358 research outputs found
Electronic Structure Shift of Deep Nanoscale Silicon by SiO- vs. SiN-Embedding as Alternative to Impurity Doping
Conventional impurity doping of deep nanoscale silicon (dns-Si) used in ultra
large scale integration (ULSI) faces serious challenges below the 14 nm
technology node. We report on a new fundamental effect in theory and
experiment, namely the electronic structure of dns-Si experiencing energy
offsets of ca. 1 eV as a function of SiO- vs. SiN-embedding with a
few monolayers (MLs). An interface charge transfer (ICT) from dns-Si specific
to the anion type of the dielectric is at the core of this effect and arguably
nested in quantum-chemical properties of oxygen (O) and nitrogen (N) vs. Si. We
investigate the size up to which this energy offset defines the electronic
structure of dns-Si by density functional theory (DFT), considering interface
orientation, embedding layer thickness, and approximants featuring two Si
nanocrystals (NCs); one embedded in SiO and the other in SiN.
Working with synchrotron ultraviolet photoelectron spectroscopy (UPS), we use
SiO- vs. SiN-embedded Si nanowells (NWells) to obtain their energy
of the top valence band states. These results confirm our theoretical findings
and gauge an analytic model for projecting maximum dns-Si sizes for NCs,
nanowires (NWires) and NWells where the energy offset reaches full scale,
yielding to a clear preference for electrons or holes as majority carriers in
dns-Si. Our findings can replace impurity doping for n/p-type dns-Si as used in
ultra-low power electronics and ULSI, eliminating dopant-related issues such as
inelastic carrier scattering, thermal ionization, clustering, out-diffusion and
defect generation. As far as majority carrier preference is concerned, the
elimination of those issues effectively shifts the lower size limit of Si-based
ULSI devices to the crystalization limit of Si of ca. 1.5 nm and enables them
to work also under cryogenic conditions.Comment: 14 pages, 17 Figures with a total 44 graph
Evaluation of Swine-Specific PCR Assays Used for Fecal Source Tracking and Analysis of Molecular Diversity of Swine-Specific bacteroidales Populations
In this study, we evaluated the specificity, distribution, and sensitivity of Prevotella strain-based (PF163 and PigBac1) and methanogen-based (P23-2) PCR assays proposed to detect swine fecal pollution in environmental waters. The assays were tested against 222 fecal DNA extracts derived from target and nontarget animal hosts and against 34 groundwater and 15 surface water samples from five different sites. We also investigated the phylogenetic diversity of 1,340 Bacteroidales 16S rRNA gene sequences derived from swine feces, swine waste lagoons, swine manure pits, and waters adjacent to swine operations. Most swine fecal samples were positive for the host-specific Prevotella-based PCR assays (80 to 87%), while fewer were positive with the methanogen-targeted PCR assay (53%). Similarly, the Prevotella markers were detected more frequently than the methanogen-targeted assay markers in waters historically impacted with swine fecal contamination. However, the PF163 PCR assay cross-reacted with 23% of nontarget fecal DNA extracts, although Bayesian statistics suggested that it yielded the highest probability of detecting pig fecal contamination in a given water sample. Phylogenetic analyses revealed previously unknown swine-associated clades comprised of clones from geographically diverse swine sources and from water samples adjacent to swine operations that are not targeted by the Prevotella assays. While deeper sequencing coverage might be necessary to better understand the molecular diversity of fecal Bacteroidales species, results of sequence analyses supported the presence of swine fecal pollution in the studied watersheds. Overall, due to nontarget cross amplification and poor geographic stability of currently available host-specific PCR assays, development of additional assays is necessary to accurately detect sources of swine fecal pollution
Influence of the Occlusion Site
Background: Previous findings suggest that transient myocardial ischemia and reperfusion may elicit changes in the autonomic balance. In this study, a spectral analysis of heart rate variability was used to assess the modifications of sympathovagal balance induced by coronary angioplasty and their relationship with the occlusion site. Methods: We studied 23 patients (17M, 6F, age 58 ± 10 years) with left anterior descending and 19 patients (15M, 4F, age 56 ± 9 years) with right coronary artery stenosis. Spectral analysis of heart rate variability was performed, by autoregressive model, in basal conditions and during each balloon inflation. At least two inflations of 90–120 seconds were performed in each patient. Results: In patients with left anterior descending artery stenosis, the first occlusion induced marked changes in the autonomic balance, which moved toward a sympathetic predominance. The low frequency component of the spectrum and the low-to-high frequency ratio increased from 59 ± 10 normalized units (NU) to 75 ± 10 NU (P < 0.001) and from 2.4 ± 1.4 to 7.3 ± 4.7 (P < 0.001) respectively, while the high frequency component decreased from 30 ± 11 NU to 14 ± 7 NU (P < 0.001). These changes showed a progressive attenuation during repetitive occlusions, and were significantly correlated with the entity of myocardial ischemia assessed by the ST-segment shift measured on the intracoronary electrocardiographic lead. On the contrary, in patients with right coronary artery stenosis the first occlusion was ineffective with regard to the spectral parameters whereas the third occlusion induced a significant increase in the high frequency component (from 31 ± 9 NU to 41 ± 10 NU, P < 0.01) and decrease in the low-to-high frequency ratio (from 2.1 ± 0.9 to 1.3 ± 0.5, P < 0.05) suggesting a vagal activation. The entity of vagal activation was not correlated with the ST-segment shift. Conclusions: Our data indicate that repetitive coronary occlusions induce significant changes in the autonomic balance. The direction and the time course of these changes are related to the occlusion site
Synthesis and spectroscopic characterization of alkali-metal intercalated ZrSe2
We report on the synthesis and spectroscopic characterization of alkali metal intercalated ZrSe2
single crystals. ZrSe2 is produced by chemical vapour transport and then Li intercalated. Intercalation
is performed from the liquid phase (via butyllithium) and from the vapour phase. Raman
spectroscopy of intercalated ZrSe2 reveals phonon energy shifts of the Raman active A1g and
Eg phonon modes, the disappearance of two-phonon modes and new low wavenumber Raman
modes. Angle-resolved photoemission spectroscopy is used to perform a mapping of the Fermi
surface revealing an electron concentration of 4.7 × 1014 cm−2. We also perform vapour phase
intercalation of K and Cs into ZrSe2 and observe similar changes in the Raman modes as for the
Li case
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