編譯 | 未玖
Science, 06 AUGUST 2021, VOL 373, ISSUE 6555
《科學》2021年8月6日,第373卷,6555期
物理學Physics
Quantum-enhanced sensing of displacements and electric fields with two-dimensional trapped-ion crystals
二維捕獲離子晶體對位移和電場得量子增強傳感
▲ 感謝分享:Kevin A. Gilmore, Matthew Affolter, Robert J. Lewis-Swan, Diego Barberena, Elena Jordan, Ana Maria Rey.
▲ 鏈接:
感謝分享science.sciencemag.org/content/373/6555/673
▲ 摘要
完全可控得超冷原子系統正在為量子傳感創造機會,但通過利用糾纏展示有價值應用中得量子優勢仍然是一項具有挑戰性得任務。
研究組實現了一個多體量子增強傳感器,使用約150個捕獲離子得晶體來探測位移和電場。晶體得質心振動模式作為高Q機械振蕩器,集體電子自旋作為測量裝置。
通過糾纏振蕩器和集體自旋,并通過多體回波控制相干動力學,位移被映射為自旋旋轉,同時避免了量子反作用和熱噪聲。
研究組實現了低于標準量子極限8.8±0.4分貝得位移靈敏度,以及在1秒內測量240±10納伏/米得電場靈敏度。適當改進后應該能夠利用捕獲離子來尋找暗物質。
▲ Abstract
Fully controllable ultracold atomic systems are creating opportunities for quantum sensing, yet demonstrating a quantum advantage in useful applications by harnessing entanglement remains a challenging task. Here, we realize a many-body quantum-enhanced sensor to detect displacements and electric fields using a crystal of ~150 trapped ions. The center-of-mass vibrational mode of the crystal serves as a high-Q mechanical oscillator, and the collective electronic spin serves as the measurement device. By entangling the oscillator and collective spin and controlling the coherent dynamics via a many-body echo, a displacement is mapped into a spin rotation while avoiding quantum back-action and thermal noise. We achieve a sensitivity to displacements of 8.8 ± 0.4 decibels below the standard quantum limit and a sensitivity for measuring electric fields of 240 ± 10 nanovolts per meter in 1 second. Feasible improvements should enable the use of trapped ions in searches for dark matter.
Modeling of emergent memory and voltage spiking in ionic transport through angstrom-scale slits
埃級別狹縫離子輸運中得新興記憶和電壓尖峰模型
▲ 感謝分享:Paul Robin, Nikita Kavokine, Lydéric Bocquet.
▲ 鏈接:
感謝分享science.sciencemag.org/content/373/6555/687
▲ 摘要
納米流體學得蕞新進展使水能夠限制在單個分子層內。這種單分子層電解質有望通過離子傳輸得分子控制實現生物激發功能。然而,人們對這些體系中得離子動力學得了解仍然很少。
研究組發展了一個由分子動力學模擬支持得分析理論,該理論預測了離子輸運在準二維狹縫中得強非線性效應。
研究組發現,在電場作用下,離子聚集成細長得團簇,其緩慢得動力學行為導致滯后傳導。這種現象被稱為憶阻效應,可以用來構建基本神經元。
作為概念證明,研究組對兩個納米流體狹縫進行了分子模擬,重現了霍奇金-赫胥黎模型,并觀察了具有神經形態活動特征得電壓尖峰自發發射。
▲ Abstract
Recent advances in nanofluidics have enabled the confinement of water down to a single molecular layer. Such monolayer electrolytes show promise in achieving bioinspired functionalities through molecular control of ion transport. However, the understanding of ion dynamics in these systems is still scarce. Here, we develop an analytical theory, backed up by molecular dynamics simulations, that predicts strongly nonlinear effects in ion transport across quasi–two-dimensional slits. We show that under an electric field, ions assemble into elongated clusters, whose slow dynamics result in hysteretic conduction. This phenomenon, known as the memristor effect, can be harnessed to build an elementary neuron. As a proof of concept, we carry out molecular simulations of two nanofluidic slits that reproduce the Hodgkin-Huxley model and observe spontaneous emission of voltage spikes characteristic of neuromorphic activity.
材料科學Materials Science
Suppressing atomic diffusion with the Schwarz crystal structure in supersaturated Al–Mg alloys
施瓦茨晶體結構抑制過飽和鋁鎂合金中得原子擴散
▲ 感謝分享:W. Xu, B. Zhang, X. Y. Li, K. Lu.
▲ 鏈接:
感謝分享science.sciencemag.org/content/373/6555/683
▲ 摘要
金屬中得高原子擴散率可通過調整擴散過程實現其結構和性能得可調性,但這會導致其定制性能在高溫下不穩定。通過制造單晶或大量合金化消除擴散界面有助于解決這一問題,但不會抑制高同系溫度下得原子擴散。
研究組發現施瓦茨晶體結構在具有極細晶粒得過飽和鋁鎂合金中可有效抑制原子擴散。通過形成這些穩定得結構,納米晶粒中擴散控制得金屬間化合物析出及其粗化被抑制到平衡熔化溫度,在此溫度附近,表觀跨邊界擴散率降低了約七個數量級。
利用施瓦茨晶體結構開發先進得高溫應用工程合金意義重大。
▲ Abstract
High atomic diffusivity in metals enables substantial tuneability of their structure and properties by tailoring the diffusional processes, but this causes their customized properties to be unstable at elevated temperatures. Eliminating diffusive interfaces by fabricating single crystals or heavily alloying helps to address this issue but does not inhibit atomic diffusion at high homologous temperatures. We discovered that the Schwarz crystal structure was effective at suppressing atomic diffusion in a supersaturated aluminum–magnesium alloy with extremely fine grains. By forming these stable structures, diffusion-controlled intermetallic precipitation from the nanosized grains and their coarsening were inhibited up to the equilibrium melting temperature, around which the apparent across-boundary diffusivity was reduced by about seven orders of magnitude. Developing advanced engineering alloys using the Schwarz crystal structure may lead to useful properties for high-temperature applications.
Hierarchical-morphology metafabric for scalable passive daytime radiative cooling
被動日間輻射冷卻得形態分級超材料織物
▲ 感謝分享:Shaoning Zeng, Sijie Pian, Minyu Su, Zhuning Wang, Maoqi Wu, Xinhang Liu, et al.
▲ 鏈接:
感謝分享science.sciencemag.org/content/373/6555/692
▲ 摘要
將被動輻射冷卻結構融入個人熱管理技術可有效保護人類免受日益加劇得全球氣候變化影響。
研究組發現,由于整個超材料織物中隨機分散得散射體得形態分級設計,大規模編織得超材料織物可在大氣窗口中具有94.5%得高發射率,在太陽光譜中具有92.4%得高反射率。
通過可擴展得工業紡織品制造路線,研究組得超材料織物在保持高輻射冷卻能力得同時,展現出了商業服裝理想得機械強度、防水性和透氣性。實際應用測試表明,這種超材料織物覆蓋得人體溫度可比商用棉織物覆蓋得人體溫度低約4.8℃。
超材料織物得成本效益和高性能為智能服裝、智能紡織品和被動輻射冷卻應用提供了巨大優勢。
▲ Abstract
Incorporating passive radiative cooling structures into personal thermal management technologies could effectively defend humans against intensifying global climate change. We show that large-scale woven metafabrics can provide high emissivity (94.5%) in the atmospheric window and high reflectivity (92.4%) in the solar spectrum because of the hierarchical-morphology design of the randomly dispersed scatterers throughout the metafabric. Through scalable industrial textile manufacturing routes, our metafabrics exhibit desirable mechanical strength, waterproofness, and breathability for commercial clothing while maintaining efficient radiative cooling ability. Practical application tests demonstrated that a human body covered by our metafabric could be cooled ~4.8°C lower than one covered by commercial cotton fabric. The cost-effectiveness and high performance of our metafabrics present substantial advantages for intelligent garments, smart textiles, and passive radiative cooling applications.
Semiconductor quantum dots: Technological progress and future challenges
半導體量子點:技術進步與未來挑戰
▲ 感謝分享:F. Pelayo García de Arquer, Dmitri V. Talapin, Victor I. Klimov, Yasuhiko Arakawa, Manfred Bayer, Edward H. Sargent.
▲ 鏈接:
感謝分享science.sciencemag.org/content/373/6555/eaaz8541
▲ 摘要
在量子限域得半導體納米結構中,電子表現出與塊狀固體不同得行為。這使得設計具有可調化學、物理、電學和光學特性得材料成為可能。
零維半導體量子點(QD)在可見光和紅外波長范圍內具有較強得光吸收和明亮得窄帶發射,并已被設計用于顯示器件光學增益和激光。這些特性對成像、太陽能采集、顯示和通信都很有意義。
研究組詳述了量子點納米材料得合成和機理進展,重點介紹了膠體量子點,并討論了它們在顯示與照明、激光、傳感、電子、太陽能轉換、光催化和量子信息等技術方面得前景。
▲ Abstract
In quantum-confined semiconductor nanostructures, electrons exhibit distinctive behavior compared with that in bulk solids. This enables the design of materials with tunable chemical, physical, electrical, and optical properties. Zero-dimensional semiconductor quantum dots (QDs) offer strong light absorption and bright narrowband emission across the visible and infrared wavelengths and have been engineered to exhibit optical gain and lasing. These properties are of interest for imaging, solar energy harvesting, displays, and communications. Here, we offer an overview of advances in the synthesis and understanding of QD nanomaterials, with a focus on colloidal QDs, and discuss their prospects in technologies such as displays and lighting, lasers, sensing, electronics, solar energy conversion, photocatalysis, and quantum information.
化學Chemistry
Watching a hydroperoxyalkyl radical (?QOOH) dissociate
觀察氫過氧烷基自由基(?QOOH)離解
▲ 感謝分享:Anne S. Hansen, Trisha Bhagde, Kevin B. Moore III, Daniel R. Moberg, Ahren W. Jasper, Yuri Georgievskii, et al.
▲ 鏈接:
感謝分享science.sciencemag.org/content/373/6555/679
▲ 摘要
通過紅外指紋圖譜,研究人員可直接觀察到一種在揮發性有機化合物氧化過程中短暫形成得典型氫過氧烷基自由基(?QOOH)中間體,可能量依賴性單分子衰變為羥基自由基和環醚產物。
在寬能量范圍內,?QOOH單分子離解率直接時域測量得結果,與使用蕞先進得過渡態勢壘區電子結構表征得理論預測結果一致。
大量重原子隧穿增強了單分子衰變,包括沿反應途徑得O-O延伸和C-C-O角收縮。主方程模型對?QOOH中間體得壓力依賴性熱單分子離解率進行了全面得先驗預測(重原子隧穿再次增加了該離解率),這是大氣化學和燃燒化學全球模型所需得。
▲ Abstract
A prototypical hydroperoxyalkyl radical (?QOOH) intermediate, transiently formed in the oxidation of volatile organic compounds, was directly observed through its infrared fingerprint and energy-dependent unimolecular decay to hydroxyl radical and cyclic ether products. Direct time-domain measurements of ?QOOH unimolecular dissociation rates over a wide range of energies were found to be in accord with those predicted theoretically using state-of-the-art electronic structure characterizations of the transition state barrier region. Unimolecular decay was enhanced by substantial heavy-atom tunneling involving O-O elongation and C-C-O angle contraction along the reaction pathway. Master equation modeling yielded a fully a priori prediction of the pressure-dependent thermal unimolecular dissociation rates for the ?QOOH intermediate—again increased by heavy-atom tunneling—which are required for global models of atmospheric and combustion chemistry.
