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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
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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
Photochemical tuning of dynamic defects for high-performance atomically dispersed catalysts
Chan Woo Lee
; Byoung-Hoon Lee; Sunghak Park; Yoon Jung; Jaebeom Han; Junhyeok Heo; Kangjae Lee; Wonjae Ko; Seungwoo Yoo; Megalamane S. Bootharaju; Jaeyune Ryu; Ki Tae Nam; Minho Kim; Taeghwan Hyeon
Palabras clave: Mechanical Engineering; Mechanics of Materials; Condensed Matter Physics; General Materials Science; General Chemistry.
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High-temperature Josephson diode
Sanat Ghosh; Vilas Patil; Amit Basu; Kuldeep; Achintya Dutta; Digambar A. Jangade; Ruta Kulkarni; A. Thamizhavel; Jacob F. Steiner; Felix von Oppen; Mandar M. Deshmukh
Palabras clave: Mechanical Engineering; Mechanics of Materials; Condensed Matter Physics; General Materials Science; General Chemistry.
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Persistent magnetic coherence in magnets
T. Makiuchi; T. Hioki; H. Shimizu; K. Hoshi; M. Elyasi; K. Yamamoto; N. Yokoi; A. A. Serga; B. Hillebrands; G. E. W. Bauer; E. Saitoh
Palabras clave: Mechanical Engineering; Mechanics of Materials; Condensed Matter Physics; General Materials Science; General Chemistry.
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High-quality nanocavities through multimodal confinement of hyperbolic polaritons in hexagonal boron nitride
Hanan Herzig Sheinfux; Lorenzo Orsini; Minwoo Jung; Iacopo Torre; Matteo Ceccanti; Simone Marconi; Rinu Maniyara; David Barcons Ruiz; Alexander Hötger; Ricardo Bertini; Sebastián Castilla; Niels C. H. Hesp; Eli Janzen; Alexander Holleitner; Valerio Pruneri; James H. Edgar; Gennady Shvets; Frank H. L. Koppens
Palabras clave: Mechanical Engineering; Mechanics of Materials; Condensed Matter Physics; General Materials Science; General Chemistry.
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Artificial-goosebump-driven microactuation
Mingchao Zhang; Aniket Pal; Xianglong Lyu; Yingdan Wu; Metin Sitti
<jats:title>Abstract</jats:title><jats:p>Microactuators provide controllable driving forces for precise positioning, manipulation and operation at the microscale. Development of microactuators using active materials is often hampered by their fabrication complexity and limited motion at small scales. Here we report light-fuelled artificial goosebumps to actuate passive microstructures, inspired by the natural reaction of hair bristling (piloerection) on biological skin. We use light-responsive liquid crystal elastomers as the responsive artificial skin to move three-dimensionally printed passive polymer microstructures. When exposed to a programmable femtosecond laser, the liquid crystal elastomer skin generates localized artificial goosebumps, resulting in precise actuation of the surrounding microstructures. Such microactuation can tilt micro-mirrors for the controlled manipulation of light reflection and disassemble capillary-force-induced self-assembled microstructures globally and locally. We demonstrate the potential application of the proposed microactuation system for information storage. This methodology provides precise, localized and controllable manipulation of microstructures, opening new possibilities for the development of programmable micromachines.</jats:p>
Palabras clave: Mechanical Engineering; Mechanics of Materials; Condensed Matter Physics; General Materials Science; General Chemistry.
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Publisher Correction: Absence of 3a0 charge density wave order in the infinite-layer nickelate NdNiO2
C. T. Parzyck; N. K. Gupta; Y. Wu; V. Anil; L. Bhatt; M. Bouliane; R. Gong; B. Z. Gregory; A. Luo; R. Sutarto; F. He; Y.-D. Chuang; T. Zhou; G. Herranz; L. F. Kourkoutis; A. Singer; D. G. Schlom; D. G. Hawthorn; K. M. Shen
Palabras clave: Mechanical Engineering; Mechanics of Materials; Condensed Matter Physics; General Materials Science; General Chemistry.
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Room temperature optically detected magnetic resonance of single spins in GaN
Jialun Luo; Yifei Geng; Farhan Rana; Gregory D. Fuchs
Palabras clave: Mechanical Engineering; Mechanics of Materials; Condensed Matter Physics; General Materials Science; General Chemistry.
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Immunoengineering can overcome the glycocalyx armour of cancer cells
Sangwoo Park; Marshall J. Colville; Justin H. Paek; Carolyn R. Shurer; Arun Singh; Erica J. Secor; Cooper J. Sailer; Ling-Ting Huang; Joe Chin-Hun Kuo; Marc C. Goudge; Jin Su; Minsoo Kim; Matthew P. DeLisa; Sriram Neelamegham; Jan Lammerding; Warren R. Zipfel; Claudia Fischbach; Heidi L. Reesink; Matthew J. Paszek
Palabras clave: Mechanical Engineering; Mechanics of Materials; Condensed Matter Physics; General Materials Science; General Chemistry.
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Hybrid oxide coatings generate stable Cu catalysts for CO2 electroreduction
Petru P. Albertini; Mark A. Newton; Min Wang; Ona Segura Lecina; Philippe B. Green; Dragos C. Stoian; Emad Oveisi; Anna Loiudice; Raffaella Buonsanti
<jats:title>Abstract</jats:title><jats:p>Hybrid organic/inorganic materials have contributed to solve important challenges in different areas of science. One of the biggest challenges for a more sustainable society is to have active and stable catalysts that enable the transition from fossil fuel to renewable feedstocks, reduce energy consumption and minimize the environmental footprint. Here we synthesize novel hybrid materials where an amorphous oxide coating with embedded organic ligands surrounds metallic nanocrystals. We demonstrate that the hybrid coating is a powerful means to create electrocatalysts stable against structural reconstruction during the CO<jats:sub>2</jats:sub> electroreduction. These electrocatalysts consist of copper nanocrystals encapsulated in a hybrid organic/inorganic alumina shell. This shell locks a fraction of the copper surface into a reduction-resistant Cu<jats:sup>2+</jats:sup> state, which inhibits those redox processes responsible for the structural reconstruction of copper. The electrocatalyst activity is preserved, which would not be possible with a conventional dense alumina coating. Varying the shell thickness and the coating morphology yields fundamental insights into the stabilization mechanism and emphasizes the importance of the Lewis acidity of the shell in relation to the retention of catalyst structure. The synthetic tunability of the chemistry developed herein opens new avenues for the design of stable electrocatalysts and beyond.</jats:p>
Palabras clave: Mechanical Engineering; Mechanics of Materials; Condensed Matter Physics; General Materials Science; General Chemistry.
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Spatially reconfigurable antiferromagnetic states in topologically rich free-standing nanomembranes
Hariom Jani; Jack Harrison; Sonu Hooda; Saurav Prakash; Proloy Nandi; Junxiong Hu; Zhiyang Zeng; Jheng-Cyuan Lin; Charles Godfrey; Ganesh ji Omar; Tim A. Butcher; Jörg Raabe; Simone Finizio; Aaron Voon-Yew Thean; A. Ariando; Paolo G. Radaelli
<jats:title>Abstract</jats:title><jats:p>Antiferromagnets hosting real-space topological textures are promising platforms to model fundamental ultrafast phenomena and explore spintronics. However, they have only been epitaxially fabricated on specific symmetry-matched substrates, thereby preserving their intrinsic magneto-crystalline order. This curtails their integration with dissimilar supports, restricting the scope of fundamental and applied investigations. Here we circumvent this limitation by designing detachable crystalline antiferromagnetic nanomembranes of α-Fe<jats:sub>2</jats:sub>O<jats:sub>3</jats:sub>. First, we show—via transmission-based antiferromagnetic vector mapping—that flat nanomembranes host a spin-reorientation transition and rich topological phenomenology. Second, we exploit their extreme flexibility to demonstrate the reconfiguration of antiferromagnetic states across three-dimensional membrane folds resulting from flexure-induced strains. Finally, we combine these developments using a controlled manipulator to realize the strain-driven non-thermal generation of topological textures at room temperature. The integration of such free-standing antiferromagnetic layers with flat/curved nanostructures could enable spin texture designs via magnetoelastic/geometric effects in the quasi-static and dynamical regimes, opening new explorations into curvilinear antiferromagnetism and unconventional computing.</jats:p>
Palabras clave: Mechanical Engineering; Mechanics of Materials; Condensed Matter Physics; General Materials Science; General Chemistry.
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