Institution
Nanosystems Initiative Munich
Facility•Munich, Germany•
About: Nanosystems Initiative Munich is a facility organization based out in Munich, Germany. It is known for research contribution in the topics: Quantum dot & Perovskite (structure). The organization has 323 authors who have published 549 publications receiving 24316 citations.
Topics: Quantum dot, Perovskite (structure), Exciton, Nanowire, Charge carrier
Papers
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TL;DR: A 55-nanometer–by-55-nanometers DNA-based molecular platform with an integrated robotic arm of length 25 nanometers, which can be extended to more than 400 nanometers and actuated with externally applied electrical fields, and application of piconewton forces by the robot arm is demonstrated in force-induced DNA duplex melting experiments.
Abstract: The use of dynamic, self-assembled DNA nanostructures in the context of nanorobotics requires fast and reliable actuation mechanisms. We therefore created a 55-nanometer–by–55-nanometer DNA-based molecular platform with an integrated robotic arm of length 25 nanometers, which can be extended to more than 400 nanometers and actuated with externally applied electrical fields. Precise, computer-controlled switching of the arm between arbitrary positions on the platform can be achieved within milliseconds, as demonstrated with single-pair Forster resonance energy transfer experiments and fluorescence microscopy. The arm can be used for electrically driven transport of molecules or nanoparticles over tens of nanometers, which is useful for the control of photonic and plasmonic processes. Application of piconewton forces by the robot arm is demonstrated in force-induced DNA duplex melting experiments.
279 citations
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TL;DR: High-quality hybrid halide perovskite nanocrystals are fabricated through a simple, versatile, and efficient two-step process involving a dry step followed by a ligand-assisted liquid-phase exfoliation step.
Abstract: High-quality hybrid halide perovskite nanocrystals are fabricated through a simple, versatile, and efficient two-step process involving a dry step followed by a ligand-assisted liquid-phase exfoliation step. The emission wavelength of the resulting nanocrystals can be tuned either through composition by varying the halide content or by reducing their thickness.
256 citations
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TL;DR: This review can serve as an overview and evaluation of state-of-the-art synthesis techniques as well as nanoscale optoelectronics and photonics based on low-dimensional perovskite nanocrystals.
251 citations
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Institute of Cost and Management Accountants of Bangladesh1, Technische Universität München2, Université Paris-Saclay3, Max Planck Society4, University of Science and Technology of China5, University of Pittsburgh6, University of Salerno7, Forschungszentrum Jülich8, Cornell University9, University of Milano-Bicocca10, Universidade Nova de Lisboa11, Kyoto University12, Dresden University of Technology13, Uppsala University14, Nanosystems Initiative Munich15, École Polytechnique Fédérale de Lausanne16, National Institute for Materials Science17, MESA+ Institute for Nanotechnology18, Chalmers University of Technology19, University of Dundee20, Spanish National Research Council21, University of Cambridge22, University of Arkansas23, Polytechnic University of Valencia24, RWTH Aachen University25, Jožef Stefan Institute26
TL;DR: The Towards Oxide-Based Electronics (TO-BE) Action as mentioned in this paper has been recently running in Europe and has involved as participants several hundred scientists from 29 EU countries in a wide four-year project.
251 citations
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TL;DR: A new ultrafast solid electrolyte of the composition Li11Si2PS12 is reported, which exhibits a higher room-temperature Li ion diffusivity than the present record holder Li10GeP2S12 and could be traced back to fast Li ion hopping in the crystalline lattice.
Abstract: We report on a new ultrafast solid electrolyte of the composition Li11Si2PS12, which exhibits a higher room-temperature Li ion diffusivity than the present record holder Li10GeP2S12. We discuss the high-pressure synthesis and ion dynamics of tetragonal Li11Si2PS12, and comparison is made with our investigations of related members of the LMePS family, i.e. electrolytes of the general formula Li11−xMe2−xP1+xS12 with Me = Ge, Sn : Li10GeP2S12, Li7GePS8, Li10SnP2S12. The structure and dynamics were studied with multiple complementary techniques and the macroscopic diffusion could be traced back to fast Li ion hopping in the crystalline lattice. A clear correlation between the diffusivity and the unit cell volume of the LGPS-type electrolytes was observed.
251 citations
Authors
Showing all 323 results
Name | H-index | Papers | Citations |
---|---|---|---|
Thomas Bein | 109 | 677 | 42800 |
Ernst Wagner | 96 | 537 | 36723 |
Jochen Feldmann | 91 | 417 | 31049 |
Peter Hänggi | 90 | 788 | 42272 |
Markus Fischer | 85 | 490 | 28454 |
Martin Stutzmann | 84 | 781 | 30938 |
Gerhard Abstreiter | 77 | 791 | 25631 |
Oliver Eickelberg | 75 | 329 | 19447 |
Rudolf Gross | 68 | 532 | 17739 |
Dirk Trauner | 65 | 821 | 16279 |
Peter Müller-Buschbaum | 63 | 605 | 17603 |
Bettina V. Lotsch | 62 | 248 | 14599 |
Christoph Bräuchle | 58 | 267 | 12032 |
Jonathan J. Finley | 56 | 353 | 11100 |
Paolo Lugli | 55 | 739 | 14706 |