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Nature Materials
Resumen/Descripción – provisto por la editorial en inglés
Nature Materials is a monthly multi-disciplinary journal aimed at bringing together cutting-edge research across the entire spectrum of materials science and engineering. Materials research is a diverse and fast-growing discipline, which has moved from a largely applied, engineering focus to a position where it has an increasing impact on other classical disciplines such as physics, chemistry and biology. Nature Materials covers all applied and fundamental aspects of the synthesis/processing, structure/composition, properties and performance of materials, where "materials" are identified as substances in the condensed states (liquid, solid, colloidal) designed or manipulated for technological ends.Palabras clave – provistas por la editorial
No disponibles.
Disponibilidad
| Institución detectada | Período | Navegá | Descargá | Solicitá |
|---|---|---|---|---|
| No detectada | desde jul. 2012 / hasta dic. 2023 | Nature.com |
Información
Tipo de recurso:
revistas
ISSN impreso
1476-1122
ISSN electrónico
1476-4660
Editor responsable
Springer Nature
País de edición
Reino Unido
Fecha de publicación
2001-
Cobertura temática
Tabla de contenidos
Metamaterial adhesives for programmable adhesion through reverse crack propagation
Dohgyu Hwang; Chanhong Lee
; Xingwei Yang; Jose M. Pérez-González; Jason Finnegan; Bernard Lee; Eric J. Markvicka; Rong Long; Michael D. Bartlett
Palabras clave: Mechanical Engineering; Mechanics of Materials; Condensed Matter Physics; General Materials Science; General Chemistry.
Pp. No disponible
Scalar photonic crystals with non-radiative topological surface modes
Palabras clave: Mechanical Engineering; Mechanics of Materials; Condensed Matter Physics; General Materials Science; General Chemistry.
Pp. No disponible
Exciton-assisted electron tunnelling in van der Waals heterostructures
Lujun Wang; Sotirios Papadopoulos; Fadil Iyikanat; Jian Zhang; Jing Huang; Takashi Taniguchi; Kenji Watanabe; Michel Calame; Mickael L. Perrin; F. Javier García de Abajo; Lukas Novotny
<jats:title>Abstract</jats:title><jats:p>The control of elastic and inelastic electron tunnelling relies on materials with well-defined interfaces. Two-dimensional van der Waals materials are an excellent platform for such studies. Signatures of acoustic phonons and defect states have been observed in current-to-voltage measurements. These features can be explained by direct electron–phonon or electron–defect interactions. Here we use a tunnelling process that involves excitons in transition metal dichalcogenides (TMDs). We study tunnel junctions consisting of graphene and gold electrodes separated by hexagonal boron nitride with an adjacent TMD monolayer and observe prominent resonant features in current-to-voltage measurements appearing at bias voltages that correspond to TMD exciton energies. By placing the TMD outside of the tunnelling pathway, we demonstrate that this tunnelling process does not require any charge injection into the TMD. The appearance of such optical modes in electrical transport introduces additional functionality towards van der Waals material–based optoelectronic devices.</jats:p>
Palabras clave: Mechanical Engineering; Mechanics of Materials; Condensed Matter Physics; General Materials Science; General Chemistry.
Pp. No disponible
Operando electron microscopy investigation of polar domain dynamics in twisted van der Waals homobilayers
Kahyun Ko; Ayoung Yuk; Rebecca Engelke; Stephen Carr; Junhyung Kim; Daesung Park; Hoseok Heo; Hyun-Mi Kim; Seul-Gi Kim; Hyeongkeun Kim; Takashi Taniguchi; Kenji Watanabe; Hongkun Park; Efthimios Kaxiras; Sang Mo Yang; Philip Kim; Hyobin Yoo
Palabras clave: Mechanical Engineering; Mechanics of Materials; Condensed Matter Physics; General Materials Science; General Chemistry.
Pp. No disponible
Elimination of charge-carrier trapping by molecular design
Oskar Sachnik; Xiao Tan; Dehai Dou; Constantin Haese; Naomi Kinaret; Kun-Han Lin; Denis Andrienko; Martin Baumgarten; Robert Graf; Gert-Jan A. H. Wetzelaer; Jasper J. Michels; Paul W. M. Blom
<jats:title>Abstract</jats:title><jats:p>A common obstacle of many organic semiconductors is that they show highly unipolar charge transport. This unipolarity is caused by trapping of either electrons or holes by extrinsic impurities, such as water or oxygen. For devices that benefit from balanced transport, such as organic light-emitting diodes, organic solar cells and organic ambipolar transistors, the energy levels of the organic semiconductors are ideally situated within an energetic window with a width of 2.5 eV where charge trapping is strongly suppressed. However, for semiconductors with a band gap larger than this window, as used in blue-emitting organic light-emitting diodes, the removal or disabling of charge traps poses a longstanding challenge. Here we demonstrate a molecular strategy where the highest occupied molecular orbital and lowest unoccupied molecular orbital are spatially separated on different parts of the molecules. By tuning their stacking by modification of the chemical structure, the lowest unoccupied molecular orbitals can be spatially protected from impurities that cause electron trapping, increasing the electron current by orders of magnitude. In this way, the trap-free window can be substantially broadened, opening a path towards large band gap organic semiconductors with balanced and trap-free transport.</jats:p>
Palabras clave: Mechanical Engineering; Mechanics of Materials; Condensed Matter Physics; General Materials Science; General Chemistry.
Pp. No disponible
A mixed legacy
Palabras clave: Mechanical Engineering; Mechanics of Materials; Condensed Matter Physics; General Materials Science; General Chemistry.
Pp. 793-793
Revisiting point defects in ionic solids and semiconductors
Roger De Souza; George Harrington
Palabras clave: Mechanical Engineering; Mechanics of Materials; Condensed Matter Physics; General Materials Science; General Chemistry.
Pp. 794-797
Delivering Europe’s graphene promise
Amos Martinez
Palabras clave: Mechanical Engineering; Mechanics of Materials; Condensed Matter Physics; General Materials Science; General Chemistry.
Pp. 798-799
Mixing magnetic microbots
Philip Ball
Palabras clave: Mechanical Engineering; Mechanics of Materials; Condensed Matter Physics; General Materials Science; General Chemistry.
Pp. 800-800
Better electronics from immiscibility
Youdi Liu; Faheem Ershad; Yifan Tao; Cunjiang Yu
Palabras clave: Mechanical Engineering; Mechanics of Materials; Condensed Matter Physics; General Materials Science; General Chemistry.
Pp. 801-802