Nome |
# |
Design and Test of Imaging and Particle Detection Microelectronic System for Frontier Research Applications, file e40f7b87-7a41-afca-e053-6605fe0aeaf2
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244
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P-Type Silicon Strip Sensors for the new CMS Tracker at HL-LHC, file e40f7b87-31a2-afca-e053-6605fe0aeaf2
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209
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Test beam demonstration of silicon microstrip modules with transverse momentum discrimination for the future CMS tracking detector, file e40f7b88-16dd-afca-e053-6605fe0aeaf2
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182
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Precision measurement of the structure of the CMS inner tracking system using nuclear interactions, file e40f7b88-2b52-afca-e053-6605fe0aeaf2
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177
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Beam test performance of prototype silicon detectors for the Outer Tracker for the Phase-2 Upgrade of CMS, file e40f7b89-8f6b-afca-e053-6605fe0aeaf2
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138
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Signal and Noise Performance of a 110-nm CMOS Technology for Photon Science Applications, file e40f7b8a-3982-afca-e053-6605fe0aeaf2
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128
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Experimental study of different silicon sensor options for the upgrade of the CMS Outer Tracker, file e40f7b89-8f66-afca-e053-6605fe0aeaf2
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118
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RD53 analog front-end processors for the ATLAS and CMS experiments at the high-luminosity LHC, file e40f7b89-7c07-afca-e053-6605fe0aeaf2
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112
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Precision measurement of the structure of the CMS inner tracking system using nuclear interactions, file e40f7b87-fb1e-afca-e053-6605fe0aeaf2
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95
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Characterisation of irradiated thin silicon sensors for the CMS phase II pixel upgrade, file e40f7b87-5213-afca-e053-6605fe0aeaf2
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92
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In Search of Cosmic-Ray Antinuclei from Dark Matter with the GAPS Experiment, file 867adabe-d492-4adb-a433-72546413c6ff
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85
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Front-end electronics for the GAPS tracker, file e40f7b89-4ceb-afca-e053-6605fe0aeaf2
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81
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RD53A: A large scale prototype for HL-LHC silicon pixel detector phase 2 upgrades, file e40f7b89-c715-afca-e053-6605fe0aeaf2
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76
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Ionizing Radiation Effects on the Noise of 65 nm CMOS Transistors for Pixel Sensor Readout at Extreme Total Dose Levels, file e40f7b8a-293e-afca-e053-6605fe0aeaf2
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76
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The MiniSDD-Based 1-Mpixel Camera of the DSSC Project for the European XFEL, file e40f7b8b-0248-afca-e053-6605fe0aeaf2
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67
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Comparative evaluation of analogue front-end designs for the CMS Inner Tracker at the High Luminosity LHC, file e40f7b8a-eda3-afca-e053-6605fe0aeaf2
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65
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The CMS Phase-1 pixel detector upgrade, file e40f7b8a-c5ce-afca-e053-6605fe0aeaf2
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64
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Selection of the silicon sensor thickness for the Phase-2 upgrade of the CMS Outer Tracker, file e40f7b8a-d85e-afca-e053-6605fe0aeaf2
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62
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Neural Networks approach to event reconstruction for the GAPS experiment, file a907c6a4-5952-4445-8e0e-7cdbb4ce9105
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36
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Cosmic Antiproton Sensitivity for the GAPS Experiment, file f1747cba-a69a-4996-a6f0-897852377604
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36
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Searching for cosmic antihelium nuclei with the GAPS experiment, file a470888a-440d-4e54-95cc-d9450edf9809
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35
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Reconstruction of antinucleus-annihilation events in the GAPS experiment, file b226042e-a8ad-4cfa-b6f9-d2332ab132bb
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33
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Strategies and performance of the CMS silicon tracker alignment during LHC Run 2, file 2c9be3b1-ac9d-4a67-a792-d9a2c4ef825d
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31
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Beam test performance of a prototype module with Short Strip ASICs for the CMS HL-LHC tracker upgrade, file 687628a9-fb9c-4bf6-9609-b656b14e8d54
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31
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The GAPS Instrument: A Large Area Time of Flight and High Resolution Exotic Atom Spectrometer for Cosmic Antinuclei, file d4554030-9496-4bd5-ad9b-3fd73f3dd1c7
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30
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Test beam performance of a CBC3-based mini-module for the Phase-2 CMS Outer Tracker before and after neutron irradiation, file 661713e6-4061-4cd9-a5d6-5dc6bdfc0990
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26
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Test results and prospects for RD53A, a large scale 65 nm CMOS chip for pixel readout at the HL-LHC, file e40f7b89-3972-afca-e053-6605fe0aeaf2
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9
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65-nm CMOS Front-End Channel for Pixel Readout in the HL-LHC Radiation Environment, file e40f7b87-4b64-afca-e053-6605fe0aeaf2
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8
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Design implementation and test results of the RD53A, a 65 nm large scale chip for next generation pixel detectors at the HL-LHC, file e40f7b89-318a-afca-e053-6605fe0aeaf2
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8
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Optimization of the 65-nm CMOS Linear Front-End Circuit for the CMS Pixel Readout at the HL-LHC, file e40f7b8a-ea66-afca-e053-6605fe0aeaf2
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8
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Characterization of bandgap reference circuits designed for high energy physics applications, file e40f7b85-c4ef-afca-e053-6605fe0aeaf2
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7
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Ionizing Radiation Effects on the Noise of 65 nm CMOS Transistors for Pixel Sensor Readout at Extreme Total Dose Levels, file e40f7b87-6aea-afca-e053-6605fe0aeaf2
|
7
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A Rad-Hard Bandgap Voltage Reference for High Energy Physics Experiments, file e40f7b89-9828-afca-e053-6605fe0aeaf2
|
6
|
28 nm CMOS analog front-end channels for future pixel detectors, file e998c4fc-8175-4d99-8b75-f6eb3ba7fcc1
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6
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Charge preamplifier in a 65 nm CMOS technology for pixel readout in the Grad TID regime, file e40f7b87-aeb9-afca-e053-6605fe0aeaf2
|
5
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In vitro exposure of endothelial cells to mechanical vibrations, file 88784cd7-e035-4f6d-b6ff-96d66521ef55
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4
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Effect of the in Vitro Exposure of Endothelial Cells to Mechanical Vibrations, file 89d7025f-ea31-4785-ab12-47210800a09c
|
4
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A mixed-signal processor for X-ray spectrometry and tracking in the GAPS experiment, file c95f7295-9767-4a3a-a4d5-bb002f6d7213
|
4
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CHIPIX65: Developments on a new generation pixel readout ASIC in CMOS 65 nm for HEP experiments, file e40f7b85-0d7e-afca-e053-6605fe0aeaf2
|
4
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Low-Noise Analog Channel for the Readout of the Si(Li) Detector of the GAPS Experiment, file e40f7b8b-0d95-afca-e053-6605fe0aeaf2
|
4
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The 32 Analog Channels Readout for the Long-Flight GAPS Balloon Experiment Tracking System, file be2dad97-8c3f-4054-8dfb-070ab4fe4d1f
|
3
|
Large-area Si(Li) detectors for X-ray spectrometry and particle tracking in the GAPS experiment, file e40f7b89-2b5a-afca-e053-6605fe0aeaf2
|
3
|
Threshold tuning DACs for pixel readout chips at the High Luminosity LHC, file e40f7b89-4246-afca-e053-6605fe0aeaf2
|
3
|
Large-area Si(Li) Detectors for X-ray Spectrometry and Particle Tracking for the GAPS Experiment, file e40f7b89-4b50-afca-e053-6605fe0aeaf2
|
3
|
Endothelial cells exposure to mechanical vibrations, file 9cb2ffc1-7f88-491d-bbbf-4fd2ef018369
|
2
|
Total ionizing dose effects on CMOS devices in a 110 nm technology, file e40f7b87-3825-afca-e053-6605fe0aeaf2
|
2
|
Signal and Noise Performance of a 110-nm CMOS Technology for Photon Science Applications, file e40f7b88-18dc-afca-e053-6605fe0aeaf2
|
2
|
Qualification and Integration Aspects of the DSSC Mega-Pixel X-Ray Imager, file e40f7b88-fb78-afca-e053-6605fe0aeaf2
|
2
|
Characterization of PFM3, a 32×32 readout chip for PixFEL X-ray imager, file e40f7b89-3ec6-afca-e053-6605fe0aeaf2
|
2
|
A zero dead-time front-end channel in 28 nm CMOS for future high energy physics detectors, file 6d4cdb53-5b4f-483e-893e-c979dab63ca4
|
1
|
Sensitivity of the GAPS experiment to low-energy cosmic-ray antiprotons, file 938a0783-4122-4231-b235-add80f0f1d5b
|
1
|
Design and Test of the CROCv1 Analog Front-End Processor for the CMS Pixel Readout at the HL-LHC, file c7a8075b-0326-4f4f-931e-1eb0ed4f244c
|
1
|
Evaluation of HPK n+-p planar pixel sensors for the CMS Phase-2 upgrade, file e20a0f17-4642-4069-97de-87bfdaabd8b0
|
1
|
Design and Test of Imaging and Particle Detection Microelectronic System for Frontier Research Applications, file e40f7b87-c91f-afca-e053-6605fe0aeaf2
|
1
|
Cosmic antihelium-3 nuclei sensitivity of the GAPS experiment, file e40f7b8b-04cd-afca-e053-6605fe0aeaf2
|
1
|
Totale |
2.441 |