Photon-induced near-field electron microscopy (PINEM): theoretical and experimental

Electron imaging in space and time is achieved in microscopy with timed (near relativistic) electron packets of picometer wavelength coincident with light pulses of femtosecond duration. The photons (with an energy of a few electronvolts) are used to impulsively heat or excite the specimen so that the evolution of structures from their nonequilibrium state can be followed in real time. As such, and at relatively low fluences, there is no interaction between the electrons and the photons; certainly that is the case in vacuum because energy–momentum conservation is not possible. In the presence of nanostructures and at higher fluences, energy–momentum conservation is possible and the electron packet can either gain or lose light quanta. Recently, it was reported that, when only electrons with gained energy are filtered, near-field imaging enables the visualization of nanoscale particles and interfaces with enhanced contrast (Barwick et al 2009 Nature 462 902). To explore a variety of applications, it is important to express, through analytical formulation, the key parameters involved in this photon-induced near-field electron microscopy (PINEM) and to predict the associated phenomena of, e.g., forty-photon absorption by the electron packet. In this paper, we give an account of the theoretical and experimental results of PINEM. In particular, the time-dependent quantum solution for ultrafast electron packets in the nanostructure scattered electromagnetic (near) field is solved in the high kinetic energy limit to obtain the evolution of the incident electron packet into a superposition of discrete momentum wavelets. The characteristic length and time scales of the halo of electron–photon coupling are discussed in the framework of Rayleigh and Mie scatterings, providing the dependence of the PINEM effect on size, polarization, material and spatiotemporal localization. We also provide a simple classical description that is based on features of plasmonics. A major part of this paper is devoted to the comparisons between the theoretical results and the recently obtained experimental findings about the imaging of materials and biological systems

Cavity enhanced detection of cold molecules

Cold quantum gases are versatile tools not only to investigate quantum many-body physics and ultracold chemistry, but also for testing fundamental theories. Many degenerate quantum gases, however, consist of atoms and provide only short-range interactions between different particles limiting research opportunities. Hence, shortly after the production of the first atomic gases an interest arose in ensembles of cold polar molecules that exhibit adjustable long-range anisotropic dipole-dipole interactions to expand research fields further. Loading such a molecular cloud into an optical lattice provides an excellent experimental control regarding particle-particle interactions and to simulate condensed matter physics. Experiments with cold quantum gases require imaging techniques to determine properties like the number of atoms and molecules or the position of single particles. For atomic ensembles, absorption or fluorescence techniques are often utilised since atoms usually provide closed cycling transitions allowing to scatter a large number of photons for the imaging signal. The internal level structure of molecules, though, is more complex compared to atoms due to additional rovibrational states and many molecules do not provide closed cycling transitions. For these molecules new imaging techniques need to be developed. In the first part of the thesis a theoretical background of the imaging technique is provided, starting with a classical approach. The advantages of a classical theory are an intuitive understanding of the detection method and an applicability to spherical nanoparticles, which can then be utilised as test objects for the proposed imaging scheme. The resolution capability of the detection technique is discussed and the important role of small cavity waists for high resolutions is highlighted. In a next step, a full quantum mechanical approach is presented and compared to the classical theory. It is shown that both theories are equivalent except for vacuum fluctuations, a pure quantum physical effect important to determine quantum noise correctly. After introducing theoretical backgrounds, cavity geometries suitable for the detection of molecules are discussed. Properties, directly important for the imaging process, e.\;g. waist, mode number and linewidth, and technical aspects like misalignment sensitivity are taken into account. A simultaneous optimisation of all these properties is not possible since they are partially contradicting each other. However, a balance between these different aspects is found. Two cavity geometrics, feasible for imaging NaK molecules, a hemispherical resonator and a concentric cavity are proposed. Finally, an experimental setup to demonstrate the general feasibility of the imaging technique is developed. Titania and silver are identified as materials for nanoparticles best suited to imitate NaK molecules. Imaging resonators are designed and an alignment procedure for these cavities is presented

Divergence Model for Measurement of Goos-Hanchen Shift

In this effort a new measurement technique for the lateral Goos-Hanchen shift is developed, analyzed, and demonstrated. The new technique uses classical image formation methods fused with modern detection and analysis methods to achieve higher levels of sensitivity than obtained with prior practice. Central to the effort is a new mathematical model of the dispersion seen at a step shadow when the Goos-Hanchen effect occurs near critical angle for total internal reflection. Image processing techniques are applied to measure the intensity distribution transfer function of a new divergence model of the Goos-Hanchen phenomena providing verification of the model. This effort includes mathematical modeling techniques, analytical derivations of governing equations, numerical verification of models and sensitivities, optical design of apparatus, image processin

Physics at BES-III

This physics book provides detailed discussions on important topics in $\tau$-charm physics that will be explored during the next few years at \bes3 . Both theoretical and experimental issues are covered, including extensive reviews of recent theoretical developments and experimental techniques. Among the subjects covered are: innovations in Partial Wave Analysis (PWA), theoretical and experimental techniques for Dalitz-plot analyses, analysis tools to extract absolute branching fractions and measurements of decay constants, form factors, and CP-violation and \DzDzb-oscillation parameters. Programs of QCD studies and near-threshold tau-lepton physics measurements are also discussed.Comment: Edited by Kuang-Ta Chao and Yi-Fang Wan

From filters to features:Scale-space analysis of edge and blur coding in human vision

To make vision possible, the visual nervous system must represent the most informative features in the light pattern captured by the eye. Here we use Gaussian scale-space theory to derive a multiscale model for edge analysis and we test it in perceptual experiments. At all scales there are two stages of spatial filtering. An odd-symmetric, Gaussian first derivative filter provides the input to a Gaussian second derivative filter. Crucially, the output at each stage is half-wave rectified before feeding forward to the next. This creates nonlinear channels selectively responsive to one edge polarity while suppressing spurious or "phantom" edges. The two stages have properties analogous to simple and complex cells in the visual cortex. Edges are found as peaks in a scale-space response map that is the output of the second stage. The position and scale of the peak response identify the location and blur of the edge. The model predicts remarkably accurately our results on human perception of edge location and blur for a wide range of luminance profiles, including the surprising finding that blurred edges look sharper when their length is made shorter. The model enhances our understanding of early vision by integrating computational, physiological, and psychophysical approaches. © ARVO

Theory of ultrafast electron transfer from localized quantum states at surfaces .

190 p.The ability of materials to transfer electrons is a basic property controlling the functionality and performance of devices at the nanoscale. Of particular importance is the tranfor of electros at surfaces as a fundamental process in catalytic and photocatalytic applications. This work aims along these lines at a theoretical description of resonant charge injection at surfaces using a combination of density functional theory and Green's functions. A close comparison with available data from core-hole-clock experiments is maintained throughout the work and confirms the validity and predictive power of our first-principles approach. This is demonstrated on the basis of three prototypical systems where we study fundamental aspects of charge transfer, providing additional, often complementary information to the interpretation of the experiments. First, we present a detailed study of the effects of structural fluctuations on elastic charge transfer for isonicotinic acid adsorbed on rutile (110) in relation to photovoltaic applications. Second we explore spin-dependent charge injection from core-excited argon resonances on Co(0001) and Fe(110), with possible implications for spintronics. Third, we examine the directionality of charge transfer from sulfur related resonances at surfaces of layered 1T-TaS2 in the commensurate charge density wave phase.DIPC CSIC CICnanoGune CFM Marie Curie Action

Heavy Quarkonium Physics

This report is the result of the collaboration and research effort of the Quarkonium Working Group over the last three years. It provides a comprehensive overview of the state of the art in heavy-quarkonium theory and experiment, covering quarkonium spectroscopy, decay, and production, the determination of QCD parameters from quarkonium observables, quarkonia in media, and the effects on quarkonia of physics beyond the Standard Model. An introduction to common theoretical and experimental tools is included. Future opportunities for research in quarkonium physics are also discussed.Comment: xviii + 487 pages, 260 figures. The full text is also available at the Quarkonium Working Group web page: http://www.qwg.to.infn.i