Zobrazeno 1 - 10
of 547
pro vyhledávání: '"da Costa, João P."'
Autor:
Li, Shuqi, Wu, Tianya, Huang, Xinhui, Zhou, Jia, Yan, Ziyue, Wang, Wei, Zeng, Hao, Hu, Yiming, Zhang, Xiaoxu, Liang, Zhijun, Wei, Wei, Zhang, Ying, Wei, Xiaomin, Zhang, Lei, Qi, Ming, Hu, Jun, Fu, Jinyu, Zhang, Hongyu, Li, Gang, Wu, Linghui, Dong, Mingyi, Li, Xiaoting, Casanova, Raimon, Zhang, Liang, Dong, Jianing, Wang, Jia, Zheng, Ran, Lu, Weiguo, Grinstein, Sebastian, da Costa, João Guimarães
The Circular Electron Positron Collider (CEPC) has been proposed to enable more thorough and precise measurements of the properties of Higgs, W, and Z bosons, as well as to search for new physics. In response to the stringent performance requirements
Externí odkaz:
http://arxiv.org/abs/2404.03688
Autor:
Wu, Tianya, Li, Shuqi, Wang, Wei, Zhou, Jia, Yan, Ziyue, Hu, Yiming, Zhang, Xiaoxu, Liang, Zhijun, Wei, Wei, Zhang, Ying, Wei, Xiaomin, Huang, Xinhui, Zhang, Lei, Qi, Ming, Zeng, Hao, Jia, Xuewei, Hu, Jun, Fu, Jinyu, Zhang, Hongyu, Li, Gang, Wu, Linghui, Dong, Mingyi, Li, Xiaoting, Casanova, Raimon, Zhang, Liang, Dong, Jianing, Wang, Jia, Zheng, Ran, Lu, Weiguo, Grinstein, Sebastian, da Costa, João Guimarães
The proposed Circular Electron Positron Collider (CEPC) imposes new challenges for the vertex detector in terms of pixel size and material budget. A Monolithic Active Pixel Sensor (MAPS) prototype called TaichuPix, based on a column drain readout arc
Externí odkaz:
http://arxiv.org/abs/2311.05932
Autor:
Sun, Weiyi, Li, Mengzhao, Liang, Zhijun, Zhao, Mei, Zhang, Xiaoxu, Zhang, Tianyuan, Feng, Yuan, Li, Shuqi, Huang, Xinhui, Fan, Yunyun, Wu, Tianya, Yang, Xuan, Liu, Bo, Heng, Wei Wang. Yuekun, Xu, Gaobo, da Costa, João Guimaraes
The AC-coupled Strip LGAD (Strip AC-LGAD) is a novel LGAD design that diminishes the density of readout electronics through the use of strip electrodes, enabling the simultaneous measurement of time and spatial information. The Institute of High Ener
Externí odkaz:
http://arxiv.org/abs/2307.03894
Autor:
Sun, Weiyi, Fan, Yunyun, Zhao, Mei, Cui, Han, Yu, Chengjun, Li, Shuqi, Feng, Yuan, Huang, Xinhui, Liang, Zhijun, Jia, Xuewei, Wang, Wei, Wu, Tianya, Li, Mengzhao, da Costa, João Guimarães, Xu, Gaobo
Low Gain Avalanche Detectors (LGAD) for the High-Granularity Timing Detector (HGTD) are crucial in reducing pileups in the High-Luminosity Large Hadron Collider. Numerous studies have been conducted on the bulk irradiation damage of LGADs. However, f
Externí odkaz:
http://arxiv.org/abs/2303.05839
Autor:
Wu, Kewei, Jia, Xuewei, Yang, Tao, Li, Mengzhao, Wang, Wei, Zhao, Mei, Liang, Zhijun, da Costa, Joao Guimaraes, Fan, Yunyun, Cui, Han, Howard, Alissa, Kramberger, Gregor, Shi, Xin, Heng, Yuekun, Tan, Yuhang, Liu, Bo, Feng, Yuan, Li, Shuqi, Li, Mengran, Yu, Chengjun, Yang, Xuan, Zhai, Mingjie, Xu, Gaobo, Yan, Gangping, Zhai, Qionghua, Ding, Mingzheng, Luo, Jun, Yin, Huaxiang, Li, Junfeng
The low gain avalanche detectors (LGADs) are thin sensors with fast charge collection which in combination with internal gain deliver an outstanding time resolution of about 30 ps. High collision rates and consequent large particle rates crossing the
Externí odkaz:
http://arxiv.org/abs/2205.05025
Autor:
Zhao, Mei, Jia, Xuewei, Wu, Kewei, Yang, Tao, Li, Mengzhao, Fan, Yunyun, Yan, Gangping, Wang, Wei, Li, Mengran, Xu, Gaobo, Ding, Mingzheng, Yin, Huaxiang, Luo, Jun, Li, Junfeng, Shi, Xin, Liang, Zhijun, da Costa, João Guimarães
This paper shows the simulation and test results of 50um thick Low Gain Avalanche Detectors (LGAD) sensors designed by the Institute of High Energy Physics (IHEP) and fabricated by the Institute of Microelectronics of the Chinese Academy of Sciences
Externí odkaz:
http://arxiv.org/abs/2109.11209
Autor:
Li, Mengzhao, Fan, Yunyun, Liu, Bo, Cui, Han, Jia, Xuewei, Li, Shuqi, Yu, Chengjun, Yang, Xuan, Wang, Wei, Zhai, Mingjie, Yang, Tao, Wu, Kewei, Tan, Yuhang, Xiao, Suyu, Zhao, Mei, Shi, Xin, Liang, Zhijun, Heng, Yuekun, da Costa, Joao Guimaraes, Zhang, Xingan, Han, Dejun, Howard, Alissa, Kramberger, Gregor
The performances of Low Gain Avalanche diode (LGAD) sensors from a neutron irradiation campaign with fluences of 0.8 x 10^15, 15 x 10^15 and 2.5 x 10^15 neq/cm2 are reported in this article. These LGAD sensors are developed by the Institute of High E
Externí odkaz:
http://arxiv.org/abs/2107.03563
Autor:
Yang, Tao, Wu, Kewei, Zhao, Mei, Jia, Xuewei, Tan, Yuhang, Xiao, Suyu, Liu, Kai, Zhang, Xiyuan, Wang, Congcong, Li, Mengzhao, Fan, Yunyun, Li, Shuqi, Yu, Chengjun, Cui, Han, Zeng, Hao, Zhai, Mingjie, Xin, Shuiting, Jing, Maoqiang, Yan, Gangping, Zhai, Qionghua, Ding, Mingzheng, Xu, Gaobo, Yin, Huaxiang, Kramberger, Gregor, Liang, Zhijun, da Costa, João Guimarães, Shi, Xin
We report precise TCAD simulations of IHEP-IME-v1 Low Gain Avalanche Diode (LGAD) calibrated by secondary ion mass spectroscopy (SIMS). Our setup allows us to evaluate the leakage current, capacitance, and breakdown voltage of LGAD, which agree with
Externí odkaz:
http://arxiv.org/abs/2106.15421
Publikováno v:
In Trends in Analytical Chemistry March 2024 172
Autor:
Poley, Luise, Sawyer, Craig, Addepalli, Sagar, Affolder, Anthony, Allongue, Bruno, Allport, Phil, Anderssen, Eric, Anghinolfi, Francis, Arguin, Jean-François, Arling, Jan-Hendrik, Arnaez, Olivier, Asbah, Nedaa Alexandra, Ashby, Joe, Asimakopoulou, Eleni Myrto, Atlay, Naim Bora, Bartsch, Ludwig, Basso, Matthew J., Beacham, James, Beaupré, Scott L., Beck, Graham, Beichert, Carl, Bergsten, Laura, Bernabeu, Jose, Bhattarai, Prajita, Bloch, Ingo, Blue, Andrew, Bochenek, Michal, Botte, James, Boynton, Liam, Brenner, Richard, Brueers, Ben, Buchanan, Emma, Bullard, Brendon, Capocasa, Francesca, Carr, Isabel, Carra, Sonia, Chao, Chen Wen, Chen, Jiayi, Chen, Liejian, Chen, Yebo, Chen, Xin, Cindro, Vladimir, Ciocio, Alessandra, Civera, Jose V., Cormier, Kyle, Cornell, Ella, Crick, Ben, Dabrowski, Wladyslaw, Dam, Mogens, David, Claire, Demontigny, Gabriel, Dette, Karola, DeWitt, Joel, Diez, Sergio, Doherty, Fred, Dopke, Jens, Dressnandt, Nandor, Edwards, Sam, Fadeyev, Vitaliy, Farrington, Sinead, Fawcett, William, Fernandez-Tejero, Javier, Filmer, Emily, Fleta, Celeste, Gallop, Bruce, Galloway, Zachary, Argos, Carlos Garcia, Garg, Diksha, Gignac, Matthew, Gillberg, Dag, Giovinazzo, Dena, Glover, James, Goettlicher, Peter, Gonella, Laura, Gorišek, Andrej, Grant, Charles, Grant, Fiona, Gray, Calum, Greenall, Ashley, Gregor, Ingrid-Maria, Greig, Graham, Grillo, Alexander A., Gu, Shan, Guescini, Francesco, da Costa, Joao Barreiro Guimaraes, Gunnell, Jane, Gupta, Ruchi, Haber, Carl, Halgeri, Amogh, Hamersly, Derek, Haugen, Tom-Erik, Hauser, Marc, Heim, Sarah, Heim, Timon, Helling, Cole, Herde, Hannah, Hessey, Nigel P., Hommels, Bart, Hönig, Jan Cedric, Hunter, Amelia, Jackson, Paul, Jewkes, Keith, John, Jaya John, Johnson, Thomas Allan, Jones, Tim, Kachiguin, Serguei, Kang, Nathan, Kaplon, Jan, Kareem, Mohammad, Keener, Paul, Keller, John, Key-Charriere, Michelle, Kilani, Samer, Kisliuk, Dylan, Klein, Christoph Thomas, Koffas, Thomas, Kramberger, Gregor, Krizka, Karol, Kroll, Jiri, Kuehn, Susanne, Kurth, Matthew, Labitan, Charilou, Lacasta, Carlos, Lacker, Heiko, Leitao, Pedro Vicente, León, Pablo, Li, Boyang, Li, Chenyang, Li, Yiming, Li, Zhiying, Liang, Zhijun, Liberatore, Marianna, Lister, Alison, Liu, Kai, Liu, Peilian, Lohse, Thomas, Lönker, Jonas, Lou, Xinchou, Lu, Weiguo, Luce, Zachary, Lynn, David, MacFadyen, Ross, Mägdefessel, Sven, Mahboubi, Kambiz, Malik, Usha, Mandić, Igor, La Marra, Daniel, Martin, Jean-Pierre, Martinez-Mckinney, Forest, Mikestikova, Marcela, Mikuž, Marko, Mitra, Ankush, Mladina, Evan, Montalbano, Alyssa, Monzat, David, Morii, Masahiro, Mullier, Geoffrey, Neundorf, Jonas, Newcomer, Mitch, Ng, Yanwing, Nikolica, Adrian, Nikolopoulos, Konstantinos, Oechsle, Jan, Oliver, Jason, Orr, Robert S., Ottino, Gregory, Paillard, Christian, Pani, Priscilla, Paowell, Sam, Parzefall, Ulrich, Phillips, Peter W., Platero, Adrián, Platero, Vicente, Prahl, Volker, Pyatt, Simon, Ran, Kunlin, Reardon, Nikita, Rehnisch, Laura, Renardi, Alessia, Renzmann, Martin, Rifki, Othmane, Rodriguez, Arturo Rodriguez, Rosin, Guy, Rossi, Edoardo, Ruggeri, Tristan, Rühr, Frederik, Rymaszewski, Piotr, Sadrozinski, Hartmut F. -W., Sanethavong, Phathakone, Santpur, Sai Neha, Scharf, Christian, Schillaci, Zach, Schmitt, Stefan, Sharma, Abhishek, Sciolla, Gabriella, Seiden, Abraham, Shi, Xin, Simpson-Allsop, Cameron, Snoek, Hella, Snow, Steve, Solaz, Carles, Soldevila, Urmila, Sousa, Filipe, Sperlich, Dennis, Staats, Ezekiel, Stack, Tynan Louis, Stanitzki, Marcel, Starinsky, Nikolai, Steentoft, Jonas, Stegler, Martin, Stelzer, Bernd, Stucci, Stefania, Swientek, Krzysztof, Taylor, Geoffrey N., Taylor, Wendy, Teoh, Jia Jian, Teuscher, Richard, Thomas, Jürgen, Tigchelaar, Allen, Tran, Tony, Tricoli, Alessandro, Trischuk, Dominique Anderson, Unno, Yoshinobu, van Nieuwenhuizen, Gerrit, Ullán, Miguel, Vermeulen, Jos, Vickey, Trevor, Vidal, Guillem, Vreeswijk, Marcel, Warren, Matt, Weidberg, Tony, Wiehe, Moritz, Wiglesworth, Craig, Wiik-Fuchs, Liv, Williams, Scott, Wilson, John, Witharm, Rhonda, Wizemann, Felix, Wonsak, Sven, Worm, Steve, Wormald, Mike, Xella, Stefania, Yang, Yuzhen, Yarwick, Joseph, Yu, Tang-Fai, Zhang, Dengfeng, Zhang, Kaili, Zhou, Maosen, Zhu, Hongbo
Publikováno v:
published 3 September 2020, Journal of Instrumentation, Volume 15, September 2020
For the Phase-II Upgrade of the ATLAS Detector, its Inner Detector, consisting of silicon pixel, silicon strip and transition radiation sub-detectors, will be replaced with an all new 100 % silicon tracker, composed of a pixel tracker at inner radii
Externí odkaz:
http://arxiv.org/abs/2009.03197