Performance of almost edgeless silicon detectors in CTS and 3D-planar technologies

E. Alagoz; G. Anelli; G. Antchev; V. Avati; V. Bassetti; V. Berardi; V. Boccone; M. Bozzo; E. Brücken; A. Buzzo; M. G. Catanesi; S. Cuneo; C. Da Vià; M. Deile; R. Dinapoli; K. Eggert; V. Eremin; F. Ferro; J. Hasi; F. Haug; J. Heino; P. Jarron; J. Kalliopuska; J. Kašpar; C. Kenney; A. Kok; V. Kundrát; K. Kurvinen; R. Lauhakangas; E. Lippmaa; M. Lokajíček; T. Luntama; D. Macina; M. Macrí; S. Minutoli; L. Mirabito; H. Niewiadomski; E. Noschis; F. Oljemark; R. Orava; M. Oriunno; K. Österberg; S. Parker; A. L. Perrot; E. Radermacher; E. Radicioni; G. Ruggiero; H. Saarikko; A. Santroni; G. Sette; P. Siegrist; J. Smotlacha; W. Snoeys; C. Taylor; S. Watts; J. Whitmore

doi:10.1088/1748-0221/8/06/P06009

Performance of almost edgeless silicon detectors in CTS and 3D-planar technologies

E. Alagoz
, G. Anelli
, G. Antchev
, V. Avati
, V. Bassetti
, V. Berardi
, V. Boccone
, M. Bozzo
, E. Brücken
, A. Buzzo
, M. G. Catanesi
, S. Cuneo
, C. Da Vià
, M. Deile
, R. Dinapoli
, K. Eggert
, V. Eremin
, F. Ferro
, J. Hasi
, F. Haug

J. Heino, P. Jarron, J. Kalliopuska, J. Kašpar, C. Kenney, A. Kok, V. Kundrát, K. Kurvinen, R. Lauhakangas, E. Lippmaa, M. Lokajíček, T. Luntama, D. Macina, M. Macrí, S. Minutoli, L. Mirabito, H. Niewiadomski, E. Noschis, F. Oljemark, R. Orava, M. Oriunno, K. Österberg, S. Parker, A. L. Perrot, E. Radermacher, E. Radicioni, G. Ruggiero, H. Saarikko, A. Santroni, G. Sette, P. Siegrist, J. Smotlacha, W. Snoeys, C. Taylor, S. Watts, J. Whitmore

Physics and Astronomy

CERN
University of Genoa
Polytechnic University of Bari
University of Helsinki
Ioffe Physical Technical Institute
Brunel University London
University of Manchester
Czech Academy of Sciences
Stanford Nanofabrication Facility
National Institute of Chemical Physics and Biophysics, Tallinn
Lawrence Berkeley National Laboratory
Case Western Reserve University
Pennsylvania State University

Research output: Contribution to journal › Article › peer-review

6 Scopus citations

Abstract

The physics programme of the TOTEM experiment requires the detection of very forward protons scattered by only a few microradians out of the LHC beams. For this purpose, stacks of planar Silicon detectors have been mounted in moveable near-beam telescopes (Roman Pots) located along the beamline on both sides of the interaction point. In order to maximise the proton acceptance close to the beams, the dead space at the detector edge had to be minimised. During the detector prototyping phase, different sensor technologies and designs have been explored. A reduction of the dead space to less than 50 μm has been accomplished with two novel silicon detector technologies: one with the Current Terminating Structure (CTS) design and one based on the 3D edge manufacturing. This paper describes performance studies on prototypes of these detectors, carried out in 2004 in a fixed-target muon beam at CERN's SPS accelerator. In particular, the efficiency and accuracy in the vicinity of the beam-facing edges are discussed.

Original language	English
Article number	P06009
Journal	Journal of Instrumentation
Volume	8
Issue number	6
DOIs	https://doi.org/10.1088/1748-0221/8/06/P06009
State	Published - Jun 2013

Keywords

Particle tracking detectors
Particle tracking detectors (Solid-state detectors)

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10.1088/1748-0221/8/06/P06009

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Alagoz, E., Anelli, G., Antchev, G., Avati, V., Bassetti, V., Berardi, V., Boccone, V., Bozzo, M., Brücken, E., Buzzo, A., Catanesi, M. G., Cuneo, S., Da Vià, C., Deile, M., Dinapoli, R., Eggert, K., Eremin, V., Ferro, F., Hasi, J., ... Whitmore, J. (2013). Performance of almost edgeless silicon detectors in CTS and 3D-planar technologies. Journal of Instrumentation, 8(6), Article P06009. https://doi.org/10.1088/1748-0221/8/06/P06009

@article{d951fa3e8d3c4a1fbc88e49d2811e030,

title = "Performance of almost edgeless silicon detectors in CTS and 3D-planar technologies",

abstract = "The physics programme of the TOTEM experiment requires the detection of very forward protons scattered by only a few microradians out of the LHC beams. For this purpose, stacks of planar Silicon detectors have been mounted in moveable near-beam telescopes (Roman Pots) located along the beamline on both sides of the interaction point. In order to maximise the proton acceptance close to the beams, the dead space at the detector edge had to be minimised. During the detector prototyping phase, different sensor technologies and designs have been explored. A reduction of the dead space to less than 50 μm has been accomplished with two novel silicon detector technologies: one with the Current Terminating Structure (CTS) design and one based on the 3D edge manufacturing. This paper describes performance studies on prototypes of these detectors, carried out in 2004 in a fixed-target muon beam at CERN's SPS accelerator. In particular, the efficiency and accuracy in the vicinity of the beam-facing edges are discussed.",

keywords = "Particle tracking detectors, Particle tracking detectors (Solid-state detectors)",

author = "E. Alagoz and G. Anelli and G. Antchev and V. Avati and V. Bassetti and V. Berardi and V. Boccone and M. Bozzo and E. Br{\"u}cken and A. Buzzo and Catanesi, \{M. G.\} and S. Cuneo and \{Da Vi{\`a}\}, C. and M. Deile and R. Dinapoli and K. Eggert and V. Eremin and F. Ferro and J. Hasi and F. Haug and J. Heino and P. Jarron and J. Kalliopuska and J. Ka{\v s}par and C. Kenney and A. Kok and V. Kundr{\'a}t and K. Kurvinen and R. Lauhakangas and E. Lippmaa and M. Lokaj{\'i}{\v c}ek and T. Luntama and D. Macina and M. Macr{\'i} and S. Minutoli and L. Mirabito and H. Niewiadomski and E. Noschis and F. Oljemark and R. Orava and M. Oriunno and K. {\"O}sterberg and S. Parker and Perrot, \{A. L.\} and E. Radermacher and E. Radicioni and G. Ruggiero and H. Saarikko and A. Santroni and G. Sette and P. Siegrist and J. Smotlacha and W. Snoeys and C. Taylor and S. Watts and J. Whitmore",

year = "2013",

month = jun,

doi = "10.1088/1748-0221/8/06/P06009",

language = "English",

volume = "8",

journal = "Journal of Instrumentation",

issn = "1748-0221",

number = "6",

}

Alagoz, E, Anelli, G, Antchev, G, Avati, V, Bassetti, V, Berardi, V, Boccone, V, Bozzo, M, Brücken, E, Buzzo, A, Catanesi, MG, Cuneo, S, Da Vià, C, Deile, M, Dinapoli, R, Eggert, K, Eremin, V, Ferro, F, Hasi, J, Haug, F, Heino, J, Jarron, P, Kalliopuska, J, Kašpar, J, Kenney, C, Kok, A, Kundrát, V, Kurvinen, K, Lauhakangas, R, Lippmaa, E, Lokajíček, M, Luntama, T, Macina, D, Macrí, M, Minutoli, S, Mirabito, L, Niewiadomski, H, Noschis, E, Oljemark, F, Orava, R, Oriunno, M, Österberg, K, Parker, S, Perrot, AL, Radermacher, E, Radicioni, E, Ruggiero, G, Saarikko, H, Santroni, A, Sette, G, Siegrist, P, Smotlacha, J, Snoeys, W, Taylor, C, Watts, S & Whitmore, J 2013, 'Performance of almost edgeless silicon detectors in CTS and 3D-planar technologies', Journal of Instrumentation, vol. 8, no. 6, P06009. https://doi.org/10.1088/1748-0221/8/06/P06009

TY - JOUR

T1 - Performance of almost edgeless silicon detectors in CTS and 3D-planar technologies

AU - Alagoz, E.

AU - Anelli, G.

AU - Antchev, G.

AU - Avati, V.

AU - Bassetti, V.

AU - Berardi, V.

AU - Boccone, V.

AU - Bozzo, M.

AU - Brücken, E.

AU - Buzzo, A.

AU - Catanesi, M. G.

AU - Cuneo, S.

AU - Da Vià, C.

AU - Deile, M.

AU - Dinapoli, R.

AU - Eggert, K.

AU - Eremin, V.

AU - Ferro, F.

AU - Hasi, J.

AU - Haug, F.

AU - Heino, J.

AU - Jarron, P.

AU - Kalliopuska, J.

AU - Kašpar, J.

AU - Kenney, C.

AU - Kok, A.

AU - Kundrát, V.

AU - Kurvinen, K.

AU - Lauhakangas, R.

AU - Lippmaa, E.

AU - Lokajíček, M.

AU - Luntama, T.

AU - Macina, D.

AU - Macrí, M.

AU - Minutoli, S.

AU - Mirabito, L.

AU - Niewiadomski, H.

AU - Noschis, E.

AU - Oljemark, F.

AU - Orava, R.

AU - Oriunno, M.

AU - Österberg, K.

AU - Parker, S.

AU - Perrot, A. L.

AU - Radermacher, E.

AU - Radicioni, E.

AU - Ruggiero, G.

AU - Saarikko, H.

AU - Santroni, A.

AU - Sette, G.

AU - Siegrist, P.

AU - Smotlacha, J.

AU - Snoeys, W.

AU - Taylor, C.

AU - Watts, S.

AU - Whitmore, J.

PY - 2013/6

Y1 - 2013/6

N2 - The physics programme of the TOTEM experiment requires the detection of very forward protons scattered by only a few microradians out of the LHC beams. For this purpose, stacks of planar Silicon detectors have been mounted in moveable near-beam telescopes (Roman Pots) located along the beamline on both sides of the interaction point. In order to maximise the proton acceptance close to the beams, the dead space at the detector edge had to be minimised. During the detector prototyping phase, different sensor technologies and designs have been explored. A reduction of the dead space to less than 50 μm has been accomplished with two novel silicon detector technologies: one with the Current Terminating Structure (CTS) design and one based on the 3D edge manufacturing. This paper describes performance studies on prototypes of these detectors, carried out in 2004 in a fixed-target muon beam at CERN's SPS accelerator. In particular, the efficiency and accuracy in the vicinity of the beam-facing edges are discussed.

AB - The physics programme of the TOTEM experiment requires the detection of very forward protons scattered by only a few microradians out of the LHC beams. For this purpose, stacks of planar Silicon detectors have been mounted in moveable near-beam telescopes (Roman Pots) located along the beamline on both sides of the interaction point. In order to maximise the proton acceptance close to the beams, the dead space at the detector edge had to be minimised. During the detector prototyping phase, different sensor technologies and designs have been explored. A reduction of the dead space to less than 50 μm has been accomplished with two novel silicon detector technologies: one with the Current Terminating Structure (CTS) design and one based on the 3D edge manufacturing. This paper describes performance studies on prototypes of these detectors, carried out in 2004 in a fixed-target muon beam at CERN's SPS accelerator. In particular, the efficiency and accuracy in the vicinity of the beam-facing edges are discussed.

KW - Particle tracking detectors

KW - Particle tracking detectors (Solid-state detectors)

UR - https://www.scopus.com/pages/publications/84879285810

U2 - 10.1088/1748-0221/8/06/P06009

DO - 10.1088/1748-0221/8/06/P06009

M3 - Article

AN - SCOPUS:84879285810

SN - 1748-0221

VL - 8

JO - Journal of Instrumentation

JF - Journal of Instrumentation

IS - 6

M1 - P06009

ER -

Performance of almost edgeless silicon detectors in CTS and 3D-planar technologies

Abstract

Keywords

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