Radiation hardness of diamond and silicon sensors compared

被引：74

作者：

de Boer, Wim

Bol, Johannes

Furgeril, Alex

Mueller, Steffen

Sander, Christian

Berdermann, Eleni

Pomorski, Michal

Huhtinen, Mika

机构：

[1] Univ Karlsruhe, D-76128 Karlsruhe, Germany

[2] Gesell Schwerionenforsch mbH, D-64291 Darmstadt, Germany

[3] CERN, CH-1211 Geneva, Switzerland

来源：

PHYSICA STATUS SOLIDI A-APPLICATIONS AND MATERIALS SCIENCE | 2007年 / 204卷 / 09期

关键词：

TRACKING DETECTORS; ENERGY;

D O I：

10.1002/pssa.200776327

中图分类号：

T [工业技术];

学科分类号：

08 ;

摘要：

The radiation hardness of silicon charged particle sensors is compared with single crystal and polycrystalline diamond sensors, both experimentally and theoretically. It is shown that for Si- and C-sensors, the NIEL hypothesis, which states that the signal loss is proportional to the Non-Ionizing Energy Loss, is a good approximation to the present data. At incident proton and neutron energies well above 0.1 GeV the radiation damage is dominated by the inelastic cross section, while at non-relativistic energies the elastic cross section prevails. The smaller inelastic nucleon-carbon cross section and the light nuclear fragments imply that at high energies diamond is an order of magnitude more radiation hard than silicon, while at energies below 0.1 GeV the difference becomes significantly smaller. (C) 2007 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.

引用

页码：3004 / 3010

页数：7

共 12 条

[1] Radiation hard diamond sensors for future tracking applications [J].

Adam, W. ;

de Boer, W. ;

Borchi, E. ;

Bruzzi, M. ;

Colledani, C. ;

D'Angelo, P. ;

Dabrowski, V. ;

Dulinski, W. ;

van Eijk, B. ;

Eremin, V. ;

Fizzotti, F. ;

Frais-Koelbl, H. ;

Furetta, C. ;

Gan, K. K. ;

Gorisek, A. ;

Griesmayer, E. ;

Grigoriev, E. ;

Hartjes, F. ;

Hrubec, J. ;

Huegging, F. ;

Kagan, H. ;

Kaplon, J. ;

Kass, R. ;

Knoepfle, K. T. ;

Krammer, M. ;

Lange, W. ;

Logiudice, A. ;

Manfredotti, C. ;

Mathes, M. ;

Menichelli, D. ;

Mishina, M. ;

Moroni, L. ;

Noomen, J. ;

Oh, A. ;

Pernegger, H. ;

Pernicka, M. ;

Potenza, R. ;

Riester, J. L. ;

Rudge, A. ;

Sala, S. ;

Schnetzer, S. ;

Sciortino, S. ;

Stone, R. ;

Sutera, C. ;

Trischuk, W. ;

Velthuis, J. J. ;

Vincenzo, B. ;

Weilhammer, P. ;

Weingarten, J. ;

Wermes, N. .

NUCLEAR INSTRUMENTS & METHODS IN PHYSICS RESEARCH SECTION A-ACCELERATORS SPECTROMETERS DETECTORS AND ASSOCIATED EQUIPMENT, 2006, 565 (01) :278-283

[2]

*ASTM, 1648 WK1

[3] Simulation of non-ionising energy loss and defect formation in silicon [J].

Huhtinen, M .

NUCLEAR INSTRUMENTS & METHODS IN PHYSICS RESEARCH SECTION A-ACCELERATORS SPECTROMETERS DETECTORS AND ASSOCIATED EQUIPMENT, 2002, 491 (1-2) :194-215

[4] DISPLACEMENT THRESHOLD ENERGY FOR TYPE-IIA DIAMOND [J].

KOIKE, J ;

PARKIN, DM ;

MITCHELL, TE .

APPLIED PHYSICS LETTERS, 1992, 60 (12) :1450-1452

[5] Radiation hard silicon detectors -: developments by the RD48 (ROSE) collaboration [J].

Lindström, G ;

Ahmed, M ;

Albergo, S ;

Allport, P ;

Anderson, D ;

Andricek, L ;

Angarano, MM ;

Augelli, V ;

Bacchetta, N ;

Bartalini, P ;

Bates, R ;

Biggeri, U ;

Bilei, GM ;

Bisello, D ;

Boemi, D ;

Borchi, E ;

Botila, T ;

Brodbeck, TJ ;

Bruzzi, M ;

Budzynski, T ;

Burger, P ;

Campabadal, F ;

Casse, G ;

Catacchini, E ;

Chilingarov, A ;

Ciampolini, P ;

Cindro, V ;

Costa, MJ ;

Creanza, D ;

Clauws, P ;

Da Via, C ;

Davies, G ;

De Boer, W ;

Dell'Orso, R ;

De Palma, M ;

Dezillie, B ;

Eremin, V ;

Evrard, O ;

Fallica, G ;

Fanourakis, G ;

Feick, H ;

Focardi, E ;

Fonseca, L ;

Fretwurst, E ;

Fuster, J ;

Gabathuler, K ;

Glaser, M ;

Grabiec, P ;

Grigoriev, E ;

Hall, G .

NUCLEAR INSTRUMENTS & METHODS IN PHYSICS RESEARCH SECTION A-ACCELERATORS SPECTROMETERS DETECTORS AND ASSOCIATED EQUIPMENT, 2001, 466 (02) :308-326

[6] Radiation tolerant semiconductor sensors for tracking detectors [J].

Moll, Michael .

NUCLEAR INSTRUMENTS & METHODS IN PHYSICS RESEARCH SECTION A-ACCELERATORS SPECTROMETERS DETECTORS AND ASSOCIATED EQUIPMENT, 2006, 565 (01) :202-211

[7]

MULLER S, 2006, THESIS U KARLSRUHE

[8] Low-temperature tracking detectors [J].

Niinikoski, TO ;

Abreu, M ;

Anbinderis, P ;

Anbinderis, T ;

D'Ambrosio, N ;

de Boer, W ;

Borchi, E ;

Borer, K ;

Bruzzi, M ;

Buontempo, S ;

Chen, W ;

Cindro, V ;

Dezillie, B ;

Dierlamm, A ;

Eremin, V ;

Gaubas, E ;

Gorbatenko, V ;

Granata, V ;

Grigoriev, E ;

Grohmann, S ;

Hauler, F ;

Heijne, E ;

Heising, S ;

Hempel, O ;

Herzog, R ;

Härkönen, J ;

Ilyashenko, I ;

Janos, S ;

Jungermann, L ;

Kalesinskas, V ;

Kapturauskas, J ;

Laiho, R ;

Li, Z ;

Luukka, P ;

Mandic, I ;

De Masi, R ;

Menichelli, D ;

Mikuz, M ;

Militaru, O ;

Nuessle, G ;

O'Shea, V ;

Pagano, S ;

Paul, S ;

Solano, BP ;

Piotrzkowski, K ;

Pirollo, S ;

Pretzl, K ;

Rahman, M ;

Mendes, PR ;

Rouby, X .

NUCLEAR INSTRUMENTS & METHODS IN PHYSICS RESEARCH SECTION A-ACCELERATORS SPECTROMETERS DETECTORS AND ASSOCIATED EQUIPMENT, 2004, 520 (1-3) :87-92

[9]

WEILHAMMER P, 2006, CERNLHCC2006010

[10]

ZAMANTZAS C, 2005, P DIPAC LYON FRANC

← 1 2 →