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Deposition of thin layers of CZTS by sol-gel route via spin-coating

Materials Today: Proceedings 2024年

作者： Marius Armand Amou Bouchaib Hartiti Ahmed Ziti Fransisco Kouadio Konan Abdelkrim Batan Hicham Labrim Laazizi Abdellah Boko Aka Philippe thevenin Laboratoire de Virologie Oncologie Biosciences Environnement et Energies Nouvelles (LVOBEEN) Groupe Matériaux Energie Eau Modélisation et Développement Durable (GMEEM & DD) FSTM Hassan II University of Casablanca (UH2C) BP 146 Mohammedia 20650 Morocco Laboratoire d’Energie Solaire et de Nanotechnologie (LESN) – IREN (Institut de Recherches sur les Energies Nouvelles) Université Nangui Abrogoua 02 BP 801 Abidjan 02 Ivory Coast West Africa Ecole Normale Superieure (ENS) d’Abidjan Laboratoire des Sciences Physiques Fondamentales et Appliquées 08 BP I0 Ivory Coast West Africa FST Errachidia Equipe Sciences des Materiaux University Moulay Ismail of Meknes BP 509 Boutalamine 52000 Errachidia Morocco Advanced Systems Engineering Laboratory National School of Applied Sciences Ibn Tofaîl University Kenitra Morocco Laboratory of Materials Metallurgy and Process Engineering ENSAM Meknes Morocco MOPS Laboratory University of Lorraine Centrale Supelec – 2 rue E. Belin B.P. 57070 Metz France

This work focuses on the development of Cu 2 ZnSnS 4 (CZTS) thin films by chemical sol gel via spin-coating for photovoltaic applications. CZTS thin films were developed using metal salts of copper II chloride dihydrate (CuCl 2 , 2H 2 O), zinc(II) chloride (ZnCl 2 ), tin II chloride dihydrate (SnCl 2 , 2H 2 O), and thiourea (CS(NH 2 ) 2 ) respectively as precursors of copper, zinc, tin and sulphur dissolved in a solvent consisting of a mixture of ethanol and distilled water (30 % ethanol and 70% water). Monoethanolamine (MEA) was used as a stabilising agent. The characterisation techniques used were X-ray diffraction (XRD), Raman spectroscopy and UV–visible spectroscopy (UV–vis). DRX analysis shows that the samples possess the CZTS kesterite phase with a preferential orientation in the (1 1 2) direction. This result is confirmed by the Raman spectrum of the samples. Optical characterisation indicates that the layers have a relatively high absorption coefficient (greater than 10 4 cm −1 ) in the visible spectrum with a gap energy equal to or close to the optimum value of 1.5 eV. These kesterite-type CZTS samples with good structural and optical properties are likely to fulfil sought-after functionalities as absorber layers for photovoltaic applications.

关键词： CZTS kesterite Sol-gel Spin-coating DRX UV–visible Raman

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Calculation of the temperature distribution in an asynchronous machine

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European Transactions on Electrical Power 1995年第3期5卷 181-186页

作者： Xypteras, J. Maras, K. Spyrelis, D. Associate Professor Dr.-Ing. Jannis Xypteras (1937) Director of the Electrical Machines Laboratory Dept. of Electrical Engineering Aristotle University of Thessaloniki (AUT)/Greece graduated from the Fakultatfur Elektrotechnik of the RWTH AachedGermany. During the years 1965 to 1980 he had been employed in German and Greek factories for electrical machines several years as chief of development departments. In 1978 he obtained his Dr. Electr. Eng. degree in the AUT. His subject was in the area of eddy currents. Since 1984 he is Ass. hofessor in the same University. His special interests: Design and development of electrical machines vibration and noise problems electromagnetic fields eddy currents. (Dept. of Electrical Engineering Aristotle University GR-54006 Thessaloniki/Greece T +30 3 1 I99 62 93 Fax +303 11 99 63 02) Kostas Maras (1966) received his degree in Electrical Engineering from the Electrotechnical Faculty of Aristotle University of Thessaloniki/Greece in 1989. In 1990 he graduated as M.Sc. in Digital Electronics in the King's College London at the University of LondordGB with the project “Design of a Transversal Filter on VLSI CMOS”. Since then he has been working at M. Papasavas S.A. at KallithedGreece as an analyst in developing industrial software. Projects: Design and implementation of a dynamic relational model used to tackle production problems in industry. From 1991 to 93 he was responsible for the development of production planning used in industries. (M. Papasavas S.A. Sofocleus 261 GR-17874 KallithedGreece T +30 119423246 Fax +30 1/9429561) Dimitrios S. Spyrelis (1965) received his Diploma in Electrical Engineering from the University of Thessalonikil Greece in 1989. In 1990 he joined the Coding Center of Greek Army as research Assistant. He is currently working as technical director in a pigpoultry breeding company which includes feed processing industry slaughter houses by product process industry wastes treatment systems from farm livestock. His last fields of interest

In this paper the temperature distribution on the section vertical to the axis of an asynchronous machine is calculated. For the calculation the numerical method of “control Volumes” has been used. The technique used can be easily modified to fit any kind of machine. It can also analyse transients. Copyright © 1995 John Wiley & Sons, Ltd.

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Roadmap for Optical Tweezers

arXiv

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arXiv 2022年

作者： Volpe, Giovanni Maragò, Onofrio M. Rubinzstein-Dunlop, Halina Pesce, Giuseppe Stilgoe, Alexander B. Volpe, Giorgio Tkachenko, Georgiy Truong, Viet Giang Chormaic, Síle Nic Kalantarifard, Fatemeh Elahi, Parviz Käll, Mikael Callegari, Agnese Marqués, Manuel I. Neves, Antonio A.R. Moreira, Wendel L. Fontes, Adriana Cesar, Carlos L. Saija, Rosalba Saidi, Abir Beck, Paul Eismann, Jörg S. Banzer, Peter Fernandes, Thales F.D. Pedaci, Francesco Bowen, Warwick P. Vaippully, Rahul Lokesh, Muruga Roy, Basudev Thalhammer, Gregor Ritsch-Marte, Monika García, Laura Pérez Arzola, Alejandro V. Castillo, Isaac Pérez Argun, Aykut Muenker, Till M. Vos, Bart E. Betz, Timo Cristiani, Ilaria Minzioni, Paolo Reece, Peter J. Wang, Fan McGloin, David Ndukaife, Justus C. Quidant, Romain Roberts, Reece P. Laplane, Cyril Volz, Thomas Gordon, Reuven Hanstorp, Dag Marmolejo, Javier Tello Bruce, Graham D. Dholakia, Kishan Li, Tongcang Brzobohatý, Oto Simpson, Stephen H. Zemánek, Pavel Ritort, Felix Roichman, Yael Bobkova, Valeriia Wittkowski, Raphael Denz, Cornelia Kumar, G.V. Pavan Foti, Antonino Donato, Maria Grazia Gucciardi, Pietro G. Gardini, L. Bianchi, G. Kashchuk, A. Capitanio, M. Paterson, Lynn Jones, P.H. Berg-Sørensen, Kirstine Barooji, Younes F. Oddershede, Lene B. Pouladian, Pegah Preece, Daryl Adiels, Caroline Beck De Luca, Anna Chiara Magazzù, A. Ciriza, D. Bronte Iatì, M.A. Swartzlander, Grover A. Department of Physics University of Gothenburg Gothenburg41296 Sweden CNR IPCF Istituto per i Processi Chimico-Fisici Messina Italy ARC CoE for Engineered Quantum Systems School of Mathematics and Physics The University of Queensland Australia Department of Chemistry University College London 20 Gordon Street LondonWC1H 0AJ United Kingdom Dipartimento di Fisica Università degli studi di Napoli Federico II Italy Okinawa Institute of Science and Technology Graduate University Japan Department of Health Technology Technical University of Denmark Lyngby Denmark Physics Department Boğaziçi University Istanbul Turkey Chalmers University of Technology Gothenburg Sweden Departamento de Física de Materiales IFIMAC Instituto Nicolás Cabrera Universidad Autónoma de Madrid Spain Santo André São Paulo Brazil Tratamento de dados geofísicos Tecnologia e processamento de geologia e geofísica Exploração Petrobras - Petróleo Brasileiro S.A. Rio de Janeiro Rio de Janeiro Brazil Pernambuco Recife Brazil Ceará Fortaleza Brazil Campinas São Paulo Brazil Dipartimento di Scienze Matematiche e Informatiche Scienze Fisiche e Scienze della Terra Università di Messina Italy Institute of Optics Information and Photonics University Erlangen-Nuremberg Staudtstr. 7/B2 ErlangenD-91058 Germany Max Planck Institute for the Science of Light Staudtstr. 2 ErlangenD-91058 Germany Institute of Physics University of Graz NAWI Graz Universitätsplatz 5 Graz8010 Austria Centre de Biologie Structurale CNRS INSERM Univ.Montpellier France Indian Institute of Technology Madras India Institute for Biomedical Physics Medical University of Innsbruck Austria Instituto de Física Universidad Nacional Autónoma de México Ciudad de MéxicoC. P. 04510 Mexico Departamento de Física Universidad Autónoma Metropolitana-Iztapalapa San Rafael Atlixco 186 Ciudad de México09340 Mexico Third Institute of Physics - Biophysics Georg August University Göttingen Germany Department of Electrical

Optical tweezers are tools made of light that enable contactless pushing, trapping, and manipulation of objects ranging from atoms to space light sails. Since the pioneering work by Arthur Ashkin in the 1970s, optical tweezers have evolved into sophisticated instruments and have been employed in a broad range of applications in life sciences, physics, and engineering. These include accurate force and torque measurement at the femtonewton level, microrheology of complex fluids, single micro- and nanoparticle spectroscopy, single-cell analysis, and statistical-physics experiments. This roadmap provides insights into current investigations involving optical forces and optical tweezers from their theoretical foundations to designs and setups. It also offers perspectives for applications to a wide range of research fields, from biophysics to space exploration. Copyright © 2022, The Authors. All rights reserved.

关键词： Optical tweezers

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THE AMERICAN SOCIETY OF NAVAL ENGINEERS takes great pleasure in presenting: THE GOLD MEDAL AWARD FOR 1991

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Naval Engineers Journal 1992年第4期104卷

作者： CAPTAIN CLARK GRAHAM USN Captain Clark “Corky” Graham throughout his naval career has been a major force in the pursuit of a technology-based vision of the Navy of the future and the development of an engineering bridge to turn the vision into a reality. After an already distinguished naval career he was assigned to NavSea as Ship Design Manager and Technical Director for the Navy's newest destroyer the USSArleigh Burke(DDG-51). He was a major contributor to the many technical innovations that made this ship one of the most effective combatants in the Fleet. Upon return to MIT as a teacher and head of the Navy Program he continued to espouse the virtues of systems engineering instilling in his students the need to continually question old paradigms and to examine and assess the merits of new and innovative approaches to ship design. During his tour as Commander of the David Taylor Research Center he established a broad-based strategic planning process for exploring technology options and issues for the fleet of the future. He stimulated the Center's technologists and managers to challenge current paradigms and to make ships and ship systems more affordable without sacrifice in mission capabilities. He provided a collaborative systems oriented culture that addressed long range fleet operational and affordability goals. This led to the development of a battleforce design incorporating a multi-purpose modular ship concept called Carrier of Large Objects (CLO) double-hull structural concepts and an emphasis on technologies and processes to enhance the affordability of future ships. He also waged a successful campaign to convince higher authority of the merits of an integrated electric drive for ships. This ultimately led to his present assignment as Manager of NavSea's Advanced Surface Ship Machinery Program. Capt. Graham has laid a technological foundation for the Navy to meet the challenges of the future in a world of profound geopolitical change. Perhaps of even greater importance he articulated his ideas and philosophy to a

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Lattice Compression Revealed at the ≈1 nm Scale

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Angewandte Chemie 2023年第39期135卷

作者： Ziwei Xu Hongwei Dong Dr. Wanmiao Gu Dr. Zhen He Fengming Jin Dr. Chengming Wang Dr. Qing You Prof. Dr. Jin Li Prof. Dr. Haiteng Deng Dr. Lingwen Liao Dr. Dong Chen Prof. Dr. Jun Yang Prof. Dr. Zhikun Wu Key Laboratory of Materials Physics Anhui Key Laboratory of Nanomaterials and Nanotechnology CAS Center for Excellence in Nanoscience Institute of Solid State Physics HFIPS Chinese Academy of Sciences Hefei Anhui 230031 P. R. China University of Science and Technology of China Hefei 230026 P. R. China Institute of Physical Science and Information Technology Anhui University Hefei 230601 P. R. China Department of Chemistry City University of Hong Kong and Hong Kong Branch of National Precious Metals Material Engineering Research Center (NPMM) Hong Kong 999077 P. R. China Instruments' Center for Physical Science University of Science and Technology of China Hefei 230026 P. R. China Tsinghua University-Peking University Joint Center for Life Sciences School of Life Sciences Tsinghua University Beijing 100084 P. R. China MOE Key Laboratory of Bioinformatics School of Life Sciences Tsinghua University Beijing 100084 P. R. China State Key Laboratory of Multiphase Complex Systems Institute of Process Engineering Chinese Academy of Sciences Beijing 100190 P. R. China

Lattice tuning at the ≈1 nm scale is fascinating and challenging; for instance, lattice compression at such a minuscule scale has not been observed. The lattice compression might also bring about some unusual properties, which waits to be verified. Through ligand induction, we herein achieve the lattice compression in a ≈1 nm gold nanocluster for the first time, as detected by the single-crystal X-ray crystallography. In a freshly synthesized Au 52 (CHT) 28 (CHT=S- c −C 6 H 11 ) nanocluster, the lattice distance of the (110) facet is found to be compressed from 4.51 to 3.58 Å at the near end. However, the lattice distances of the (111) and (100) facets show no change in different positions. The lattice-compressed nanocluster exhibits superior electrocatalytic activity for the CO 2 reduction reaction (CO 2 RR) compared to that exhibited by the same-sized Au 52 (TBBT) 32 (TBBT=4- tert -butyl-benzenethiolate) nanocluster and larger Au nanocrystals without lattice variation, indicating that lattice tuning is an efficient method for tailoring the properties of metal nanoclusters. Further theoretical calculations explain the high CO 2 RR performance of the lattice-compressed Au 52 (CHT) 28 and provide a correlation between its structure and catalytic activity.

关键词： CO2 Reduction Gold Heterogeneous Catalysis Lattice Compression Nanoclusters

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Correction: Additive-mediated intercalation and surface modification of MXenes

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Chemical Society reviews 2022年第8期51卷 3314页

作者： Jing Zou Jing Wu Yizhou Wang Fengxia Deng Jizhou Jiang Yizhou Zhang Song Liu Neng Li Han Zhang Jiaguo Yu Tianyou Zhai Husam N Alshareef School of Environmental Ecology and Biological Engineering School of Chemistry and Environmental Engineering Key Laboratory of Green Chemical Engineering Process of Ministry of Education Engineering Research Center of Phosphorus Resources Development and Utilization of Ministry of Education Wuhan Institute of Technology Wuhan Hubei 430205 P. R. China. 027wit@***. Key Laboratory of Rare Mineral Ministry of Natural Resources Geological Experimental Testing Center of Hubei Province Wuhan Hubei 430034 P. R. China. Physical Science and Engineering Division Materials Science & Engineering King Abdullah University of Science and Technology (KAUST) Thuwal 23955-6900 Kingdom of Saudi Arabia. husam.alshareef@kaust.edu.sa. State Key Laboratory of Urban Water Resources and Environment School of Environment Harbin Institute of Technology Harbin 150090 P. R. China. Institute of Advanced Materials and Flexible Electronics (IAMFE) School of Chemistry and Materials Science Nanjing University of Information Science & Technology Nanjing 210044 P. R. China. yizhou.zhang@***. Key Laboratory for Organic Electronics & Information Displays and Institute of Advanced Materials Nanjing University of Posts and Telecommunications Nanjing 210023 P. R. China. Institute of Chemical Biology and Nanomedicine (ICBN) State Key Laboratory of Chemo/Biosensing and Chemometrics College of Chemistry and Chemical Engineering Hunan University Changsha 410082 P. R. China. State Key Laboratory of Advanced Technology for Materials Synthesis and Processing State Key Laboratory of Silicate Materials for Architectures Wuhan University of Technology Wuhan Hubei 430070 P. R. China. Shenzhen Engineering Laboratory of Phosphorene and Optoelectronics and Key Laboratory of Optoelectronic Devices and Systems of Ministry of Education and Guangdong Province Shenzhen University Shenzhen 518060 P. R. China. State Key Laboratory of Material Processing and Die & Mould Technology School of Materials Science and Engineering H

Correction for 'Additive-mediated intercalation and surface modification of MXenes' by Jing Zou , , 2022, DOI: 10.1039/d0cs01487g.

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A NEURO-FUZZY SYSTEM DESIGN METHODOLOGY FOR VIBRATION control

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Asian Journal of control 2008年第4期7卷

作者： S. M. Yang Y. J. Tung Y. C. Liu Shih-Ming Yang:has been with the Institute of Aeronautics and Astronautics National Cheng Kung University Taiwan since 1989. He received Ph.D. degree from University of California at Berkeley U.S.A. His current interests are smart structure systems system identification and intelligent controller design in digital signal processor and digital watermarking. Yu-Ju Tung:received B.S. and M.S. in Aeronautics and Astronautics from the National Cheng Kung University Taiwan in 1999 and 2001. Her research interests have been in Digital Signal Processing of computer peripherals. She is currently a Firmware Engineer on wireless applications in Syntech Information Co. in Taiwan. Department of Information Management Tainan Woman's College of Arts and Technology Taiwan R.O.C. Yu-Chuan Liu:is an Assistant Professor in the Department of Information Management at Tainan Women's University. Dr. Liu received his Ph.D. in Aeronautics and Astronautics from the National Cheng Kung University of Taiwan in 1993 and served as the R&D manager and vice-president in mechanical and optoelectronics industries. Dr. Liu joined the faulty in 2002 and his research interests are in process control and management information system computer-integrated manufacturing (CIM) and e-Business. Dr. Liu has published more than 25 technical articles in this area.

Fuzzy system has been known to provide a framework for handling uncertainties and imprecision by taking linguistic information from human experts. However, difficulties arise in determining effectively the fuzzy system configuration, i.e. , the number of rules, input and output membership functions. A neuro-fuzzy system design methodology by combining neural network and fuzzy logic is developed in this paper to adaptively adjust the fuzzy membership functions and dynamically optimize the linguistic-fuzzy rules. The structure of a five-layer feedforward network is shown to determine systematically the correct fuzzy logic rules, tune optimally (in the sense of local region) the parameters of the membership functions, and perform accurately the fuzzy inference. It is shown both numerically and experimentally that engineering applications of the neuro-fuzzy system to vibration control have been very successful.

关键词： Neural network fuzzy logic vibration control.

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HIGH‐ACCURACY MARINE NAVIGATION WITH THE “BOTTLED STAR”

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Naval Engineers Journal 1964年第4期76卷 569-576页

作者： WEEMS, P.V.H. BENFIELD, CHARLES W. USN (Ret.) Captain Phillip Van Horn Weems USN Retired is the co-founder of the American Institute of Navigation a man whose name is referenced nine times in the index of “Bowditch” hardly needs an introduction in a navigation journal. Captain Weems has been a rallying point and idea innovator in marine navigation for over half a century. He is chairman of the board and technical mentor of Weems System of Navigation Inc. internationally known supplier of courses books instruments and charts at Annapolis Maryland. Captain Weems' books and inventions may be found in the chart room of nearly every English speaking country's vessels as well as those of many other nations. He has recently devoted enthusiastic attention to improving the accuracy and convenience of the navigator's tools by applying some of the advances of modern aerospace and electronics technology. Born in Montgomery County Tennessee 29 March 1889 he was graduated from the U.S. Navy Academy in 1912. His honors and awards include: Bronze Star Gold Medal Aero Club of France Royal Society of Arts Award for second setting watch Magellanic Premium from American Philosophical Society Gold Medal from British Institute of Navigation and Thurlow Award American Institute of Navigation. He holds seven patents in navigation and has written many textbooks and papers. He was on the 1920 Olympic Wrestling team as well as being a former All American Team member after his accomplishments on the Navy football team. Charles W. Benfield is a Senior Development Engineer in the Systems section of Honeywell's Aero Division Florida facility at St. Petersburg. He received his degree in Electrical Engineering at the University of Florida in 1948. A former regular navy man with six years sea duty and flying he has been actively interested in the art of way finding for over 20 years. Presently he is actively working to apply the company's capabilities to automation of the marine navigation process but he also has been active in studies of manual space navig

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State of the art of performance evaluation methods for concentrating solar collectors

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AIP Conference Proceedings 2016年第1期1734卷

作者： Annie Hofer Loreto Valenzuela Nicole Janotte Juan Ignacio Burgaleta Jaime Arraiza Marco Montecchi Fabienne Sallaberry Tiago Osório Maria João Carvalho Fabrizio Alberti Korbinian Kramer Anna Heimsath Werner Platzer Stephan Scholl 1Dipl.-Ing. Scientific Researcher Fraunhofer Institute for Solar Energy Systems ISE Heidenhofstr. 2 79110 Freiburg Germany 2CIEMAT – Plataforma Solar de Almería Crta. Senes km. 4.5 04200 Tabernas (Almería) Spain 3German Aerospace Center (DLR) Linder Hohe 51147 Cologne Germany 4SENER Engineering Division Adva. Zugazarte 56 48930 Las Arenas Bizkaia Spain 5Acciona Energía S.A. Avda. Ciudad de la Innovación N° 5 31621 Sarriguren Navarra Spain 6Researcher Physicist ENEA CR Casaccia Via Anguillarese 301 00123 S. Maria di Galeria (Roma) Italy 7National Renewable Energy Centre of Spain (CENER) Solar Thermal Energy Department Ciudad de la Innovación 7 31621 Sarriguren Navarra Spain 8University of Évora – ST Renewable Energies Chair Palácio do Vimioso Largo Marquês de Marialva 7002-554 Évora Portugal 9Senior Researcher LNEG Laboratório Nacional de Energia e Geologia Estrada do Paço do Lumiar 22 1649-038 Lisboa Portugal 10Fondazione Bruno Kessler ARES Unit Via alla Cascata 56/C 38123 Trento Italy 11Scientific Researchers Fraunhofer ISE Heidenhofstr. 2 79110 Freiburg Germany 12Prof. Dr.-Ing. Head of Institute for Chemical and Thermal Process Engineering ICTV Technical University Braunschweig Langer Kamp 7 38106 Braunschweig Germany

For the development and establishment of concentrating solar thermal collectors a reliable and comparable performance testing and evaluation is of great importance. To ensure a consistent performance testing in the area of low- temperature collectors a widely accepted and commonly used international testing standard (ISO 9806:2013) is already available. In contrast to this, the standard ISO 9806:2013 has not completely penetrated the testing sector of concentrating collectors yet. On that account a detailed literature review has been performed on published testing procedures and evaluation methodologies as well as existing testing standards. The review summarizes characteristics of the different steady-state, quasi-dynamic and fully dynamic testing methods and presents current advancements, assets and drawbacks as well as limitations of the evaluation procedures. Little research is published in the area of (quasi-) dynamic testing of large solar collectors and fields. As a complementary a survey has been conducted focusing on currently implemented evaluation procedures in this particular field. Among the ten participants of the survey were project partners of relevant industry and research institutions within the European project STAGE-STE (Work package 11 - Linear focusing STE technologies). The survey addressed general aspects of the systems under test, as well as required process conditions and detailed characteristics of the evaluation procedures. In congruence with the literature review, the survey shows a similar tendency: the quasi-dynamic testing method according ISO 9806:2013 presents the most common and advanced evaluation procedure mainly used in the context of tracking concentrating collectors for the performance assessment of parabolic trough collectors operating with thermal oil or pressurized water. These common solar systems can be evaluated with minor adaptions to the testing standard. Evaluation procedures focused on in-situ measurements in solar f

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Corrigendum to "Enantiomeric profiling of quinolones and quinolones resistance gene qnrS in European wastewaters" [Water Res. 175 (2020) 115653]

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Water research 2020年 182卷 116345页

作者： Erika Castrignano Zhugen Yang Edward J Feil Richard Bade Sara Castiglioni Ana Causanilles Emma Gracia-Lor Felix Hernandez Benedek G Plόszi Pedram Ramin Nikolaos I Rousis Yeonsuk Ryu Kevin V Thomas Pim de Voogt Ettore Zuccato Barbara Kasprzyk-Hordern Department of Chemistry Faculty of Science University of Bath Bath BA2 7AY United Kingdom Department of Analytical Environmental & Forensic Sciences School of Population Health & Environmental Sciences King's College London London SE1 9NH United Kingdom. School of Water Energy and Environment Cranfield University Cranfield MK43 0AL United Kingdom. Department of Biology and Biochemistry University of Bath Bath BA27AY United Kingdom. Research Institute for Pesticides and Water University Jaume I Avda. Sos Baynat s/n E-12071 Castellón Spain School of Pharmacy and Medical Sciences University of South Australia Adelaide South Australia 5000 Australia. Institute for Biodiversity and Ecosystem Dynamics University of Amsterdam P.O. Box 94248 1090 GE Amsterdam the Netherlands. KWR Watercycle Research Institute Chemical Water Quality and Health P.O. Box 1072 3430 BB Nieuwegein the Netherlands Istituto di Ricerche Farmacologiche Mario Negri IRCCS Department of Environmental Health Sciences Via La Masa 19 20156 Milan Italy Department of Analytical Chemistry Faculty of Chemistry Complutense University of Madrid Avenida Complutense s/n Madrid Spain. Department of Chemical Engineering University of Bath Claverton Down Bath BA2 7AY United Kingdom. Department of Environmental Engineering Technical University of Denmark Bygningstorvet Building 115 2800 Kgs. Lyngby Denmark Process and Systems Engineering Center (PROSYS) Department of Chemical and Biochemical Engineering Technical University of Denmark Building 229 2800 Kgs. Lyngby Denmark. Norwegian Institute for Water Research (NIVA) Gaustadalléen 21 0349 Oslo Norway. Norwegian Institute for Water Research (NIVA) Gaustadalléen 21 0349 Oslo Norway Queensland Alliance for Environmental Health Science (QAEHS) University of Queensland 20 Cornwall Street Woolloongabba QLD 4102 Australia. IBED-University of Amsterdam the Netherlands. Department of Chemistry Faculty of Science University of Bath Bath BA

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