Review of laser scanning methods for microelectronic semiconductor structures investigation

The development and widespread of high-tech microelectronic products impose increased requirements on the quality and reliability of microcircuits. The most effective methods for reliability improvement of electronic systems include diagnostic non-destructive testing (NDT) methods and selective destructive testing in special cases. Studies using visual inspection and electrical testing, consisting of functional and parametric testing, do not provide enough information to detect latent defects (for example, macro-defects in SiO 2 layers in CMOS chips) and to detect fakes and counterfeits. A fake integrated circuit (IC) may contain an undeclared malicious modification of the circuit, called hardware bugs. The common ICs studying tools are systems based on microfocus X-ray sources, scanning acoustic microscopes, optical and scanning electron microscopes, and X-ray fluorescence spectroscopes. Products destruction avoidance is a fundamental point, for example, for the technological process control in crystal manufacturing. Investigation of ICs using a light microscope is one of the most accessible and widespread method of microchip NDT. Semiconductor ICs structure scanning from the side of the device layer is limited by the shielding effect of metallization, since the metal is opaque for light. This limitation can be overcome by an alternative approach to microchip scanning based on irradiating the IC from the side of the substrate with laser sources in the near-IR range. This paper provides a brief overview of the major methods used in laser scanning microscopy to analyze the structures, responses, and features of the operating modes of semiconductor circuits. The main advantages and limitations in the use of optical methods are described, as well as what information about the product can be obtained as a result of laser scanning

Nonlinear acousto-electric transport in a two-dimensional electron system

We study both theoretically and experimentally the nonlinear interaction between an intense surface acoustic wave and a two-dimensional electron plasma in semiconductor-piezocrystal hybrid structures. The experiments on hybrid systems exhibit strongly nonlinear acousto-electric effects. The plasma turns into moving electron stripes, the acousto-electric current reaches its maximum, and the sound absorption strongly decreases. To describe the nonlinear phenomena, we develop a coupled-amplitude method for a two-dimensional system in the strongly nonlinear regime of interaction. At low electron densities the absorption coefficient decreases with increasing sound intensity, whereas at high electron density the absorption coefficient is not a monotonous function of the sound intensity. High-harmonic generation coefficients as a function of the sound intensity have a nontrivial behavior. Theory and experiment are found to be in a good agreement.Comment: 27 pages, 6 figure

Explaining bathymetric diversity patterns in marine benthic invertebrates and demersal fishes: physiological contributions to adaptation of life at depth

Bathymetric biodiversity patterns of marine benthic invertebrates and demersal fishes have been identified in the extant fauna of the deep continental margins. Depth zonation is widespread and evident through a transition between shelf and slope fauna from the shelf break to 1000 m, and a transition between slope and abyssal fauna from 2000 to 3000 m; these transitions are characterised by high species turnover. A unimodal pattern of diversity with depth peaks between 1000 and 3000 m, despite the relatively low area represented by these depths. Zonation is thought to result from the colonisation of the deep sea by shallow-water organisms following multiple mass extinction events throughout the Phanerozoic. The effects of low temperature and high pressure act across hierarchical levels of biological organisation and appear sufficient to limit the distributions of such shallow-water species. Hydrostatic pressures of bathyal depths have consistently been identified experimentally as the maximum tolerated by shallow-water and upper bathyal benthic invertebrates at in situ temperatures, and adaptation appears required for passage to deeper water in both benthic invertebrates and demersal fishes. Together, this suggests that a hyperbaric and thermal physiological bottleneck at bathyal depths contributes to bathymetric zonation. The peak of the unimodal diversity–depth pattern typically occurs at these depths even though the area represented by these depths is relatively low. Although it is recognised that, over long evolutionary time scales, shallow-water diversity patterns are driven by speciation, little consideration has been given to the potential implications for species distribution patterns with depth. Molecular and morphological evidence indicates that cool bathyal waters are the primary site of adaptive radiation in the deep sea, and we hypothesise that bathymetric variation in speciation rates could drive the unimodal diversity–depth pattern over time. Thermal effects on metabolic-rate-dependent mutation and on generation times have been proposed to drive differences in speciation rates, which result in modern latitudinal biodiversity patterns over time. Clearly, this thermal mechanism alone cannot explain bathymetric patterns since temperature generally decreases with depth. We hypothesise that demonstrated physiological effects of high hydrostatic pressure and low temperature at bathyal depths, acting on shallow-water taxa invading the deep sea, may invoke a stress–evolution mechanism by increasing mutagenic activity in germ cells, by inactivating canalisation during embryonic or larval development, by releasing hidden variation or mutagenic activity, or by activating or releasing transposable elements in larvae or adults. In this scenario, increased variation at a physiological bottleneck at bathyal depths results in elevated speciation rate. Adaptation that increases tolerance to high hydrostatic pressure and low temperature allows colonisation of abyssal depths and reduces the stress–evolution response, consequently returning speciation of deeper taxa to the background rate. Over time this mechanism could contribute to the unimodal diversity–depth pattern

Stability and Structural Analysis of Alpha-Amylase from the Antarctic Psychrophile Alteromonas Haloplanctis A23

The alpha-amylase secreted by the antarctic bacterium Alteromonas haloplanctis displays 66% amino acid sequence similarity with porcine pancreatic alpha-amylase. The psychrophilic alpha-amylase is however characterized by a sevenfold higher kcat and kcat/Km values at 4 degrees C and a lower conformational stability estimated as 10 kJ.mol-1 with respect to the porcine enzyme. It is proposed that both properties arise from an increase in molecular flexibility required to compensate for the reduction of reaction rates at low temperatures. This is supported by the fast denaturation rates induced by temperature, urea or guanidinium chloride and by the shift towards low temperatures of the apparent optimal temperature of activity. When compared with the known three-dimensional structure of porcine pancreatic alpha-amylase, homology modelling of the psychrophilic alpha-amylase reveals several features which may be assumed to be responsible for a more flexible, heat-labile conformation: the lack of several surface salt bridges in the (beta/alpha)8 domain, the reduction of the number of weakly polar interactions involving an aromatic side chain, a lower hydrophobicity associated with the increased flexibility index of amino acids forming the hydrophobic clusters and by substitutions of proline for alanine residues in loops connecting secondary structures. The weaker affinity of the enzyme for Ca2+ (Kd = 44 nM) and for Cl- (Kd = 1.2 mM at 4 degrees C) can result from single amino acid substitutions in the Ca(2+)-binding and Cl(-)-binding sites and can also affect the compactness of alpha-amylase