연구성과로 돌아가기

2020 연구성과 (161 / 270)

※ 컨트롤 + 클릭으로 열별 다중 정렬 가능합니다.
Excel 다운로드
WoS SCOPUS Document Type Document Title Abstract Authors Affiliation ResearcherID (WoS) AuthorsID (SCOPUS) Author Email(s) Journal Name JCR Abbreviation ISSN eISSN Volume Issue WoS Edition WoS Category JCR Year IF JCR (%) FWCI FWCI Update Date WoS Citation SCOPUS Citation Keywords (WoS) KeywordsPlus (WoS) Keywords (SCOPUS) KeywordsPlus (SCOPUS) Language Publication Stage Publication Year Publication Date DOI JCR Link DOI Link WOS Link SCOPUS Link
Article; Proceedings Paper Fabrication and testing of a 1024-pixel SiPM camera We have fabricated a 1024-pixel SiPM sensor and the associated electronics. We integrated the SiPM sensor and the electronics to build a SiPM camera. In this paper, we present the fabrication and assembly procedure of the SiPM sensor and the readout electronics, and the preliminary result of testing the camera. This camera can be readily used as an X-ray detector with an array of the scintillator pixels placed in front of the SiPM sensor. The application of such an X-ray detector includes the X-ray or gamma-ray imaging in the medical field and the detection of astronomical or astrophysical X-ray sources in space. This camera also can be used as a detector that counts photons in low light environment. Jeon, J. A.; Lee, H. Y.; Lee, J. Inst for Basic Sci Korea, Ctr Underground Phys, Daejon 34126, South Korea; Kyungpook Natl Univ, Ctr High Energy Phys, Daegu 41566, South Korea 24478376500; 57199646872; 36835827400 jiklee999@gmail.com; NUCLEAR INSTRUMENTS & METHODS IN PHYSICS RESEARCH SECTION A-ACCELERATORS SPECTROMETERS DETECTORS AND ASSOCIATED EQUIPMENT NUCL INSTRUM METH A 0168-9002 1872-9576 958 SCIE INSTRUMENTS & INSTRUMENTATION;NUCLEAR SCIENCE & TECHNOLOGY;PHYSICS, NUCLEAR;PHYSICS, PARTICLES & FIELDS 2020 1.455 48.5 0.17 2025-06-25 2 2 Silicon photomultiplier; Photon counting; Pinhole camera Photon counting; Pinhole camera; Silicon photomultiplier Fabrication; Gamma rays; Medical imaging; Photons; Pinhole cameras; Silicon; X ray apparatus; X rays; Associated electronics; Gamma-ray imaging; Medical fields; Photon counting; Readout Electronics; Scintillator pixels; Silicon photomultiplier; X-ray sources; X ray detectors English 2020 2020-04-01 10.1016/j.nima.2019.162839 바로가기 바로가기 바로가기 바로가기
Article; Proceedings Paper First test-beam results obtained with IDEA, a detector concept designed for future lepton colliders IDEA (Innovative Detector for Electron-positron Accelerators) is a detector concept designed for a future leptonic collider operating as a Higgs factory. It is based on innovative detector technologies developed over years of R&D. In September 2018, prototypes of the proposed sub-detectors have been tested for the first time on a beam line at CERN. The preliminary results from this test of a full slice of the IDEA detector and standalone measurements of dual read-out calorimeter prototypes are presented. Aly, R.; Antonello, M.; Azzi, P.; Bedeschi, F.; Bencivenni, G.; Borgonovi, L.; Caccia, M. L. M.; Chu, X.; Cibinetto, G.; Coates, T.; Cussans, D.; De Filippis, N.; De Santo, A.; Dunser, M.; Ete, R.; Farinelli, R.; Ferrari, R.; Fontanesi, E.; Franchino, S.; Gaudio, G.; Giacomelli, P.; Grancagnolo, F.; Gribanov, S.; Hauptman, J. M.; Janot, P.; Jones, S. D.; Lee, K.; Lee, S.; Lerner, G.; Morello, G.; Nam, K.; Pezzotti, L.; Pingault, A.; Lener, M. Poli; Popov, A. A.; Salvatore, F.; Santoro, R.; Taliercio, A.; Tassielli, G. F.; Testa, B.; Vivarelli, I.; Wigmans, R. Politecn Bari, Bari, Italy; INFN, Bari, Italy; Univ Insubria, Como, Italy; INFN, Milan, Italy; INFN, Padua, Italy; Univ Pisa, Pisa, Italy; INFN, Pisa, Italy; Lab Nazl Frascati INFN, Frascati, Italy; Univ Bologna, Alma Mater Studiorum, Bologna, Italy; INFN, Bologna, Italy; Chinese Acad Sci, Beijing, Peoples R China; INFN, Ferrara, Italy; Sussex Univ, Brighton, E Sussex, England; Univ Bristol, Bristol, Avon, England; CERN, Meyrin, Switzerland; DESY, Hamburg, Germany; Univ Ferrara, Ferrara, Italy; INFN, Pavia, Italy; Heidelberg Univ, Kirchhoff Inst Phys, Heidelberg, Germany; Univ Salento, Lecce, Italy; INFN, Lecce, Italy; Budker Inst Nucl Phys, Novosibirsk, Russia; Iowa State Univ, Ames, IA USA; Seoul Natl Univ, Seoul, South Korea; Kyungpook Natl Univ, Daegu, South Korea; Univ Pavia, Pavia, Italy; Univ Ghent, Ghent, Belgium; Texas Tech Univ, Lubbock, TX 79409 USA Gribanov, Sergei/ABH-9238-2020; Caccia, Massimo/C-5407-2012; Antonello, Massimiliano/KIB-8239-2024; Pezzotti, Lorenzo/GRO-2971-2022; Farineli, Riccardo/GVS-7124-2022; Bedeschi, Franco/AAA-6068-2021; Fazio, Salvatore/G-5156-2010; Tassielli, Giovanni/K-2929-2015; gaudio, gabriella/AAN-6039-2021; Azzi, Patrizia/H-5404-2012; My, Salvatore/HTM-1335-2023; morello, giovanni/C-7547-2012; Tassielli, Giovanni Francesco/K-2929-2015; De Filippis, Nicola/AAD-6280-2019 56681884400; 57201049419; 57376972400; 35226934500; 7005398566; 57194828479; 55654886100; 59859092800; 35227032700; 57203094876; 35239832600; 24758748200; 56978912000; 55097216400; 56301395600; 6603347013; 57987123200; 55441008100; 57207893123; 15843180700; 7006418936; 7003373011; 57170268500; 35227360000; 7006485458; 57194522941; 56118947200; 57257924100; 56950373900; 16175853500; 57224657115; 57202249553; 57188758738; 55891278800; 57212934960; 35278894500; 8680451900; 57208691356; 8654627200; 57208684876; 6603371615; 7003708514 lisa.borgonovi@cern.ch; NUCLEAR INSTRUMENTS & METHODS IN PHYSICS RESEARCH SECTION A-ACCELERATORS SPECTROMETERS DETECTORS AND ASSOCIATED EQUIPMENT NUCL INSTRUM METH A 0168-9002 1872-9576 958 SCIE INSTRUMENTS & INSTRUMENTATION;NUCLEAR SCIENCE & TECHNOLOGY;PHYSICS, NUCLEAR;PHYSICS, PARTICLES & FIELDS 2020 1.455 48.5 0.42 2025-06-25 4 5 IDEA; Dual-readout calorimeter; MPGD; mu-RWELL; GEM; Drift-chamber; Test-beam; Gas detectors Drift-chamber; Dual-readout calorimeter; Gas detectors; GEM; IDEA; MPGD; Test-beam; μ-RWELL Calorimeters; Drift chambers; Gas detectors; Gems; Beam lines; Detector concepts; Detector technology; Dual readouts; IDEA; Measurements of; MPGD; Test beam; High energy physics English 2020 2020-04-01 10.1016/j.nima.2019.04.042 바로가기 바로가기 바로가기 바로가기
Article; Proceedings Paper Linearity response measurement of a SiPM-based dual-readout calorimeter for future leptonic colliders A dual-readout fibre sampling calorimeter module, based on Silicon Photomultiplier readout, was developed and tested on beam in 2016 and 2017. This test completed the proof-of-concept but also revealed a non-linear response to the scintillation light. In 2018, the signal linearity was studied after the interposition of a yellow filter between the scintillating fibres and the sensors. This paper reports the latest results on the module performance, highlighting as well the key and potentially critical parameters and the adopted solutions. Antonello, M.; Caccia, M.; Ferrari, R.; Franchino, S.; Gaudio, G.; Hauptman, J.; Lee, S.; Pezzotti, L.; Salvatore, F.; Santoro, R.; Vivarelli, I.; Wigmans, R. INFN, Milan, Italy; Univ Insubria, Como, Italy; INFN, Pavia, Italy; Heidelberg Univ, Kirchhoff Inst Phys, Heidelberg, Germany; Iowa State Univ, Ames, IA USA; Kyungpook Natl Univ, Daegu, South Korea; Univ Pavia, Pavia, Italy; Sussex Univ, Brighton, E Sussex, England; Texas Tech Univ, Lubbock, TX 79409 USA Antonello, Massimiliano/KIB-8239-2024; gaudio, gabriella/AAN-6039-2021; Pezzotti, Lorenzo/GRO-2971-2022; Caccia, Massimo/C-5407-2012; Fazio, Salvatore/G-5156-2010 57201049419; 55654886100; 57987123200; 57207893123; 15843180700; 35227360000; 57257924100; 57202249553; 35278894500; 8680451900; 6603371615; 7003708514 m.antonello@uninsubria.it; NUCLEAR INSTRUMENTS & METHODS IN PHYSICS RESEARCH SECTION A-ACCELERATORS SPECTROMETERS DETECTORS AND ASSOCIATED EQUIPMENT NUCL INSTRUM METH A 0168-9002 1872-9576 958 SCIE INSTRUMENTS & INSTRUMENTATION;NUCLEAR SCIENCE & TECHNOLOGY;PHYSICS, NUCLEAR;PHYSICS, PARTICLES & FIELDS 2020 1.455 48.5 0 2025-06-25 0 0 Dual-readout calorimetry; Cherenkov light; Optical fibres; SiPM SILICON PHOTOMULTIPLIER Cherenkov light; Dual-readout calorimetry; Optical fibres; SiPM Optical fibers; Scintillation; Cherenkov light; Dual readout calorimetries; Non-linear response; Sampling calorimeters; Scintillating fibres; Scintillation light; Silicon photomultiplier; SiPM; Calorimeters English 2020 2020-04-01 10.1016/j.nima.2019.04.090 바로가기 바로가기 바로가기 바로가기
Article; Proceedings Paper Material defect study of thallium lead iodide (TlPbI3) crystals for radiation detector applications TlPbI3 is a promising semiconductor material for fabricating room-temperature radiation detectors, which have wide applications in national security, medical imaging, astrophysics research, industrial process monitoring and environmental survey. TlPbI3 has a large energy bandgap at 2.3 eV, a high density (6.04 g/cm3) and high concentrations of the high atomic number elements Tl and Pb. Such physical properties offer great potential to use TlPbI3 to detect gamma-ray at room temperature with high detection efficiency. In this work, we used the positron annihilation lifetime spectroscopy (PALS) measurement and infrared transmission microscopy to study the material defects in bulk TlPbI3 crystals. These crystals were grown with Bridgman method. For the PALS measurements, we used the positron experimental setup at North Carolina State University's PULSTAR reactor facility. A 15 mu Ci Na-22 positron source sealed with 7.6 mu m thick Kapton films was sandwiched between two identical pieces of TlPbI3 samples. Two cylindrical plastic scintillators (1 inch diameter by 1 inch long) combined with Hamamatsu H3378-50 photomultiplier tubes (PMT) were used to detect the 1.27 MeV gamma-rays in coincidence with the 511 keV annihilation gamma-rays as the start and the stop signals, respectively. A LeCroy Wavepro 7300A digital oscilloscope was used to digitize the raw PMT pulses and acquire the PALS spectra. The dominating positron lifetime in TlPbI3 is 393 ps and its intensity is more than 92%. This component is typically attributed to some vacancy type (or more likely, vacancy cluster) positron trapping sites. The first component of similar to 140 ps could be related to mono-vacancies or positrons annihilate in a delocalized lattice state. Compared with MAPbI(3), the higher average lifetime, tau(av), and the higher intermediate lifetime (tau 2) in TlPbI3 indicate the presence of more anion-type vacancies and imply an increase in ionic conductivity. Using infrared transmission microscopy, we also observed the formation of large volume TlPbI3 single crystal even in the transition portion between the conical seeding pocket and the normal growth chunk. Yang, G.; Phan, Q. V.; Liu, M.; Hawari, A.; Kim, H. North Carolina State Univ, Dept Nucl Engn, Raleigh, NC 27695 USA; Kyungpook Natl Univ, Dept Phys, Daegu, South Korea ; Kim, Hong Joo/AAE-1178-2022; Yang, Ge/G-1354-2011 57203587369; 57202820686; 57198348144; 8602433000; 59051568100 gyang9@ncsu.edu; NUCLEAR INSTRUMENTS & METHODS IN PHYSICS RESEARCH SECTION A-ACCELERATORS SPECTROMETERS DETECTORS AND ASSOCIATED EQUIPMENT NUCL INSTRUM METH A 0168-9002 1872-9576 954 SCIE INSTRUMENTS & INSTRUMENTATION;NUCLEAR SCIENCE & TECHNOLOGY;PHYSICS, NUCLEAR;PHYSICS, PARTICLES & FIELDS 2020 1.455 48.5 0.37 2025-06-25 8 11 TlPbI3; Radiation detectors; Positron annihilation lifetime spectroscopy; Infrared microscopy TE INCLUSIONS; PERFORMANCE Infrared microscopy; Positron annihilation lifetime spectroscopy; Radiation detectors; TlPbI<sub>3</sub> Astrophysics; Atoms; Cathode ray oscilloscopes; Crystal growth from melt; Defects; Electrons; Gamma rays; Industrial research; Infrared transmission; Iodine compounds; Layered semiconductors; Medical imaging; National security; Photomultipliers; Positron annihilation spectroscopy; Positrons; Process monitoring; Radiation detectors; Single crystals; Thallium compounds; Atomic number elements; Industrial process monitoring; Infrared microscopy; Infrared transmission microscopy; North Carolina State University; Positron annihilation lifetime spectroscopy; Temperature radiation; TlPbI3; Semiconducting lead compounds English 2020 2020-02-21 10.1016/j.nima.2018.10.194 바로가기 바로가기 바로가기 바로가기
Article; Proceedings Paper Performance of the Belle II Silicon Vertex Detector The Belle II experiment at the SuperKEKB collider of KEK (Japan) started recording physics data in spring 2019 with all its subdetectors installed and with the goal of accumulating 50 ab(-1) of e(+)e(-) collision events at the unprecedented instantaneous luminosity of 8x10(35) cm(-2)s(-1), about 40 times larger than its predecessor. The Belle II vertex detector plays a crucial role in the broad Belle II physics program, especially for time-dependent CP measurements. It consists of two layers of DEPFET-based pixels and four layers of double-sided silicon strip detectors (SVD). The experience gained from the first period of SVD operation can be summarized as smooth and reliable running of the detector, with high stability of noise levels and calibration parameters obtained from local calibration runs. No major problem has been experienced. The detector even survived a few serious radiation accidents in which the beam was lost due to failure in the machine focusing quadrupoles without any notable damage. The SVD performance were carefully studied with these first physics data. The SVD showed excellent hit and tracking efficiency. Moreover, cluster energy and signal to noise ratio as well as the hit time and spatial resolutions measured on data showed a fair agreement with the expected performance. Tanigawa, H.; Adamczyk, K.; Aihara, H.; Aziz, T.; Bacher, S.; Bahinipati, S.; Batignani, G.; Baudot, J.; Behera, P. K.; Bettarini, S.; Bilka, T.; Bozek, A.; Buchsteiner, F.; Casarosa, G.; Cervenkov, D.; Chen, Y. Q.; Corona, L.; Czank, T.; Das, S. B.; Dash, N.; de Marino, G.; Dolezal, Z.; Dujany, G.; Forti, F.; Friedl, M.; Ganiev, E.; Gobbo, B.; Halder, S.; Hara, K.; Hazra, S.; Higuchi, T.; Irmler, C.; Ishikawa, A.; Jeon, H. B.; Joo, C.; Kaleta, M.; Kaliyar, A. B.; Kandra, J.; Kang, K. H.; Kapusta, P.; Kodys, P.; Kohriki, T.; Kumar, M.; Kumar, R.; Kvasnicka, P.; La Licata, C.; Lalwani, K.; Lanceri, L.; Lee, S. C.; Li, Y. B.; Libby, J.; Lueck, T.; Maity, S.; Mayekar, S. N.; Mohanty, G. B.; Grimaldo, J. A. Mora; Morii, T.; Nakamura, K. R.; Natkaniec, Z.; Onuki, Y.; Ostrowicz, W.; Paladino, A.; Paoloni, E.; Park, H.; Rao, K. K.; Ripp-Baudot, I; Rizzo, G.; Rout, N.; Sahoo, D.; Sato, N.; Schwanda, C.; Suzuki, J.; Tanaka, S.; Thalmeier, R.; Tsuboyama, T.; Uematsu, Y.; Verbycka, O.; Vitale, L.; Wan, K.; Watanuki, S.; Webb, J.; Wiechczynski, J.; Yin, H.; Zani, L.; Zhang, T. Univ Melbourne, Sch Phys, Melbourne, Vic 3010, Australia; Austrian Acad Sci, Inst High Energy Phys, A-1050 Vienna, Austria; Peking Univ, Dept Tech Phys, Beijing 100871, Peoples R China; Univ Sci & Technol China, Dept Modern Phys, Hefei 230026, Peoples R China; Charles Univ Prague, Fac Math & Phys, Prague 12116, Czech Republic; Univ Strasbourg, CNRS, IPHC, UMR 7178, F-67037 Strasbourg, France; Indian Inst Technol Bhubaneswar, Satya Nagar, India; Indian Inst Technol Madras, Chennai 600036, Tamil Nadu, India; Malaviya Natl Inst Technol Jaipur, Jaipur 302017, Rajasthan, India; Punjab Agr Univ, Ludhiana 141004, Punjab, India; Tata Inst Fundamental Res, Mumbai 400005, Maharashtra, India; Univ Pisa, Dipartimento Fis, I-56127 Pisa, Italy; Ist Nazl Fis Nucl, Sez Pisa, I-56127 Pisa, Italy; Univ Trieste, Dipartimento Fis, I-34127 Trieste, Italy; Ist Nazl Fis Nucl, Sez Trieste, I-34127 Trieste, Italy; Grad Univ Adv Studies SOKENDAI, Hayama, Kanagawa 2400193, Japan; Univ Tokyo, Kavli Inst Phys & Math Universe WPI, Kashiwa, Chiba 2778583, Japan; Tohoku Univ, Dept Phys, Sendai, Miyagi 9808578, Japan; Univ Tokyo, Dept Phys, Tokyo 1130033, Japan; High Energy Accelerator Res Org KEK, Tsukuba, Ibaraki 3050801, Japan; Kyungpook Natl Univ, Dept Phys, Daegu 41566, South Korea; H Niewodniczanski Inst Nucl Phys, PL-31342 Krakow, Poland; Ludwig Maximilian Univ Munich, D-80539 Munich, Germany Behera, Prafulla/AAK-8686-2020; Rizzo, Giuliana/A-8516-2015; Kodys, Peter/P-2636-2017; Bilka, Tadeáš/Q-3680-2017; Bilka, Tadeas/Q-3680-2017; Pachariya, Manoj/A-9646-2016; Adamczyk, Karol/W-2301-2018; Doležal, Zdeněk/K-6861-2017; bettarini, stefano/M-2502-2016; Ostrowicz, Waclaw/Y-3938-2018; Natkaniec, Zbigniew/AAP-2995-2021; Park, Hae/AAM-2956-2021; Kumar, Rajender/JSL-0696-2023; Forti, Francesco/H-3035-2011; Llácer, María/AAQ-7522-2020; OSTROWICZ, WACLAW/Y-3938-2018; Chen, Ziqi/HPE-6145-2023; Aihara, Hiroaki/F-3854-2010; ISHIKAWA, Akimasa/AAG-9668-2020; Cervenkov, Daniel/D-2884-2017; Joo, Changwoo/ABI-4034-2020; Li, Jiarong/ABG-6750-2022 57203804357; 56448523500; 26431253400; 57198200847; 57014918700; 35226929900; 35226921900; 7003306478; 57943353600; 55116333600; 56624583600; 35226998700; 56446995000; 36169158700; 55913471500; 59817779600; 57209105515; 57028463700; 57202083225; 56985709800; 57216841951; 57214699347; 56200044200; 35227146800; 10044712100; 57215857442; 35227306900; 57209094410; 57205557485; 57222816542; 57224139534; 15069585600; 35227389900; 57014196800; 54398896700; 57203805096; 57193274163; 57015230400; 57224903543; 24329126300; 14826956800; 35227561100; 57221404520; 55553737220; 57093553100; 55759603000; 46661127500; 57211953490; 57257924100; 58754147400; 55820982400; 35086577400; 57220731521; 55949914700; 35227732200; 56582129000; 57014635700; 56394864900; 35227761700; 35227766800; 35227773600; 56572518100; 35227715200; 35086680500; 59633046200; 35227855600; 35227845800; 57213625981; 57215857178; 57216629640; 35228014600; 57222040123; 57232742000; 56447101400; 16020533400; 57216843679; 57216841841; 57198320699; 57195153044; 57014809700; 57014140800; 15835927600; 57013958200; 57195150092; 57216843658 tanigawa@hep.phys.s.u-tokyo.ac.jp; NUCLEAR INSTRUMENTS & METHODS IN PHYSICS RESEARCH SECTION A-ACCELERATORS SPECTROMETERS DETECTORS AND ASSOCIATED EQUIPMENT NUCL INSTRUM METH A 0168-9002 1872-9576 972 SCIE INSTRUMENTS & INSTRUMENTATION;NUCLEAR SCIENCE & TECHNOLOGY;PHYSICS, NUCLEAR;PHYSICS, PARTICLES & FIELDS 2020 1.455 48.5 0 2025-06-25 0 0 Belle II; Silicon Vertex Detector; Performance Belle II; Performance; Silicon Vertex Detector Calibration; Silicon; Silicon detectors; Calibration parameters; Collision events; Double-sided silicon strip detectors; Physics programs; Recording physics; Silicon Vertex Detectors; Spatial resolution; Vertex detectors; Signal to noise ratio English 2020 2020-08-21 10.1016/j.nima.2020.164129 바로가기 바로가기 바로가기 바로가기
Article Performance test for a pixelated silicon sensor with junction field effect transistor We fabricated a pixelated silicon sensor with a junction field effect transistor (JFET) on a 650 mu m thick, high-resistivity (> 5 k Omega.cm) n-type double-sided polished 6-in. silicon wafer using a double-sided fabrication process. The JFET, which had a cylindrical structure, acted as a switch to read out charges accumulated in the pixelated sensor. We investigated the electrical characteristics of the pixelated sensor, which had a size of 100 mu m x 100 mu m. We also measured the drain current as a function of the drain voltage for different gate voltages to examine the switching performance of the JFET and optimized the design parameters of the pixelated sensor for the proper functioning of the switch. Furthermore, the pixelated sensor's responses under illumination by a light-emitting diode and X-rays were measured. The electrical characteristics and responses of the pixelated sensors are presented in this paper. Lee, S. C.; Baek, J. M.; Jeon, H. B.; Kang, K. H.; Kim, J. Y.; Lee, H. Y.; Lee, M. W.; Park, H. Kyungpook Natl Univ, Dept Phys, Daegu 41566, South Korea; Inst Basic Sci IBS, Ctr Underground Phys CUP, Daejeon 34126, South Korea; Dongnam Inst Radiol & Med Sci, Jwadong Gil 40, Busan 40633, South Korea 57257924100; 57787573100; 57014196800; 57224903543; 57208867729; 57199646872; 59835515500; 35086680500 coreadasom@gmail.com; NUCLEAR INSTRUMENTS & METHODS IN PHYSICS RESEARCH SECTION A-ACCELERATORS SPECTROMETERS DETECTORS AND ASSOCIATED EQUIPMENT NUCL INSTRUM METH A 0168-9002 1872-9576 978 SCIE INSTRUMENTS & INSTRUMENTATION;NUCLEAR SCIENCE & TECHNOLOGY;PHYSICS, NUCLEAR;PHYSICS, PARTICLES & FIELDS 2020 1.455 48.5 0 2025-06-25 0 0 Field effect transistor; Pixelated sensor; Switch; Gate voltage; Drain current DETECTOR; MODEL Drain current; Field effect transistor; Gate voltage; Pixelated sensor; Switch Drain current; Silicon sensors; Silicon wafers; Cylindrical structure; Design parameters; Electrical characteristic; Fabrication process; High resistivity; Junction field effect transistors; Performance tests; Switching performance; Junction gate field effect transistors English 2020 2020-10-21 10.1016/j.nima.2020.164419 바로가기 바로가기 바로가기 바로가기
Article; Proceedings Paper Run and slow control system of the Belle II silicon vertex detector The Belle II Silicon Vertex Detector (SVD) was installed recently and has been prepared for physics run at SuperKEKB factory, Tsukuba, Japan. For a reliable operation and data taking of the SVD, a sophisticated and robust run and slow control system has been implemented, which utilizes the Experimental Physics and Industrial Control System (EPICS) framework. EPICS uses client/server and publish/subscribe techniques to communicate between the various sub-systems and computers. The information exchange between the different pieces of software and computers is done by process variables (PVs). These PVs are provided by input/output controllers (IOCs), which communicate and interface with the hardware components. The Belle II SVD slow and run control comprises five groups of subsystems, which are SVD DAQ controller, Flash ADC controller, environmental monitors and interlocks, power supplies and EPICS infrastructure services. In this paper we describe the tasks and the implementation of the individual sub-systems, the interaction between them and the global Belle II run and slow control as well as the first experience from commissioning and initial operation of the SuperKEKB accelerator. Irmler, C.; Aihara, H.; Aziz, T.; Bacher, S.; Bahinipati, S.; Barberio, E.; Baroncelli, Ti.; Baroncelli, To.; Basith, A. K.; Batignani, G.; Bauer, A.; Behera, P. K.; Bertacchi, V.; Bettarini, S.; Bhuyan, B.; Bilka, T.; Bosi, F.; Bosisio, L.; Bozek, A.; Buchsteiner, F.; Caria, G.; Casarosa, G.; Ceccanti, M.; Cervenkov, D.; Czank, T.; Dash, N.; De Nuccio, M.; Dolezal, Z.; Forti, F.; Friedl, M.; Gobbo, B.; Grimaldo, J. A. M.; Hara, K.; Higuchi, T.; Ishikawa, A.; Jeon, H. B.; Joo, C.; Kaleta, M.; Kandra, J.; Kang, K. H.; Kodys, P.; Kohriki, T.; Komarov, I.; Kumar, M.; Kumar, R.; Kvasnicka, P.; La Licata, C.; Lalwani, K.; Lanceri, L.; Lee, J. Y.; Lee, S. C.; Li, Y.; Libby, J.; Lueck, T.; Mammini, P.; Martini, A.; Mayekar, S. N.; Mohanty, G. B.; Morii, T.; Nakamura, K. R.; Natkaniec, Z.; Onuki, Y.; Ostrowicz, W.; Paladino, A.; Paoloni, E.; Park, H.; Prasanth, K.; Profeti, A.; Rao, K. K.; Rashevskaya, I.; Resmi, P. K.; Rizzo, G.; Rozanska, M.; Sahoo, D.; Sasaki, J.; Sato, N.; Schultschik, S.; Schwanda, C.; Stypula, J.; Suzuki, J.; Tanaka, S.; Tanigawa, H.; Taylor, G. N.; Thalmeier, R.; Tsuboyama, T.; Urquijo, P.; Vitale, L.; Wan, K.; Watanabe, M.; Watanuki, S.; Watson, I. J.; Webb, J.; Wiechczynski, J.; Williams, S.; Yin, H.; Zani, L. Univ Melbourne, Sch Phys, Melbourne, Vic 3010, Australia; Austrian Acad Sci, Inst High Energy Phys, A-1050 Vienna, Austria; Peking Univ, Dept Tech Phys, Beijing 100871, Peoples R China; Charles Univ Prague, Fac Math & Phys, Prague 12116, Czech Republic; Indian Inst Technol, Bhubaneswar, Satya Nagar, India; Indian Inst Technol Madras, Chennai 600036, Tamil Nadu, India; Indian Inst Technol Guwahati, Gauhati 781039, Assam, India; Malaviya Natl Inst Technol Jaipur, Jaipur 302017, Rajasthan, India; Punjab Agr Univ, Ludhiana 141004, Punjab, India; Tata Inst Fundamental Res, Mumbai 400005, Maharashtra, India; Univ Pisa, Dipartimento Fis, I-56127 Pisa, Italy; INFN Sez Pisa, I-56127 Pisa, Italy; Univ Trieste, Dipartimento Fis, I-34127 Trieste, Italy; INFN Sez Trieste, I-34127 Trieste, Italy; Univ Tokyo, Kavli Inst Phys & Math Universe WPI, Kashiwa, Chiba 2778583, Japan; Niigata Univ, Dept Phys, Niigata 9502181, Japan; Tohoku Univ, Dept Phys, Sendai, Miyagi 9808578, Japan; Univ Tokyo, Dept Phys, Tokyo 1130033, Japan; High Energy Accelerator Res Org KEK, Tsukuba, Ibaraki 3050801, Japan; Kyungpook Natl Univ, Dept Phys, Daegu 702701, South Korea; Seoul Natl Univ, Dept Phys & Astron, Seoul 151742, South Korea; H Niewodniczanski Inst Nucl Phys, PL-31342 Krakow, Poland; TIFPA INFN, I-38123 Trento, Italy; Nippon Dent Univ, Niigata 9518580, Japan Park, Hae/AAM-2956-2021; Cervenkov, Daniel/D-2884-2017; Williams, Spencer/C-3545-2009; OSTROWICZ, WACLAW/Y-3938-2018; Forti, Francesco/H-3035-2011; bettarini, stefano/M-2502-2016; Joo, Changwoo/ABI-4034-2020; Behera, Prafulla/AAK-8686-2020; Kodys, Peter/P-2636-2017; Rozanska, Maria/X-1840-2018; Bertacchi, Valerio/KFQ-6990-2024; Ostrowicz, Waclaw/Y-3938-2018; Li, Jiarong/ABG-6750-2022; Higuchi, Takashi/C-4571-2017; Dash, Nibedita/ABA-4232-2021; Bilka, Tadeas/Q-3680-2017; Watson, Ian/IAM-9344-2023; Rizzo, Giuliana/A-8516-2015; Pachariya, Manoj/A-9646-2016; Bilka, Tadeáš/Q-3680-2017; Llácer, María/AAQ-7522-2020; Rozanska, Maria/ABG-6745-2020; ISHIKAWA, Akimasa/AAG-9668-2020; Lee, Jeeyun/I-7171-2015; Komarov, Ivan/HRE-1390-2023; Natkaniec, Zbigniew/AAP-2995-2021; Barberio, Elisabetta/A-4978-2010; Aihara, Hiroaki/F-3854-2010; Doležal, Zdeněk/K-6861-2017; KUMAR, RAJEEV/ADE-7638-2022 15069585600; 26431253400; 57198200847; 57014918700; 35226929900; 35775092300; 57195155294; 36016044400; 57195644350; 35226921900; 57196955631; 57943353600; 57203807394; 55116333600; 57830739900; 56624583600; 7004296450; 34767849000; 35226998700; 56446995000; 57197856101; 36169158700; 55009243100; 55913471500; 57028463700; 56985709800; 57203807007; 57214699347; 35227146800; 10044712100; 35227306900; 56582129000; 57205557485; 57224139534; 35227389900; 57014196800; 54398896700; 57203805096; 57015230400; 57224903543; 14826956800; 35227561100; 57203089210; 57221404520; 55553737220; 57093553100; 55759603000; 46661127500; 57211953490; 55870761600; 57257924100; 58754147400; 55820982400; 35086577400; 6701815309; 57204078384; 55949914700; 35227732200; 57014635700; 56394864900; 35227761700; 57201560199; 35227773600; 56572518100; 35227715200; 58642658300; 57215967699; 6701469333; 59633046200; 15844304700; 57200576462; 35227845800; 15751743800; 57215857178; 57014372000; 57216629640; 57015564500; 35228014600; 35086942200; 57201875266; 57232742000; 57203804357; 57203335500; 56447101400; 16020533400; 35228106200; 57198320699; 57195153044; 35228289800; 57014809700; 7102030607; 57014140800; 15835927600; 57214066113; 57013958200; 57195150092 christian.irmler@oeaw.ac.at; NUCLEAR INSTRUMENTS & METHODS IN PHYSICS RESEARCH SECTION A-ACCELERATORS SPECTROMETERS DETECTORS AND ASSOCIATED EQUIPMENT NUCL INSTRUM METH A 0168-9002 1872-9576 958 SCIE INSTRUMENTS & INSTRUMENTATION;NUCLEAR SCIENCE & TECHNOLOGY;PHYSICS, NUCLEAR;PHYSICS, PARTICLES & FIELDS 2020 1.455 48.5 0.25 2025-06-25 2 4 Belle II; Silicon vertex detector; Belle II SVD; Slow control; Run control; EPICS Belle II; Belle II SVD; EPICS; Run control; Silicon vertex detector; Slow control Control systems; Silicon; Belle II; Environmental monitor; EPICS; Industrial control systems; Information exchanges; Infrastructure services; Silicon Vertex Detectors; Slow control; Controllers English 2020 2020-04-01 10.1016/j.nima.2019.162706 바로가기 바로가기 바로가기 바로가기
Article; Proceedings Paper Series production testing and commissioning of the Belle II SVD readout system This paper shows the hardware and the procedure utilized to test all components of the readout system (cables, FADC boards, junction boards) of the Belle II Silicon Vertex Detector after the series production. For the FADC board special testing hardware and firmware were designed and created to check all digital and analog inputs and outputs as well as all data interconnections on the board. The main FPGA on the FADC board generates digital signals which are converted to periodic analog differential alternating voltages up to 40 MHz on the FADC board tester, which then are fed into the analog inputs of the FADC board. Histograms and scans of the samples are recorded by using random equivalent-time sampling or sequential equivalent-time sampling, allowing to characterize the behavior of the system with a much higher bandwidth than the ADCs could do with conventional measurements. Small changes of parameters of the assembly (like using a cable of different length) lead to significant changes of the measured values, creating a sensitive testing instrument. The shapes of the distributions are analyzed and compared to references by software which then decides if a test is passed or not. The commissioning setup of the whole readout chain, with all the final components including the final detector, has been tested in three phases. The respective graphs of the signal-to-noise ratios of the strips of a detector module and histograms of the noise development of the whole detector show very high consistency of the SVD readout system. Thalmeier, R.; Aihara, H.; Aziz, T.; Bacher, S.; Bahinipati, S.; Barberio, E.; Baroncelli, Ti.; Baroncelli, To.; Basith, A. K.; Batignani, G.; Bauer, A.; Behera, P. K.; Bertacchi, V.; Bettarini, S.; Bhuyan, B.; Bilka, T.; Bosi, F.; Bosisio, L.; Bozek, A.; Buchsteiner, F.; Caria, G.; Casarosa, G.; Ceccanti, M.; Cervenkov, D.; Czank, T.; Dash, N.; De Nuccio, M.; Dolezal, Z.; Forti, F.; Friedl, M.; Gobbo, B.; Grimaldo, J. A. M.; Hara, K.; Higuchi, T.; Irmler, C.; Ishikawa, A.; Jeon, H. B.; Joo, C.; Kaleta, M.; Kandra, J.; Kang, K. H.; Kodys, P.; Kohriki, T.; Komarov, I.; Kumar, M.; Kumar, R.; Kvasnicka, P.; La Licata, C.; Lalwani, K.; Lanceri, L.; Lee, J. Y.; Lee, S. C.; Li, Y.; Libby, J.; Lueck, T.; Mammini, P.; Martini, A.; Mayekar, S. N.; Mohanty, G. B.; Morii, T.; Nakamura, K. R.; Natkaniec, Z.; Onuki, Y.; Ostrowicz, W.; Paladino, A.; Paoloni, E.; Park, H.; Prasanth, K.; Profeti, A.; Rao, K. K.; Rashevskaya, I.; Resmi, P. K.; Rizzo, G.; Rozanska, M.; Sahoo, D.; Sasaki, J.; Sato, N.; Schultschik, S.; Schwanda, C.; Stypula, J.; Suzuki, J.; Tanaka, S.; Tanigawa, H.; Taylor, G. N.; Tsuboyama, T.; Urquijo, P.; Vitale, L.; Wan, K.; Watanabe, M.; Watanuki, S.; Watson, I. J.; Webb, J.; Wiechczynski, J.; Williams, S.; Yin, H.; Zani, L. Univ Melbourne, Sch Phys, Melbourne, Vic 3010, Australia; Austrian Acad Sci, Inst High Energy Phys, A-1050 Vienna, Austria; Peking Univ, Dept Tech Phys, Beijing 100871, Peoples R China; Charles Univ Prague, Fac Math & Phys, CR-12116 Prague, Czech Republic; Indian Inst Technol Bhubaneswar, Satya Nagar, India; Indian Inst Technol Madras, Chennai 600036, Tamil Nadu, India; Indian Inst Technol Guwahati, Gauhati 781039, Assam, India; Malaviya Natl Inst Technol Jaipur, Jaipur 302017, Rajasthan, India; Punjab Agr Univ, Ludhiana 141004, Punjab, India; Tata Inst Fundamental Res, Mumbai 400005, Maharashtra, India; Univ Pisa, Dipartimento Fis, I-56127 Pisa, Italy; INFN, Sez Pisa, I-56127 Pisa, Italy; Univ Trieste, Dipartimento Fis, I-34127 Trieste, Italy; INFN, Sez Trieste, I-34127 Trieste, Italy; Univ Tokyo, Kavli Inst Phys & Math Universe WPI, Kashiwa, Chiba 2778583, Japan; Niigata Univ, Dept Phys, Niigata 9502181, Japan; Tohoku Univ, Dept Phys, Sendai, Miyagi 9808578, Japan; Univ Tokyo, Dept Phys, Tokyo 1130033, Japan; High Energy Accelerator Res Org KEK, Tsukuba, Ibaraki 3050801, Japan; Kyungpook Natl Univ, Dept Phys, Daegu 702701, South Korea; Seoul Natl Univ, Dept Phys & Astron, Seoul 151742, South Korea; H Niewodniczanski Inst Nucl Phys, PL-31342 Krakow, Poland; INFN, TIFPA, I-38123 Trento, Italy; Nippon Dent Univ, Niigata 9518580, Japan Rizzo, Giuliana/A-8516-2015; Komarov, Ivan/HRE-1390-2023; Llácer, María/AAQ-7522-2020; Bertacchi, Valerio/KFQ-6990-2024; Cervenkov, Daniel/D-2884-2017; Pachariya, Manoj/A-9646-2016; Barberio, Elisabetta/A-4978-2010; Natkaniec, Zbigniew/AAP-2995-2021; KUMAR, RAJEEV/ADE-7638-2022; OSTROWICZ, WACLAW/Y-3938-2018; Dash, Nibedita/ABA-4232-2021; Rozanska, Maria/X-1840-2018; Joo, Changwoo/ABI-4034-2020; Williams, Spencer/C-3545-2009; Bilka, Tadeas/Q-3680-2017; Ostrowicz, Waclaw/Y-3938-2018; Higuchi, Takashi/C-4571-2017; Aihara, Hiroaki/F-3854-2010; Doležal, Zdeněk/K-6861-2017; Behera, Prafulla/AAK-8686-2020; Lee, Jeeyun/I-7171-2015; Rozanska, Maria/ABG-6745-2020; Watson, Ian/IAM-9344-2023; Forti, Francesco/H-3035-2011; Kodys, Peter/P-2636-2017; bettarini, stefano/M-2502-2016; Park, Hae/AAM-2956-2021; ISHIKAWA, Akimasa/AAG-9668-2020; Li, Jiarong/ABG-6750-2022; Bilka, Tadeáš/Q-3680-2017 56447101400; 26431253400; 57198200847; 57014918700; 35226929900; 35775092300; 57195155294; 36016044400; 57195644350; 35226921900; 57196955631; 57943353600; 57203807394; 55116333600; 57830739900; 56624583600; 7004296450; 34767849000; 35226998700; 56446995000; 57197856101; 36169158700; 55009243100; 55913471500; 57028463700; 56985709800; 57203807007; 57214699347; 35227146800; 10044712100; 35227306900; 56582129000; 57205557485; 57224139534; 15069585600; 35227389900; 57014196800; 54398896700; 57203805096; 57015230400; 57224903543; 14826956800; 35227561100; 57203089210; 57221404520; 55553737220; 57093553100; 55759603000; 46661127500; 57211953490; 55870761600; 57257924100; 58754147400; 55820982400; 35086577400; 6701815309; 57204078384; 55949914700; 35227732200; 57014635700; 56394864900; 35227761700; 57201560199; 35227773600; 56572518100; 35227715200; 58642658300; 57215967699; 6701469333; 59633046200; 15844304700; 57200576462; 35227845800; 15751743800; 57215857178; 57014372000; 57216629640; 57015564500; 35228014600; 35086942200; 57201875266; 57232742000; 57203804357; 57203335500; 16020533400; 35228106200; 57198320699; 57195153044; 35228289800; 57014809700; 7102030607; 57014140800; 15835927600; 57214066113; 57013958200; 57195150092 Richard.Thalmeier@oeaw.ac.at; NUCLEAR INSTRUMENTS & METHODS IN PHYSICS RESEARCH SECTION A-ACCELERATORS SPECTROMETERS DETECTORS AND ASSOCIATED EQUIPMENT NUCL INSTRUM METH A 0168-9002 1872-9576 958 SCIE INSTRUMENTS & INSTRUMENTATION;NUCLEAR SCIENCE & TECHNOLOGY;PHYSICS, NUCLEAR;PHYSICS, PARTICLES & FIELDS 2020 1.455 48.5 0.08 2025-06-25 1 1 Belle II SVD readout hardware; Testing; Commissioning Belle II SVD readout hardware; Commissioning; Testing Cables; Firmware; Graphic methods; Instrument testing; Readout systems; Signal to noise ratio; Testing; Well testing; Alternating voltages; Commissioning; Conventional measurements; Equivalent-time samplings; Noise development; Sequential-equivalent-time; Silicon Vertex Detectors; Testing hardwares; Software testing English 2020 2020-04-01 10.1016/j.nima.2019.162942 바로가기 바로가기 바로가기 바로가기
Article The CLAS12 Central Time-of-Flight system The Central Time-of-Flight system for the large-acceptance CLAS12 spectrometer in Hall B at the Thomas Jefferson National Accelerator Facility is described. The system consists of a hermetic barrel of 48 scintillation counters at a radius of 25 cm from the beamline. The wedge-shaped counters are 3.4 cm wide, 3.0 cm thick, and 90 cm long, and span a range of polar angles relative to the center of the nominal target location from roughly 35 degrees to 125 degrees. The counters reside in the 5-T field of the CLAS12 superconducting solenoid. The bars are read out via bent light guides 1 m long on the upstream end of the counters and 1.6 m long on the downstream end. The phototubes are shielded by a mull-layer dynamical magnetic shield system to reduce the local fringe fields in the range from 400 G to 1000 G down to the level of 0.2 G at the location of the photocathodes. The average effective time resolution of the counters is 80 ps. Carman, D. S.; Asryan, G.; Baturin, V; Clark, L.; De Vita, R.; Kim, W.; Miller, B.; Wiggins, C. Thomas Jefferson Natl Accelerator Facil, Newport News, VA 23606 USA; Univ Glasgow, Glasgow G12 8QQ, Lanark, Scotland; Ist Nazl Fis Nucl, Sez Genova, I-16146 Genoa, Italy; Kyungpook Natl Univ, Daegu 41566, South Korea 7005853901; 35277128500; 59799053800; 36022213600; 59345445900; 35227558900; 57215058099; 57204952924 carman@jlab.org; NUCLEAR INSTRUMENTS & METHODS IN PHYSICS RESEARCH SECTION A-ACCELERATORS SPECTROMETERS DETECTORS AND ASSOCIATED EQUIPMENT NUCL INSTRUM METH A 0168-9002 1872-9576 960 SCIE INSTRUMENTS & INSTRUMENTATION;NUCLEAR SCIENCE & TECHNOLOGY;PHYSICS, NUCLEAR;PHYSICS, PARTICLES & FIELDS 2020 1.455 48.5 0.51 2025-06-25 11 8 CLAS12; Time of flight; Plastic scintillator; Particle identification CLAS12; Particle identification; Plastic scintillator; Time of flight Field emission cathodes; Optical fibers; Scintillation counters; Accelerator facilities; CLAS12; Particle identifications; Plastic scintillator; Superconducting solenoids; Target location; Time of flight; Time of flight systems; Magnetic shielding English 2020 2020-04-21 10.1016/j.nima.2020.163626 바로가기 바로가기 바로가기 바로가기
Article The CLAS12 forward electromagnetic calorimeter The CLAS12 Forward Detector includes six independent lead-scintillator electromagnetic sampling calorimeters to provide the primary electron trigger and extend the CLAS12 detection capability to photons and neutrons. Each calorimeter package consists of two modules, the legacy Electromagnetic Calorimeter (EC) previously used in the CLAS detector, and a new pre-shower calorimeter (PCAL) located in front of the EC to extend the total detector radiation length, in order to fully absorb the electromagnetic showers induced by electrons with energies up to 12 GeV. Both calorimeters use a novel triangular hodoscope geometry with stereo readout. The PCAL uses an upgraded design to provide the high spatial resolution necessary for reconstructing pi(0) and eta decays, and neutrons with high efficiency. This paper treats the design, construction, and calibration of the PCAL and the preliminary combined performance of both detectors. Asryan, G.; Chandavar, Sh; Chetry, T.; Compton, N.; Daniel, A.; Dashyan, N.; Gevorgyan, N.; Ghandilyan, Y.; Giovanetti, K.; Griffioen, K.; Hicks, K.; Kashy, D.; Khachatryan, G.; Khandaker, M.; Phelps, W.; Riso, J.; Simonyan, A.; Salgado, C.; Smith, C.; Stepanyan, S.; Tang, W.; Voskanyan, H.; Yurov, M. Thomas Jefferson Natl Accelerator Facil, Newport News, VA 23606 USA; Coll William & Mary, Williamsburg, VA 23185 USA; Ohio Univ, Athens, OH 45701 USA; Norfolk State Univ, Norfolk, VA 23504 USA; Univ Virginia, Charlottesville, VA 22901 USA; A Alikhanyan Natl Sci Lab, Yerevan 375036, Armenia; James Madison Univ, Harrisonburg, VA 22807 USA; Kyungpook Natl Univ, Daegu 41566, South Korea 35277128500; 52563252700; 57189889203; 56592910700; 7102003713; 6507987909; 12753483500; 57215024895; 6701352818; 7004574641; 22966851900; 10043180600; 57197062611; 13405022500; 56362788600; 6506505025; 38663311400; 35228024200; 14822463500; 7004491103; 55538905900; 6504161736; 16029849600 lcsmith@jlab.org; NUCLEAR INSTRUMENTS & METHODS IN PHYSICS RESEARCH SECTION A-ACCELERATORS SPECTROMETERS DETECTORS AND ASSOCIATED EQUIPMENT NUCL INSTRUM METH A 0168-9002 1872-9576 959 SCIE INSTRUMENTS & INSTRUMENTATION;NUCLEAR SCIENCE & TECHNOLOGY;PHYSICS, NUCLEAR;PHYSICS, PARTICLES & FIELDS 2020 1.455 48.5 0.76 2025-06-25 12 12 CLAS12; Sampling calorimeter; Plastic scintillator; Particle identification CLAS12; Particle identification; Plastic scintillator; Sampling calorimeter Chemical detection; Particle detectors; Readout systems; Scintillation counters; CLAS12; Detection capability; Electro-magnetic showers; Electromagnetic calorimeter; High spatial resolution; Particle identifications; Plastic scintillator; Sampling calorimeters; Calorimeters English 2020 2020-04-11 10.1016/j.nima.2020.163425 바로가기 바로가기 바로가기 바로가기
Article The CLAS12 Spectrometer at Jefferson Laboratory The CEBAF Large Acceptance Spectrometer for operation at 12 GeV beam energy (CLAS12) in Hall B at Jefferson Laboratory is used to study electro-induced nuclear and hadronic reactions. This spectrometer provides efficient detection of charged and neutral particles over a large fraction of the full solid angle. CLAS12 has been part of the energy-doubling project of Jefferson Lab's Continuous Electron Beam Accelerator Facility, funded by the United States Department of Energy. An international collaboration of 48 institutions contributed to the design and construction of detector hardware, developed the software packages for the simulation of complex event patterns, and commissioned the detector systems. CLAS12 is based on a dual-magnet system with a superconducting torus magnet that provides a largely azimuthal field distribution that covers the forward polar angle range up to 35 degrees, and a solenoid magnet and detector covering the polar angles from 35 degrees to 125 degrees with full azimuthal coverage. Trajectory reconstruction in the forward direction using drift chambers and in the central direction using a vertex tracker results in momentum resolutions of <1% and <3%, respectively. Cherenkov counters, time-of-flight scintillators, and electromagnetic calorimeters provide good particle identification. Fast triggering and high data-acquisition rates allow operation at a luminosity of 10(35) cm(-2) s(-1). These capabilities are being used in a broad program to study the structure and interactions of nucleons, nuclei, and mesons, using polarized and unpolarized electron beams and targets for beam energies up to 11 GeV. This paper gives a general description of the design, construction, and performance of CLAS12. Burkert, V. D.; Elouadrhiri, L.; Adhikari, K. P.; Adhikari, S.; Amaryan, M. J.; Anderson, D.; Angelini, G.; Antonioli, M.; Atac, H.; Aune, S.; Avakian, H.; Gayoso, C. Ayerbe; Baltzell, N.; Barion, L.; Battaglieri, M.; Baturin, V; Bedlinskiy, I; Benmokhtar, F.; Bianconi, A.; Biselli, A. S.; Bonneau, P.; Bossu, F.; Boyarinov, S.; Briscoe, W. J.; Brooks, W. K.; Bruhwel, K.; Carman, D. S.; Celentano, A.; Charles, G.; Chatagnon, P.; Chetry, T.; Christiaens, G.; Christo, S.; Ciullo, G.; Clary, B. A.; Cole, P. L.; Contalbrigo, M.; Cook, M.; Crede, V; Cruz-Torres, R.; Cuevas, C.; D'Angelo, A.; Dashyan, N.; Defurne, M.; Deur, A.; De Vita, R.; Diehl, S.; Djalali, C.; Dodge, G.; Dupre, R.; Ehrhart, M.; El Fassi, L.; Eng, B.; Ewing, T.; Fair, R.; Fedotov, G.; Filippi, A.; Forest, T. A.; Garcon, M.; Gavalian, G.; Ghoshal, P.; Gilfoyle, G. P.; Giovanetti, K.; Girod, F. X.; Glazier, D., I; Golovatch, E.; Gothe, R. W.; Gotra, Y.; Griffioen, K. A.; Guidal, M.; Gyurjyan, V; Hafidi, K.; Hakobyan, H.; Hanretty, C.; Harrison, N.; Hattawy, M.; Hauenstein, F.; Hayward, T. B.; Heddle, D.; Hemler, P.; Hen, O. A.; Hicks, K.; Hobart, A.; Hogan, J.; Holtrop, M.; Ilieva, Y.; Illari, I.; Insley, D.; Ireland, D. G.; Ishkhanov, B. S.; Isupov, E. L.; Jacobs, G.; Jo, H. S.; Johnston, R.; Joo, K.; Joosten, S.; Kageya, T.; Kashy, D.; Keith, C.; Keller, D.; Khachatryan, M.; Khanal, A.; Kim, A.; Kim, C. W.; Kim, W.; Kubarovsky, V; Kuhn, S. E.; Lanza, L.; Leffel, M.; Lucherini, V; Lung, A.; Kabir, M. L.; Leali, M.; Lee, S.; Lenisa, P.; Livingston, K.; Lowry, M.; MacGregor, I. J. D.; Mandjavidze, I; Marchand, D.; Markov, N.; Mascagna, V; McKinnon, B.; McMullen, M.; Mealer, C.; Mestayer, M. D.; Meziani, Z. E.; Miller, R.; Milner, R. G.; Mineeva, T.; Mirazita, M.; Mokeev, V; Moran, P.; Movsisyan, A.; Camacho, C. Munoz; Naidoo, P.; Nanda, S.; Newton, J.; Niccolai, S.; Niculescu, G.; Osipenko, M.; Paolone, M.; Pappalardo, L. L.; Paremuzyan, R.; Pastor, O.; Pasyuk, E.; Phelps, W.; Pogorelko, O.; Poudel, J.; Price, J. W.; Price, K.; Procureur, S.; Prok, Y.; Protopopescu, D.; Rajput-Ghoshal, R.; Raue, B. A.; Raydo, B.; Ripani, M.; Ritman, J.; Rizzo, A.; Rosner, G.; Rossi, P.; Rowley, J.; Roy, B. J.; Sabatie, F.; Salgado, C.; Schadmand, S.; Schmidt, A.; Segarra, E. P.; Sergeyeva, V; Sharabian, Y. G.; Shrestha, U.; Skorodumina, Iu; Smith, G. D.; Smith, L. C.; Sokhan, D.; Soto, O.; Sparveris, N.; Stepanyan, S.; Stoler, P.; Strauch, S.; Tan, J. A.; Taylor, M.; Tilles, D.; Turisini, M.; Tyler, N.; Ungaro, M.; Venturelli, L.; Voskanyan, H.; Voutier, E.; Watts, D.; Wei, X.; Weinstein, L. B.; Wiggins, C.; Wiseman, M.; Wood, M. H.; Yegneswaran, A.; Young, G.; Zachariou, N.; Zarecky, M.; Zhang, J.; Zhao, Z. W.; Ziegler, V Argonne Natl Lab, Argonne, IL 60439 USA; Calif State Univ, Dominguez Hills, Carson, CA 90747 USA; Canisius Coll, Buffalo, NY 14208 USA; Univ Paris Saclay, CEA, IRFU, F-91191 Gif Sur Yvette, France; Christopher Newport Univ, Newport News, VA 23606 USA; Univ Connecticut, Storrs, CT 06269 USA; Duke Univ, Durham, NC 27708 USA; Duquesne Univ, Pittsburgh, PA 15282 USA; Univ Edinburgh, Edinburgh EH9 3JZ, Midlothian, Scotland; Fairfield Univ, Fairfield, CT 06824 USA; Univ Ferrara, I-44121 Ferrara, Italy; Florida Int Univ, Miami, FL 33199 USA; George Washington Univ, Washington, DC 20052 USA; Idaho State Univ, Pocatello, ID 83209 USA; Ist Nazl Fis Nucl, Sez Ferrara, I-44100 Ferrara, Italy; Ist Nazl Fis Nucl, Lab Nazl Frascati, I-00044 Frascati, Italy; Ist Nazl Fis Nucl, Sez Genova, I-16146 Genoa, Italy; Ist Nazl Fis Nucl, Sez Roma Tor Vergata, I-00133 Rome, Italy; Ist Nazl Fis Nucl, Sez Torino, I-10125 Turin, Italy; Ist Nazl Fis Nucl, Sez Pavia, I-27100 Pavia, Italy; Univ Paris Sacla, Univ Paris Sud, Inst Phys Nucl, IN2P3,CNRS, F-91406 Orsay, France; Inst Kernphys Juelich, D-52428 Julich, Germany; James Madison Univ, Harrisonburg, VA 22807 USA; Kyungpook Natl Univ, Daegu 41566, South Korea; Lamar Univ, Beaumont, TX 77710 USA; MIT, 77 Massachusetts Ave, Cambridge, MA 02139 USA; Florida State Univ, Tallahassee, FL 32306 USA; Mississippi State Univ, Mississippi State, MS 39762 USA; Natl Res Ctr Kurchatov Inst ITEP, Moscow 117259, Russia; Univ New Hampshire, Durham, NH 03824 USA; Norfolk State Univ, Norfolk, VA 23504 USA; Ohio Univ, Athens, OH 45701 USA; Old Dominion Univ, Norfolk, VA 23529 USA; Rensselaer Polytech Inst, Troy, NY 12180 USA; Univ Richmond, Richmond, VA 23173 USA; Univ Roma Tor Vergata, I-00133 Rome, Italy; Lomonosov Moscow State Univ, Skobeltsyn Inst Nucl Phys, Moscow 119234, Russia; Univ South Carolina, Columbia, SC 29208 USA; Temple Univ, Philadelphia, PA 19122 USA; Thomas Jefferson Natl Accelerator Facil, Newport News, VA 23606 USA; Univ Tecn Federico Santa Maria, Casilla 110-V, Valparaiso, Chile; Univ Insubria, I-22100 Como, Italy; Univ Brescia, I-25123 Brescia, Italy; Univ Glasgow, Glasgow G12 8QQ, Lanark, Scotland; Univ York, York YO10 5DD, N Yorkshire, England; Univ Virginia, Charlottesville, VA 22901 USA; Coll William & Mary, Williamsburg, VA 23187 USA; Yerevan Phys Inst, Yerevan 375036, Armenia ; Higinbotham, Douglas/J-9394-2014; Pappalardo, Luciano/AAB-2380-2021; Zhao, Zhi-Wen/HZI-5398-2023; Khanal, Aaditya/ABI-5610-2020; Lanza, Lucilla/E-6479-2017; Deur, Alexandre/H-9778-2019; Burkert, Volker/AAF-7395-2020; D'Angelo, Annalisa/A-2439-2012; Lee, Sangbaek/MVV-9130-2025; Holtrop, Maurik/A-9017-2010; Battaglieri, Marco/I-6262-2018; Turisini, Matteo/AAK-3160-2020; Bashkanov, Mikhail/R-1333-2018; Jo, Hyon-Suk/HGC-7070-2022; Osipenko, Mikhail/N-8292-2015; Joosten, Sylvester/HZL-4182-2023; Sparveris, Nikolaos/C-4751-2008; Hakobyan, Hayk/JUF-6461-2023; Mineeva, Taisiya/MDT-1592-2025; Ciullo, Giuseppe/X-6539-2018; Schumacher, Reinhard/K-6455-2013; Rizzo, Alessandro/C-6397-2014; Zhang, Jixie/A-1461-2016; Sabatie, Franck/K-9066-2015; Filippi, Alessandra/AAE-9322-2020; Mascagna, Valerio/HLQ-1103-2023; POUDEL, JIWAN/KQU-6557-2024; Celentano, Andrea/JFJ-2728-2023; Protopopescu, Dan/D-5645-2012; Ireland, David/E-8618-2010; Adikaram, Dasuni/D-1539-2016; Gyurjyan, Vardan/GSD-5715-2022; Isupov, Evgeny/J-2976-2012; Rosner, Guenther/ABB-5516-2021; McKinnon, Bryan/J-2928-2018; Bozzi, Giuseppe/H-7283-2017; Brooks, William/C-8636-2013; Filippi, Alessandra/I-9530-2012; MacGregor, Ian/D-4072-2011 7004440244; 35227171600; 25823658400; 56258456900; 35277104000; 59607342500; 57193121212; 55946432800; 57210826461; 7004408280; 7006613415; 15755099700; 35226938500; 23033257000; 7004520678; 59799053800; 35277104100; 57218527298; 7102358422; 35227021700; 56275991700; 35725064700; 6506986368; 7005532059; 35400106000; 24376462300; 7005853901; 54392656300; 40461141400; 57202987431; 57189889203; 57214079912; 6602561069; 6603765308; 57202060165; 35227101500; 7003468594; 57214099476; 6602900241; 57201114991; 7005832777; 55828029600; 6507987909; 56272524200; 6604025441; 59345445900; 57217562965; 35374416600; 7006854029; 35069234100; 57193421717; 14041647600; 57212103381; 57214826524; 18037154600; 57215092344; 8695796100; 35227189500; 6603943054; 35227304900; 18037061500; 6603686320; 6701352818; 35227280900; 8258896400; 35227273800; 7102183142; 35225777000; 7004574641; 7003432409; 35227312600; 34570410000; 57208726428; 17433911800; 52863649900; 56115055200; 55382488300; 57206656408; 7003821864; 56632105300; 36993853800; 22966851900; 57214681432; 7202269780; 7005060869; 35227424100; 57214820710; 6504730016; 7006927902; 7006434288; 35227460400; 57196531173; 35227429400; 57205376015; 57202638465; 23034837300; 26424284700; 10043180600; 7005417443; 7102814361; 57193668661; 57208691543; 36604596000; 59817767500; 35227558900; 6701392158; 7103392237; 56047689500; 55790043400; 56238532600; 7004652789; 57200978499; 6507646370; 58375580000; 56273696800; 9278396500; 7102089268; 7006040977; 6602252277; 7004889588; 35227617100; 22135531000; 35227669300; 9039853600; 57214819728; 36123326800; 24500876300; 57203645213; 16019693900; 26023453000; 35227656900; 7004546205; 57205376704; 58474853600; 12244632700; 57214093211; 58304644200; 56530113800; 35227746500; 35227763200; 6701825145; 22986163400; 7004207376; 36085149700; 56494589300; 35227791700; 56362788600; 8903140900; 57200602864; 55329126900; 57214493323; 11241906700; 35227871000; 35227881200; 15136554800; 7004527121; 24484201100; 7003515879; 6701495633; 56589489300; 7102538331; 58092074700; 57214597279; 7201660483; 35227896300; 35228024200; 7003648916; 57212416423; 57203683484; 56035349200; 35227996900; 57213706614; 55834228500; 57202770694; 8115440100; 16065283100; 55787422600; 57214826199; 7004491103; 8331193400; 7004321986; 57200599233; 57225966874; 6506359898; 44861810200; 57203722948; 35228099400; 22136651400; 6504161736; 6603350317; 7201539565; 13204321200; 35377851100; 57204952924; 7006681487; 57201559118; 35228264400; 56493935200; 36836386600; 6505460715; 57215210642; 57216598335; 59819934500 dr.v.burkert@gmail.com; NUCLEAR INSTRUMENTS & METHODS IN PHYSICS RESEARCH SECTION A-ACCELERATORS SPECTROMETERS DETECTORS AND ASSOCIATED EQUIPMENT NUCL INSTRUM METH A 0168-9002 1872-9576 959 SCIE INSTRUMENTS & INSTRUMENTATION;NUCLEAR SCIENCE & TECHNOLOGY;PHYSICS, NUCLEAR;PHYSICS, PARTICLES & FIELDS 2020 1.455 48.5 5.86 2025-06-25 84 102 CLAS12; Magnetic spectrometer; Electromagnetic physics; Large acceptance; Luminosity PROTON; CEBAF CLAS12; Electromagnetic physics; Large acceptance; Luminosity; Magnetic spectrometer Computer software; Data acquisition; Electron beams; Germanium compounds; International cooperation; Luminance; Magnets; Superconducting magnets; Cebaf large acceptance spectrometers; CLAS12; Electromagnetic calorimeter; Electromagnetic physics; International collaborations; Large acceptance; Magnetic spectrometers; United states department of energies; Spectrometers English 2020 2020-04-11 10.1016/j.nima.2020.163419 바로가기 바로가기 바로가기 바로가기
Review Molecular genetic approaches for enhancing stress tolerance and fruit quality of tomato Numerous efforts have been made to genetically improve tomato (Solanum lycopersicum) cultivars using various conventional breeding methods, despite severe restrictions to improve some target traits. Molecular approaches such as metabolic genetic engineering and genome editing tools have been able to overcome the restrictions and have achieved the generation of tomatoes with improved, commercially important traits. Due to continuing global climate change and market competition, the molecular approaches have been greatly applied in genetic improvement of agronomic (e.g., biotic and abiotic stress tolerance) and fruit quality (e.g., antioxidant enrichment and prolongation of shelf-life) traits in tomato. In this review, we summarize the results of previous studies that achieved genetic improvement of tomato agronomic and fruit quality traits using the molecular approaches and highlight how the molecular approaches are crucial for the genetic improvement of tomato. In addition, this review describes the functional roles of genes that enhance fruit quality and improve biotic/abiotic stress tolerance; therefore, it will also provide information of the specific genes for further genetic improvement in other tomato cultivars or horticultural crops using the molecular approaches, thus allowing for a time-saving approach to advancing plant biology and the horticultural industry. Wai, Antt Htet; Naing, Aung Htay; Lee, Do-Jin; Kim, Chang Kil; Chung, Mi-Young Sunchon Natl Univ, Dept Agr Educ, Sunchon, South Korea; Univ Mandalay, Dept Bot, Mandalay, Myanmar; Kyungpook Natl Univ, Dept Hort, Daegu, South Korea Naing, Aung Htay/AAF-4277-2019; Wai, Antt/AAG-9099-2021 57196010294; 37112768100; 7406659787; 7409880701; 24821361600 queen@scnu.ac.kr; PLANT BIOTECHNOLOGY REPORTS PLANT BIOTECHNOL REP 1863-5466 1863-5474 14 5 SCIE BIOTECHNOLOGY & APPLIED MICROBIOLOGY;PLANT SCIENCES 2020 2.01 48.7 0.49 2025-06-25 28 30 Genetic engineering; Stress tolerance; Fruit quality; Genome editing; Tomato MAP-BASED CLONING; TRANSGENIC TOMATO; TRANSCRIPTION FACTOR; DISEASE RESISTANCE; OVER-EXPRESSION; SALT TOLERANCE; POLYAMINE ACCUMULATION; DECARBOXYLASE GENE; DROUGHT TOLERANCE; OXIDATIVE STRESS Fruit quality; Genetic engineering; Genome editing; Stress tolerance; Tomato English 2020 2020-10 10.1007/s11816-020-00638-1 바로가기 바로가기 바로가기 바로가기
Article The dehydrin gene of the Arctic plant Cerastium arcticum, CaDHN, increases tolerance to multiple stresses in Arabidopsis thaliana Cerastium arcticum is one of the few flowering plants that thrives in the Arctic, suggesting that it possesses mechanisms for overcoming this extreme environment. To verify the functionality of C. arcticum dehydrin (CaDHN), known to play a protective role during cellular dehydration, the gene was introduced to Arabidopsis and Escherichia coli. Transgenic plants expressing CaDHN had significantly greater fresh weight and relative water content than wild-type plants under 15% PEG treatments, representing enhanced tolerance to drought. Under chilling conditions, transgenic plants remained vivid green, containing about 1.35-fold higher levels of chlorophyll than wild-type plants, and transgenic seeds germinated 2-3 days earlier with approximately threefold higher germination rates than wild-type seeds. Furthermore, oxidative stress under chilling conditions was 30% lower in transgenic plants than in wild-type plants. Transgenic plants also showed improved tolerance to various stresses, such as cold shock and salinity. In addition, transformed E. coli expressing CaDHN also showed enhanced tolerance to stress conditions, which suggests that CaDHN is conserved across taxa to provide tolerance to stress. These results indicate that CaDHN plays an important role in conferring tolerance to oxidative stress. Shin, Sun-Young; Kim, Hyun-Young; Kim, Il-Sup; Kim, Jin-Ju; Kim, Young- saeng; Yoon, Ho-Sung Kyungpook Natl Univ, Coll Nat Sci, Dept Biol, Daegu 41566, South Korea; DAESANG, 697 Jungbu Daero, Icheon Si 17384, Gyeonggi Do, South Korea; Kyungpook Natl Univ, Res Inst Ulleung Do & Dok Do, Daegu 41566, South Korea Shin, Sun-Young/AAH-9914-2019 54943706600; 57191717848; 55477678200; 57203324864; 35798433500; 7402990205 hyoon@knu.ac.kr; PLANT BIOTECHNOLOGY REPORTS PLANT BIOTECHNOL REP 1863-5466 1863-5474 14 4 SCIE BIOTECHNOLOGY & APPLIED MICROBIOLOGY;PLANT SCIENCES 2020 2.01 48.7 0.34 2025-06-25 5 5 Dehydrin; Arctic plant; Cerastium arcticum; Dehydration tolerance; Chilling tolerance; Arabidopsis thaliana KS-TYPE DEHYDRIN; ENHANCES TOLERANCE; EXPRESSION; PROTEINS; DROUGHT; OVEREXPRESSION; ACCUMULATION; TRANSCRIPTS; RESPONSES; SALT Arabidopsis thaliana; Arctic plant; Cerastium arcticum; Chilling tolerance; Dehydration tolerance; Dehydrin English 2020 2020-08 10.1007/s11816-020-00611-y 바로가기 바로가기 바로가기 바로가기
Article 3-D Space Visualization System Using Ultrasonic Sensors as an Assistive Device for the Blind This study proposes a new assistive device for the blind that uses more than one-dimensional data to draw objects. The study aims to convert three-dimensional (3-D) spatial information into sound information using 6-axis and ultrasonic sensors, and to draw a 3-D depiction of the space ahead for the user. Fourteen participants were involved in testing, wherein 4 were visually impaired. Moreover, the male to female ratio was 7:3, with the average age of participants at 28.8 years. An initial sound recognition experiment was designed to assess the device's accuracy through participant use. Recognition rates were 70% for normal participants and 88% for the blind participants. Additional experiments expanded the environmental conditions by requiring participants to discern the distances of 10 objects, positioned at both high and low locations. Two different scenarios were employed: stationary and walking scenarios. The stationary distance measurement participants scored an average of 96 points, while the walking participants averaged 81 points. Under the given conditions, this study found that its assistive device for the visually impaired can draw a 3-D space with 88.5% accuracy. This probability promises a basic level of utility that can assist those with visual impairment in controlled environments, such as hospitals and homes. Kim, Jung-Hun; Park, Ji-Eun; Lee, Jong-Min Kyungpook Natl Univ, Sch Elect Engn, Daegu 41566, South Korea ; Lee, Jongmin/AAR-6361-2020 58567949800; 57209642201; 55689919700 jonglee@knu.ac.kr; IEEE JOURNAL OF TRANSLATIONAL ENGINEERING IN HEALTH AND MEDICINE IEEE J TRANSL ENG HE 2168-2372 8 SCIE ENGINEERING, BIOMEDICAL 2020 3.316 48.9 0.49 2025-06-25 4 9 Acoustics; Assistive devices; Ultrasonic imaging; Visualization; Distance measurement; Sensor systems; Auditory signal; visual disturbance; visual reconstruction; vision system Auditory signal; vision system; visual disturbance; visual reconstruction Ultrasonic sensors; Additional experiments; Auditory signals; Controlled environment; Environmental conditions; Threedimensional (3-d); Vision systems; visual disturbance; Visual reconstruction; adult; Article; blindness; clinical article; female; human; loudness; male; sound; spatial orientation; three-dimensional imaging; ultrasound; walking; Three dimensional computer graphics English 2020 2020 10.1109/jtehm.2020.2978842 바로가기 바로가기 바로가기 바로가기
Article Comparative Characterization of G Protein α Subunits in Aspergillus fumigatus Trimeric G proteins play a central role in the G protein signaling in filamentous fungi and G alpha subunits are the major component of trimeric G proteins. In this study, we characterize three G alpha subunits in the human pathogen Aspergillus fumigatus. While the deletion of gpaB and ganA led to reduced colony growth, the growth of the Delta gpaA strain was increased in minimal media. The germination rate, conidiation, and mRNA expression of key asexual development regulators were significantly decreased by the loss of gpaB. In contrast, the deletion of gpaA resulted in increased conidiation and mRNA expression levels of key asexual regulators. The deletion of gpaB caused a reduction in conidial tolerance against H2O2, but not in paraquat (PQ). Moreover, the Delta gpaB mutant showed enhanced susceptibility against membrane targeting azole antifungal drugs and reduced production of gliotoxin (GT). The protein kinase A (PKA) activity of the Delta ganA strain was severely decreased and protein kinase C (PKC) activity was detected all strains at similar levels, indicating that all G protein alpha subunits of A. fumigatus may be a component of the cAMP/PKA signaling pathway and appear to possess the PKC signaling pathway as an alternative backup pathway to compensate for PKA depletion. Collectively, the three G alpha subunits regulate growth, germination, asexual development, resistance to oxidative stress, and GT production differently via the PKA or PKC signaling pathway. The function of GanA of A. fumigatus was elucidated for the first time. Choi, Yong-Ho; Lee, Na-Young; Kim, Sung-Su; Park, Hee-Soo; Shin, Kwang-Soo Daejeon Univ, Grad Sch, Dept Microbiol, Daejeon 34520, South Korea; Daejeon Univ, Dept Biomed Lab Sci, Daejeon 34520, South Korea; Kyungpook Natl Univ, Sch Food Sci & Biotechnol, Inst Agr Sci & Technol, Daegu 41566, South Korea Park, Hee-Soo/AAC-6422-2019; Choi, Yong-Ho/AAD-7708-2020 57205576573; 57216580967; 56034424600; 15751448400; 13310380600 youngho1107@gmail.com;1209leeny@gmail.com;sungsu@dju.kr;phsoo97@knu.ac.kr;shinks@dju.kr; PATHOGENS PATHOGENS 2076-0817 9 4 SCIE MICROBIOLOGY 2020 3.492 48.9 0.38 2025-06-25 14 13 Aspergillus fumigatus; G protein alpha subunits; asexual development; stress response; antifungal drug; GT; PKA; PKC SECONDARY METABOLISM; ASEXUAL SPORULATION; STRESS-RESPONSE; KINASE; GROWTH; GERMINATION; EXPRESSION; REGULATOR; VIRULENCE; UPSTREAM Antifungal drug; Asexual development; Aspergillus fumigatus; G protein α subunits; Gt; Pka; Pkc; Stress response adenosine diphosphate ribosylation factor; catalase; creatine kinase; cyclic AMP dependent protein kinase; hydrogen peroxide; messenger RNA; reactive oxygen metabolite; antifungal susceptibility; Article; Aspergillus fumigatus; biotic stress; broth dilution; controlled study; enzyme activity; gene; gene deletion; gene expression; genetic transfection; germination; minimum inhibitory concentration; mycelial growth; nonhuman; oxidative stress; phenotype; real time reverse transcription polymerase chain reaction; RNA isolation; sequence alignment; signal transduction; single nucleotide polymorphism; thin layer chromatography; Western blotting English 2020 2020-04 10.3390/pathogens9040272 바로가기 바로가기 바로가기 바로가기
페이지 이동:

논문 데이터 용어 설명

용어 설명
WoS Web of Science. Clarivate Analytics에서 제공하는 학술 데이터베이스입니다. 해당 논문이 WoS에 수록되어 있는지 여부를 표시합니다 (○: 수록됨).
SCOPUS Elsevier에서 제공하는 세계 최대 규모의 초록 및 인용 데이터베이스입니다. 해당 논문이 SCOPUS에 수록되어 있는지 여부를 표시합니다 (○: 수록됨).
Document Type 문헌의 유형을 나타냅니다. Article(원저), Review(리뷰), Proceeding Paper(학회논문), Editorial Material(편집자료), Letter(레터) 등으로 분류됩니다.
Title 논문의 제목입니다.
Abstract 논문의 초록(요약)입니다. 연구의 목적, 방법, 결과, 결론을 간략히 요약한 내용입니다.
Authors 논문의 저자 목록입니다. 공동 저자가 여러 명인 경우 세미콜론(;)으로 구분됩니다.
Affiliation 저자들의 소속 기관 정보입니다. 대학, 연구소, 기업 등 저자가 소속된 기관명이 표시됩니다.
ResearcherID (WoS) Web of Science의 고유 연구자 식별번호입니다. 동명이인을 구분하고 연구자의 업적을 정확하게 추적할 수 있습니다.
AuthorsID (SCOPUS) SCOPUS의 고유 저자 식별번호입니다. 연구자의 모든 출판물을 추적하고 관리하는 데 사용됩니다.
Journal 논문이 게재된 학술지의 정식 명칭입니다.
JCR Abbreviation Journal Citation Reports에서 사용하는 저널의 공식 약어입니다. 저널을 간략하게 표기할 때 사용됩니다.
ISSN International Standard Serial Number. 국제표준연속간행물번호로, 인쇄본 저널에 부여되는 고유 식별번호입니다.
eISSN Electronic ISSN. 전자 버전 저널에 부여되는 고유 식별번호입니다.
Volume 저널의 권(Volume) 번호입니다. 보통 연도별로 하나의 권이 부여됩니다.
Issue 저널의 호(Issue) 번호입니다. 한 권 내에서 여러 호로 나누어 출판되는 경우가 많습니다.
WoS Edition Web of Science의 에디션입니다. SCIE(Science Citation Index Expanded), SSCI(Social Sciences Citation Index), AHCI(Arts & Humanities Citation Index) 등으로 구분됩니다.
WoS Category Web of Science의 주제 분류 카테고리입니다. 저널과 논문이 속한 학문 분야를 나타냅니다.
JCR Year 해당 저널의 JCR(Journal Citation Reports) 지표가 산출된 연도입니다.
IF (Impact Factor) 저널 영향력 지수. 최근 2년간 발표된 논문이 해당 연도에 평균적으로 인용된 횟수를 나타냅니다. 저널의 학술적 영향력을 나타내는 대표적인 지표입니다.
JCR (%) 해당 카테고리에서 저널이 위치하는 상위 백분율입니다. 값이 낮을수록 우수한 저널임을 의미합니다 (예: 5%는 상위 5%를 의미).
FWCI Field-Weighted Citation Impact. 분야별 가중 인용 영향력 지수입니다. 논문이 받은 인용을 동일 분야, 동일 연도, 동일 문헌 유형의 평균과 비교한 값입니다. 1.0이 평균이며, 1.0보다 높으면 평균 이상의 인용을 받았음을 의미합니다.
FWCI UpdateDate FWCI 값이 마지막으로 업데이트된 날짜입니다. FWCI는 인용이 누적됨에 따라 주기적으로 업데이트됩니다.
WOS Citation Web of Science에서 집계된 해당 논문의 총 인용 횟수입니다.
SCOPUS Citation SCOPUS에서 집계된 해당 논문의 총 인용 횟수입니다.
Keywords (WoS) 저자가 논문에서 직접 지정한 키워드입니다. Web of Science에 등록된 저자 키워드 목록입니다.
KeywordsPlus (WoS) Web of Science에서 자동으로 추출한 추가 키워드입니다. 논문의 참고문헌 제목에서 자주 등장하는 단어들로 생성됩니다.
Keywords (SCOPUS) 저자가 논문에서 직접 지정한 키워드입니다. SCOPUS에 등록된 저자 키워드 목록입니다.
KeywordsPlus (SCOPUS) SCOPUS에서 자동으로 추출하거나 추가한 색인 키워드입니다.
Language 논문이 작성된 언어입니다. 대부분 English이며, 그 외 다양한 언어로 작성된 논문이 포함될 수 있습니다.
Publication Year 논문이 출판된 연도입니다.
Publication Date 논문의 정확한 출판 날짜입니다 (년-월-일 형식).
DOI Digital Object Identifier. 디지털 객체 식별자로, 논문을 고유하게 식별하는 영구적인 식별번호입니다. 이를 통해 논문의 온라인 위치를 찾을 수 있습니다.