Amplification of coherent optical pulses and "non-bound-state" solitons

Unknown Date

A simple model for optical pulse propagation in a nondegenerate two-level amplifying medium is considered, under the assumption of extreme Doppler broadening. Starting with a "Pade approximant" left reflection coefficient with N simple poles and N$\sb{\rm b}\leq$ N bound states, and employing Lamb's one-component inverse scattering method*, pulses whose initial area can be $>\pi$ are obtained. Then, employing the asymptotic behavior of the eigenvalues of the kernel of the right Marchenko equation, the asymptotic behavior of the pulses far into the medium is analyzed in detail when N $\leq$ 3. In addition to the expected portion of area $\pi$ near the light cone which undergoes amplification and compression, pulses with a continuous leading edge develop forward-moving oscillations, and some pulses trail behind one or more 2$\pi$ (or 0$\pi$) solitons. Pulses whose final area is $\pi$, 3$\pi$, and 5$\pi$ are obtained. Interestingly, the number of trailed solitons is in general not equal to the number of bound states. These solitons are associated with a subset of the zeroes of the transmission coefficient rather than of its poles. Conditions for the appearance of a soliton are given in terms of the poles and residues of the left reflection coefficient. A connection is established between the values of the pulse profiles and their first 2N $-$ 1 derivatives at the light cone, and the residue and pole parameters of the left reflection coefficient. For N = 2 and the case in N = 3 where the pulse has a continuous leading edge, simple conditions for the appearance of a soliton are obtained in terms of the values of the pulse profiles and their first N $-$ 1 derivatives at the light cone, and the poles of the left reflection coefficient. It is established for N $\leq$ 3 that for each 2$\pi$ soliton there is a purely imaginary zero of the left reflection coefficient / in the lower half $\nu$ plane and that for a 0$\pi$ soliton there are a pair of zeroes of the left reflection coefficient lying symmetrically about the negative imaginary $\nu$ axis. ftn*G. L. Lamb, Jr., Phys. Rev. A 12, 2052 (1975). / Source: Dissertation Abstracts International, Volume: 49-03, Section: B, page: 0806. / Major Professor: J. Daniel Kimel. / Thesis (Ph.D.)--The Florida State University, 1987.

Physics, Optics

Fabrication and packaging of a 1X4 ultra fast all-photonic switch

Bahamin, Babak

January 2005

No description available.

Physics, Optics.

Optical wavemixing in nonlinear absorptive Kerr media

Skirtach, Andrei G.

January 1997

No description available.

Physics, Optics.

Electromagnetic modeling and experimental evaluation of plasmon-based molecular sensors

Chien, Wei-Yin

January 2008

No description available.

Physics - Optics

Broadband teleportation and entanglement in cascaded open quantum systems

Noh, Changsuk

January 2009

Quantum optics provides powerful means to probe quantum mechanics. In this thesis, we study various aspects of quantum phenomena arising in quantum optical systems. Part I studies broadband quantum teleportation. After presenting three different methods of analyzing the standard teleportation protocol, we study the interplay between various bandwidths in determining the fidelity of a broadband quantum field teleportation. Explicit formulae for the degrees of first- and secondorder coherence for the teleportation of resonance fluorescence are derived for this purpose. Part II studies entanglement arising in cascaded open quantum (optical) systems. First, a detailed laser model is produced within quantum trajectory theory to study the total decoherence rate of a laser-driven qubit. Second, using this model, we address the issue of laser quantum state, viewed in connection with separability of the laser-driven-qubit system. Third, a measure of entanglement within quantum trajectory theory called ‘Contextual Entanglement’ is calculated for a few simple systems and compared with the ‘Entanglement of Formation’. Lastly, we introduce a method to quantify entanglement (based on the contextual entanglement) between a source and the field it emits, which we call the ‘Entanglement Spectrum’. It is applied to study the entanglement between a laser-driven qubit and the field the qubit scatters.

Quantum optics

A Study of the Purkinje phenomenon with spectral lights ... /

Porter, Ethel Mary Chamberlain,

January 1900

Thesis (Ph. D.)--University of Chicago, 1911. / "Private edition, distributed by the University of Chicago Libraries, Chicago, Illinois, 1911." Includes bibliographical references. Also available on the Internet.

Physiological optics.

Rare Earth elements in optical materials and design of high power ytterbium fiber laser for frequency doubling using nonlinear ppKTP crystal.

Rydberg, Sara

January 2010

No description available.

Optics

Optik

Nonresonant surface enhanced Raman optical activity

January 2009

Nanoshells (NS) and nanoparticles (NP) are tunable plasmonic particles that can be precisely engineered for specific applications including surface enhanced spectroscopies. A new, general method for the synthesis of core-shell and solid nanoparticles has been developed and is presented. Based on the CO reduction of Au3+, this new process yields the highest quality gold nanoshells synthesized to date. The constraints on precursor lifetime have been relaxed and post-synthesis purification has been eliminated. Nonresonant surface enhanced Raman optical activity (SEROA) has been investigated using biomolecular analytes deposited on Au nanoshell or nanoparticle substrates. The first, and currently the only, near-infrared (780 nm) excited scattered circular polarization Raman optical activity spectrometer (NIROAS) has been constructed. Surface enhanced Raman optical activity spectroscopy has been validated by the collection of symmetrical, surface enhanced, signed circular polarization intensity difference spectra from several test molecules including, (S)- and (R)-tryptophan, and (SS)- and (RR)-phenylalanine-cysteine.

Physics

Optics

Manipulation of electromagnetic fields with plasmonic nanostructures: Nonlinear frequency mixing, optical manipulation, enhancement and suppression of photocurrent in a silicon photodiode, and surface-enhanced spectroscopy

January 2010

Metallic nanostructures are one of the most versatile tools available for manipulating light at the nanoscale. These nanostructures support surface plasmons, which are collective excitations of the conduction electrons that can exist as propagating waves at a metallic interface or as localized excitations of a nanoparticle or nanostructure. Plasmonic structures can efficiently couple energy from freely propagating electromagnetic waves to localized electromagnetic fields and vice-versa, essentially acting as an optical antenna. As a result, the intensity of the local fields around and inside the nanostructure are strongly enhanced compared to the incident radiation. In this thesis, this ability to manipulate electromagnetic fields on the nanoscale is employed to control a wide range of optical phenomena. These studies are performed using structures based on metallic nanoshells, which consist of a thin Au shell coating a silica nanosphere. To investigate the parameters controlling the plasmonic response of metallic nanoshells, two changes to the nanoshell composition are studied: (1) the Au shell is replaced with Cu which has interband transitions that strongly influence the plasmon resonance, and (2) the silica core is replaced by a semiconducting Cu 2O core which has a significantly higher dielectric constant and non-trivial absorbance. The focusing of electromagnetic energy into intense local fields by plasmonic nanostructures is then directly investigated by profiling the nanoshell near field using a Raman-based molecular ruler. Next, plasmons supported by Au nanoshells are used to control the fluorescence of near-infrared fluorophores placed at controlled distances from the nanoshell surface. In this context, the analogy of an optical antenna is very relevant: the enhanced field at the surface of the nanoshell increases the absorption of light by the fluorophore, or equivalently couples propagating electromagnetic waves into a localized receiver, while the large scattering cross section enhances the coupling of energy from a localized source, the fluorophore, to far-field radiation. Excellent agreement with models based on Mie theory is achieved for both Raman and fluorescence. Experimentally measured enhancements of the radiative decay rate for fluorophores on Au nanoshells and Au nanorods are also consistent with this model. Plasmonic nanostructures can also control the flow of light into larger structures. This is observed by measuring the nanoparticle-induced enhancement and suppression of photocurrent in a silicon photodiode is at the single particle level for silica nanospheres, Au nanospheres, and two types of Au nanoshell Finally, the simultaneous physical manipulation of an individual plasmonic nanostructure on the few-nanometer scale using light and detection of the local electromagnetic field during this ongoing process with the same incident beam is performed. For this experiment, a Au nanoshell is separated from a metallic surface by a few-nanometer thick polymer layer to form a nanoscale junction, or nanogap Illuminating this structure with ultrashort optical pulses, exciting the plasmon resonance, results in a continuous, monitorable collapse of the nanogap. An easily detectable four-wave mixing (FWM) signal is simultaneously generated by this illumination of the nanogap, providing a continuous, highly sensitive optical monitor of the nanogap spacing while it is being optically reduced. The dramatic increase in this signal upon contact provides a clear, unambiguous signal of the gap closing.

Physics

Optics

A real-time snapshot hyperspectral endoscope and miniature endomicroscopy objectives for a two field-of-view (Bi-FOV) endoscope

January 2010

This thesis focuses on the development of two novel imaging technologies which will serve as the basis for the future development of a two field-of-view or "Bi-FOV" endoscope capable of imaging at both microscopic and macroscopic regimes simultaneously. The goal of the Bi-FOV is to provide clinicians with a better tool for pre- and early cancer detection. The first technology developed makes it possible to obtain low cost, high performance, miniature optical systems for use in the microscopic portion of the Bi-FOV endoscope. The second technology developed for the Bi-FOV is a real-time snapshot hyperspectral endoscope called the IMS endoscope. The IMS endoscope is based on an image mapping technique which is capable of achieving high temporal and spatial resolution, excellent optical throughput, and low costs. The parallel, high throughput nature of this technique enables the device to operate at frame rates of 5.2 fps while collecting a 3D (x, y, gamma ) datacube of 350 x 350 x 48. We have successfully imaged tissue in vivo resolving tissue vasculature and oxy-hemoglobin which are important early cancer biomarkers.

Physics

Optics