A 3D diamond detector for particle tracking

M. Artuso; F. Bachmair; L. Bäni; M. Bartosik; J. Beacham; V. Bellini; V. Belyaev; B. Bentele; E. Berdermann; P. Bergonzo; A. Bes; J. M. Brom; M. Bruzzi; M. Cerv; C. Chau; G. Chiodini; D. Chren; V. Cindro; G. Claus; J. Collot; S. Costa; J. Cumalat; A. Dabrowski; R. Dalessandro; W. De Boer; B. Dehning; D. Dobos; M. Dünser; V. Eremin; R. Eusebi; G. Forcolin; J. Forneris; H. Frais-Kölbl; K. K. Gan; M. Gastal; M. Goffe; J. Goldstein; A. Golubev; L. Gonella; A. Gorišek; L. Graber; E. Grigoriev; J. Grosse-Knetter; B. Gui; M. Guthoff; I. Haughton; D. Hidas; D. Hits; M. Hoeferkamp; T. Hofmann; J. Hosslet; J. Y. Hostachy; F. Hügging; H. Jansen; J. Janssen; H. Kagan; K. Kanxheri; G. Kasieczka; R. Kass; F. Kassel; M. Kis; G. Kramberger; S. Kuleshov; A. Lacoste; S. Lagomarsino; A. Lo Giudice; C. Maazouzi; I. Mandic; C. Mathieu; N. McFadden; G. McGoldrick; M. Menichelli; M. Mikuž; A. Morozzi; J. Moss; R. Mountain; S. Murphy; A. Oh; P. Olivero; G. Parrini; D. Passeri; M. Pauluzzi; H. Pernegger; R. Perrino; F. Picollo; M. Pomorski; R. Potenza; A. Quadt; A. Re; G. Riley; S. Roe; M. Sapinski; M. Scaringella; S. Schnetzer; T. Schreiner; S. Sciortino; A. Scorzoni; S. Seidel; L. Servoli; A. Sfyrla; G. Shimchuk; D. S. Smith; B. Sopko; V. Sopko; S. Spagnolo; S. Spanier; K. Stenson; R. Stone; C. Sutera; A. Taylor; M. Traeger; D. Tromson; W. Trischuk; C. Tuve; L. Uplegger; J. Velthuis; N. Venturi; E. Vittone; S. Wagner; R. Wallny; J. C. Wang; P. Weilhammer; J. Weingarten; C. Weiss; T. Wengler; N. Wermes; M. Yamouni; M. Zavrtanik

doi:10.1016/j.nima.2015.09.079

A 3D diamond detector for particle tracking

M. Artuso, F. Bachmair, L. Bäni, M. Bartosik, J. Beacham, V. Bellini, V. Belyaev, B. Bentele, E. Berdermann, P. Bergonzo, A. Bes, J. M. Brom, M. Bruzzi, M. Cerv, C. Chau, G. Chiodini, D. Chren, V. Cindro, G. Claus, J. CollotS. Costa, J. Cumalat, A. Dabrowski, R. Dalessandro, W. De Boer, B. Dehning, D. Dobos, M. Dünser, V. Eremin, R. Eusebi, G. Forcolin, J. Forneris, H. Frais-Kölbl, K. K. Gan, M. Gastal, M. Goffe, J. Goldstein, A. Golubev, L. Gonella, A. Gorišek, L. Graber, E. Grigoriev, J. Grosse-Knetter, B. Gui, M. Guthoff, I. Haughton, D. Hidas, D. Hits, M. Hoeferkamp, T. Hofmann, J. Hosslet, J. Y. Hostachy, F. Hügging, H. Jansen, J. Janssen, H. Kagan, K. Kanxheri, G. Kasieczka, R. Kass, F. Kassel, M. Kis, G. Kramberger, S. Kuleshov, A. Lacoste, S. Lagomarsino, A. Lo Giudice, C. Maazouzi, I. Mandic, C. Mathieu, N. McFadden, G. McGoldrick, M. Menichelli, M. Mikuž, A. Morozzi, J. Moss, R. Mountain, S. Murphy, A. Oh, P. Olivero, G. Parrini, D. Passeri, M. Pauluzzi, H. Pernegger, R. Perrino, F. Picollo, M. Pomorski, R. Potenza, A. Quadt, A. Re, G. Riley, S. Roe, M. Sapinski, M. Scaringella, S. Schnetzer, T. Schreiner, S. Sciortino, A. Scorzoni, S. Seidel, L. Servoli, A. Sfyrla, G. Shimchuk, D. S. Smith, B. Sopko, V. Sopko, S. Spagnolo, S. Spanier, K. Stenson, R. Stone, C. Sutera, A. Taylor, M. Traeger, D. Tromson, W. Trischuk, C. Tuve, L. Uplegger, J. Velthuis, N. Venturi, E. Vittone, S. Wagner, R. Wallny, J. C. Wang, P. Weilhammer, J. Weingarten, C. Weiss, T. Wengler, N. Wermes, M. Yamouni, M. Zavrtanik

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5 Citas (Scopus)

Resumen

© 2015 Elsevier B.V.All rights reserved. In the present study, results towards the development of a 3D diamond sensor are presented. Conductive channels are produced inside the sensor bulk using a femtosecond laser. This electrode geometry allows full charge collection even for low quality diamond sensors. Results from testbeam show that charge is collected by these electrodes. In order to understand the channel growth parameters, with the goal of producing low resistivity channels, the conductive channels produced with a different laser setup are evaluated by Raman spectroscopy.

Idioma original	Inglés
Páginas (desde-hasta)	402-405
Número de páginas	4
Publicación	Nuclear Instruments and Methods in Physics Research, Section A: Accelerators, Spectrometers, Detectors and Associated Equipment
DOI	https://doi.org/10.1016/j.nima.2015.09.079
Estado	Publicada - 11 jul. 2016
Publicado de forma externa	Sí

Áreas temáticas de ASJC Scopus

Física nuclear y de alta energía

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10.1016/j.nima.2015.09.079

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Artuso, M., Bachmair, F., Bäni, L., Bartosik, M., Beacham, J., Bellini, V., Belyaev, V., Bentele, B., Berdermann, E., Bergonzo, P., Bes, A., Brom, J. M., Bruzzi, M., Cerv, M., Chau, C., Chiodini, G., Chren, D., Cindro, V., Claus, G., ... Zavrtanik, M. (2016). A 3D diamond detector for particle tracking. Nuclear Instruments and Methods in Physics Research, Section A: Accelerators, Spectrometers, Detectors and Associated Equipment, 402-405. https://doi.org/10.1016/j.nima.2015.09.079

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title = "A 3D diamond detector for particle tracking",

abstract = "{\textcopyright} 2015 Elsevier B.V.All rights reserved. In the present study, results towards the development of a 3D diamond sensor are presented. Conductive channels are produced inside the sensor bulk using a femtosecond laser. This electrode geometry allows full charge collection even for low quality diamond sensors. Results from testbeam show that charge is collected by these electrodes. In order to understand the channel growth parameters, with the goal of producing low resistivity channels, the conductive channels produced with a different laser setup are evaluated by Raman spectroscopy.",

author = "M. Artuso and F. Bachmair and L. B{\"a}ni and M. Bartosik and J. Beacham and V. Bellini and V. Belyaev and B. Bentele and E. Berdermann and P. Bergonzo and A. Bes and Brom, {J. M.} and M. Bruzzi and M. Cerv and C. Chau and G. Chiodini and D. Chren and V. Cindro and G. Claus and J. Collot and S. Costa and J. Cumalat and A. Dabrowski and R. Dalessandro and {De Boer}, W. and B. Dehning and D. Dobos and M. D{\"u}nser and V. Eremin and R. Eusebi and G. Forcolin and J. Forneris and H. Frais-K{\"o}lbl and Gan, {K. K.} and M. Gastal and M. Goffe and J. Goldstein and A. Golubev and L. Gonella and A. Gori{\v s}ek and L. Graber and E. Grigoriev and J. Grosse-Knetter and B. Gui and M. Guthoff and I. Haughton and D. Hidas and D. Hits and M. Hoeferkamp and T. Hofmann and J. Hosslet and Hostachy, {J. Y.} and F. H{\"u}gging and H. Jansen and J. Janssen and H. Kagan and K. Kanxheri and G. Kasieczka and R. Kass and F. Kassel and M. Kis and G. Kramberger and S. Kuleshov and A. Lacoste and S. Lagomarsino and {Lo Giudice}, A. and C. Maazouzi and I. Mandic and C. Mathieu and N. McFadden and G. McGoldrick and M. Menichelli and M. Miku{\v z} and A. Morozzi and J. Moss and R. Mountain and S. Murphy and A. Oh and P. Olivero and G. Parrini and D. Passeri and M. Pauluzzi and H. Pernegger and R. Perrino and F. Picollo and M. Pomorski and R. Potenza and A. Quadt and A. Re and G. Riley and S. Roe and M. Sapinski and M. Scaringella and S. Schnetzer and T. Schreiner and S. Sciortino and A. Scorzoni and S. Seidel and L. Servoli and A. Sfyrla and G. Shimchuk and Smith, {D. S.} and B. Sopko and V. Sopko and S. Spagnolo and S. Spanier and K. Stenson and R. Stone and C. Sutera and A. Taylor and M. Traeger and D. Tromson and W. Trischuk and C. Tuve and L. Uplegger and J. Velthuis and N. Venturi and E. Vittone and S. Wagner and R. Wallny and Wang, {J. C.} and P. Weilhammer and J. Weingarten and C. Weiss and T. Wengler and N. Wermes and M. Yamouni and M. Zavrtanik",

year = "2016",

month = jul,

day = "11",

doi = "10.1016/j.nima.2015.09.079",

language = "English",

pages = "402--405",

journal = "Nuclear Instruments and Methods in Physics Research, Section A: Accelerators, Spectrometers, Detectors and Associated Equipment",

issn = "0168-9002",

publisher = "Elsevier",

}

Artuso, M, Bachmair, F, Bäni, L, Bartosik, M, Beacham, J, Bellini, V, Belyaev, V, Bentele, B, Berdermann, E, Bergonzo, P, Bes, A, Brom, JM, Bruzzi, M, Cerv, M, Chau, C, Chiodini, G, Chren, D, Cindro, V, Claus, G, Collot, J, Costa, S, Cumalat, J, Dabrowski, A, Dalessandro, R, De Boer, W, Dehning, B, Dobos, D, Dünser, M, Eremin, V, Eusebi, R, Forcolin, G, Forneris, J, Frais-Kölbl, H, Gan, KK, Gastal, M, Goffe, M, Goldstein, J, Golubev, A, Gonella, L, Gorišek, A, Graber, L, Grigoriev, E, Grosse-Knetter, J, Gui, B, Guthoff, M, Haughton, I, Hidas, D, Hits, D, Hoeferkamp, M, Hofmann, T, Hosslet, J, Hostachy, JY, Hügging, F, Jansen, H, Janssen, J, Kagan, H, Kanxheri, K, Kasieczka, G, Kass, R, Kassel, F, Kis, M, Kramberger, G, Kuleshov, S, Lacoste, A, Lagomarsino, S, Lo Giudice, A, Maazouzi, C, Mandic, I, Mathieu, C, McFadden, N, McGoldrick, G, Menichelli, M, Mikuž, M, Morozzi, A, Moss, J, Mountain, R, Murphy, S, Oh, A, Olivero, P, Parrini, G, Passeri, D, Pauluzzi, M, Pernegger, H, Perrino, R, Picollo, F, Pomorski, M, Potenza, R, Quadt, A, Re, A, Riley, G, Roe, S, Sapinski, M, Scaringella, M, Schnetzer, S, Schreiner, T, Sciortino, S, Scorzoni, A, Seidel, S, Servoli, L, Sfyrla, A, Shimchuk, G, Smith, DS, Sopko, B, Sopko, V, Spagnolo, S, Spanier, S, Stenson, K, Stone, R, Sutera, C, Taylor, A, Traeger, M, Tromson, D, Trischuk, W, Tuve, C, Uplegger, L, Velthuis, J, Venturi, N, Vittone, E, Wagner, S, Wallny, R, Wang, JC, Weilhammer, P, Weingarten, J, Weiss, C, Wengler, T, Wermes, N, Yamouni, M & Zavrtanik, M 2016, 'A 3D diamond detector for particle tracking', Nuclear Instruments and Methods in Physics Research, Section A: Accelerators, Spectrometers, Detectors and Associated Equipment, pp. 402-405. https://doi.org/10.1016/j.nima.2015.09.079

TY - JOUR

T1 - A 3D diamond detector for particle tracking

AU - Artuso, M.

AU - Bachmair, F.

AU - Bäni, L.

AU - Bartosik, M.

AU - Beacham, J.

AU - Bellini, V.

AU - Belyaev, V.

AU - Bentele, B.

AU - Berdermann, E.

AU - Bergonzo, P.

AU - Bes, A.

AU - Brom, J. M.

AU - Bruzzi, M.

AU - Cerv, M.

AU - Chau, C.

AU - Chiodini, G.

AU - Chren, D.

AU - Cindro, V.

AU - Claus, G.

AU - Collot, J.

AU - Costa, S.

AU - Cumalat, J.

AU - Dabrowski, A.

AU - Dalessandro, R.

AU - De Boer, W.

AU - Dehning, B.

AU - Dobos, D.

AU - Dünser, M.

AU - Eremin, V.

AU - Eusebi, R.

AU - Forcolin, G.

AU - Forneris, J.

AU - Frais-Kölbl, H.

AU - Gan, K. K.

AU - Gastal, M.

AU - Goffe, M.

AU - Goldstein, J.

AU - Golubev, A.

AU - Gonella, L.

AU - Gorišek, A.

AU - Graber, L.

AU - Grigoriev, E.

AU - Grosse-Knetter, J.

AU - Gui, B.

AU - Guthoff, M.

AU - Haughton, I.

AU - Hidas, D.

AU - Hits, D.

AU - Hoeferkamp, M.

AU - Hofmann, T.

AU - Hosslet, J.

AU - Hostachy, J. Y.

AU - Hügging, F.

AU - Jansen, H.

AU - Janssen, J.

AU - Kagan, H.

AU - Kanxheri, K.

AU - Kasieczka, G.

AU - Kass, R.

AU - Kassel, F.

AU - Kis, M.

AU - Kramberger, G.

AU - Kuleshov, S.

AU - Lacoste, A.

AU - Lagomarsino, S.

AU - Lo Giudice, A.

AU - Maazouzi, C.

AU - Mandic, I.

AU - Mathieu, C.

AU - McFadden, N.

AU - McGoldrick, G.

AU - Menichelli, M.

AU - Mikuž, M.

AU - Morozzi, A.

AU - Moss, J.

AU - Mountain, R.

AU - Murphy, S.

AU - Oh, A.

AU - Olivero, P.

AU - Parrini, G.

AU - Passeri, D.

AU - Pauluzzi, M.

AU - Pernegger, H.

AU - Perrino, R.

AU - Picollo, F.

AU - Pomorski, M.

AU - Potenza, R.

AU - Quadt, A.

AU - Re, A.

AU - Riley, G.

AU - Roe, S.

AU - Sapinski, M.

AU - Scaringella, M.

AU - Schnetzer, S.

AU - Schreiner, T.

AU - Sciortino, S.

AU - Scorzoni, A.

AU - Seidel, S.

AU - Servoli, L.

AU - Sfyrla, A.

AU - Shimchuk, G.

AU - Smith, D. S.

AU - Sopko, B.

AU - Sopko, V.

AU - Spagnolo, S.

AU - Spanier, S.

AU - Stenson, K.

AU - Stone, R.

AU - Sutera, C.

AU - Taylor, A.

AU - Traeger, M.

AU - Tromson, D.

AU - Trischuk, W.

AU - Tuve, C.

AU - Uplegger, L.

AU - Velthuis, J.

AU - Venturi, N.

AU - Vittone, E.

AU - Wagner, S.

AU - Wallny, R.

AU - Wang, J. C.

AU - Weilhammer, P.

AU - Weingarten, J.

AU - Weiss, C.

AU - Wengler, T.

AU - Wermes, N.

AU - Yamouni, M.

AU - Zavrtanik, M.

PY - 2016/7/11

Y1 - 2016/7/11

N2 - © 2015 Elsevier B.V.All rights reserved. In the present study, results towards the development of a 3D diamond sensor are presented. Conductive channels are produced inside the sensor bulk using a femtosecond laser. This electrode geometry allows full charge collection even for low quality diamond sensors. Results from testbeam show that charge is collected by these electrodes. In order to understand the channel growth parameters, with the goal of producing low resistivity channels, the conductive channels produced with a different laser setup are evaluated by Raman spectroscopy.

AB - © 2015 Elsevier B.V.All rights reserved. In the present study, results towards the development of a 3D diamond sensor are presented. Conductive channels are produced inside the sensor bulk using a femtosecond laser. This electrode geometry allows full charge collection even for low quality diamond sensors. Results from testbeam show that charge is collected by these electrodes. In order to understand the channel growth parameters, with the goal of producing low resistivity channels, the conductive channels produced with a different laser setup are evaluated by Raman spectroscopy.

UR - https://www.scopus.com/inward/record.uri?partnerID=HzOxMe3b&scp=84951909458&origin=inward

UR - https://www.scopus.com/inward/citedby.uri?partnerID=HzOxMe3b&scp=84951909458&origin=inward

U2 - 10.1016/j.nima.2015.09.079

DO - 10.1016/j.nima.2015.09.079

M3 - Article

SN - 0168-9002

SP - 402

EP - 405

JO - Nuclear Instruments and Methods in Physics Research, Section A: Accelerators, Spectrometers, Detectors and Associated Equipment

JF - Nuclear Instruments and Methods in Physics Research, Section A: Accelerators, Spectrometers, Detectors and Associated Equipment

ER -

A 3D diamond detector for particle tracking

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Áreas temáticas de ASJC Scopus

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Huella

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