9 research outputs found
Diffraction and Total Cross-Section at the Tevatron and the LHC
At the Tevatron, the total p_bar-p cross-section has been measured by CDF at 546 GeV and 1.8 TeV, and by E710/E811 at 1.8 TeV. The two results at 1.8 TeV disagree by 2.6 standard deviations, introducing big uncertainties into extrapolations to higher energies. At the LHC, the TOTEM collaboration is preparing to resolve the ambiguity by measuring the total p-p cross-section with a precision of about 1 %. Like at the Tevatron experiments, the luminosity-independent method based on the Optical Theorem will be used. The Tevatron experiments have also performed a vast range of studies about soft and hard diffractive events, partly with antiproton tagging by Roman Pots, partly with rapidity gap tagging. At the LHC, the combined CMS/TOTEM experiments will carry out their diffractive programme with an unprecedented rapidity coverage and Roman Pot spectrometers on both sides of the interaction point. The physics menu comprises detailed studies of soft diffractive differential cross-sections, diffractive structure functions, rapidity gap survival and exclusive central production by Double Pomeron Exchange.Peer reviewe
Double modified internal gate (MIG) pixel for fluorescence imaging applications
In this work we present a double modified internal gate (MIG) pixel structure, fabricated in a slightly modified 0.35”m CMOS process, to be effectively used in, e.g. low-level irradiance fluorescent imaging applications. The pixel structure enables a non-destructive readout, which facilitates a constant monitoring of the molecule fluorescence process. The readout isbased on signal averaging and up-the-ramp sampling current differential readout, which drastically reduces the amount of noise in the pixel output signal. The modified internal gates enable extremely low dark-current and very low-noise operation
Superior gamma-detection and IR imaging via ALD-passivated germanium nanostructures
| openaire: EC/H2020/777222/EU//ATTRACTNon peer reviewe
[Role of surgical splanchnicectomy in the treatment of pancreatic carcinoma].
Palliative surgical procedures offer considerable benefit for the patients with unresectable pancreatic cancer: surgical splanchnicectomy performed in conjunction with biliary-enteric by-pass offers good results as regard pain relief without increased morbidity and mortality. We treated 25 patients with unresectable pancreatic cancer by mean of biliary-enteric by-pass plus bilateral splanchnicectomy performed through different surgical approaches. In this series of patients postoperative mortality was nil, mean survival time was 7.2 months (range 3-14 months). Preoperatively, we assessed all patients as affected by visceral pain: Scott-Huskisson 10 mark-scale value in quantitative assessment of pain was equal or above the 7th mark in 87.5\% of patients. One month later in the postoperative follow-up, 96\% of the patients had a significant reduction in pain intensity from a preoperative median of 7 mark to a postoperative median of 1.5 mark (p = 0.0001). The mean period free of pain recurrence was 4.8 months. However, after 6 months only 46\% of survivors were pain-free with such rate decreasing further to a 10\% of survivors after 8 months. Nevertheless, the patients had around 70\% of their survival span free of pain. We strongly believe that failure in relief of pain is due to a mistake in preoperative evaluation of the type of pain (somatic and not visceral, or both) and to the onset of somatic pain in the course of the disease rather than to surgical technical errors. Recurrence of pain has been considered inevitable in the biological progression of unresected cancer, and would be treated by combination of therapies, such as non steroidal anti-inflammatory drugs, transaortic coeliac plexus block, narcotics and cervical cordotomy
TOTEM PHYSICS
Presented by K. Eggert This article discusses the physics programme of the TOTEM experiment at the LHC. A new special beam optics with ÎČ â = 90 m, enabling the measurements of the total cross-section, elastic pp scattering and diffractive phenomena already at early LHC runs, is explained. For this and the various other TOTEM running scenarios, the acceptances of the leading proton The physics programme of the TOTEM experiment can be performed in several few-days run
Diffraction and Total Cross-Section at the Tevatron and the LHC
At the Tevatron, the total p_bar-p cross-section has been measured by CDF at 546 GeV and 1.8 TeV, and by E710/E811 at 1.8 TeV. The two results at 1.8 TeV disagree by 2.6 standard deviations, introducing big uncertainties into extrapolations to higher energies. At the LHC, the TOTEM collaboration is preparing to resolve the ambiguity by measuring the total p-p cross-section with a precision of about 1 %. Like at the Tevatron experiments, the luminosity-independent method based on the Optical Theorem will be used. The Tevatron experiments have also performed a vast range of studies about soft and hard diffractive events, partly with antiproton tagging by Roman Pots, partly with rapidity gap tagging. At the LHC, the combined CMS/TOTEM experiments will carry out their diffractive programme with an unprecedented rapidity coverage and Roman Pot spectrometers on both sides of the interaction point. The physics menu comprises detailed studies of soft diffractive differential cross-sections, diffractive structure functions, rapidity gap survival and exclusive central production by Double Pomeron Exchange.At the Tevatron, the total p_bar-p cross-section has been measured by CDF at 546 GeV and 1.8 TeV, and by E710/E811 at 1.8 TeV. The two results at 1.8 TeV disagree by 2.6 standard deviations, introducing big uncertainties into extrapolations to higher energies. At the LHC, the TOTEM collaboration is preparing to resolve the ambiguity by measuring the total p-p cross-section with a precision of about 1 %. Like at the Tevatron experiments, the luminosity-independent method based on the Optical Theorem will be used. The Tevatron experiments have also performed a vast range of studies about soft and hard diffractive events, partly with antiproton tagging by Roman Pots, partly with rapidity gap tagging. At the LHC, the combined CMS/TOTEM experiments will carry out their diffractive programme with an unprecedented rapidity coverage and Roman Pot spectrometers on both sides of the interaction point. The physics menu comprises detailed studies of soft diffractive differential cross-sections, diffractive structure functions, rapidity gap survival and exclusive central production by Double Pomeron Exchange