736 research outputs found
Design and cryogenic operation of a hybrid quantum-CMOS circuit
Silicon-On-Insulator nanowire transistors of very small dimensions exhibit
quantum effects like Coulomb blockade or single-dopant transport at low
temperature. The same process also yields excellent field-effect transistors
(FETs) for larger dimensions, allowing to design integrated circuits. Using the
same process, we have co-integrated a FET-based ring oscillator circuit
operating at cryogenic temperature which generates a radio-frequency (RF)
signal on the gate of a nanoscale device showing Coulomb oscillations. We
observe rectification of the RF signal, in good agreement with modeling
Effect of discrete impurities on electron transport in ultra-short MOSFET using 3D Monte Carlo simulation
This paper discusses the influence of the channel impurity distribution on
the transport and the drive current in short-gate MOSFET. In this purpose, a
careful description of electron-ion interaction suitable for the case of
discrete impurities has been implemented in a 3D particle Monte Carlo
simulator. This transport model is applied to the investigation of 50 nm MOSFET
operation. The results show that a small change in the number of doping
impurities or in the position of a single discrete impurity in the inversion
layer may significantly influence the drain current. This effect is not only
related to threshold voltage fluctuations but also to variations in transport
properties in the inversion layer, especially at high drain voltage. The
results are analyzed in terms of local fluctuations of electron velocity and
current density. In a set of fifteen simulated devices the drive current Ion,
determined at VGS = VDS = 0.6 V, is found to vary in a range of 23% according
to the position of channel impurities.Comment: 31 pages, 13 figures, revised version: discussions and references
added, to be published in IEEE Trans. Electron. Device
Nitrite production by ammonia-oxidizing bacteria mediates chloramine decay and resistance in a mixed-species community
As water distribution centres increasingly switch to using chloramine to disinfect drinking water, it is of paramount importance to determine the interactions of chloramine with potential biological contaminants, such as bacterial biofilms, that are found in these systems. For example, ammonia-oxidizing bacteria (AOB) are known to accelerate the decay of chloramine in drinking water systems, but it is also known that organic compounds can increase the chloramine demand. This study expanded upon our previously published model to compare the decay of chloramine in response to alginate, Pseudomonas aeruginosa, Nitrosomonas europaea and a mixed-species nitrifying culture, exploring the contributions of microbial by-products, heterotrophic bacteria and AOBs to chloramine decay. Furthermore, the contribution of AOBs to biofilm stability during chloramination was investigated. The results demonstrate that the biofilm matrix or extracellular polymeric substances (EPS), represented by alginate in these experiments, as well as high concentrations of dead or inactive cells, can drive chloramine decay rather than any specific biochemical activity of P. aeruginosa cells. Alginate was shown to reduce chloramine concentrations in a dose-dependent manner at an average rate of 0.003 mg l−1 h−1 per mg l−1 of alginate. Additionally, metabolically active AOBs mediated the decay of chloramine, which protected members of mixed-species biofilms from chloramine-mediated disinfection. Under these conditions, nitrite produced by AOBs directly reacted with chloramine to drive its decay. In contrast, biofilms of mixed-species communities that were dominated by heterotrophic bacteria due to either the absence of ammonia, or the addition of nitrification inhibitors and glucose, were highly sensitive to chloramine. These results suggest that mixed-species biofilms are protected by a combination of biofilm matrix-mediated inactivation of chloramine as well as the conversion of ammonia to nitrite through the activity of AOBs present in the community
Nitrite production by ammonia-oxidizing bacteria mediates chloramine decay and resistance in a mixed-species community.
As water distribution centres increasingly switch to using chloramine to disinfect drinking water, it is of paramount importance to determine the interactions of chloramine with potential biological contaminants, such as bacterial biofilms, that are found in these systems. For example, ammonia-oxidizing bacteria (AOB) are known to accelerate the decay of chloramine in drinking water systems, but it is also known that organic compounds can increase the chloramine demand. This study expanded upon our previously published model to compare the decay of chloramine in response to alginate, Pseudomonas aeruginosa, Nitrosomonas europaea and a mixed-species nitrifying culture, exploring the contributions of microbial by-products, heterotrophic bacteria and AOBs to chloramine decay. Furthermore, the contribution of AOBs to biofilm stability during chloramination was investigated. The results demonstrate that the biofilm matrix or extracellular polymeric substances (EPS), represented by alginate in these experiments, as well as high concentrations of dead or inactive cells, can drive chloramine decay rather than any specific biochemical activity of P. aeruginosa cells. Alginate was shown to reduce chloramine concentrations in a dose-dependent manner at an average rate of 0.003 mg l-1 h-1 per mg l-1 of alginate. Additionally, metabolically active AOBs mediated the decay of chloramine, which protected members of mixed-species biofilms from chloramine-mediated disinfection. Under these conditions, nitrite produced by AOBs directly reacted with chloramine to drive its decay. In contrast, biofilms of mixed-species communities that were dominated by heterotrophic bacteria due to either the absence of ammonia, or the addition of nitrification inhibitors and glucose, were highly sensitive to chloramine. These results suggest that mixed-species biofilms are protected by a combination of biofilm matrix-mediated inactivation of chloramine as well as the conversion of ammonia to nitrite through the activity of AOBs present in the community
The E-peak distribution of the GRBs detected by HETE FREGATE instrument
The FREGATE gamma ray detector of HETE-2 is sensitive to photons between 6
and 400 keV. This sensitivity range, extended towards low energies, allows us
to explore the emission of GRBs in hard X-rays. We fit the spectra of 23 GRBs
with Band's spectral function in order to derive the distribution of their peak
energies (E-peak). This distribution is then compared with the E-peak
distributions measured by BATSE and GINGA.Comment: 3 pages, Woods Hole Proceeding
Biofilm formation inhibition and dispersal of multi-species communities containing ammonia-oxidising bacteria
© 2019, The Author(s). Despite considerable research, the biofilm-forming capabilities of Nitrosomonas europaea are poorly understood for both mono and mixed-species communities. This study combined biofilm assays and molecular techniques to demonstrate that N. europaea makes very little biofilm on its own, and relies on the activity of associated heterotrophic bacteria to establish a biofilm. However, N. europaea has a vital role in the proliferation of mixed-species communities under carbon-limited conditions, such as in drinking water distribution systems, through the provision of organic carbon via ammonia oxidation. Results show that the addition of nitrification inhibitors to mixed-species nitrifying cultures under carbon-limited conditions disrupted biofilm formation and caused the dispersal of pre-formed biofilms. This dispersal effect was not observed when an organic carbon source, glucose, was included in the medium. Interestingly, inhibition of nitrification activity of these mixed-species biofilms in the presence of added glucose resulted in increased total biofilm formation compared to controls without the addition of nitrification inhibitors, or with only glucose added. This suggests that active AOB partially suppress or limit the overall growth of the heterotrophic bacteria. The experimental model developed here provides evidence that ammonia-oxidising bacteria (AOB) are involved in both the formation and maintenance of multi-species biofilm communities. The results demonstrate that the activity of the AOB not only support the growth and biofilm formation of heterotrophic bacteria by providing organic carbon, but also restrict and limit total biomass in mixed community systems
Biofilm formation inhibition and dispersal of multi-species communities containing ammonia-oxidising bacteria.
Despite considerable research, the biofilm-forming capabilities of Nitrosomonas europaea are poorly understood for both mono and mixed-species communities. This study combined biofilm assays and molecular techniques to demonstrate that N. europaea makes very little biofilm on its own, and relies on the activity of associated heterotrophic bacteria to establish a biofilm. However, N. europaea has a vital role in the proliferation of mixed-species communities under carbon-limited conditions, such as in drinking water distribution systems, through the provision of organic carbon via ammonia oxidation. Results show that the addition of nitrification inhibitors to mixed-species nitrifying cultures under carbon-limited conditions disrupted biofilm formation and caused the dispersal of pre-formed biofilms. This dispersal effect was not observed when an organic carbon source, glucose, was included in the medium. Interestingly, inhibition of nitrification activity of these mixed-species biofilms in the presence of added glucose resulted in increased total biofilm formation compared to controls without the addition of nitrification inhibitors, or with only glucose added. This suggests that active AOB partially suppress or limit the overall growth of the heterotrophic bacteria. The experimental model developed here provides evidence that ammonia-oxidising bacteria (AOB) are involved in both the formation and maintenance of multi-species biofilm communities. The results demonstrate that the activity of the AOB not only support the growth and biofilm formation of heterotrophic bacteria by providing organic carbon, but also restrict and limit total biomass in mixed community systems
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