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Ê×·¢2024-07-15 15:55¡¤³¬¹Ú¡¶¿Æѧ¡·£¨20221223³ö°æ£©Ò»ÖÜÂÛÎĵ¼¶Á2022-12-25 20:04¡¤¿ÆѧÍø±àÒë | ÀîÑÔScience, 23 DEC 2022, Volume 378 Issue 6626¡¶¿Æѧ¡·2022Äê12ÔÂ23ÈÕ£¬µÚ378¾í£¬6626ÆÚ²ÄÁÏ¿ÆѧMaterials ScienceThree-dimensional nanofabrication via ultrafast laser patterning and kinetically regulated material assembly»ùÓÚ³¬¿ì¼¤¹âͼ°¸ºÍ¶¯Ì¬µ÷½Ú²ÄÁÏ×é×°µÄ3DÄÉÃ×ÖÆÔì¡ø ×÷ÕߣºFEI HAN, SONGYUN GU, ALEKS KLIMAS et al.¡ø Á´½Ó£ºhttps://www.science.org/doi/10.1126/science.abm8420¡ø ÕªÒª£ºÎÒÃÇÌá³öÁËÒ»ÖÖʹÓöàÖÖ²ÄÁÏÖÆÔìÈÎÒâ3DÄÉÃ׽ṹµÄ·½·¨£¬²ÄÁÏ°üÀ¨½ðÊô¡¢½ðÊôºÏ½ð¡¢2D²ÄÁÏ¡¢Ñõ»¯Îï¡¢½ð¸Õʯ¡¢ÉÏת»»²ÄÁÏ¡¢°ëµ¼Ìå¡¢¾ÛºÏÎï¡¢ÉúÎï²ÄÁÏ¡¢·Ö×Ó¾§ÌåºÍÄ«Ë®¡£¾ßÌåÀ´Ëµ£¬ÎÒÃǽ«ÓÉ·ÉÃ뼤¹âÖÆ×÷µÄË®Äý½ºÓÃ×÷Ä£°å£¬Ö±½Ó×é×°²ÄÁÏÈ¥ÐγÉÉè¼ÆºÃµÄÄÉÃ׽ṹ¡£Í¨¹ýÆعâ²ßÂÔºÍͼÐÎÄý½ºÌØÕ÷µÄ¾«Ï¸µ÷Õû£¬ÎÒÃÇÖÆ×÷ÁË20¼°200ÄÉÃ×·Ö±æÂÊϵÄ2DºÍ3DÄÉÃ׽ṹ¡£ÎÒÃÇÖÆ×÷ÁË°üÀ¨¼ÓÃܹâѧ´æ´¢ºÍ΢µç¼«ÔÚÄÚµÄÄÉÃ×É豸£¬ÒÔÑÝʾÕâЩÉ豸µÄÉè¼ÆµÄ¹¦Äܺ;«¶È¡£ÕâЩ½á¹û±íÃ÷£¬ÎÒÃǵķ½·¨Îª²»Í¬ÖÖÀàµÄ²ÄÁϵÄÄÉÃ×ÖÆÔìÌṩÁËÒ»¸öϵͳµÄ½â¾ö·½°¸£¬²¢ÎªÖÇÄÜÄÉÃ×É豸µÄÉè¼Æ´øÀ´Á˽øÒ»²½µÄ¿ÉÄÜÐÔ¡£¡ø Abstract£ºWe present a strategy for fabricating arbitrary 3D nanostructures with a library of materials including metals, metal alloys, 2D materials, oxides, diamond, upconversion materials, semiconductors, polymers, biomaterials, molecular crystals, and inks. Specifically, hydrogels patterned by femtosecond light sheets are used as templates that allow for direct assembly of materials to form designed nanostructures. By fine-tuning the exposure strategy and features of the patterned gel, 2D and 3D structures of 20- to 200-nm resolution are realized. We fabricated nanodevices, including encrypted optical storage and microelectrodes, to demonstrate their designed functionality and precision. These results show that our method provides a systematic solution for nanofabrication across different classes of materials and opens up further possibilities for the design of sophisticated nanodevicesCompositional texture engineering for highly stable wide-bandgap perovskite solar cells¸ßÎȶ¨¿í´ø϶¸ÆîÑÌ«ÑôÄܵç³ØµÄ×é³É½á¹¹Éè¼Æ¡ø ×÷ÕߣºQI JIANG, JINHUI TONG, REBECCA A. SCHEIDT et al.¡ø Á´½Ó£ºhttps://www.science.org/doi/10.1126/science.adf0194¡ø ÕªÒª£ºÎÒÃÇͨ¹ý½«¿ìËÙäå½á¾§Óëκ͵ÄÆø´ã·½·¨Ïà½áºÏ£¬ÖƱ¸ÁËȱÏÝÃܶȸüµÍµÄ¡¢¸ßÎÆÀíÖù×´1.75 eV äå-µâ»ìºÏ¿í½û´ø¸ÆîÑ¿ó±¡Ä¤¡£Í¨¹ýÕâÖÖ·½·¨£¬ÎÒÃÇ»ñµÃÁË1.75 eVµÄ¿í½û´ø¸ÆîÑ¿óÌ«ÑôÄܵç³Ø£¬Æ书ÂÊת»»Ð§ÂÊ´óÓÚ20%£¬¿ªÂ·µçѹԼΪ1.33 V£¬ÇÒ¾ßÓÐÁ¼ºÃµÄÔËÐÐÎȶ¨ÐÔ¡£µ±½øÒ»²½Óë1.25 eVÕ­´ø϶¸ÆîÑ¿óÌ«ÑôÄܵç³Ø¼¯³Éʱ£¬ÎÒÃÇ»ñµÃÁË27.1%µÄ¸ßЧȫ¸ÆîÑ¿óË«¶Ë´®ÁªÉ豸£¬¿ªÂ·µçѹ¸ß´ï2.2 V¡£¡ø Abstract£ºWe combined the rapid Br crystallization with a gentle gas-quench method to prepare highly textured columnar 1.75¨Celectron volt Br¨CI mixed WBG perovskite films with reduced defect density. With this approach, we obtained 1.75¨Celectron volt WBG PSCs with greater than 20% power conversion efficiency, approximately 1.33-volt open-circuit voltage (Voc), and excellent operational stability (less than 5% degradation over 1100 hours of operation under 1.2 sun at 65¡ãC). When further integrated with 1.25¨Celectron volt narrow-bandgap PSC, we obtained a 27.1% efficient, all-perovskite, two-terminal tandem device with a high Voc of 2.2 volts.ÎïÀíѧPhysicsIonocaloric refrigeration cycleÀë×ÓÈÈÖÆÀäÑ­»·¡ø ×÷ÕߣºDREW LILLEY AND RAVI PRASHER¡ø Á´½Ó£ºhttps://www.science.org/doi/10.1126/science.ade1696¡ø ÕªÒª£ºÎÒÃÇÌá³ö£¬Ê¹ÓÃÀë×ÓÈÈЧӦºÍ°éËæ¶øÀ´µÄÈÈÁ¦Ñ§Ñ­»·£¬×÷ΪһÖÖ»ùÓÚÈÈÁ¿µÄÈ«ÀäÄýÏàÀäÈ´¼¼Êõ¡£ÀíÂÛºÍʵÑé½á¹û±íÃ÷£¬ÔÚµÍÓ¦Óó¡Ç¿×÷ÓÃÏ£¬ÓëÆäËûÈÈЧӦÏà±È£¬ÕâһЧӦ¾ßÓиü¸ßµÄ¾øÈÈζȱ仯ºÍìر䡣ÎÒÃÇ֤ʵÁËÒ»¸öʹÓÃÀë×ÓÈÈ˹ÌØÁÖÖÆÀäÑ­»·µÄʵÓÃϵͳµÄ¿ÉÄÜÐÔ¡£ÎÒÃǵÄʵÑé½á¹ûչʾÁËÏà¶ÔÓÚ¿¨ÅµµÄÐÔÄÜϵÊýΪ30%£¬ÒÔ¼°ÔÚ~0.22·üµÄµçѹǿ¶ÈÏÂζȿÉÌáÉý25¶È¡£¡ø Abstract£ºWe propose using the ionocaloric effect and the accompanying thermodynamic cycle as a caloric-based, all¨Ccondensed-phase cooling technology. Theoretical and experimental results show higher adiabatic temperature change and entropy change per unit mass and volume compared with other caloric effects under low applied field strengths. We demonstrated the viability of a practical system using an ionocaloric Stirling refrigeration cycle. Our experimental results show a coefficient of performance of 30% relative to Carnot and a temperature lift as high as 25¡ãC using a voltage strength of ~0.22 volts.High-entropy mechanism to boost ionic conductivity´Ù½øÀë×ӵ絼ÐԵĸßìØ»úÖÆ¡ø ×÷ÕߣºYAN ZENG, BIN OUYANG, JUE LIU et al.¡ø Á´½Ó£ºhttps://www.science.org/doi/10.1126/science.abq1346¡ø ÕªÒª£ºÎÒÃÇÖ¤Ã÷Á˸ßìؽðÊôÑôÀë×Ó»ìºÏÎïÌá¸ß»¯ºÏÎïÖÐÀë×ӵ絼ÐÔµÄÄÜÁ¦£¬ÕâÒ»ÌØÐÔ¿ÉÒÔ¼õÉÙ¶ÔÌض¨»¯Ñ§ÎïÖʵÄÒÀÀµÍ¬Ê±ÔöÇ¿ºÏ³ÉÄÜÁ¦¡£ÒýÈë¸ßìزÄÁϵľֲ¿»û±äµ¼Ö¼îÀë×ÓµÄλÖÃÄÜÁ¿·Ö²¼Öصþ£¬Ê¹µÃ¼îÀë×ÓÄÜÒԽϵ͵ĻÄܽøÐÐÉø͸¡£ÊµÑéÖ¤Ã÷£¬¸ßìص¼ÖÂÁËï®-ÄƳ¬Àë×Óµ¼Ìå¡¢ÄƳ¬Àë×Óµ¼ÌåºÍï®-ʯÁñʯ½á¹¹µÄÀë×ӵ絼ÐÔ´ïµ½¸ü¸ßÊýÁ¿¼¶£¬¼´Ê¹ÔڼÁ¿¹Ì¶¨µÄÇé¿öÏÂÒ²ÊÇÈç´Ë¡£¡ø Abstract£ºWe demonstrate the ability of high-entropy metal cation mixes to improve ionic conductivity in a compound, which leads to less reliance on specific chemistries and enhanced synthesizability. The local distortions introduced into high-entropy materials give rise to an overlapping distribution of site energies for the alkali ions so that they can percolate with low activation energy. Experiments verify that high entropy leads to orders-of-magnitude higher ionic conductivities in lithium (Li)¨Csodium (Na) superionic conductor (Li-NASICON), sodium NASICON (Na-NASICON), and Li-garnet structures, even at fixed alkali content.Nanoscale covariance magnetometry with diamond quantum sensors½ð¸ÕʯÁ¿×Ó´«¸ÐÆ÷µÄÄÉÃ׳߶ÈЭ·½²î´ÅÁ¦²â¶¨¡ø ×÷ÕߣºJARED ROVNY, ZHIYANG YUAN, MATTIAS FITZPATRICK et al.¡ø Á´½Ó£ºhttps://www.science.org/doi/10.1126/science.ade9858¡ø ÕªÒª£ºÔÚ´Ë£¬ÎÒÃÇÌá³ö²¢ÊµÏÖÁËÒ»ÖÖ¿ÉÒÔͬʱ²âÁ¿Á½¸ö»ò¶à¸öµª¿Õ루NV£©ÖÐÐĵĴ«¸Ð·½Ê½¡£Í¬Ê±£¬ÎÒÃÇ´ÓËüÃǵÄÐźÅÖÐÌáÈ¡³öÁËÆäËû·½Ê½ÎÞ·¨»ñµÃµÄʱ¼äºÍ¿Õ¼äÏà¹ØÐÔ¡£ÎÒÃÇʹÓÃÁ½¸öNVÖÐÐĵÄ×ÔÐý-µçºÉ¶ÁÊýÑÝʾÁËÈçºÎ²âÁ¿Ïà¹ØÓ¦ÓÃÔëÒô£¬²¢ÊµÏÖÁË¿ÉÏû³ý¾Ö²¿ºÍ·Ç¾Ö²¿ÔëÉùÒôÔ´µÄ¹âÆ×Öؽ¨·½·¨¡£¡ø Abstract£ºHere, we propose and implement a sensing modality whereby two or more NV centers are measured simultaneously, and we extract temporal and spatial correlations in their signals that would otherwise be inaccessible. We demonstrate measurements of correlated applied noise using spin-to-charge readout of two NV centers and implement a spectral reconstruction protocol for disentangling local and nonlocal noise sources.ÉúÎïѧBiologyGlassfrogs conceal blood in their liver to maintain transparency²£Á§ÍÜͨ¹ýѪҺÒþ²ØÔÚ¸ÎÔàÖÐÒÔ±£³Ö͸Ã÷¡ø ×÷ÕߣºCARLOS TABOADA, JESSE DELIA, MAOMAO CHEN et al.¡ø Á´½Ó£ºhttps://www.science.org/doi/10.1126/science.abl6620¡ø ÕªÒª£º¶¯ÎïµÄ͸Ã÷»¯ÊÇÒ»ÖÖ¸´ÔÓµÄαװÐÎʽ£¬Éæ¼°µ½¼õÉÙ¹âÔÚÕû¸öÉúÎïÌåÖеÄÉ¢ÉäºÍÎüÊյĻúÖÆ¡£ÒòΪ¼¹×µ¶¯ÎïµÄÑ­»·ÏµÍ³ÖгäÂúÁË¿ÉÒÔÇ¿ÁÒË¥¼õ¹âÏߵĺìϸ°û£¨RBCs£©£¬ÊµÏÖÉíÌå͸Ã÷»¯ÊǺÜÄѵġ£ÔÚ´Ë£¬ÎÒÃǼǼÁ˲£Á§ÍÜÊÇÈçºÎͨ¹ýÒþ²ØÕâЩϸ°û´Ó¶ø¿Ë·þÕâÒ»ÌôÕ½µÄ¡£Í¨¹ýʹÓùâÉù³ÉÏñÀ´¸ú×ÙÌåÄڵĺìϸ°û£¬ÎÒÃÇչʾÁË˯ÃßʱµÄ²£Á§ÍÜÊÇÈçºÎͨ¹ý´ÓÌåÄÚÑ­»·ÖÐתÒÆ89%µÄºìϸ°û²¢½«ËüÃÇ°ü×°ÔÚ¸ÎÔàÖУ¬½«ÉíÌå͸Ã÷¶ÈÌá¸ß2µ½3±¶¡£Òò´Ë£¬¼¹×µ¶¯ÎïµÄ͸Ã÷»¯¼ÈÐèҪ͸Ã÷µÄ×éÖ¯£¬Ò²ÐèÒªÄÜ´ÓÕâЩ×éÖ¯ÖС°Çå³ý¡±ºôÎüÉ«ËصĻîÐÔ»úÖÆ¡£´ËÍ⣬²£Á§ÍÜÔÚ²»²úÉúÄýѪµÄÇé¿öÏÂÒ²Äܵ÷½Úºìϸ°ûµÄλÖá¢ÃܶȺʹ¢´æµÄÄÜÁ¦£¬Îª´úл¡¢ÑªÒº¶¯Á¦Ñ§ºÍѪÄý¿éÑо¿ÌṩÁË˼·¡£¡ø Abstract£ºTransparency in animals is a complex form of camouflage involving mechanisms that reduce light scattering and absorption throughout the organism. In vertebrates, attaining transparency is difficult because their circulatory system is full of red blood cells (RBCs) that strongly attenuate light. Here, we document how glassfrogs overcome this challenge by concealing these cells from view. Using photoacoustic imaging to track RBCs in vivo, we show that resting glassfrogs increase transparency two- to threefold by removing ~89% of their RBCs from circulation and packing them within their liver. Vertebrate transparency thus requires both see-through tissues and active mechanisms that ¡°clear¡± respiratory pigments from these tissues. Furthermore, glassfrogs¡¯ ability to regulate the location, density, and packing of RBCs without clotting offers insight in metabolic, hemodynamic, and blood-clot research.