Latest Results on Radiation Tolerance of Diamond Detectors

Oh, Alexander; Oh, A.; 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, Gabriele; Chren, D.; Cindro{, V.; Claus, G.; Collot, J.; Costa, S.; Cumalat, J.; Dabrowski, A.; D'Alessandro, R.; deBoer, W.; Dehning, B.; Dobos, D.; Dunser, M.; Eremin, V.; Eusebi, R.; Forcolin, G.; Forneris, J.; Frais-Kölbl, H.; Gastal, M.; Goffe, M.; Goldstein, J.; Golubev, A.; Gonella, L.; Gorišek, A.; Graber, L.; Grigoriev, E.; Grosse-Knetter, J.; Guthoff, M.; Haughton, I.; Hidas, D.; Hits, D.; Hoeferkamp, M.; Hofmann, T.; Hosslet, J.; Hostachy, J-Y.; 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.; LoGiudice, A.; Maazouzi, C.; Mandic, I.; Mathieu, C.; McFadden, N.; McGoldrick, G.; Menichelli, M.; Mikuž, M.; Morozzi, A.; Moss, J.; Mountain, R.; Murphy, S.; 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.; Sopko, B.; Sopko, V.; Spagnolo, S.; Spanier, S.; Stenson, K.; Stone, R.; Sutera, C.; Taylor, A. Russ; Traeger, M.; Tromson, D.; Trischuk, William; Tuve, C.; Uplegger, L.; Velthuis, J.; Venturi, N.; Vittone, E.; Wagner, S. J.; Wallny, R.; Weilhammer, P.; Weingarten, J.; Weiss, C.; Wengler, T.; Wermes, N.; Yamouni, M.; Zavrtanik, M.; Gan, K. K.; Smith, D. S.; Wang, J. C.

doi:10.22323/1.340.0597

Title: Latest Results on Radiation Tolerance of Diamond Detectors

Full Record
Other Related Research

Abstract

At present most experiments at the CERN Large Hadron Collider (LHC) are planning upgrades in the next 5-10 years for their innermost tracking layers as well as luminosity monitors to be able to take data as the luminosity increases and CERN moves toward the High Luminosity-LHC (HL-LHC). These upgrades will most likely require more radiation tolerant technologies than exist today. As a result this is one area of intense research, and Chemical Vapour Deposition (CVD) diamond is one such technology. CVD diamond has been used extensively in beam condition monitors as the innermost detectors in the highest radiation areas of all LHC experiments. This talk describes the preliminary radiation tolerance measurements of the highest quality polycrystalline CVD material for a range of proton energies and neutrons obtained with this material with the goal of elucidating the issues that should be addressed for future diamond based detectors. The talk presents the evolution of various semiconductor parameters as a function of dose.

Authors:

Oh, Alexander; Oh, A.; 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, Gabriele; Chren, D.; Cindro ^[1] more »

{, V.

Publication Date:: Fri Aug 02 00:00:00 EDT 2019

Research Org.:: Univ. of Colorado, Boulder, CO (United States)

Sponsoring Org.:: USDOE Office of Science (SC), High Energy Physics (HEP)

Contributing Org.:: The RD42 Collaboration

OSTI Identifier:: 1600509

Grant/Contract Number:: SC0010005

Resource Type:: Accepted Manuscript

Journal Name:: PoS - Proceedings of Science

Additional Journal Information:: Journal Volume: 340; Conference: 39. International Conference on High Energy Physics (ICHEP2018), Coex, Seoul (Korea, Republic of), 4-11 Jul 2018; Journal ID: ISSN 1824-8039

Publisher:: SISSA

Country of Publication:: United States

Language:: English

Subject:: 46 INSTRUMENTATION RELATED TO NUCLEAR SCIENCE AND TECHNOLOGY

Citation Formats


                    Oh, Alexander, Oh, A., 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, Gabriele, Chren, D., Cindro, Claus, G., Collot, J., Costa, S., Cumalat, J., Dabrowski, A., D'Alessandro, R., deBoer, W., Dehning, B., Dobos, D., Dunser, M., Eremin, V., Eusebi, R., Forcolin, G., Forneris, J., Frais-Kölbl, H., Gastal, M., Goffe, M., Goldstein, J., Golubev, A., Gonella, L., Gorišek, A., Graber, L., Grigoriev, E., Grosse-Knetter, J., Guthoff, M., Haughton, I., Hidas, D., Hits, D., Hoeferkamp, M., Hofmann, T., Hosslet, J., Hostachy, J-Y., 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., LoGiudice, A., Maazouzi, C., Mandic, I., Mathieu, C., McFadden, N., McGoldrick, G., Menichelli, M., Mikuž, M., Morozzi, A., Moss, J., Mountain, R., Murphy, S., 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., Sopko, B., Sopko, V., Spagnolo, S., Spanier, S., Stenson, K., Stone, R., Sutera, C., Taylor, A. Russ, Traeger, M., Tromson, D., Trischuk, William, Tuve, C., Uplegger, L., Velthuis, J., Venturi, N., Vittone, E., Wagner, S. J., Wallny, R., Weilhammer, P., Weingarten, J., Weiss, C., Wengler, T., Wermes, N., Yamouni, M., Zavrtanik, M., Gan, K. K., Smith, D. S., and Wang, J. C. Latest Results on Radiation Tolerance of Diamond Detectors.  United States: N. p., 2019. 
Web.  doi:10.22323/1.340.0597.

Copy to clipboard


                    Oh, Alexander, Oh, A., 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, Gabriele, Chren, D., Cindro, Claus, G., Collot, J., Costa, S., Cumalat, J., Dabrowski, A., D'Alessandro, R., deBoer, W., Dehning, B., Dobos, D., Dunser, M., Eremin, V., Eusebi, R., Forcolin, G., Forneris, J., Frais-Kölbl, H., Gastal, M., Goffe, M., Goldstein, J., Golubev, A., Gonella, L., Gorišek, A., Graber, L., Grigoriev, E., Grosse-Knetter, J., Guthoff, M., Haughton, I., Hidas, D., Hits, D., Hoeferkamp, M., Hofmann, T., Hosslet, J., Hostachy, J-Y., 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., LoGiudice, A., Maazouzi, C., Mandic, I., Mathieu, C., McFadden, N., McGoldrick, G., Menichelli, M., Mikuž, M., Morozzi, A., Moss, J., Mountain, R., Murphy, S., 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., Sopko, B., Sopko, V., Spagnolo, S., Spanier, S., Stenson, K., Stone, R., Sutera, C., Taylor, A. Russ, Traeger, M., Tromson, D., Trischuk, William, Tuve, C., Uplegger, L., Velthuis, J., Venturi, N., Vittone, E., Wagner, S. J., Wallny, R., Weilhammer, P., Weingarten, J., Weiss, C., Wengler, T., Wermes, N., Yamouni, M., Zavrtanik, M., Gan, K. K., Smith, D. S., & Wang, J. C. Latest Results on Radiation Tolerance of Diamond Detectors.  United States.  https://doi.org/10.22323/1.340.0597

Copy to clipboard


                    Oh, Alexander, Oh, A., 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, Gabriele, Chren, D., Cindro, Claus, G., Collot, J., Costa, S., Cumalat, J., Dabrowski, A., D'Alessandro, R., deBoer, W., Dehning, B., Dobos, D., Dunser, M., Eremin, V., Eusebi, R., Forcolin, G., Forneris, J., Frais-Kölbl, H., Gastal, M., Goffe, M., Goldstein, J., Golubev, A., Gonella, L., Gorišek, A., Graber, L., Grigoriev, E., Grosse-Knetter, J., Guthoff, M., Haughton, I., Hidas, D., Hits, D., Hoeferkamp, M., Hofmann, T., Hosslet, J., Hostachy, J-Y., 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., LoGiudice, A., Maazouzi, C., Mandic, I., Mathieu, C., McFadden, N., McGoldrick, G., Menichelli, M., Mikuž, M., Morozzi, A., Moss, J., Mountain, R., Murphy, S., 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., Sopko, B., Sopko, V., Spagnolo, S., Spanier, S., Stenson, K., Stone, R., Sutera, C., Taylor, A. Russ, Traeger, M., Tromson, D., Trischuk, William, Tuve, C., Uplegger, L., Velthuis, J., Venturi, N., Vittone, E., Wagner, S. J., Wallny, R., Weilhammer, P., Weingarten, J., Weiss, C., Wengler, T., Wermes, N., Yamouni, M., Zavrtanik, M., Gan, K. K., Smith, D. S., and Wang, J. C. Fri .  
"Latest Results on Radiation Tolerance of Diamond Detectors".  United States.  https://doi.org/10.22323/1.340.0597.  https://www.osti.gov/servlets/purl/1600509.

Copy to clipboard


                    
@article{osti_1600509,

  title        = {Latest Results on Radiation Tolerance of Diamond Detectors},

  author       = {Oh, Alexander and Oh, A. and Artuso, M. and Bachmair, F. and Bäni, L. and Bartosik, M. and Beacham, J. and Bellini^, V. and Belyaev, V. and Bentele, B. and Berdermann, E. and Bergonzo, P. and Bes, A. and Brom, J-M. and Bruzzi, M. and Cerv, M. and Chau, C. and Chiodini, Gabriele and Chren, D. and Cindro and Claus, G. and Collot, J. and Costa, S. and Cumalat, J. and Dabrowski, A. and D'Alessandro, R. and deBoer, W. and Dehning, B. and Dobos, D. and Dunser, M. and Eremin, V. and Eusebi, R. and Forcolin, G. and Forneris, J. and Frais-Kölbl, H. and Gastal, M. and Goffe, M. and Goldstein, J. and Golubev, A. and Gonella, L. and Gorišek, A. and Graber, L. and Grigoriev, E. and Grosse-Knetter, J. and Guthoff, M. and Haughton, I. and Hidas, D. and Hits, D. and Hoeferkamp, M. and Hofmann, T. and Hosslet, J. and Hostachy, J-Y. and Hügging, F. and Jansen, H. and Janssen, J. and Kagan, H. and Kanxheri, K. and Kasieczka, G. and Kass, R. and Kassel, F. and Kis, M. and Kramberger, G. and Kuleshov, S. and Lacoste, A. and Lagomarsino, S. and LoGiudice, A. and Maazouzi, C. and Mandic, I. and Mathieu, C. and McFadden, N. and McGoldrick, G. and Menichelli, M. and Mikuž, M. and Morozzi, A. and Moss, J. and Mountain, R. and Murphy, S. and Olivero, P. and Parrini, G. and Passeri, D. and Pauluzzi, M. and Pernegger, H. and Perrino, R. and Picollo, F. and Pomorski, M. and Potenza, R. and Quadt, A. and Re, A. and Riley, G. and Roe, S. and Sapinski, M. and Scaringella, M. and Schnetzer, S. and Schreiner, T. and Sciortino, S. and Scorzoni, A. and Seidel, S. and Servoli, L. and Sfyrla, A. and Shimchuk, G. and Sopko, B. and Sopko, V. and Spagnolo, S. and Spanier, S. and Stenson, K. and Stone, R. and Sutera, C. and Taylor, A. Russ and Traeger, M. and Tromson, D. and Trischuk, William and Tuve, C. and Uplegger, L. and Velthuis, J. and Venturi, N. and Vittone, E. and Wagner, S. J. and Wallny, R. and Weilhammer, P. and Weingarten, J. and Weiss, C. and Wengler, T. and Wermes, N. and Yamouni, M. and Zavrtanik, M. and Gan, K. K. and Smith, D. S. and Wang, J. C.},

  abstractNote = {At present most experiments at the CERN Large Hadron Collider (LHC) are planning upgrades in the next 5-10 years for their innermost tracking layers as well as luminosity monitors to be able to take data as the luminosity increases and CERN moves toward the High Luminosity-LHC (HL-LHC). These upgrades will most likely require more radiation tolerant technologies than exist today. As a result this is one area of intense research, and Chemical Vapour Deposition (CVD) diamond is one such technology. CVD diamond has been used extensively in beam condition monitors as the innermost detectors in the highest radiation areas of all LHC experiments. This talk describes the preliminary radiation tolerance measurements of the highest quality polycrystalline CVD material for a range of proton energies and neutrons obtained with this material with the goal of elucidating the issues that should be addressed for future diamond based detectors. The talk presents the evolution of various semiconductor parameters as a function of dose.},

  doi          = {10.22323/1.340.0597},

  journal      = {PoS - Proceedings of Science},

  number       = ,

  volume       = 340,

  place        = {United States},

  year         = {Fri Aug 02 00:00:00 EDT 2019},

  month        = {Fri Aug 02 00:00:00 EDT 2019}

}

Copy to clipboard

Journal Article:

Free Publicly Available Full Text

Accepted Manuscript (DOE)

Publisher's Version of Record

https://doi.org/10.22323/1.340.0597

Other availability

Search WorldCat to find libraries that may hold this journal

Save / Share:

Export Metadata

Save to My Library

Similar Records in DOE PAGES and OSTI.GOV collections:

Results on radiation tolerance of diamond detectors

Journal Article Venturi, N. ; Alexopoulos, A. ; Artuso, M. ; ... - Nuclear Instruments and Methods in Physics Research. Section A, Accelerators, Spectrometers, Detectors and Associated Equipment

In sight of the luminosity increase of the High Luminosity-LHC (HL-LHC), most experiments at the CERN Large Hadron Collider (LHC) are planning upgrades for their innermost layers in the next 5–10 years. These upgrades will require more radiation tolerant technologies than exist today. Usage of Chemical Vapor Deposition (CVD) diamond as detector material is one of the potentially interesting technologies for the upgrade. CVD diamond has been used extensively in the beam condition monitors of BaBar, Belle, CDF and all LHC experiments. Measurements of the radiation tolerance of the highest quality polycrystalline CVD material for a range of proton energies,more »« less
Cited by 8
https://doi.org/10.1016/j.nima.2018.08.038

Full Text Available
Diamond detectors

Conference Mikuz, M. ; et al. - PoS

With the first runs of the LHC in 2010 and luminosity upgrades expected from 2016, ATLAS and CMS are planning to upgrade their innermost tracking layers with the ultimate radiation hard technologies. Chemical Vapour Deposition (CVD) diamond has been used extensively in beam conditions monitors as the innermost detectors in the highest radiation areas of BaBar, Belle, CDF and all LHC experiments. This material is now being considered as a sensor material for the innermost layer(s) of the upgraded trackers. Recently the RD42 collaboration constructed, irradiated and tested polycrystalline and singlecrystal CVD diamond sensors to the highest fluences expected atmore »« less
https://doi.org/10.22323/1.113.0024

Full Text Available
Development of Single Crystal Chemical Vapor Deposition Diamonds for Detector Applications

Technical Report Kagan, Harris ; Kass, Richard ; Gan, K. K.

With the LHC upgrades in 2013, and further LHC upgrades scheduled in 2018, most LHC experiments are planning for detector upgrades which require more radiation hard technologies than presently available. At present all LHC experiments now have some form of diamond detector. As a result Chemical Vapor Deposition (CVD) diamond has now been used extensively in beam conditions monitors as the innermost detectors in the highest radiation areas of all LHC experiments. Moreover CVD diamond is now being discussed as an alternative sensor material for tracking very close to the interaction region of the HL-LHC where the most extreme radiationmore » conditions will exist.« less
https://doi.org/10.2172/1115741

Full Text Available
Diamond detector technology, status and perspectives

Journal Article Kagan, H. ; Alexopoulos, A. ; Artuso, M. ; ... - Nuclear Instruments and Methods in Physics Research. Section A, Accelerators, Spectrometers, Detectors and Associated Equipment

Detectors based on Chemical Vapor Deposition (CVD) diamond have been used extensively and successfully in beam conditions/beam loss monitors as the innermost detectors in the highest radiation areas of Large Hadron Collider (LHC) experiments. The startup of the LHC in 2015 brought a new milestone where the first polycrystalline CVD (pCVD) diamond pixel modules were installed in an LHC experiment and successfully began operation. The RD42 collaboration at CERN is leading the effort to develop polycrystalline CVD diamond as a material for tracking detectors operating in extreme radiation environments. The status of the RD42 project with emphasis on recent beammore » test results is presented.« less
Cited by 10
https://doi.org/10.1016/j.nima.2018.06.009

Full Text Available
Development of Single Crystal Chemical Vapor Deposition Diamonds for Detector Applications

Technical Report Kagan, Harris ; Gan, K K ; Kass, Richard

Diamond was studied as a possible radiation hard technology for use in future high radiation environments. With the commissioning of the LHC expected in 2009, and the LHC upgrades expected in 2013, all LHC experiments are planning for detector upgrades which require radiation hard technologies. Chemical Vapor Deposition (CVD) diamond has now been used extensively in beam conditions monitors as the innermost detectors in the highest radiation areas of BaBar, Belle and CDF and is installed in all LHC experiments. As a result, this material is now being discussed as an alternative sensor material for tracking very close to themore »« less
https://doi.org/10.2172/950473

Full Text Available

Similar Records