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Showing 1–14 of 14 results
Advanced filters: Author: Sven Rogge Clear advanced filters

  • Porous materials can absorb energy by water infiltration, but studies at industrially relevant high-rate intrusions are rare. Here, high-rate experiments are performed on ZIFs showing high energy storage capacity, while molecular simulations allow design rules to be formulated for absorption materials.

    • Yueting Sun
    • Sven M. J. Rogge
    • Jin-Chong Tan
    Research
    Nature Materials
    Volume: 20, P: 1015-1023

  • Experiments on Bi-doped silicon demonstrate the existence of atomic clock transitions that can be used to enhance the coherence of solid-state qubits.

    • Sven Rogge
    • Matthew J. Sellars
    News & Views
    Nature Nanotechnology
    Volume: 8, P: 544-545

  • The presence of just one dopant atom can dramatically alter the performance of a short-channel transistor, depending on where it is located.

    • Sven Rogge
    News & Views
    Nature Nanotechnology
    Volume: 5, P: 100-101

  • Spin qubits in systems with strong spin–orbit coupling can be electrically controlled, but are usually affected by short coherence times. Here, coherence times up to 10 ms are obtained for strain-engineered hole states bound to boron acceptors in silicon 28.

    • Takashi Kobayashi
    • Joseph Salfi
    • Sven Rogge
    Research
    Nature Materials
    Volume: 20, P: 38-42

  • A hybrid approach to detecting individual defect spins in solids, whereby an optically induced spin change is detected electronically, offers the high fidelities required for quantum information processing devices.

    • Chunming Yin
    • Milos Rancic
    • Sven Rogge
    Research
    Nature
    Volume: 497, P: 91-94

  • Entangled local states can be made capable of violating Bell inequalities via nonlocality activation. Typical theoretical approaches require processing many copies of the original state and performing joint measurements on the ensemble. Here, instead, the authors experimentally demonstrate how to do so using a single copy of the state, broadcasting it to two spatially separated parties within a three-node network.

    • Luis Villegas-Aguilar
    • Emanuele Polino
    • Geoff J. Pryde
    ResearchOpen Access
    Nature Communications
    Volume: 15, P: 1-8

  • Lattice anchoring, in its varied forms, has proven effective at regulating the energetics of metastable phases of polymorphic crystals. Here, the authors utilize top-down photolithography to embed a tessellating 3D interfacial network into otherwise-unstable CsPbI3 perovskite thin films and devices, stabilizing the perovskite phase.

    • Julian A. Steele
    • Tom Braeckevelt
    • Maarten B. J. Roeffaers
    ResearchOpen Access
    Nature Communications
    Volume: 13, P: 1-11

  • Soft porous crystals hold big promise as functional nanoporous materials due to their stimuli responsive flexibility. Here, molecular dynamics simulations reveal a new type of spatial disorder in mesoscale crystals that helps to understand the size-dependency of their phase transition behavior.

    • Sven M. J. Rogge
    • Michel Waroquier
    • Veronique Van Speybroeck
    ResearchOpen Access
    Nature Communications
    Volume: 10, P: 1-10

  • An essential ingredient of future worldwide quantum communication is the generation of long-lived entangled quantum states; a coherence time of six hours is now reported for optically addressable nuclear spins in europium-doped yttrium orthosilicate.

    • Manjin Zhong
    • Morgan P. Hedges
    • Matthew J. Sellars
    Research
    Nature
    Volume: 517, P: 177-180

  • While stimuli-responsive metal-organic frameworks have been widely investigated, much less is understood about structural flexibility in their covalent counterparts. Here, 3D diamondoid covalent-organic frameworks are studied via dynamic free energy simulations, revealing key insight into how the nature of the building blocks and the degree of interpenetration contribute to framework flexibility.

    • Sander Borgmans
    • Sven M. J. Rogge
    • Veronique Van Speybroeck
    ResearchOpen Access
    Communications Chemistry
    Volume: 6, P: 1-9