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arXiv 2019年

作者： Sriram, Praveen Kalantre, Sandesh S. Gharavi, Kaveh Baugh, Jonathan Muralidharan, Bhaskaran Department of Electrical Engineering Indian Institute of Technology Bombay Powai Mumbai400076 India Department of Physics Indian Institute of Technology Bombay Powai Mumbai400076 India Institute for Quantum Computing University of Waterloo WaterlooONN2L 3G1 Canada Department of Physics and Astronomy University of Waterloo WaterlooONN2L 3G1 Canada Department of Chemistry University of Waterloo WaterlooONN2L 3G1 Canada

Semiconductor-superconductor hybrid systems provide a promising platform for hosting unpaired Majorana fermions towards the realisation of fault-tolerant topological quantum computing. In this study, we employ the Keldysh Non-Equilibrium Green’s function formalism to model quantum transport in normal-superconductor junctions. We analyze III-V semiconductor nanowire Josephson junctions (InAs/Nb) using a three-dimensional discrete lattice model described by the Bogoliubov-de Gennes Hamiltonian in the tight-binding approximation, and compute the Andreev bound state spectrum and current-phase relations. Recent experiments [Zuo et al., Phys. Rev. Lett. 119,187704 (2017)] and [Gharavi et al., arXiv:1405.7455v2 (2014)] reveal critical current oscillations in these devices, and our simulations confirm these to be an interference effect of the transverse sub-bands in the nanowire. We add disorder to model coherent scattering and study its effect on the critical current oscillations, with an aim to gain a thorough understanding of the experiments. The oscillations in the disordered junction are highly sensitive to the particular realisation of the random disorder potential, and to the gate voltage. A macroscopic current measurement thus gives us information about the microscopic profile of the junction. Finally, we study dephasing in the channel by including elastic phase-breaking interactions. The oscillations thus obtained are in good qualitative agreement with the experimental data, and this signifies the essential role of phase-breaking processes in III-V semiconductor nanowire Josephson junctions. Copyright © 2019, The Authors. All rights reserved.

关键词： III-V semiconductors

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Dynamics and density correlations in matter wave jet emission of a driven condensate

arXiv

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arXiv 2018年

作者： Wu, Zhigang Zhai, Hui Shenzhen Institute for Quantum Science and Engineering Department of Physics Southern University of Science and Technology Shenzhen518055 China Center for Quantum Computing Peng Cheng Laboratory Shenzhen518055 China Institute for Advanced Study Tsinghua University Beijing100084 China

Emission of matter wave jets has been recently observed in a Bose-Einstein condensate confined by a cylindrical box potential, induced by a periodically modulated inter-particle interaction (Nature 551, 356 (2017)). In this paper we apply the time-dependent Bogoliubov theory to study the quantum dynamics and the correlation effects observed in this highly non-equilibrium phenomenon. Without any fitting parameter, our theoretical calculations on the number of ejected atoms and the angular density correlations are in excellent quantitative agreement with the experimental measurements. The exponential growth in time of the ejected atoms can be understood in terms of a dynamical instability associated with the modulation of the interaction. We interpret the angular density correlation of the jets as the Hanbury-Brown-Twiss effect between the excited quasi-particles with different angular momenta, and our theory explains the puzzling observation of the asymmetric density correlations between the jets with the same and opposite momenta. Our theory can also identify the main factors that control the height and width of the peaks in the density correlation function, which can be directly verified in future experiments. Copyright © 2018, The Authors. All rights reserved.

关键词： Bose-Einstein condensation

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Erratum: Towards a muon collider

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The European Physical Journal C 2024年第1期84卷 1-4页

作者： Accettura, Carlotta Adams, Dean Agarwal, Rohit Ahdida, Claudia Aimè, Chiara Amapane, Nicola Amorim, David Andreetto, Paolo Anulli, Fabio Appleby, Robert Apresyan, Artur Apyan, Aram Arsenyev, Sergey Asadi, Pouya Mahmoud, Mohammed Attia Azatov, Aleksandr Back, John Balconi, Lorenzo Bandiera, Laura Barlow, Roger Bartosik, Nazar Barzi, Emanuela Batsch, Fabian Bauce, Matteo Berg, J. Scott Bersani, Andrea Bertarelli, Alessandro Bertolin, Alessandro Black, Kevin Boattini, Fulvio Bogacz, Alex Bonesini, Maurizio Bordini, Bernardo Bottaro, Salvatore Bottura, Luca Braghieri, Alessandro Breschi, Marco Bruhwiler, Natalie Buffat, Xavier Buonincontri, Laura Burrows, Philip N. Burt, Graeme Buttazzo, Dario Caiffi, Barbara Calviani, Marco Calzaferri, Simone Calzolari, Daniele Capdevilla, Rodolfo Carli, Christian Casaburo, Fausto Casarsa, Massimo Castelli, Luca Catanesi, Maria Gabriella Cavallucci, Lorenzo Cavoto, Gianluca Celiberto, Francesco Giovanni Celona, Luigi Cerri, Alessandro Cesarini, Gianmario Cesarotti, Cari Chachamis, Grigorios Chance, Antoine Chen, Siyu Chien, Yang-Ting Chiesa, Mauro Colaleo, Anna Collamati, Francesco Collazuol, Gianmaria Costa, Marco Craig, Nathaniel Curatolo, Camilla Curtin, David Da Molin, Giacomo Dam, Magnus Damerau, Heiko Dasu, Sridhara de Blas, Jorge De Curtis, Stefania De Matteis, Ernesto De Rosa, Stefania Delahaye, Jean-Pierre Denisov, Dmitri Denizli, Haluk Densham, Christopher Dermisek, Radovan Di Luzio, Luca Di Meco, Elisa Di Micco, Biagio Dienes, Keith Diociaiuti, Eleonora Dorigo, Tommaso Dudarev, Alexey Edgecock, Robert Errico, Filippo Fabbrichesi, Marco Farinon, Stefania Ferrari, Anna Somoza, Jose Antonio Ferreira Filthaut, Frank Fiorina, Davide Fol, Elena Forslund, Matthew Franceschini, Roberto Ximenes, Rui Franqueira Gabrielli, Emidio Gallinaro, Michele Garosi, Francesco Giambastiani, Luca Gianelle, Alessio Gilardoni, Simone Giove, Dario Augusto Giraldin, Carlo Glioti, Alfredo Greco, Mario Greljo, Admir Groeber, Ramona Grojean, Christophe Grudiev, Alexej Gu, Jiayin Han, Chengcheng Han, T Organisation Européenne pour la Recherche Nucléaire (CERN) Geneva Switzerland STFC Rutherford Appleton Laboratory (RAL) Oxford UK Computer Science Department University of California (UC) Berkeley USA Dipartimento di Fisica Università di Pavia Pavia Italy INFN Sezione di Pavia Pavia Italy INFN Sezione di Torino Turin Italy Dipartimento di Fisica Università di Torino Turin Italy INFN Sezione di Padova Padua Italy INFN Sezione di Roma Rome Italy School of Physics and Astronomy University of Manchester Manchester UK Fermi National Accelerator Laboratory Batavia USA Department of Physics Brandeis University Waltham USA IRFU CEA University Paris-Saclay Gif-sur-Yvette France Center for Theoretical Physics Massachusetts Institute of Technology Cambridge USA Center for High Energy Physics (CHEP-FU) Fayoum University El-Fayoum Egypt SISSA International School for Advanced Studies Trieste Italy INFN Sezione di Trieste Trieste Italy Department of Physics University of Warwick Coventry UK Dipartimento di Fisica Università di Milano Milan Italy INFN Laboratori Acceleratori e Superconduttività Applicata (LASA) Milan Italy INFN Sezione di Ferrara Ferrara Italy School of Computing and Engineering The University of Huddersfield Huddersfield UK Ohio State University Columbus USA Brookhaven National Laboratory Upton USA INFN Sezione di Genova Genoa Italy University of Wisconsin Wisconsin USA Center for Advanced Studies of Accelerators Jefferson Lab Newport News USA INFN Sezione di Milano Bicocca Milan Italy Dipartimento di Fisica Università di Milano Bicocca Milan Italy Scuola Normale Superiore Pisa Italy INFN Sezione di Pisa Pisa Italy Dipartimento di Ingegneria dell’Energia Elettrica e dell’Informazione Università di Bologna Bologna Italy INFN Sezione di Bologna Bologna Italy Department of Physics University of California (UC) Berkeley USA Dipartimento di Fisica e Astronomia Università di Padova Padoa Italy John Adams Institute University of O

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Joint measurement of the 235U antineutrino spectrum by PROSPECT and STEREO

arXiv

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arXiv 2021年

作者： Almazán, H. Andriamirado, M. Balantekin, A.B. Band, H.R. Bass, C.D. Bergeron, D.E. Bernard, L. Blanchet, A. Bonhomme, A. Bowden, N.S. Bryan, C.D. Buck, C. Classen, T. Conant, A.J. Deichert, G. Del Amo Sanchez, P. Delgado, A. Diwan, M.V. Dolinski, M.J. El Atmani, I. Erickson, A. Foust, B.T. Gaison, J.K. Galindo-Uribarri, A. Gilbert, C.E. Hans, S. Hansell, A.B. Heeger, K.M. Heffron, B. Jaffe, D.E. Jayakumar, S. Ji, X. Jones, D.C. Koblanski, J. Kyzylova, O. Labit, L. Lamblin, J. Lane, C.E. Langford, T.J. LaRosa, J. Letourneau, A. Lhuillier, D. Licciardi, M. Lindner, M. Littlejohn, B.R. Lu, X. Maricic, J. Materna, T. Mendenhall, M.P. Meyer, A.M. Milincic, R. Mueller, P.E. Mumm, H.P. Napolitano, J. Neilson, R. Nikkel, J.A. Nour, S. Palomino, J.L. Pessard, H. Pushin, D.A. Qian, X. Réal, J.-S. Ricol, J.-S. Roca, C. Rogly, Rudolph Rosero, R. Salagnac, T. Savu, V. Schoppmann, S. Searles, M. Sergeyeva, V. Soldner, T. Stutz, A. Surukuchi, P.T. Tyra, M.A. Varner, R.L. Venegas-Vargas, D. Vialat, M. Weatherly, P.B. White, C. Wilhelmi, J. Woolverton, A. Yeh, M. Zhang, C. Zhang, X. Max-Planck-Institut für Kernphysik Saupfercheckweg 1 Heidelberg69117 Germany Department of Physics Illinois Institute of Technology ChicagoIL United States Department of Physics University of Wisconsin MadisonWI United States Wright Laboratory Department of Physics Yale University New HavenCT United States Department of Physics Le Moyne College SyracuseNY United States National Institute of Standards and Technology GaithersburgMD United States Univ. Grenoble Alpes CNRS Grenoble INP LPSC-IN2P3 Grenoble38000 France IRFU CEA Université Paris-Saclay Gif-sur-Yvette91191 France Nuclear and Chemical Sciences Division Lawrence Livermore National Laboratory LivermoreCA United States High Flux Isotope Reactor Oak Ridge National Laboratory Oak RidgeTN United States Univ. Grenoble Alpes Université Savoie Mont Blanc CNRS IN2P3 LAPP Annecy74000 France Physics Division Oak Ridge National Laboratory Oak RidgeTN United States Department of Physics and Astronomy University of Tennessee KnoxvilleTN United States Brookhaven National Laboratory UptonNY United States Department of Physics Drexel University PhiladelphiaPA United States George W. Woodruff School of Mechanical Engineering Georgia Institute of Technology AtlantaGA United States Department of Physics Temple University PhiladelphiaPA United States Department of Physics & Astronomy University of Hawaii HonoluluHI United States Institute for Quantum Computing Department of Physics and Astronomy University of Waterloo WaterlooON Canada Institut Laue-Langevin CS 20156 Grenoble Cedex 938042 France

The PROSPECT and STEREO collaborations present a combined measurement of the pure 235U antineutrino spectrum, without site specific corrections or detector-dependent effects. The spectral measurements of the two highest precision experiments at research reactors are found to be compatible with χ2/ndf = 24:1/21, allowing a joint unfolding of the prompt energy measurements into antineutrino energy. This νeenergy spectrum is provided to the community, and an excess of events relative to the Huber model is found in the 5-6 MeV region. When a Gaussian bump is fitted to the excess, the data-model χ2value is improved, corresponding to a 2.4σ significance. Copyright © 2021, The Authors. All rights reserved.

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Photonic quantum data locking

arXiv

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arXiv 2019年

作者： Huang, Zixin Rohde, Peter P. Berry, Dominic W. Kok, Pieter Dowling, Jonathan P. Lupo, Cosmo Department of Physics & Astronomy University of Sheffield United Kingdom Faculty of Engineering & Information Technology University of Technology SydneyNSW2007 Australia Department of Physics and Astronomy Macquarie University SydneyNSW2109 Australia Hearne Institute for Theoretical Physics Department of Physics & Astronomy Louisiana State University Baton RougeLA70803 United States National Institute of Information and Communications Technology 4-2-1 Nukui-Kitamachi Koganei Tokyo184-8795 Japan NYU-ECNU Institute of Physics NYU Shanghai Shanghai200062 China CAS-Alibaba Quantum Computing Laboratory USTC Shanghai201315 China

1 quantum data locking is a quantum phenomenon that allows us to encrypt a long message with a small secret key with information-theoretic security. This is in sharp contrast with classical information theory where, according to Shannon, the secret key needs to be at least as long as the message. Here we explore photonic architectures for quantum data locking, where information is encoded in multi-photon states and processed using multi-mode linear optics and photo-detection, with the goal of extending an initial secret key into a longer one. The secret key consumption depends on the number of modes and photons employed. In the no-collision limit, where the likelihood of photon bunching is suppressed, the key consumption is shown to be logarithmic in the dimensions of the system. Our protocol can be viewed as an application of the physics of Boson Sampling to quantum cryptography. Experimental realisations are challenging but feasible with state-of-the-art technology, as techniques recently used to demonstrate Boson Sampling can be adapted to our scheme (e.g., Phys. Rev. Lett. 123, 250503, 2019). © 2019, CC BY-NC-ND.

关键词： Bosons

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Experimental Evidence of the Topological Surface States in Mg3Bi2 Films Grown by Molecular Beam Epitaxy

arXiv

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arXiv 2019年

作者： Zhou, Tong Zhu, Xie-Gang Tong, Mingyu Zhang, Yun Luo, Xue-Bing Xie, Xiangnan Feng, Wei Chen, Qiuyun Tan, Shiyong Wang, Zhen-Yu Jiang, Tian Lai, Xin-Chun Yang, Xuejun State Key Laboratory of High Performance Computing College of Computer National University of Defense Technology Changsha410073 China Science and Technology on Surface Physics and Chemistry Laboratory Jiangyou Sichuan621908 China National Innovation Institute of Defense Technology Academy of Military Sciences PLA China Beijing100010 China Institute of Materials China Academy of Engineering Physics Mianyang Sichuan621700 China College of Advanced Interdisciplinary Studies National University of Defense Technology Changsha410073 China Academy of Military Sciences PLA China Beijing100010 China Beijing Academy of Quantum Information Sciences Beijing100084 China

Type-II nodal line semimetal (NLS) is a new quantum state hosting one-dimensional closed loops formed by the crossing of two bands which have the same sign in their slopes along the radial direction of the loop. According to the theoretical prediction, Mg3Bi2 is an ideal candidate for studying the type-II NLS by tuning its spin-orbit coupling (SOC). In this paper, high quality Mg3Bi2 films are grown by molecular beam epitaxy (MBE). By in-situ angle resolved photoemission spectroscopy (ARPES), a pair of surface resonance bands (SRBs) around point is clearly seen. It shows that Mg3Bi2 films grown by MBE is Mg(1)-terminated by comparing the ARPES data with the first principles calculations results. And, the temperature dependent weak anti-localization (WAL) effect in Mg3Bi2 films is observed under low magnetic field, which shows a clear two dimensional (2D) e-e scattering characteristics by fitting with the Hikami-Larkin-Nagaoka (HLN) model. Combining with ARPES, magneto-transport measurements and the first principles calculations, this work proves that Mg3Bi2 is a semimetal with topological surface states TSSs, which paves the way for Mg3Bi2 as an ideal materials platform for studying the exotic features of type-II nodal line semimetals (NLSs) and the topological phase transition by tuning its SOC. Copyright © 2019, The Authors. All rights reserved.

关键词： Binary alloys

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Nonfuel antineutrino contributions in the ORNL High Flux Isotope Reactor (HFIR)

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Physical Review C 2020年第5期101卷 054605-054605页

作者： A. B. Balantekin H. R. Band C. D. Bass D. E. Bergeron D. Berish N. S. Bowden J. P. Brodsky C. D. Bryan T. Classen A. J. Conant G. Deichert M. V. Diwan M. J. Dolinski A. Erickson B. T. Foust J. K. Gaison A. Galindo-Uribarri C. E. Gilbert B. T. Hackett S. Hans A. B. Hansell K. M. Heeger B. Heffron D. E. Jaffe X. Ji D. C. Jones O. Kyzylova C. E. Lane T. J. Langford J. LaRosa B. R. Littlejohn X. Lu J. Maricic M. P. Mendenhall R. Milincic I. Mitchell P. E. Mueller H. P. Mumm J. Napolitano R. Neilson J. A. Nikkel D. Norcini S. Nour J. L. Palomino-Gallo D. A. Pushin X. Qian E. Romero-Romero R. Rosero P. T. Surukuchi M. A. Tyra R. L. Varner C. White J. Wilhelmi A. Woolverton M. Yeh A. Zhang C. Zhang X. Zhang Department of Physics University of Wisconsin Madison Madison Wisconsin 53706 USA Wright Laboratory Department of Physics Yale University New Haven Connecticut 06520 USA Department of Physics Le Moyne College Syracuse New York 13214 USA National Institute of Standards and Technology Gaithersburg Maryland 20899 USA Department of Physics Temple University Philadelphia Pennsylvania 19122 USA Nuclear and Chemical Sciences Division Lawrence Livermore National Laboratory Livermore California 94550 USA High Flux Isotope Reactor Oak Ridge National Laboratory Oak Ridge Tennessee 37830 USA George W. Woodruff School of Mechanical Engineering Georgia Institute of Technology Atlanta Georgia 30332 USA Brookhaven National Laboratory Upton New York 11973 USA Department of Physics Drexel University Philadelphia Pennsylvania 19104 USA Physics Division Oak Ridge National Laboratory Oak Ridge Tennessee 37830 USA Department of Physics and Astronomy University of Tennessee Knoxville Tennessee 37996 USA Department of Physics Illinois Institute of Technology Chicago Illinois 60616 USA Department of Physics & Astronomy University of Hawaii Honolulu Hawaii 96822 USA Institute for Quantum Computing and Department of Physics and Astronomy University of Waterloo Waterloo Ontario N2L 3G1 Canada

Reactor neutrino experiments have seen major improvements in precision in recent years. With the experimental uncertainties becoming lower than those from theory, carefully considering all sources of ν¯e is important when making theoretical predictions. One source of ν¯e that is often neglected arises from the irradiation of the nonfuel materials in reactors. The ν¯e rates and energies from these sources vary widely based on the reactor type, configuration, and sampling stage during the reactor cycle and have to be carefully considered for each experiment independently. In this article, we present a formalism for selecting the possible ν¯e sources arising from the neutron captures on reactor and target materials. We apply this formalism to the High Flux Isotope Reactor (HFIR) at Oak Ridge National Laboratory, the ν¯e source for the the Precision Reactor Oscillation and Spectrum Measurement (PROSPECT) experiment. Overall, we observe that the nonfuel ν¯e contributions from HFIR to PROSPECT amount to 1% above the inverse β decay threshold with a maximum contribution of 9% in the 1.8–2.0 MeV range. Nonfuel contributions can be particularly high for research reactors like HFIR because of the choice of structural and reflector material in addition to the intentional irradiation of target material for isotope production. We show that typical commercial pressurized water reactors fueled with low-enriched uranium will have significantly smaller nonfuel ν¯e contribution.

关键词： Neutrino oscillations Neutron physics Nucleus-neutrino interactions Theory, design & simulation of reactors Monte Carlo methods Nuclear reactions Nuclear structure & decays

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Optimized ultrabroadband absorbing multilayer thin film structure

Optimized ultrabroadband absorbing multilayer thin film stru...

引用

Frontiers in Optics, FIO 2018

作者： Matyas, Corey You, Chenglong Huang, Yin Dowling, Jonathan P. Veronis, Georgios Hearne Institute for Theoretical Physics Department of Physics and Astronomy Louisiana State University Baton RougeLA70803 United States Department of Optoelectrics Information Science and Engineering School of Physics and Electronics Central South University Changsha Hunan410012 China NYU-ECNU Institute of Physics NYU Shanghai 3663 Zhongshan Road North Shanghai200062 China CAS-Alibaba Quantum Computing Laboratory CAS Center for Excellence in Quantum Information and Quantum Physics University of Science and Technology of China Shanghai201315 China School of Electrical Engineering and Computer Science Louisiana State University Baton RougeLA70803 United States Center for Computation and Technology Louisiana State University Baton RougeLA70803 United States

We design an optimized aperiodic multilayer thin film structure with ultra-broadband absorption over a broad angular range. Using a hybrid optimization algorithm, we achieve an average 97.9% absorption from 400 nm to ... 详细信息

ISBN: (纸本)9781943580460

关键词： Film preparation

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Hybrid quantum photonic integrated circuits

Hybrid quantum photonic integrated circuits

引用

2018 International Conference Laser Optics, ICLO 2018

作者： Elshaari, A.W. Esmaeil Zadeh, I. Fognini, A. Dalacu, D. Poole, P.J. Reimer, M.E. Zwiller, V. Jöns, K.D. Applied Physics Department Royal Institute of Technology Albanova University Centre Roslagstullsbacken 21 Stockholm106 91 Sweden Kavli Institute of Nanoscience Delft University of Technology Lorentzweg 1 Delft2628CJ Netherlands National Research Council of Canada OttawaK1A 0R6 Canada Institute for Quantum Computing Department of Electrical and Computer Engineering University of Waterloo WaterlooN2L 3G1 Canada

ISBN: (纸本)9781538636121

quantum photonic integrated circuits require a scalable approach to integrate bright on-demand sources of entangled photon-pairs in complex on-chip quantum photonic circuits. Currently, the most promising sources are based on III/V semiconductor quantum dots. However, complex photonic circuitry is mainly achieved in silicon photonics due to the tremendous technological challenges in circuit fabrication. We take the best of both worlds by developing a new hybrid on-chip nanofabrication approach, allowing to integrate III/V semiconductor nanowire quantum emitters into silicon-based photonics. © 2018 IEEE.

关键词： Timing circuits

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Correction: Core–shell defective TiO 2 nanoparticles by femtosecond laser irradiation with enhanced photocatalytic performance

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Materials Advances 2023年第5期4卷 1403-1403页

作者： Bersu Bastug Azer Ahmet Gulsaran Joel R. Pennings Reza Karimi Aydin Ashrafi Belgabad Alexander H. Xu Liena Zaidan Samed Kocer Joseph Sanderson Michal Bajcsy Michael A. Pope Mustafa Yavuz Department of Mechanical and Mechatronics Engineering University of Waterloo 200 University Ave. West Waterloo ON N2L 3G1 Canada bbastuga@uwaterloo.ca myavuz@uwaterloo.ca Waterloo Institute for Nanotechnology (WIN) University of Waterloo 200 University Ave. West Waterloo ON N2L 3G1 Canada Department of Physics and Astronomy University of Waterloo 200 University Ave. West Waterloo ON N2L 3G1 Canada Department of Physics and Energy Engineering Amirkabir University of Technology (Tehran Polytechnic) P.O. Box 15875-4413 Tehran Iran Department of Nanotechnology Engineering University of Waterloo 200 University Ave. West Waterloo ON N2L 3G1 Canada Department of Electrical and Computer Engineering University of Waterloo 200 University Ave. West Waterloo ON N2L 3G1 Canada Department of Systems Design Engineering University of Waterloo 200 University Ave. West Waterloo ON N2L 3G1 Canada Institute for Quantum Computing University of Waterloo 200 University Ave. West Waterloo ON N2L 3G1 Canada Department of Chemical Engineering University of Waterloo 200 University Ave. West Waterloo ON N2L 3G1 Canada

Correction for ‘Core–shell defective TiO 2 nanoparticles by femtosecond laser irradiation with enhanced photocatalytic performance’ by Bersu Bastug Azer et al. , Mater. Adv. , 2023, https://***/10.1039/d3ma00019b .

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