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ÎïÀíѧPhysics

Scalable entanglement of nuclear spins mediated by electron exchange

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¡ø ×÷ÕߣºHOLLY G. STEMP, MARK R. VAN BLANKENSTEIN, SERWAN ASAAD, MATEUSZ T. M?DZIK, BENJAMIN JOECKER, HANNES R. FIRGAU, ET AL.

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https://www.science.org/doi/10.1126/science.ady3799

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¡ø Abstract£ºThe use of nuclear spins for quantum computation is limited by the difficulty in creating genuine quantum entanglement between distant nuclei. Current demonstrations of nuclear entanglement in semiconductors rely on coupling the nuclei to a coÃÃÃÃon electron, which is not a scalable strategy. In this work, we demonstrated a two-qubit controlled-Z logic operation between the nuclei of two phosphorus atoms in a silicon device, separated by up to 20 nanometers. Each atom binds separate electrons, whose exchange interaction mediates the nuclear two-qubit gate. We prepared and measured a nuclear Bell state with a fidelity of 76+5-5% and a concurrence of 0.67+0.05-0.05. With this method, future progress in scaling up semiconductor spin qubits can be extended to the development of nuclear spin based quantum computers.

Quantum squeezing of a levitated nanomechanical oscillator

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¡ø ×÷ÕߣºMitsuyoshi Kamba, Naoki Hara and Kiyotaka Aikawa

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https://www.science.org/doi/10.1126/science.ady4652

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¡ø Abstract£ºManipulating the motion of macroscopic objects near their quantum mechanical uncertainties has been desired in diverse fields, including fundamental physics, sensing, and transducers. Despite progress in ground-state cooling of a levitated solid particle, realizing its nonclassical states has been elusive. Here, we demonstrate quantum squeezing of the motion of a single nanoparticle by rapidly varying its oscillation frequency. We reveal appreciable narrowing of the velocity variance to 4.9 0.1 decibels of that of the ground state using free-expansion measurements. Our work shows that a levitated nanoparticle offers an ideal platform for studying nonclassical states of its motion and provides a route to developing applications in quantum sensing and exploring quantum mechanics at a macroscopic scale.

»¯Ñ§Chemistry

Stereo-reversed E2 unlocks Z-selective C functionalization

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¡ø ×÷ÕߣºPeter J. Verardi, Elizabeth A. Ryutov, Poulami Mukherjee, Remy Lalisse, Karina Targos, Tetsuya Inagaki, et al.

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https://www.science.org/doi/10.1126/science.adv7630

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Ñо¿×éÃèдÁËÏ©Ìþת»¯ÎªµßÄ©ZÑ¡ÔñÐÔÏûåôµÄ˲̬1,2-Ë«ï³ÖмäÌ壬¾­ÓÉÀú³ÌÎȶ¨Ï໥×÷ÓÃÇ㸲Á˽̿ÆÊ鼶µÄE2Á¢ÌåÑ¡ÔñÐÔ¹æÔò¡£ËûÃǽ«Åä¶ÔÓÚµç½âÈ·¶¨ÎªÒ»ÖÖʹÄÜÕ½ÂÔ£¬¼È¿ÉÒÔÑ¡ÔñÐÔµØÔÐÓý·¢ÉúËùÐèµÄË«ï³ÖмäÌ壬Óֿɽ«ÆäÓÚԭλ¿ìËÙÏûåô¡£

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¡ø Abstract£ºThe stereoselective functionalization of C H bonds represents a central challenge in modern organic synthesis. Despite decades of innovation in C H activation chemistry, methods for Z-selective functionalization of alkenes have eluded synthetic practitioners. Terminal alkenes present the biggest challenge for Z-selectivity as they require selective cleavage of the more hindered of two otherwise virtually identical C H bonds. Herein, we describe the transformation of alkenes into transient 1,2-bis-sulfonium intermediates found to undergo Z-selective elimination, overturning a textbook E2 stereoselectivity rule through stabilizing interactions. We identify paired electrolysis as an enabling strategy to both selectively generate the requisite bis-sulfonium intermediate and drive its rapid elimination in situ. The resultant Z-alkenyl sulfonium linchpins provide access to a wide array of Z-alkene targets from inexpensive feedstocks through robust cross-coupling reactions.

High-capacity, reversible hydrogen storage using H -conducting solid electrolytes

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¡ø ×÷ÕߣºTakashi Hirose, Naoki Matsui, Takashi Itoh, Yoyo Hinuma, Kazutaka Ikeda, Kazuma Gotoh, et al.

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https://www.science.org/doi/10.1126/science.adw1996

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¡ø Abstract£ºHydrogen absorption and desorption in solids are pivotal reactions involved in batteries and hydrogen storage devices. However, cppµç×ÓÊ×Ò³-onventional thermodynamic and electrochemical hydrogen storage using high-capacity materials suffers from high hydrogen-desorption temperatures and instability of electrolytes. In this work, we explored electrochemical hydride ion (H ) driven hydrogen storage and developed a solid electrolyte, anti -AgI type Ba0.5Ca0.35Na0.15H1.85, which exhibits excellent H conductivity and electrochemical stability. This electrolyte is compatible with several metal-hydrogen electrodes, such as titanim hydride and magnesium hydride (MgH2), allowing for high-capacity, reversible hydrogen storage at low temperatures. Specifically, Mg H2 cells operating as hydrogen storage devices (Mg + H2 = MgH2) achieved a reversible capacity of 2030 milliampere hours per gram at 90 C, offering safe and efficient hydrogen-electricity conversion and hydrogen storage devices.

µØÇò¿ÆѧEarth Science

Crustal stresses and damage evolve throughout the seismic cycle of the Ridgecrest fault zone

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¡ø ×÷ÕߣºJARED BRYAN, WILLIAM B. FRANK AND PASCAL AUDET

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https://www.science.org/doi/10.1126/science.adu9116

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¡ø Abstract£ºEarthquakes abruptly release tectonic stress that builds slowly over time through the coupled evolution of faults and the surrounding crust. Seismic wavespeeds track crustal deformation and stress changes, but typical monitoring methods are most sensitive to shallow depths. Using receiver functions, we tracked rupture-zone wavespeed and anisotropy changes throughout the crust during the 2019 Ridgecrest earthquake sequence. Shallow coseismic wavespeed reductions recovered within months, whereas a deeper postseismic wavespeed drop persisted without measurable recovery over several years. The deep, persistent wavespeed drop likely reflects accumulating damage driven by postseismic deformation, suggesting two possible scenarios: (i) a slow interseismic recovery where wavespeed and anisotropy track long-term stress evolution; or (ii) permanent deformation of an iÃÃÃÃature fault zone. Both scenarios affect the dynamics and energy budget of the seismic cycle.

More extreme Indian monsoon rainfall in El Ni o suÃÃÃÃers

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¡ø ×÷ÕߣºSPENCER A. HILL, DESTINY ZAMIR MEYERS, ADAM H. SOBEL, MICHELA BIASUTTI, MARK A. CANE, MICHAEL K. TIPPETT, ET AL.

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https://www.science.org/doi/10.1126/science.adg5577

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¡ø Abstract£ºExtreme rainfall during the Indian suÃÃÃÃer monsoon can be destructive and deadly to the world s third-largest economy and most populous country. Although El Ni?o events in the equatorial Pacific are known to suppress total suÃÃÃÃer rainfall throughout India, we show using observational data spanning 1901 to 2020 that, counterintuitively, they simultaneously intensify extreme daily rainfall. This is partly driven by increases in extreme daily values of convective buoyancy, provided that both the undilute instability of near-surface air and the dilution by mixing with drier air above are considered. El Ni?o could plausibly drive similar changes in other tropical regions, and our framework could be further applied to changes in hourly extremes, to other internal variability modes, and to forced trends under climate change.

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