Your search keyword '"Dalla Betta, Gian-Franco"' showing total 3 results

1. Silicon microstrip detectors in 3D technology for the sLHC

Author

Parzefall, Ulrich, Dalla Betta, Gian-Franco, Eckert, Simon, Eklund, Lars, Fleta, Celeste, Jakobs, Karl, Kühn, Susanne, Pahn, Gregor, Parkes, Chris, Pennicard, David, Ronchin, Sabina, Zoboli, Andrea, and Zorzi, Nicola

Subjects

*STRIP transmission lines, *SILICON diodes, *NUCLEAR track detectors, *LARGE Hadron Collider, *LUMINESCENCE, *RADIATION hardening (Electronics), *PROTOTYPES, *IONIZING radiation

Abstract

Abstract: The projected luminosity upgrade of the large hadron collider (LHC), the sLHC, will constitute a challenging radiation environment for tracking detectors. Massive improvements in radiation hardness are required with respect to the LHC. In the layout for the new ATLAS tracker, silicon strip detectors (SSDs) with short strips cover the region from 28 to 60cm distance to the beam. These SSDs will be exposed to fluences up to , hence radiation resistance is the major concern. It is advantageous to fuse the superior radiation hardness of the 3D design originally conceived for pixel-style applications with the benefits of the well-known planar technology for strip detectors. This is achieved by ganging rows of 3D columns together to form strips. Several prototype sLHC detector modules using 3D SSD with short strips, processed on p-type silicon, and LHC-speed front-end electronics from the present ATLAS semi-conductor tracker (SCT) were built. The modules were tested before and after irradiation to fluences of . The tests were performed with three systems: a highly focused IR-laser with spot size to make position-resolved scans of the charge collection efficiency (CCE), a -source set-up to measure the signal levels for a minimum ionizing particles (MIPs), and a beam test with 180GeV pions at CERN. This article gives a brief overview of the performance of these 3D modules, and draws conclusions about options for using 3D strip sensors as tracking detectors at the sLHC. [Copyright &y& Elsevier]

Published

2009

2. Efficiency measurements for 3D silicon strip detectors

Author

Parzefall, Ulrich, Dalla Betta, Gian-Franco, Boscardin, Maurizio, Eckert, Simon, Eklund, Lars, Fleta, Celeste, Jakobs, Karl, Köhler, Michael, Kühn, Susanne, Pahn, Gregor, Parkes, Chris, Pennicard, David, Ronchin, Sabina, Zoboli, Andrea, and Zorzi, Nicola

Subjects

*SILICON diodes, *NUCLEAR track detectors, *LARGE Hadron Collider, *RADIATION hardening (Electronics), *PARTICLES (Nuclear physics)

Abstract

Abstract: Silicon strip detectors are widely used as part of the inner tracking layers in particle physics experiments. For applications at the luminosity upgrade of the Large Hadron Collider (LHC), the sLHC, silicon detectors with extreme radiation hardness are required. The 3D detector design, where electrodes are processed from underneath the strips into the silicon bulk material, provides a way to enhance the radiation tolerance of standard planar silicon strip detectors. Detectors with several innovative 3D designs that constitute a simpler and more cost-effective processing than the 3D design initially proposed were connected to read-out electronics from LHC experiments and subsequently tested. Results on the amount of charge collected, the noise and the uniformity of charge collection are given. [ABSTRACT FROM AUTHOR]

Published

2010

3. 3D silicon strip detectors

Author

Parzefall, Ulrich, Bates, Richard, Boscardin, Maurizio, Dalla Betta, Gian-Franco, Eckert, Simon, Eklund, Lars, Fleta, Celeste, Jakobs, Karl, Kühn, Susanne, Lozano, Manuel, Pahn, Gregor, Parkes, Chris, Pellegrini, Giulio, Pennicard, David, Piemonte, Claudio, Ronchin, Sabina, Szumlak, Tomasz, Zoboli, Andrea, and Zorzi, Nicola

Subjects

*SILICON diodes, *LARGE Hadron Collider, *NUCLEAR track detectors, *PHYSICS experiments, *RADIATION hardening (Electronics)

Abstract

Abstract: While the Large Hadron Collider (LHC) at CERN has started operation in autumn 2008, plans for a luminosity upgrade to the Super-LHC (sLHC) have already been developed for several years. This projected luminosity increase by an order of magnitude gives rise to a challenging radiation environment for tracking detectors at the LHC experiments. Significant improvements in radiation hardness are required with respect to the LHC. Using a strawman layout for the new tracker of the ATLAS experiment as an example, silicon strip detectors (SSDs) with short strips of 2–3cm length are foreseen to cover the region from 28 to 60cm distance to the beam. These SSD will be exposed to radiation levels up to , which makes radiation resistance a major concern for the upgraded ATLAS tracker. Several approaches to increasing the radiation hardness of silicon detectors exist. In this article, it is proposed to combine the radiation hard 3D-design originally conceived for pixel-style applications with the benefits of the established planar technology for strip detectors by using SSDs that have regularly spaced doped columns extending into the silicon bulk under the detector strips. The first 3D SSDs to become available for testing were made in the Single Type Column (STC) design, a technological simplification of the original 3D design. With such 3D SSDs, a small number of prototype sLHC detector modules with LHC-speed front-end electronics as used in the semiconductor tracking systems of present LHC experiments were built. Modules were tested before and after irradiation to fluences of . The tests were performed with three systems: a highly focused IR-laser with spot size to make position-resolved scans of the charge collection efficiency, an -source set-up to measure the signal levels for a minimum ionizing particle (MIP), and a beam test with 180GeV pions at CERN. This article gives a brief overview of the results obtained with 3D-STC-modules. [Copyright &y& Elsevier]

Published

2009