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¡¶¿Æѧ¡·£¨20230818³ö°æ£©Ò»ÖÜÂÛÎĵ¼¶Á2023-08-21 09:48¡¤¿ÆѧÍø±àÒë | ÀîÑÔScience, 18 AUG 2023, Volume 381 Issue 6659¡¶¿Æѧ¡·2023Äê8ÔÂ18ÈÕµÚ381¾í6659ÆÚÉúÎïÎïÀíѧBiophysicsAlcanivorax borkumensis biofilms enhance oil degradation by interfacial tubulation²´¿âµºÊ³Íé¾úÉúÎïĤͨ¹ý½çÃæ¹Ü»¯´Ù½øʯÓͽµ½â¡ø ×÷ÕߣºM. PRASAD, N. OBANA et al.¡ø Á´½Ó£ºhttps://www.science.org/doi/full/10.1126/science.adf3345¡ø ÕªÒª£ºÔÚÏûºÄÍéÌþµÄ¹ý³ÌÖв´¿âµºÊ³Íé¾ú»áÔÚÓ͵ÎÖÜΧÐγÉÉúÎïĤµ«ÕâÔÚ½µ½â¹ý³ÌÖÐËùÆðµÄ×÷ÓÃÉв»Çå³þÎÒÃÇ·¢ÏÖÁËÉúÎïĤÐÎ̬µÄ±ä»¯È¡¾öÓÚ¶ÔʯÓÍÏûºÄµÄÊÊÓ¦£º³¤Ê±¼äµÄ±©Â¶µ¼ÖÂÊ÷Í»×´ÉúÎïĤµÄ³öÏÖͨ¹ý½çÃæµÄ¹Ü×´Ó°ÏìÓÅ»¯ÁËʯÓÍÏûºÄԭλ΢Á÷Ìå¸ú×ÙʹÎÒÃÇÄܹ»½«¹Ü×´Óë½çÃæϸ°ûÓÐÐòÖеľֲ¿È±ÏÝÁªÏµÆðÀ´ÎÒÃÇÑÝʾÁËͨ¹ýʹÓÃÏÞÖÆÀ´¶¨Î»È±ÏÝÀ´¿ØÖÆÒºµÎ±äÐδӶøʹµÃÒºµÎ²úÉú°¼ÏÝÎÒÃÇ¿ª·¢ÁËÒ»¸öÄ£ÐÍÀ´½âÊÍÉúÎïĤÐÎ̬½«Î¢¹Ü»¯Óë½çÃæÕÅÁ¦½µµÍºÍϸ°ûÊèË®ÐÔÔö¼ÓÁªÏµÆðÀ´¡ø Abstract£ºDuring the consumption of alkanes, Alcanivorax borkumensis will form a biofilm around an oil droplet, but the role this plays during degradation remains unclear. We identified a shift in biofilm morphology that depends on adaptation to oil consumption: Longer exposure leads to the appearance of dendritic biofilms optimized for oil consumption effected through tubulation of the interface. In situ microfluidic tracking enabled us to correlate tubulation to localized defects in the interfacial cell ordering. We demonstrate control over droplet deformation by using confinement to position defects, inducing dimpling in the droplets. We developed a model that elucidates biofilm morphology, linking tubulation to decreased interfacial tension and increased cell hydrophobicity.ÌìÌåÎïÀíѧAstrophysicsA massive helium star with a sufficiently strong magnetic field to form a magnetarÓÐ×㹻ǿ´Å³¡ÐγɴÅÐǵĴóÖÊÁ¿º¤ºãÐÇ¡ø ×÷ÕߣºTOMER SHENAR, GREGG A. WADE, PABLO MARCHANT et al.¡ø Á´½Ó£ºhttps://www.science.org/doi/full/10.1126/science.ade3293¡ø ÕªÒª£º´ÅÐÇÊǸ߶ȴŻ¯µÄÖÐ×ÓÐǵ«ÐγɻúÖÆÉв»Çå³þ¹âÆ×ÒÔ·¢ÉäÏßΪÖ÷µÄ¸»º¤ºãÐDZ»³ÆΪÎÖ¶û·ò-À­Ò¶ÐÇÎÒÃÇÓùâÆ×Æ«Õñ·¨¹Û²âÁËË«ÐÇϵͳHD 45166²¢ÀûÓõµ°¸Êý¾ÝÖØзÖÎöÁËËüµÄ¹ìµÀÎÒÃÇ·¢ÏÖ¸ÃÐÇϵÖÐÓÐÒ»¿ÅÎÖ¶û·ò-À­Ò¶ÐÇÆäÖÊÁ¿ÊÇÌ«ÑôµÄ2±¶´Å³¡Îª43ǧ¸ß˹ºãÐÇÑÝ»¯¼ÆËã±íÃ÷Õâ¿ÅÐǽ«±¬Õ¨³ÉΪһ¿Å³¬ÐÂÐǶøËüµÄ´Å³¡Ç¿´óµ½×ãÒÔÈó¬ÐÂÐÇÁôÏ´ÅÐÇÒż£ÎÒÃÇÌá³ö´Å»¯µÄÎÖ¶û·ò-À­Ò¶ÐÇÊÇÓÉÁ½¿ÅµÍÖÊÁ¿º¤ºãÐǺϲ¢ÐγɵÄ¡ø Abstract£ºMagnetars are highly magnetized neutron stars, the formation mechanism of which is unknown. Hot helium-rich stars with spectra dominated by emission lines are known as Wolf-Rayet stars. We observed the binary system HD 45166 using spectropolarimetry and reanalyzed its orbit using archival data. We found that the system contains a Wolf-Rayet star with a mass of 2 solar masses and a magnetic field of 43 kilogauss. Stellar evolution calculations indicate that this component will explode as a supernova, and that its magnetic field is strong enough for the supernova to leave a magnetar remnant. We propose that the magnetized Wolf-Rayet star formed by the merger of two lower-mass helium stars.¹âѧOpticsOvercoming losses in superlenses with synthetic waves of complex frequencyÓø´ÆµÂʺϳɲ¨¿Ë·þ³¬Í¸¾µËðºÄ¡ø ×÷ÕߣºFUXIN GUAN, XIANGDONG GUO, KEBO ZENG et al.¡ø Á´½Ó£ºhttps://www.science.org/doi/full/10.1126/science.adi1267¡ø ÕªÒª£ºÕ¹Ê¾³öʱ¼äË¥¼õÐÐΪµÄ¸´ÆµÂʹⲨ±»Ìá³öͨ¹ýÒýÈëÐéÄâÔöÒæÀ´µÖÏû³¬Í¸¾µµÄ±¾Õ÷Ëðʧµ«ÊÇÓÉÓÚ¾ßÓÐʱ¼äË¥¼õµÄ³ÉÏñ²âÁ¿À§ÄÑÒ»Ö±ºÜÄÑÔÚʵÑéÖÐʵÏÖÔÚÕâÏîÑо¿ÖÐÎÒÃÇÌá³öÁËÒ»ÖÖ»ùÓÚʵ¼ÊƵÂʲâÁ¿µÄ¶àƵ·½·¨À´¹¹½¨¸´ÆµÂʹⲨÕâÖÖ·½·¨ÔÊÐíÎÒÃÇÔÚʵÑéÉÏʵÏÖÐéÄâÔöÒæ²¢¹Û²ìÉîÑDz¨³¤Í¼ÏñÎÒÃǵÄÑо¿Îª¿Ë·þ³ÉÏñºÍ´«¸ÐÓ¦ÓÃÖеÈÀë×ÓÌåϵͳµÄ¹ÌÓÐËðºÄÌṩÁËÒ»¸öʵÓõĽâ¾ö·½°¸¡ø Abstract£ºOptical waves of complex frequency that exhibit a temporally attenuating behavior have been proposed to offset the intrinsic losses in superlenses through the introduction of virtual gain, but experimental realization has been lacking because of the difficulty of imaging measurements with temporal decay. In this work, we present a multifrequency approach to constructing synthetic excitation waves of complex frequency based on measurements at real frequencies. This approach allows us to implement virtual gain experimentally and observe deep-subwavelength images. Our work offers a practical solution to overcome the intrinsic losses of plasmonic systems for imaging and sensing applications.ÎïÀíѧPhysicsErgodicity breaking in rapidly rotating C60 fullerenes¿ìËÙÐýתµÄC60¸»ÀÕÏ©µÄ±éÀúÐÔÆÆ»µ¡ø ×÷ÕߣºLEE R. LIU, DINA ROSENBERG et al.¡ø Á´½Ó£ºhttps://www.science.org/doi/full/10.1126/science.adi6354¡ø ÕªÒª£ºÔÚÕâÀïÎÒÃDZ¨¸æÁËÔÚÒ»¸öÇ°ËùδÓеĴó·Ö×Ó12C60Öй۲쵽µÄÐýת±éÀúÐÔÆÆ»µÕâÊÇ´ÓËüµÄ¶þÊ®ÃæÌåÐýתÕñ¶¯¾«Ï¸½á¹¹ÖÐÈ·¶¨µÄ±éÀúÐÔ¶ÏÁÑ·¢ÉúÔÚÔ¶µÍÓÚÕñ¶¯±éÀúÐÔãÐÖµµÄµØ·½²¢ÇÒËæ׎Ƕ¯Á¿µÄÔö¼ÓÔÚ±éÀúºÍ·Ç±éÀú״̬Ö®¼ä±íÏÖ³ö¶à´Îת±äÕâЩÌØÊâµÄ¶¯Á¦Ñ§À´Ô´ÓÚ·Ö×ӵĶԳơ¢´óСºÍ¸ÕÐÔµÄ×éºÏÍ»³öÁËËüÓë½é¹ÛÁ¿×ÓϵͳÖÐÓ¿ÏÖÏÖÏóµÄÏà¹ØÐÔ¡ø Abstract£ºHere, we report the observation of rotational ergodicity breaking in an unprecedentedly large molecule, 12C60, determined from its icosahedral rovibrational fine structure. The ergodicity breaking occurs well below the vibrational ergodicity threshold and exhibits multiple transitions between ergodic and nonergodic regimes with increasing angular momentum. These peculiar dynamics result from the molecule¡¯s distinctive combination of symmetry, size, and rigidity, highlighting its relevance to emergent phenomena in mesoscopic quantum systems.ÉúÎïѧBiologyDesign of stimulus-responsive two-state hinge proteins´Ì¼¤·´Ó¦Ë«Ì¬½ÂÁ´µ°°×µÄÉè¼Æ¡ø ×÷ÕߣºFLORIAN PRAETORIUS, PHILIP J. Y. LEUNG et al.¡ø Á´½Ó£ºhttps://www.science.org/doi/full/10.1126/science.adg7731¡ø ÕªÒª£ºÉè¼Æ¾ßÓÐÁ½ÖÖ²»Í¬µ«½á¹¹ÍêÕûµÄµ°°×ÖÊÊǵ°°×ÖÊÉè¼ÆÖеÄÒ»´óÌôÕ½ÒòΪËüÐèÒªµñ¿Ì¾ßÓÐÁ½¸ö²»Í¬×îСֵµÄÄÜÁ¿¾°¹ÛÔÚ´ËÎÒÃÇÃèÊöÁ˽ÂÁ´µ°°×µÄÉè¼ÆËüÔÚûÓÐÅäÌåµÄÇé¿öÏ¿ÉÒÔÐγÉÒ»ÖÖÉè¼Æ״̬ÔÚÅäÌå´æÔÚµÄÇé¿öÏÂÐγÉÁíÒ»ÖÖÉè¼Æ״̬XÉäÏß¾§Ìåѧ¡¢µç×ÓÏÔ΢¾µ¡¢Ë«µç×Ó-µç×Ó¹²Õñ¹âÆ׺ͽáºÏ²âÁ¿±íÃ÷¾¡¹Ü´æÔÚÏÔÖøµÄ½á¹¹²îÒ쵫ÕâÁ½ÖÖ״̬µÄÉè¼Æ¾ßÓÐÔ­×ÓˮƽµÄ¾«¶È²¢ÇÒ¹¹ÏóƽºâºÍ½áºÏƽºâÊǽôÃÜñîºÏµÄ¡ø Abstract£ºDesigning proteins with two distinct but fully structured conformations is a challenge for protein design as it requires sculpting an energy landscape with two distinct minima. Here we describe the design of hinge proteins that populate one designed state in the absence of ligand and a second designed state in the presence of ligand. X-ray crystallography, electron microscopy, double electron-electron resonance spectroscopy, and binding measurements demonstrate that despite the significant structural differences the two states are designed with atomic level accuracy and that the conformational and binding equilibria are closely coupled.¹ÅÉúÎïѧPaleontologyPre¨CYounger Dryas megafaunal extirpation at Rancho La Brea linked to fire-driven state shiftÐÂÏÉŮľʱÆÚ֮ǰÀ­²¼À×ÑÇÄÁ³¡µÄ¾ÞÐͶ¯ÎïÃð¾øÓë»ðÔÖÇý¶¯µÄ״̬ת±äÓйءø ×÷ÕߣºF. ROBIN O¡¯KEEFE, REGAN E. DUNN et al.¡ø Á´½Ó£ºhttps://www.science.org/doi/full/10.1126/science.abo3594¡ø ÕªÒª£º¸üÐÂÊÀ¾ÞÐͶ¯ÎïÃð¾øµÄÔ­ÒòºÜÄÑÈ·¶¨²¿·ÖÔ­ÒòÊÇ»¯Ê¯¼Ç¼µÄ½Ï²îʱ¿Õ·Ö±æÂÊ×è°­ÁËÎïÖÖÏûʧÓ뿼¹ÅºÍ»·¾³Êý¾ÝµÄ¶ÔÆëÎÒÃÇÔÚ¼ÓÖÝÀ­²¼À×ÑÇÄÁ³¡µÄ´óÐͶ¯ÎïÒż£ÖлñµÃ172¸öеķÅÉäÐÔ̼Äê´úʱ¼ä¾à½ñ1.56ÍòÄêÖÁ1ÍòÄêÇ°ÓÐ7ÖÖÃð¾øµÄ¾ÞÐͶ¯ÎïÏûʧÓÚ1.29 ÍòÄêÇ°ÔÚÐÂÏÉŮľÆÚ¿ªÊ¼Ç°Óë¸ß·Ö±æÂÊÇøÓòÊý¾Ý¼¯µÄ±È½Ï±íÃ÷ÕâЩÏûʧÓëůÆÚ£¨1.469 ~ 1.289ÍòÄ꣩¸Éºµ»¯ºÍÖ²±»±ä»¯ÒýÆðµÄÉú̬״̬ת±äÏàÎǺÏʱ¼äÐòÁÐÄ£ÐͱíÃ÷´ó¹æÄ£»ðÔÖÊÇÎïÖÖÃð¾øµÄÖ÷ÒªÔ­Òò¶øÕâÖÖ״̬ת±äµÄ´ß»¯¼Á¿ÉÄÜÊÇÈËÀà¶Ô¸Éºµ¡¢±äůºÍÔ½À´Ô½ÈÝÒ×·¢Éú»ðÔÖµÄÉú̬ϵͳµÄÓ°Ïì¡ø Abstract£ºThe cause, or causes, of the Pleistocene megafaunal extinctions have been difficult to establish, in part because poor spatiotemporal resolution in the fossil record hinders alignment of species disappearances with archeological and environmental data. We obtained 172 new radiocarbon dates on megafauna from Rancho La Brea in California spanning 15.6 to 10.0 thousand calendar years before present (ka). Seven species of extinct megafauna disappeared by 12.9 ka, before the onset of the Younger Dryas. Comparison with high-resolution regional datasets revealed that these disappearances coincided with an ecological state shift that followed aridification and vegetation changes during the B?lling-Aller?d (14.69 to 12.89 ka). Time-series modeling implicates large-scale fires as the primary cause of the extirpations, and the catalyst of this state shift may have been mounting human impacts in a drying, warming, and increasingly fire-prone ecosystem.

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