order Runge-Kutta time-stepping scheme in order to keep the overall method fully explicit. To ensure efficient use of the schemes, a stability analysis is performed to find bounds on the largest usable time step-size as a function of the spatial step-size. The numerical methods are implemented into codes which are run on NVIDIA graphic processing unit (GPU) parallel architectures. The codes running on the GPU are shown to be many times faster than their serial counterparts. The codes are developed with future usability in mind, and therefore are written to interface with MATLAB utilizing custom GPU-enabled C codes with a MEX-compiler interface. Reproducibility of results is achieved by combining the codes into a code package called NLSEmagic which is freely distributed on a dedicated website.

Bose-Einstein condensates

GPU

Applied Mathematics

Computer Sciences

Condensed Matter Physics

Propagation non-linéaire de paquets d'onde. / Nonlinear propagation of wave packets.

Hari, Lysianne

25 September 2014

Les résultats présentés dans cette thèse concernent l'étude, dans la limite semi-classique, de systèmes d'équations de Schrödinger non-linéaires couplées. Selon le potentiel considéré, le système peut, ou non, présenterun couplage linéaire, en plus de celui induit par le terme non-linéaire. Dans ce manuscrit, c'est la propagation d'états cohérents -états localisés dans l'espace des phases, et que l'on va faire vivre dans un niveau d'énergie donné - qui va nous intéresser.Dans le cadre linéaire, plusieurs situations ont été étudiées, certaines préservant l'adiabaticité,et d'autres la brisant, faisant apparaître des transitions entre les niveaux d'énergie.Le rôle de la non-linéarité et l'interaction de ses effets avec un éventuel couplage linéaire sur ces phénomènes est une questionimportante pour comprendre des systèmes qui entrent en jeu dans des problèmes très actuels en physique quantique.Dans un premier temps, le potentiel pris en compte aura des valeurs propres bien séparées par un trou spectral,et nous montrerons un théorème adiabatique pour une non-linéarité qui présente un exposant critique pour le paramètre semi-classique devant la non-linéarité. Un point de vue équivalent est de considérer des données petites de l'ordre d'une puissance positive du paramètre semi-classique.Il s'agit d'un résultat analogue à celui de Carles et Fermanian-Kammerer mais dans un cadre sur-critique L^2.Dans un deuxième temps, nous considèrerons, pour le cas unidimensionnel, un potentiel explicite de taille 2 X 2,qui présente un croisement évité :les deux valeurs propres sont séparées par un paramètre delta - paramètre adiabatique -qui va tendre vers zéro lorsque le paramètre semi-classique va tendre vers zéro. Nous montrerons alors que des transitions entre les modes ont lieu.Il s'agit ici d'une version non-linéaire des travaux d'Hagedorn et Joyeoù une telle transition est démontrée pour des systèmes linéaires. / This thesis is devoted to the study of coupled nonlinear Schrödinger equations in the semi-classical limit.Depending on the potential we consider, the system can present a linear coupling, in addition to the nonlinear one.We will focus on the propagation of coherent states that will be polarized along a given eigenvector of the potential.In the linear setting, several situations have been analyzed; some of them lead to adiabatic theorems whereas the others implytransitions between energy levels. When one adds a nonlinearity, understanding nonlinear effects onthe propagation and the competition between them and the linear coupling becomes a very interesting issue.We first consider a potential with eigenvalues that present a spectral gap and will prove an adiabatic theoremfor a critical nonlinearity in the semi-classical sense. This is a L^2-supercritical result,similar to the one proved by Carles and Fermanian-Kammerer for the one-dimensional case, which is L^2-subcritical.The second part of the thesis deals with an explicit 2 X 2 potential that presents an avoided crossing point :the minimal gap between its eigenvalues becomes smaller as the semiclassical parameter tends to zero. We will prove that this system exhibits transitions between the modes. This result is a nonlinear version of the study performed by Hagedorn and Joye in the linear case.

Equation de Schrödinger non-Linéaire

Analyse semi-Classique

Paquets d'onde/Etats cohérents

Transition non-Adiabatique

Nonlinear Schrödinger equation

Semi-Classical analysis

Wave packets/Coherent states

Non-Adiabatic transitions

Couplage entre auto-focalisation et diffusion Brillouin stimulée pour une impulsion laser nanoseconde dans la silice / Coupling between self-focusing and stimulated Brillouin scattering for nanosecond laser pulses in silica

Mauger, Sarah

29 September 2011

Dans le cadre des études sur l’endommagement laser liées au projet Mégajoule, nous analysons le couplage entre l’auto-focalisation induite par effet Kerr et la rétrodiffusion Brillouin stimulée pour des impulsions de durée nanoseconde se propageant dans des échantillons de silice. L’influence de la puissance d’entrée, des modulations de phase ou d’amplitude ainsi que la forme spatiale du faisceau sur la dynamique de filamentation est discutée. Nous montrons qu’une modulation d’amplitude appropriée divisant l’impulsion incidente en train d’impulsions de l’ordre de la dizaine de picosecondes supprime l’effet Brillouin pour toute puissance incidente mais réduit notablement la puissance laser disponible. A l’inverse, des impulsions modulées en phase avec une largeur spectrale comparable peuvent subir de la filamentation multiple et une auto-focalisation à distance plus courte causées par des instabilités modulationnelles. Nous démontrons cependant l’existence d’une largeur spectrale critique à partir de laquelle la rétrodiffusion peut être radicalement inhibée par une modulation de phase, même pour des fortes puissances. Cette observation reste valide pour des faisceaux de forme carrée avec des profils spatiaux plus larges, qui s’auto-focalisent beaucoup plus rapidement et se brisent en filaments multiples sur de courtes distances. L’inclusion de la génération de plasma pour limiter la croissance des ondes pompe et Stokes est finalement abordée. / As part of the studies on laser damage linked to the Megajoule project, we analyze the coupling between the Kerr induce self-focusing and the stimulated Brillouin backscattering pour nanosecond optical pulses propagating in silica samples. The influence of the incident power, phase or amplitude modulations as well as the spatial profile of the pulse of the filamentation dynamic is discussed. We show that an appropriate amplitude modulation dividing the incident pulse in pulse trains of picosecond durations suppresses the Brillouin effect for any incident power but noticeably reduces the available average laser power. On the contrary, phase modulated pulses with a comparable spectral width can undergo multiple filamentation and self-focusing at a shorter distance, caused by modulational instabilities. We demonstrate however the existence of a critical spectral bandwidth from which the backscattering can be radically inhibited by a phase modulation, even for high powers. This conclusion remains valid for spatially broader squared pulses, which self-focus earlier and break into multiple filaments at shorter distances. The inclusion of plasma generation to limit the growth of pump and Stokes waves is finally addressed.

Interaction laser-matière

Endommagement laser

Equation de Schrödinger non-linéaire

Effet Kerr

Auto-focalisation

Filamentation

Diffusion Brillouin Stimulée

Laser-matter interaction

Laser induced damage

Nonlinear Schrödinger equation

Kerr effect

Self-focusing

Filamentation

Stimulated Brillouin scattering

Ολοκληρώσιμες μη γραμματικές μερικές διαφορικές εξισώσεις και διαφορική γεωμετρία

Βλάχου, Αναστασία

09 October 2014

Στόχος της παρούσας εργασίας είναι η σύνδεση της μοντέρνας θεωρίας σολιτονίων με την κλασική διαφορική γεωμετρία. Ειδικότερα, αρχίζουμε με ένα εισαγωγικό μέρος, όπου παραθέτουμε τις βασικές έννοιες που αφορούν: α) Τις λύσεις μη-γραμμικών μερικών διαφορικών εξισώσεων (ΜΔΕ) που ονομάζονται σολιτόνια (solitons) και β) Την γεωμετρία των ομαλών καμπυλών και επιφανειών του Ευκλείδειου χώρου). Ακολουθεί, το δεύτερο και κύριο μέρος, στο οποίο μελετάμε την σχέση τριών χαρακτηριστικών μη-γραμμικών εξισώσεων εξέλιξης, της εξίσωσης sine-Gordon, της τροποποιημένης εξίσωσης Korteweg de Vries (mKdV) και της μη γραμμικής εξίσωσης Schrödinger (NLS), με την θεωρία καμπυλών και επιφανειών. Αναλυτικότερα, στο πρώτο μέρος και πιο συγκεκριμένα στο πρώτο κεφάλαιο παρουσιάζουμε μια ιστορική αναδρομή στην έννοια του σολιτονίου. Στην συνέχεια αναζητούμε κυματικές-σολιτονικές λύσεις για τις εξισώσεις KdV και NLS. Κλείνουμε παραθέτοντας τις προϋποθέσεις κάτω από τις οποίες μια μη γραμμική εξίσωση είναι ολοκληρώσιμη. Επιλέγουμε να αναλύσουμε δύο από αυτές τις προϋποθέσεις, χρησιμοποιώντας συγκεκριμένα παραδείγματα, ενώ, για τις άλλες δύο, περιοριζόμαστε σε μια συνοπτική περιγραφή . Στο δεύτερο κεφάλαιο του εισαγωγικού μέρους γίνεται μια εκτενής αναφορά σε θεμελιώδεις έννοιες της διαφορικής γεωμετρίας. Πιο συγκεκριμένα, οι έννοιες αυτές σχετίζονται με την θεωρία καμπυλών και επιφανειών και για ορισμένες από αυτές παρουσιάζουμε κάποια αντιπροσωπευτικά παραδείγματα. Ακολουθεί το κύριο μέρος και ειδικότερα το πρώτο κεφάλαιο, στο οποίο, μελετώντας υπερβολικές επιφάνειες, καταλήγουμε σε ένα κλασικό μη γραμμικό σύστημα εξισώσεων. Είναι αυτό που οφείλουμε στον Bianchi και το οποίο ενσωματώνει τις εξισώσεις Gauss-Mainardi-Codazzi. Στην συνέχεια, περιοριζόμαστε στις ψευδοσφαιρικές επιφάνειες και έτσι καταλήγουμε στην εξίσωση sine-Gordon. Ακολουθεί η ενότητα 1.2, στην οποία βρίσκουμε τον μετασχηματισμό auto-Bäcklund για την εξίσωση sine-Gordon και περιγράφουμε την γεωμετρική διαδικασία για την κατασκευή ψευδοσφαιρικών επιφανειών. Στην ενότητα 1.3, χρησιμοποιώντας τον παραπάνω μετασχηματισμό Bäcklund, καταλήγουμε στο Θεώρημα Αντιμεταθετικότητας του Bianchi. Συνεχίζουμε με την ενότητα 1.4, στην οποία παρουσιάζουμε ψευδοσφαιρικές επιφάνειες, οι οποίες αντιστοιχούν σε σολιτονικές λύσεις της εξίσωσης sine-Gordon. Πιο αναλυτικά, στην υποενότητα 1.4.1 κατασκευάζουμε την ψευδόσφαιρα του Beltrami, η οποία αντιστοιχεί στην στάσιμη μονο-σολιτονική λύση. Στην υποενότητα 1.4.2 μελετάμε το ελικοειδές που δημιουργείται από την έλκουσα καμπύλη, δηλαδή την επιφάνεια Dini, την οποία και κατασκευάζουμε. Ακολουθεί η υποενότητα 1.4.3, όπου, χρησιμοποιώντας το θεώρημα μεταθετικότητας, καταλήγουμε στην λύση δύο-σολιτονίων για την εξίσωση sine-Gordon και συνεχίζουμε με την υποενότητα 1.4.4, όπου κατασκευάζουμε περιοδικές λύσεις των δύο-σολιτονίων γνωστές ως breathers. Στο δεύτερο κεφάλαιο μελετάμε την κίνηση συγκεκριμένων καμπυλών και επιφανειών, οι οποίες οδηγούν σε σολιτονικές εξισώσεις. Ειδικότερα, στην ενότητα 2.1 καταλήγουμε στην εξίσωση sine-Gordon μέσω της κίνησης μιας μη-εκτατής καμπύλης σταθερής καμπυλότητας ή στρέψης. Ακολουθεί η ενότητα 2.2, όπου η εξίσωση sine- Gordon προκύπτει ως η συνθήκη συμβατότητας για το 2 2 γραμμικό σύστημα AKNS. Στην συνέχεια, στην ενότητα 2.3 ασχολούμαστε με την κίνηση ψευδοσφαιρικών επιφανειών. Πιο συγκεκριμένα, στην υποενότητα 2.3.1 συνδέουμε την κίνηση μιας ψευδοσφαιρικής επιφάνειας με ένα μη αρμονικό μοντέλο πλέγματος, το οποίο ενσωματώνει την εξίσωση mKdV. Επιπλέον, στην υποενότητα 2.3.2 δείχνουμε ότι η καθαρά κάθετη κίνηση μιας ψευδοσφαιρικής επιφάνειας, παράγει το κλασικό σύστημα Weingarten. Ολοκληρώνουμε την ενότητα 2.3 με την κατασκευή των μετασχηματισμών Bäcklund τόσο για το μοντέλο πλέγματος, όσο και για το σύστημα Weingarten. Το κεφάλαιο κλείνει με την ενότητα 2.4, όπου μέσω της κίνησης μιας μη εκτατής καμπύλης μηδενικής στρέψης, καταλήγουμε στην εξίσωση mKdV. Στην συνέχεια μελετάμε την κίνηση των επιφανειών Dini και τελικά κατασκευάζουμε επιφάνειες που αντιστοιχούν στο τριπλά ορθογώνιο σύστημα Weingarten. Στο τρίτο και τελευταίο κεφάλαιο επικεντρωνόμαστε στην εξίσωση NLS. Πιο συγκεκριμένα, στην ενότητα 3.1 καταλήγουμε στην εξίσωση NLS μ’ έναν καθαρά γεωμετρικό τρόπο. Επιπλέον, κατασκευάζουμε επιφάνειες, οι οποίες αντιστοιχούν στην μονο-σολιτονική λύση της εξίσωσης NLS και παρουσιάζουμε γι’ αυτές κάποιες γενικές γεωμετρικές ιδιότητες. Το κεφάλαιο 3 ολοκληρώνεται με την ενότητα 3.3 όπου αρχικά λαμβάνουμε ακόμη μια φορά την εξίσωση NLS, χρησιμοποιώντας την μελέτη στην κινηματική των Marris και Passman. Κλείνουμε και αυτό το κεφάλαιο με τον auto- Bäcklund μετασχηματισμό για την εξίσωση NLS και επιπλέον παρουσιάζουμε χωρικά περιοδικές λύσεις της, γνωστές ως smoke-ring (δαχτυλίδι-καπνού). / The aim of this diploma thesis is to find a connection between modern soliton theory and classical differential geometry. More particularly, we begin with an introductory section, where we present the basic concepts regarding soliton equations and the geometry of smooth curves ans surfaces. This is followed by the main body of the thesis, which focuses on three partial differential equations, namely, the sine-Gordon equation, the modified Korteweg de Vries equation (mKdV) and the nonlinear Scrödinger equation (NLS), and their connection to the theory of curves and surfaces. The first introductory chapter is a historical overview of the notion of solitons. We then seek travelling wave solutions for the KdV and NLS equations. Closing, we quote the conditions under which a nonlinear equation is integrable. We choose to analyze in detail two of these conditions while we settle for a brief description of the other two. The second chapter is an extensive report on fundamental concepts of differential geometry, namely, those associated with the theory of curves and surfaces in Euclidean three-dimensional space, and we present some representative examples. Chapter 1 of the main part, opens with the derivation of a classical nonlinear system which we owe to Bianchi and embodies the Gauss-Mainardi-Codazzi equations. We then specialise to pseudospherical surfaces and produce the sine-Gordon equation. Section 1.2 includes the derivation of the auto-Bäcklund transformation for the sine-Gordon equation along with the geometric procedure for the construction of pseudospherical surfaces. In section 1.3, we use the above transformation to conclude to Bianchi’s Permutability Theorem. We continue to section 1.4, where we present certain pseudospherical surfaces. These surfaces correspond to solitonic solutions of the sine- Gordon equation, i.e. in subsection 1.4.1 we construct the pseudosphere which corresponds to the stationary single soliton solution. Also, in subsection 1.4.2 we examine the helicoid that is created by the tractrix, namely, the Dini surface. In section 1.4.3, by use of Bianchi’s Permutability Theorem, we end up in the two-soliton solution for the sine-Gordon equation and continue in the next subsection, where we present periodic two-soliton solutions, known as breathers. In Chapter 2, we show how certain motions of curves and surfaces can lead to solitonic equations. More precisely, in section 2.1, we arrive at the sine-Gordon equation, through the motion of an inextensible curve of constant curvature or torsion. Then, section 2.2 displays how the sine-Gordon equation arises as the compatibility condition for the linear 2 2 AKNS system. In section 2.3 we study the movement of pseudospherical surfaces. In particular, we connect, in subsection 2.3.1, the motion of a pseudospherical surface to a continuum version of an unharmonic lattice model, which encorporates the mKdV equation. Moreover, in subsection 2.3.2, we show that a purely normal motion of a pseudospherical surface produces the classical Weingarten system. We conclude section 2.3 by constructing the Bäcklund transformation both for the lattice model and the Weingarten system. The chapter ends with section 2.4, where through the motion of an inextensible curve of zero torsion, we produce the mKdV equation. Furthermore, we investigate the motion of Dini surfaces and, finally, construct surfaces corresponding to the triply orthogonal Weingarten system. The third and final chapter focuses on the NLS equation. In section 3.1 we produce the NLS equation through a purely geometric manner. We then construct surfaces, that correspond to the single-soliton solution of this equation, and also present certain general geometric properties of them. We conclude the final chapter with the auto-Bäcklund transformation for the NLS equation and the presentation of spatially periodic solutions, known as smoke-ring.

Σολιτόνια

Σολιτονικές λύσεις

Εξίσωση Sine-Gordon

Εξίσωση NLS

Μετασχηματισμός Bäcklund

530.124

Solitons

Soliton solutions

Soliton surfaces

Basics of differential geometry

Sine-Gordon equation

Nonlinear Schrödinger equation

Bäcklund transform

Um estudo sobre a boa colocação local da equação não linear de Schrödinger cúbica unidimensional em espaços de Sobolev periódicos / A study about the locally well posed of cubic nonlinear Schrödinger equation in periodic Sobolev spaces

Romão, Darliton Cezario

25 March 2009

In this work we study, in details, the Cauchy problem of the nonlinear Schrödinger equation, with initial datas in periodic Sobolev spaces. Specifically, we prove that this problem is locally well posed for datas in Hsper, with s ≥ 0. Particularly, for initial datas in L2 the problem is globally well posed, due to the conservation law of the equation in this space. Moreover, we prove the this result is the best one, seeing we expose examples that show that the equation flow is not locally uniformly continuous for initial datas with regularity less than L2. / Coordenação de Aperfeiçoamento de Pessoal de Nível Superior / Neste trabalho, fazemos um estudo detalhado do problema de Cauchy para a equação não-linear cúbica de Schrödinger, com dados iniciais em espaços de Sobolev no toro. Especificamente, provaremos que este modelo é localmente bem posto para dados em Hsper, com s ≥ 0. Em particular, para dados iniciais em L2 o modelo é globalmente bem posto, devido à lei de conservação da equação neste espaço. Além disso, provaremos que os resultados obtidos são os melhores possíveis, visto que exibiremos exemplos que mostram que o fluxo da equação não é localmente uniformemente contínuo para dados iniciais com regularidade menor que L2.

Problemas de Cauchy

Espaço de Sobolev

Equação não linear de Schrödinger

Boa colocação local

Má colocação

Cauchy problem

Sobolev spaces

Nonlinear Schrödinger equation

Locally well posed

Ill posed

Método compacto de diferenças finitas para resolver equações de Schrödinger não lineares com dispersão de quarta ordem / Compact finite Diference method to solve nonlinear Schrödinger equations with fourth order dispersion

Jesus, Hugo Naves

16 September 2016

Submitted by JÚLIO HEBER SILVA (julioheber@yahoo.com.br) on 2016-11-10T11:15:34Z No. of bitstreams: 2 Dissertação - Hugo Naves de Jesus - 2016.pdf: 1851851 bytes, checksum: 71cb8f26f4f38eb5f89d99aafc926b66 (MD5) license_rdf: 0 bytes, checksum: d41d8cd98f00b204e9800998ecf8427e (MD5) / Approved for entry into archive by Jaqueline Silva (jtas29@gmail.com) on 2016-11-10T17:47:53Z (GMT) No. of bitstreams: 2 Dissertação - Hugo Naves de Jesus - 2016.pdf: 1851851 bytes, checksum: 71cb8f26f4f38eb5f89d99aafc926b66 (MD5) license_rdf: 0 bytes, checksum: d41d8cd98f00b204e9800998ecf8427e (MD5) / Made available in DSpace on 2016-11-10T17:47:53Z (GMT). No. of bitstreams: 2 Dissertação - Hugo Naves de Jesus - 2016.pdf: 1851851 bytes, checksum: 71cb8f26f4f38eb5f89d99aafc926b66 (MD5) license_rdf: 0 bytes, checksum: d41d8cd98f00b204e9800998ecf8427e (MD5) Previous issue date: 2016-09-16 / Conselho Nacional de Pesquisa e Desenvolvimento Científico e Tecnológico - CNPq / Finite difference schemes belong to a class of numerical methods used to approximate derivatives. They are widely used to find approximations to differential equations. There are a lot of numerical methods, whose deductions are made through expansions in Taylor Series. Depending on the manner in which expansion is made, it can be combined with other expansions to obtain derivatives with better numerical approximations. Usually when we get numerical derivative with better approaches, it is necessary to increase the amount of points used in the grid. An alternative to this problem are compact methods, which achieve better approximations for the same derivative but without increasing the number of mesh points. This work is an attempt to develop the Compact-SSFD method for the Schrödinger Equation Nonlinear Fourth Order. SSFD methods are used to separate the parts of a differential equation so that each part can be solved separately. For example in the case of non-linear differential equations it is often used to separate the linear parts of nonlinear parts. In Compact-SSFD methods nonlinear parts are resolved exactly as the linear are resolved using compact methods. Our work is inspired in the Dehghan and Taleei’s work where was used the Compact-SSFD method for solving numerically the equation Nonlinear Schrödinger. Before we try to develop our method, the results of the authors was correctly reproduced. But when we try to deduce a method analogous to the differential equation we wanted to solve, which also involves derived from fourth order, we realized that a Compact type method does not get as trivially as in the case of used to approach second-order derivatives. / Métodos de diferenças finitas pertencem a uma classe de métodos numéricos usados para se aproximar derivadas. Eles são amplamente usados para encontrar-se soluções numéricas para equações diferenciais. Há uma grande quantidade de métodos numéricos, cuja as deduções são feitas através de expansões em séries de Taylor. Dependendo da forma em que uma expansão é feita, ela pode ser combinada com outras expansões para obter-se derivadas numéricas com melhores aproximações. Geralmente quando obtemos derivadas numéricas com aproximações melhores, é necessário aumentar-se a quantidade de pontos usados no domínio discretizado. Uma alternativa a este problema são os chamados métodos compact, que obtêm melhores aproximações para a mesma derivada mas sem precisar aumentar a quantidade de pontos da malha. Este trabalho é uma tentativa de desenvolver-se um método Compact-SSFD para a Equação de Schrödinger Não Linear de Quarta Ordem. Métodos SSFD são usados para separar-se as partes de uma equação diferencial tal que cada parte possa ser resolvida separadamente. Por exemplo no caso de equações diferenciais não lineares ele é bastante usado para separar-se as partes lineares das partes não lineares. Nos métodos Compact-SSFD as partes não lineares são resolvidas exatamente enquanto as lineares são resolvidas usando-se métodos compact. Nos baseamos no trabalho de Dehghan e Taleei onde foi usado o Método Compact-SSFD para resolver-se numericamente a Equação de Schrödinger Não Linear. Antes de tentarmos desenvolver nosso método, reproduzimos corretamente os resultados dos autores. Mas ao tentarmos deduzir um método análogo para a equação diferencial que queríamos resolver, que envolve também derivadas de quarta ordem, percebemos que um método do tipo Compact não se obtêm tão trivialmente como no caso dos usados para aproximar-se derivadas de segunda ordem.

Compact-SSFD

Métodos de diferenças finitas

Dispersão de quarta ordem

Sólitons

Equação de Schrödinger não linear

Compact-SSFD

Finite difference scheme

Fourth-order dispersion

Sólitons

Nonlinear Schrödinger equation

Ondes scélérates complexes dans les fibres optiques / Complex rogue wave in the fiber optics

Frisquet, Benoit

24 March 2016

Ce manuscrit de thèse présente l’étude d’instabilités non-linéaires et la génération d’ondes scélérates complexes liées à la propagation de la lumière dans des fibres optiques standards des télécommunications optiques. Un rappel est tout d’abord présenté sur les phénomènes physiques linéaires et non-linéaires impliqués et qui peuvent présenter une analogie directe avec le domaine de l’hydrodynamique. Les différentes formes d’ondes scélérates liées au processus d’instabilité de modulation, aussi appelées « breathers », sont alors présentées, elles sont obtenues par la résolution de l’équation de Schrödinger non-linéaire. À partir de ces solutions exactes, divers systèmes expérimentaux sont alors conçus par simulation numérique à partir de deux méthodes d’excitation d’ondes scélérates. La première est une génération exacte à partir des solutions analytiques en effectuant une mise en forme spectrale en intensité et en phase d’un peigne de fréquence optique. La seconde méthode est basée sur des conditions initiales approchées avec des ondes continues modulées sinusoïdalement. Les mesures expérimentales réalisées avec ces deux méthodes démontrent parfaitement la génération d’ondes scélérates complexes (solutions d’ordre supérieur du système) issues de la superposition non-linéaire ou collisions de « breathers » de premier ordre. Enfin, nous avons également étudié un système non-linéaire équivalent au modèle de Manakov, qui fait intervenir la propagation de deux ondes distinctes avec des polarisations orthogonales dans une fibre optique. L’analyse de stabilité et des simulations numériques de ce système multi-variable mettent en évidence un nouveau régime d’instabilité de modulation vectorielle ainsi que de nouvelles solutions d’ondes scélérates noires et couplées en polarisation. Un nouveau système expérimental mis en place a permis de confirmer ces prédictions théoriques avec un excellent accord quantitatif. / This manuscript presents the generation of complex rogue waves related to nonlinear instabilities occurring through the propagation of light in standard optical fibers. Linear and nonlinear physical phenomena involved are first listed, in particular some of them by analogy with the field of hydrodynamics. The different forms of rogue waves induced by the modulation instability process are then presented. They are also known as "breathers", and they are obtained by solving the nonlinear Schrödinger equation. From these exact solutions, various experimental systems were designed by means of numerical simulations based on two rogue-wave excitation methods. The first one is an exact generation of mathematical solutions based on the spectral shaping of an optical frequency comb. The second method uses approximate initial conditions with a simple sinusoidal modulation of continuous waves. For both cases, experimental measurements demonstrate the generation of complex rogue waves (i.e., higher-order solutions of the system) arising from the nonlinear superposition or collision of first-order breathers. Finally, we also studied a nonlinear fiber system equivalent to the Manakov model, which involves the propagation of two distinct waves with orthogonal polarizations. The stability analysis and numerical simulations of this multi-component system highlight a novel regime of vector modulation instability and the existence of coupled dark rogue-wave solutions. A new experimental system setup was conceived and theoretical predictions are confirmed with an excellent quantitative agreement.

Optique non-linéaire ultrarapide

Fibres optiques

Instabilité de modulation

Ondes scélérates

Polarisation

Équation de Schrödinger non-linéaire

Système de Manakov

Ultrafast nonlinear optics

Optical fibers

Modulation instability

Rogue waves

Polarization

Nonlinear Schrödinger equation

Manakov system

535

Nonlinear Schrödinger equation and Schrödinger-Poisson system in the semiclassical limit / Equation de Schrödinger non-linéaire et système de Schrödinger-Poisson dans la limite semi-classique

Di Cosmo, Jonathan

29 September 2011

The nonlinear Schrödinger equation appears in different fields of physics, for example in the theory of Bose-Einstein condensates or in wave propagation models. From a mathematical point of view, the study of this equation is interesting and delicate, notably because it can have a very rich set of solutions with various behaviours.<p><p>In this thesis, we have been interested in standing waves, which satisfy an elliptic partial differential equation. When this equation is seen as a singularly perturbed problem, its solutions concentrate, in the sense that they converge uniformly to zero outside some concentration set, while they remain positive on this set.<p><p>We have obtained three kind of new results. Firstly, under symmetry assumptions, we have found solutions concentrating on a sphere. Secondly, we have obtained the same type of solutions for the Schrödinger-Poisson system. The method consists in applying the mountain pass theorem to a penalized problem. Thirdly, we have proved the existence of solutions of the nonlinear Schrödinger equation concentrating at a local maximum of the potential. These solutions are found by a more general minimax principle. Our results are characterized by very weak assumptions on the potential./<p><p>L'équation de Schrödinger non-linéaire apparaît dans différents domaines de la physique, par exemple dans la théorie des condensats de Bose-Einstein ou dans des modèles de propagation d'ondes. D'un point de vue mathématique, l'étude de cette équation est intéressante et délicate, notamment parce qu'elle peut posséder un ensemble très riche de solutions avec des comportements variés. <p><p>Dans cette thèse ,nous nous sommes intéressés aux ondes stationnaires, qui satisfont une équation aux dérivées partielles elliptique. Lorsque cette équation est vue comme un problème de perturbations singulières, ses solutions se concentrent, dans le sens où elles tendent uniformément vers zéro en dehors d'un certain ensemble de concentration, tout en restant positives sur cet ensemble. <p><p>Nous avons obtenu trois types de résultats nouveaux. Premièrement, sous des hypothèses de symétrie, nous avons trouvé des solutions qui se concentrent sur une sphère. Deuxièmement, nous avons obtenu le même type de solutions pour le système de Schrödinger-Poisson. La méthode consiste à appliquer le théorème du col à un problème pénalisé. Troisièmement, nous avons démontré l'existence de solutions de l'équation de Schrödinger non-linéaire qui se concentrent en un maximum local du potentiel. Ces solutions sont obtenues par un principe de minimax plus général. Nos résultats se caractérisent par des hypothèses très faibles sur le potentiel. / Doctorat en sciences, Spécialisation mathématiques / info:eu-repo/semantics/nonPublished

Mathématiques

Schrödinger equation

Differential equations, Partial

Schrödinger, Equation de

Equations aux dérivées partielles

Partial differential equations

équation de Schrödinger non-linéaire

méthodes variationnelles

nonlinear Schrödinger equation