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AIDA-D7.1

AIDAAdvanced European Infrastructures for Detectors at Accelerators

Deliverable Report

Transnational Access to JSI, Slovenia

Cindro, V. (JSI) et al

29 January 2015

The research leading to these results has received funding from the European Commissionunder the FP7 Research Infrastructures project AIDA, grant agreement no. 262025.

This work is part of AIDA Work Package 7: Transnational access European irradiationfacilities.

The electronic version of this AIDA Publication is available via the AIDA web site<http://cern.ch/aida> or on the CERN Document Server at the following URL:

<http://cds.cern.ch/search?p=AIDA-D7.1>

AIDA-D7.1

http://cern.ch/aida

http://cds.cern.ch/search?p=AIDA-D7.1

Copyright © AIDA Consortium, 2015

Grant Agreement 262025 PUBLIC 1 / 15

Grant Agreement No: 262025

AIDA Advanced European Infrastructures for Detectors at Accelerators

Seventh Framework Programme, Capaci t ies Spec i f ic Programme, Research In f rast ructu res,

Combinat ion of Col laborat ive Pro ject and Coord inat ion and Support Act ion

DELIVERABLE REPORT

TRANSNATIONAL ACCESS TO JSI, SLOVENIA

DELIVERABLE: D7.1

Document identifier: AIDA-Del-D7.1

Due date of deliverable: End of Month 48 (January 2015)

Report release date: 29/01/2015

Work package: WP7: Transnational access to European irradiation

facilities

Lead beneficiary: JSI

Document status: Final

Abstract:

In the scope of TA to JSI reactor facility 630 access units were delivered to 75 projects during 4 years

of project duration. The majority share was used for upgrade plans of LHC experiments. Principal

investigators originated from 9 European states.


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Copyright notice:

Copyright © AIDA Consortium, 2015

For more information on AIDA, its partners and contributors please see www.cern.ch/AIDA

The Advanced European Infrastructures for Detectors at Accelerators (AIDA) is a project co-funded by the European

Commission under FP7 Research Infrastructures, grant agreement no 262025. AIDA began in February 2011 and will run

for 4 years.

The information herein only reflects the views of its authors and not those of the European Commission and no warranty

expressed or implied is made with regard to such information or its use.

Delivery Slip

Name Partner Date

Authored by V. Cindro, M. Mikuž JSI 19/01/2015

Edited by M. Mikuž JSI 23/01/2015

Reviewed by

V. Cindro [Task coordinator]

M. Mikuž [WP coordinator]

L. Serin [Scientific coordinator]

JSI

JSI

CNRS

26/01/2015

Approved by Steering Committee 29/01/2015

http://www.cern.ch/AIDA


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TABLE OF CONTENTS

1. DESCRIPTION OF INFRASTRUCTURE ............................................................................................................. 4

2. SUMMARY OF TA PROVIDED ............................................................................................................................. 5

3. HIGHLIGHTS OF TA RESULTS ........................................................................................................................... 5

ANNEX 1: LIST OF TA PROJECTS ............................................................................................................................... 8

ANNEX 2: LIST OF TA PUBLICATIONS ................................................................................................................... 12


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Executive summary

The deliverable report describes the transnational access to the reactor irradiation facility of the Jožef

Stefan Institute in Ljubljana, Slovenia. Within the AIDA project this was part of WP7, providing TA to

European Irradiation Facilities.

The infrastructure consists of a TRIGA-Mark-II reactor with hot-cell laboratories and various neutron

irradiation facilities. With channels leading to the reactor core it can provide fast neutron fluences up

to 1016 cm-2 within one hour. The unit of access is a reactor hour, including sample preparation, cool

off and handling.

A total of 630 access units were provided to 169 AIDA users servicing 75 projects. All irradiations

were carried out without user presence on-site; the samples were received, irradiated and

subsequently shipped to users by JSI staff. Therefore, with the consent of AIDA management, foreseen

user support resources were reallocated to irradiation manpower and an increase of access units from

540 to 600.

The projects were focused on irradiation needs of the LHC high-luminosity upgrade, although some

of the effort went also in the ILC detectors and generic irradiation hardness studies. Principal

investigators originated from 9 European countries. ATLAS and CMS experiments dominated the

communities served.

44 scientific publications, acknowledging the TA support of the JSI facility under the AIDA framework

are listed. The estimated impact is still higher, as many of the users neglected their obligation

stipulated in the application form to inform us about the related publications.

1. DESCRIPTION OF INFRASTRUCTURE

The infrastructure consists of a TRIGA-Mark-II reactor with hot-cell laboratories and various neutron

irradiation facilities. Reactor power is 250 kW, maximum total flux is 6x1012 cm-2s-1 (central channel).

Reactor is equipped with several in-core and ex-core irradiation channels. Typical flux in the in-core

channels is 1-6 x1012cm-2s-1, and in the ex-core channels < 1011cm-2s-1. Typical thermal-to-total flux

ratio is 1/8. Maximum uninterrupted irradiation time is 16h. Irradiation facilities (channels) are

described in detail in: http://www.rcp.ijs.si/ric/description-a.html

The reactor is equipped for irradiation of various samples. Irradiation and manipulation is safe and

simple. Hot-cell laboratory with manipulators for remote handling is available for highly radioactive

samples, connected to the reactor by two automatic pneumatic transfer lines. Reactor staff is licensed

for and experienced in performing the irradiations for scientific and other purposes.

The reactor is routinely used in the following research:

1. Neutronics and reactor physics

2. Activation analysis

3. Neutron dosimetry and spectrometry

4. Neutron radiography

5. Activation of materials, nuclear waste and decommissioning

6. Irradiation of materials for fusion reactors

7. Irradiation of detectors, test structures and electronics for HEP

http://www.rcp.ijs.si/ric/description-a.html


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Services currently offered by the infrastructure:

Irradiation of neutron activation samples (1500 per year); irradiation of other samples (50 per year),

neutron radiography, training of NPP operators and other reactor specialists (20 per year)

2. SUMMARY OF TA PROVIDED

User-projects

Users supported

Units of access

(JSI = 1 irradiation hour including

preparation and handling) Eligible

submissions Selected

Total delivered

(M1-M48) 77 75 169 630

Total foreseen in

the GA (M1-M48) 90 54 540

The two projects were rejected in the initial stage of the project for formal reasons. This prompted us

to require applicants to discuss their project with the facility leader before submitting. All subsequently

submitted projects were accepted by the USP.

With the consent of AIDA management, foreseen user support resources were reallocated to irradiation

manpower and an increase of access units from 540 to 600.

The delivered users supported refers to the

number of users on the application forms of the

projects executed, the foreseen , however, to the

users that would receive support for executing

the irradiations.

The distribution of access units per year exhibits

a rather flat distribution in the first 3 years. In

the fourth year the TA ran out of access units

and although an additional 30 units were

delivered beyond the initial commitment,

finally user projects had to be turned down or

executed on cost of the proponents.

3. HIGHLIGHTS OF TA RESULTS

The main focus of the users is the foreseen upgrade of the Large Hadron Collider at CERN to higher

luminosity (HL-LHC). The JSI TA facility was mainly used to irradiate sensors, electronics and

module prototypes to the extremely high doses expected at HL-LHC. Sensors include planar silicon,

3-D silicon, HV-CMOS and diamond. A limited proportion of projects dealt with irradiation of devices

for the B-factories and the linear collider.

The distribution of projects according to origin of the principal investigator shows a good coverage of

the European Research Area. 9 countries are represented, their shares roughly reflecting their leadership in the upgrade in tracking detectors for the LHC. The CH label encompasses CERN and is

therefore overrepresented.

210, 33%

200, 32%

171.5, 27%

48.5, 8%

Access units per year

2011

2012

2013

2014


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The distribution of projects according to communities shows a share in excess of 50 % of the two big

LHC experiments, followed by the generic studies within the CERN RD50 generic radiation hard

sensor development project (cern.ch/rd50/). Among the “Other” there are studies aimed at the ILC,

generic studies of electronics and components etc.

One of the highlights resulting from AIDA TA to JSI reactor was the choice and verification of sensor

technology for the module prototypes of ATLAS IBL, the pixel layer closest to the beam instated into

the existing pixel detector. The required benchmark fluence is 6x1015 neq/cm2. Several of the prototype

sensors and modules were irradiated in the scope of AIDA-JSI-2011-02. The results of module tests

were published in 2012 JINST 7 P11010.

In the figure above the 2D efficiency map for the CNM 81 module using normal incident tracks (mean

efficiency 97.5%) is shown. CNM81 (3-D), irradiated with neutrons to 5x1015 neq/cm2, is operated at

a bias voltage of 160 V. All dimensions are in microns.

The table shows the resulting tracking efficiency for CERN beam test samples. The magnetic field was

1.6 T with the field aligned as for the ATLAS solenoid. The efficiency measurement for the FBK 87

module was made at the DESY beam in April 2012, all other measurements were made at the CERN

test beams. Modules PPS L2&L4 (planar) and CNM 81 (3-D) were irradiated as part of AIDA-JSI-

2011-02.

These tests served as the basis for validation of the module technology. Subsequent production allowed

for a timely construction of IBL, which was inserted into ATLAS in 2014 and is awaiting operation in

Run2 of the LHC in spring 2015.

ATLAS, 26

CMS, 15

RD50, 8

ALICE, 4

LHCb, 3

Belle II, 2

Other, 17

Experiments

DE, 26

CH, 20UK, 8

IT, 8

ES, 6

CZ, 3

LT, 2

BE, 1

AT, 1PI Origin

http://rd50.web.cern.ch/rd50/


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ANNEX 1: LIST OF TA PROJECTS

Project Acronym Main objectives Institute(s) (#Users) Access units

granted

AIDA-JSI-2011-01 CMS HPK irradiation KIT, CERN (3) 15

AIDA-JSI-2011-02 Irradiation of Silicon Pixel modules for ATLAS-IBL project at CERN Georg-August Universitaet

Goettingen (1) 18

AIDA-JSI-2011-03 Irradiation for CERN-RD50 Collaboration University of Liverpool (1) 13

AIDA-JSI-2011-04 Neutron Irradiation of MAPS devices and test structures INFN, Sezione di Trieste (1) 4

AIDA-JSI-2011-05 SI GE Ics Irradiations IMB-CNM (1) 6

AIDA-JSI-2011-06 Irradiation of Si diodes to high fluences INFN, Sezione di Trieste (1) 12

AIDA-JSI-2011-07 Characterization of irradiated n-in-p pixel detectors MPI Muenchen (3) 8

AIDA-JSI-2011-08 Double sided sensors irradiation GSI Darmstadt, FIAS

Frankfurt(2) 5

AIDA-JSI-2011-09 ATLAS Upgrade Silicon Strip Detector Mixed Irradiations Uni Freiburg (2) 12

AIDA-JSI-2011-10 Polyamide Radiation Harness IMB-CNM (1) 5

AIDA-JSI-2011-12 Characterization of highly irradiated (thin) n-in-p pixel detectors MPI Muenchen (3) 8

AIDA-JSI-2011-13 Irradiation of ATLAS FE-I3 SC sensors TU Dortmund (2) 12

AIDA-JSI-2011-14 Characterization of n-in-p pixel detectors irradiated to 1e16 neq MPI Muenchen (3) 8

AIDA-JSI-2011-16 Neutron irradiation of optical fibres for HL-LHC Oxford University (2) 10

AIDA-JSI-2011-17 RD50 Edgeless silicon microstrip detectors INFN Bari (3) 4

AIDA-JSI-2011-18 CMS Silicon Material Evaluation R>5cm DESY (1) 20

AIDA-JSI-2011-19 CMS Short Strip Sensor Evaluation DESY (3) 8

AIDA-JSI-2011-20 CMS Test-structure Irradiations IHEP, Wien (3) 8


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AIDA-JSI-2011-21 CMS Routing Evaluation KIT (3) 4

AIDA-JSI-2011-22 LePIX CERN (1)

AIDA-JSI-2012-02 NEUTRON IRRADIATIONS OF DEPFETS FOR BELLE II MPI Muenchen (3) 8


AIDA-JSI-2012-03 Annealing of charge multiplication University of Liverpool (1) 25

AIDA-JSI-2012-04 N-in-p pixel detectors at the highest fluences MPI Muenchen (3) 8

AIDA-JSI-2012-05 CMS Lorentz Angle studies Université Libre de

Bruxelles, KIT (2) 20

AIDA-JSI-2012-06 Characterization of SLID n-in-p pixel detectors irradiated to 1e16 neq MPI Muenchen (3)

AIDA-JSI-2012-07 MAPS-TS INFN Trieste (1) 6

AIDA-JSI-2012-08 LHCb VELO Upgrade CERN (2) 8

AIDA-JSI-2012-09 NEUTRON IRRADIATIONS OF DEPFETS FOR BELLE II MPI Muenchen (2) 11

AIDA-JSI-2012-11 Neutron irradiations of the FE-I3 and FE-I4 pixel modules MPI Muenchen (2) 14

AIDA-JSI-2011-18 CMS Silicon Material Evaluation R>5cm TU Dortmund (2) 12


AIDA-JSI-2012-10 Irradiation of mini sensors ATLAS07 Charles University, Institute

of Physics (3) 5

AIDA-JSI-2012-12 Irradiation of ATLAS FE-I3 SC sensors TU Dortmund (2) 25

AIDA-JSI-2012-13 Sensor development for the upgrade of the CMS pixel detector PSI, IF Cantabria (2) 12

AIDA-JSI-2012-14 Development and optimization of silicon detectors with 3-D Electrodes University of Trento, FBK

Trento (5) 10

AIDA-JSI-2012-15 Radiation Hardness study of Planar detector with Active Edges University of Trento, FBK

Trento (5) 4

AIDA-JSI-2012-16 Characterization of n-in-p pixel detectors at HL-LHC fluences MPI Muenchen (4) 15

AIDA-JSI-2012-17 Irradiation of HV2FEI4 active sensors CERN (2) 8


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AIDA-JSI-2012-18 LHCb Scintillating Fiber Tracker EPL Lausanne, INR Moscow

(2) 9

AIDA-JSI-2012-19 Irradiation of silicon epi diodes for ultrafast silicon detector investigation University of Florence (3) 12

AIDA-JSI-2013-01 ALICE ITS Upgrade CERN (2) 7

AIDA-JSI-2013-02 Irradiation of mini-sensors ATLAS07 Charles University, Institute

of Physics (4) 4

AIDA-JSI-2013-03 Neutron Irradiation of MAPS devices and test structures INFN Trieste (1) 2

AIDA-JSI-2013-04 Radiation damage study of 3D sensors with SCP-based slim edge University of Trento, FBK

Trento (3) 5

AIDA-JSI-2013-05 CNM 3D Strip IFAE Barcelona, CNM

Barcelona (2) 25

AIDA-JSI-2013-06 CMS Silicon Material Evaluation R=5cm and beyond Hamburg University, KIT

(3) 23

AIDA-JSI-2013-07 3DATLAS and spinoffs University of Manchester,

University of Wollongong

(3)

10

AIDA-JSI-2013-08 ALICE ITS Upgrade CERN (2) 10

AIDA-JSI-2013-09 Characterization of SLID n-in-p pixel detectors irradiated to 1e16 neq MPI Muenchen (4) 3

AIDA-JSI-2013-10 LHCb Fiber Tracker Cooling CERN, ITEP (2) 2

AIDA-JSI-2013-11 Irradiation of Si and SiGe samples Vilnius University (3) 4

AIDA-JSI-2013-12 Radiation hard bandgap test CERN (2) 5

AIDA-JSI-2013-13 Technologies for radiation hard DCDC converter ASICs CERN (2) 6

AIDA-JSI-2013-14 CBM05-DSSD-IRRA GSI Darmstadt (2) 2

AIDA-JSI-2013-15 Radiation test of materials for CMS central beam pipe INFN Padova, CERN (2) 12

AIDA-JSI-2013-16 Atlas Tracker upgrade University of Liverpool (1) 5

AIDA-JSI-2013-17 Alice ITS upgrade CERN (2) 2


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AIDA-JSI-2013-18 Irradiation of 3D thin detectors CNM, IFAE Barcelona (2) 3

AIDA-JSI-2013-19 ATLAS HEC electronics MPI Muenchen (2)

AIDA-JSI-2013-20 Neutron irradiation of CVD diamonds ETH Zurich (1) 0.5

AIDA-JSI-2013-21 ATLAS upgrade RD Université de Genève,

CERN (2) 3

AIDA-JSI-2013-22 Radiation hard DC/DC converter CERN (2) 1.5

AIDA-JSI-2013-23 Irradiation of 3D thin detectors CNM, IFAE Barcelona (2) 35

AIDA-JSI-2013-24 ALICE ITS Upgrade CERN (2) 1.5

AIDA-JSI-2014-1 Atlas tracker Upgrade University of Liverpool (1) 13

AIDA-JSI-2014-2 Irradiation of BPW-3 diodes CERN (1) 3

AIDA-JSI-2014-3 Testing of radiation monitors Vilnius University (2) 3

AIDA-JSI-2014-4 CMS HPK irradiation campaign___ KIT, CERN (2) 3.5

AIDA-JSI-2014-5 A DCDC converter for the upgrade of LHC experiments CERN (2) 8

AIDA-JSI-2014-6 Characterization of thin active edge sensors MPI Muenchen (3) 1

AIDA-JSI-2014-7 Atlas diamond detector research CERN (2)

AIDA-JSI-2014-8 CMS silicon material evaluation Hamburg University, KIT

(3) 10.5

AIDA-JSI-2014-9 Irradiation of Depleted Monolithic Active Pixel Sensor (DMAPS) Physikalisches Institut,

Universitaet Bonn (1) 5

AIDA-JSI-2014-10 ALICE ITS Upgrade CERN (2) 1.5


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ANNEX 2: LIST OF TA PUBLICATIONS

Title Author(s) Journal publication /

Conference contribution

Characterization of bulk damage in CMOS MAPS Stefano Zucca et al. IEEE TRANSACTIONS ON

NUCLEAR SCIENCE, VOL.

59, NO. 4, AUGUST 2012

Performance of novel silicon n-in-p planar Pixel Sensors C. Gallrapp et al. NIM A679(2012)29–35

Characterization of Thin Pixel Sensor Modules

Interconnected with SLID Technology Irradiated to a Fluence

of 2x1015 neq/cm2 http://de.arxiv.org/abs/1109.3299v2

P. Weigell et al. JINST 6 C12049 (2011

Performance of n-in-p pixel detectors irradiated at fluences

up to 5x1015 neq/cm2 for the future ATLAS upgrades

http://de.arxiv.org/abs/1110.4468v2

A. Macchiolo et al.

Proceedings of the Conference

Technology and Instrumentation

in Particle Physics 2011

Prototype ATLAS IBL modules using the FE-I4A front-end

readout chip ATLAS IBL Collaboration (J. Albert et al.)

2012 JINST 7 P11010

Planar slim-edge pixel sensors for the ATLAS

upgrades

S. Altenheiner, C. Goessling, J. Jentzsch, R. Klingenberg,

T. Lapsien,

D. Muenstermann, A. Rummler, G. Troska and T. Wittig

2012 JINST 7 C02051

Degradation of charge sharing after neutron irradiation in

strip silicon detectors with different geometries

G. Casse, P. Dervan, D. Forshaw, A. Greenall, T. Huse, I.

Tsurin, M. Wormald,

NIM A Volume 730, 1

December 2013, Pages 54-57

Charge multiplication in irradiated segmented silicon

detectors with special strip processing

G. Casse D. Forshaw, T. Huse, I. Tsurin, M. Wormald,

M. Lozano, G. Pellegrini

NIM A, Volume 699, 21 January

2013, Pages 9-13

Radiation tolerance of a moderate resistivity substrate in a

modern CMOS process A. Potenza et Al. NIM A 718 (2013) 347-349


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Thin n-in-p pixel sensors and the SLID-ICV vertical

integration technology for the ATLAS upgrade at the HL-

LHC

A. Macchiolo, L. Andricek, M. Ellenburg, H.G. Moser, R.

Nisius, R.H. Richter, S. Terzo, P. Weigell

NIM A Volume 731, 11

December 2013, Pages 210-215

Novel silicon n-in-p pixel sensors for the future ATLAS

upgrades

A. La Rosa, C. Gallrapp, A. Macchiolo, R. Nisius, H.

Pernegger, R.H. Richter, P. Weigell

NIM A Volume 718, 1 August

2013, Pages 329-330

Planar silicon sensors for the CMS tracker upgrade Alexandra Junkes, NIM Volume 732, 21 December

2013, Pages 113-116

Signal and charge collection efficiency of n-in-p strip

detectors after mixed irradiation to HL-LHC fluences

Susanne Kuehn, Thomas Barber, Gianluigi Casse, Paul

Dervan, Adrian Driewer, Dean Forshaw, Torkjell Huse,

Karl Jakobs, Ulrich Parzefall

NIM Volume 730, 1 December

2013, Pages 58-61

Characterization of irradiated test structures for the CMS

tracker upgrade Bernhard Lutzer,


2013, Pages 204-209

A charge collection study with dedicated RD50 charge

multiplication sensors

C. Betancourt, T. Barber, M. Hauser, K. Jakobs, S.

Kuehn, U. Parzefall, S. Wonsak


2013, Pages 62-65

Planar pixel sensors for the ATLAS tracker upgrade at HL-

LHC C. Gallrapp

NIM Volume 718, 1 August

2013, Pages 323–324

Future silicon sensors for the CMS Tracker Upgrade

Maria Bernard-Schwarz

NIM Volume 699, 21 January

2013, Pages 89–92

Recent results of the ATLAS upgrade planar pixel sensors

R&D project Philipp Weigell

Volume 731, 11 December 2013,

Pages 177-182

Radiation resistance of double-type double-sided 3D pixel

sensors

M. Fernandez, R. Jaramillo, M. Lozano, F.J. Munoz, G.

Pellegrini, D. Quirion, T. Rohe, I. Vila


Pages 137-140

Recent results of the ATLAS upgrade Planar Pixel Sensors

R&D project Dean Forshaw


Pages 44-49

Irradiation and beam tests qualification for ATLAS IBL Pixel

Modules Igor. Rubinskiy

Volume 699, 21 January 2013,

Pages 67-71

Overview of the ATLAS insertable B-layer (IBL) project S. Grinstein Volume 699, 21 January 2013,

Pages 61–66

http://www.sciencedirect.com/science/article/pii/S016890021300990X

http://www.sciencedirect.com/science/article/pii/S016890021300990X

http://www.sciencedirect.com/science/article/pii/S0168900212011667

http://www.sciencedirect.com/science/article/pii/S0168900212003804

http://www.sciencedirect.com/science/journal/01689002/699/supp/C



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3D active edge silicon sensors: Device processing, yield and

QA for the ATLAS-IBL production Cinzia Da Vià et al.

Volume 699, 21 January 2013,

Pages 18–21

Modelling Charge Loss in CMOS MAPS Exposed to Non-

Ionizing Radiation L. Ratti et al.

Nuclear Science, IEEE

Transactions on

Volume: 60 , Issue: 4 , Part: 1

Towards radiation hard sensor materials for the CMS tracker

upgrade Georg Steinbrueck

2012 IEEE Nuclear

Science Symposium and

Medical imaging Conference

Record (NSS/MIC)

Characterization of New FBK Double-Sided 3D

Sensors with Improved Breakdown Voltage Gian-Franco Dalla Betta,

Nuclear Science Symposium and

Medical Imaging Conference

(NSS/MIC), 2013 IEEE

The Timepix Telescope for high performance particle

tracking K. Akiba NIM A723(2013)47–54

Characterization of irradiated test structures for the CMS

tracker upgrade Bernhard Lutzer NIM A 730 (2013 )204–209

Review of radiation damage studies on DNW CMOS MAPS G. Traversi et al. NIM A730 (2013) 155–158

Pitch dependence of the tolerance of CMOS monolithic

active pixel

sensors to non-ionizing radiation

D. Doering et al. NIM A A730 (2013 )111–114

Monolithic pixels on moderate resistivity substrate and

sparsifying

readout architecture

P.Giubilato et al. NIM A 731 (2013) 146–153

Analysis of edge and surface TCTs for irradiated 3D

silicon strip detectors

G. Stewart, R. Bates, C. Fleta, G. Kramberger, M.

Lozano, M. Milovanovic

and G. Pellegrini

2013 JINST 8 P03002

A study of the effect of radiation on the mechanical

strength of optical fibres

B. Arvidsson, V. Cindro, B.T. Huffman, C. Issever, P.K.

Teng, A.R. Weidberg,

and J.A. Wilson

2013 JINST 8 P05011




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Radiation hardness evaluation of a 130 nm SiGe

BiCMOS technology for high energy physics

applications

S. Diez, T. Clark, A.A. Grillo, W. Kononenk, F.

Martinez-McKinney, F.M. Newcomer, M. Norgren, S.

Rescia, E. Spencer, H. Spieler, M. Ullan and M. Wilder

2013 JINST 8 P10009

High-voltage pixel sensors for ATLAS upgrade I. Perić et al. NIM A765 (2014) 172–176

Temperature-dependent characterizations of irradiated planar

nþ-in-n pixel assemblies R. Klingenberg et al. NIM A765 (2014) 135–139

Development of n-in-p large-area silicon microstrip sensors

for very high radiation environments ATLAS12 design and

initial results

Y. Unno et al. NIM A Volume 765, 21

November 2014, Pages 80-90

Update on scribe–cleave–passivate (SCP) slim edge

technology

for silicon sensors: Automated procesing and radiation

resistance

V Fadeyev et al. Nuclear Instruments and

Methods in Physics Research A

765 (2014) 59-63

Production and characterisation of SLID interconnected n-in-

p pixel

modules with 75 μm thin silicon sensors

L. Andricek et al. NIM A Volume 758, 11

September 2014, Pages 30-43

Evaluation of KEK n-in-p planar pixel sensor structures for

very high

radiation environments with testbeam

K. Motohashi et al. NIM A765(2014) 125-129

Development of active edge pixel sensors and four-side

buttable

modules using vertical integration technologies

A. Macchiolo et al. NIM AVolume 765, 21

November 2014, Pages 53-58

Radiation hard sensor materials for the CMS Tracker Phase II

Upgrade - Charge collection of different bulk polarities Martin Printz

Nuclear Instruments and

Methods in Physics Research A

765 (2014) 29

Technology developments and first measurements of Low

Gain Avalanche Detectors (LGAD) for high energy physics

applications

G. Pellegrini et al. NIM A,Volume 765, 21

November 2014, Pages 12–16

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