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¡¶¿Æѧ¡·£¨20230113³ö°æ£©Ò»ÖÜÂÛÎĵ¼¶Á2023-01-16 09:51¡¤¿ÆѧÍø±àÒë | ·ëάάSCIENCE, January 2023, Volume 379 Issue 6628¡¶¿Æѧ¡·2023Äê1Ô£¬µÚ379¾í£¬6628ÆÚÎïÀíѧPhysicsDuctile 2-GPa steels with hierarchical substructure¾ßÓзֲã×ӽṹµÄ2¼ªÅÁÈÍÐÔ¸Ö¡ø ×÷ÕߣºYUNJIE LI, GUO YUAN, LINLIN LI, JIAN KANG, FENGKAI YAN, PENGJU DU, DIERK RAABE, AND GUODONG WANGAuthors Info & Affiliations¡ø Á´½Ó£ºhttps://www.science.org/doi/10.1126/science.add7857¡ø ÕªÒª£º´Ó½»Í¨ÔËÊäµ½ÇáÁ¿»¯Éè¼ÆÔÙµ½°²È«µÄ»ù´¡ÉèÊ©£¬ºÜ¶àÁìÓò¶¼ÐèÒª»úеǿ¶ÈºÍÑÓÕ¹ÐԵijÐÖزÄÁÏ¡£µ«ÆäÖÐÒ»´óÌôÕ½ÊÇÔÚÒ»ÖÖ²ÄÁÏÖÐͳһÕâÁ½ÖÖ¹¦ÄÜ¡£×÷ÕßÑо¿±íÃ÷£¬ÔÚ¾ùÔÈÉ쳤ÂÊ>20%µÄÇé¿öÏ£¬ÆÕͨÖÐÃ̸ֿÉÒÔ¼Ó¹¤³É¿¹À­Ç¿¶È>2.2¼ªÅÁ¡£ÕâÐèÒª¶à¸öºáÏò¶ÍÔì¡¢ÉîÀä´¦ÀíºÍ»Ø»ð²½ÖèµÄ½áºÏ¡£Óɲã×´ºÍË«ÖØÍØÆËÅÅÁеÄÂíÊÏÌåÓ뾫ϸ·ÖÉ¢µÄ±£Áô°ÂÊÏÌå×é³ÉµÄ·Ö²ã΢½á¹¹£¬Í¬Ê±¼¤»î¶àÖÖ΢¹Û»úÖÆÀ´ÔöÇ¿ºÍÑÓÕ¹ÐÔ²ÄÁÏ¡£×éÖ¯Á¼ºÃµÄÂíÊÏÌåÖеÄλ´í»¬Òƺͽ¥½ø±äÐδ̼¤Ïà±äЭͬ×÷ÓòúÉúÁ˽ϸߵÄÑÓÐÔ¡£Ñо¿Õß±íʾ£¬¸ÃÄÉÃ׽ṹÉè¼Æ²ßÂÔ¿ÉÒÔÉú²ú³öÇ¿¶ÈΪ2¼ªÅÁÇÒ¾ßÓÐÑÓÕ¹ÐԵĸ֣¬¾ßÓдó¹æÄ£¹¤ÒµÉú²úµÄDZÁ¦¡£¡ø Abstract£ºMechanically strong and ductile load¨Ccarrying materials are needed in all sectors, from transportation to lightweight design to safe infrastructure. Yet, a grand challenge is to unify both features in one material. We show that a plain medium-manganese steel can be processed to have a tensile strength >2.2 gigapascals at a uniform elongation >20%. This requires a combination of multiple transversal forging, cryogenic treatment, and tempering steps. A hierarchical microstructure that consists of laminated and twofold topologically aligned martensite with finely dispersed retained austenite simultaneously activates multiple micromechanisms to strengthen and ductilize the material. The dislocation slip in the well-organized martensite and the gradual deformation-stimulated phase transformation synergistically produce the high ductility. Our nanostructure design strategy produces 2 gigapascal¨Cstrength and yet ductile steels that have attractive composition and the potential to be produced at large industrial scales.Unveiling facet-dependent degradation and facet engineering for stable perovskite solar cellsÎȶ¨¸ÆîÑ¿óÌ«ÑôÄܵç³ØµÄÃæÒÀÀµÐÔ½µ½âºÍÃ湤³Ì¡ø ×÷ÕߣºCHUNQING MA, FELIX T. EICKEMEYER, SUN-HO LEE, DONG-HO KANG, SEOK JOON KWON, MICHAEL GR?TZEL , AND NAM-GYU PARK¡ø Á´½Ó£ºhttps://www.science.org/doi/10.1126/science.adf3349¡ø ÕªÒª£ºÓдóÁ¿Ñо¿ºÍ²ßÂÔÖÂÁ¦ÓÚÌá¸ß¸ÆîÑ¿ó±¡Ä¤µÄÎȶ¨ÐÔ£»È»¶ø£¬²»Í¬¸ÆîÑ¿ó¾§ÃæÔÚÎȶ¨ÐÔÖеÄ×÷ÓÃÈÔȻδ֪¡£×÷Õß½ÒʾÁ˼װ·µâ»¯Ç¦£¨FAPbI3£©±¡Ä¤µÄÃæÒÀÀµÐÔ½µ½âµÄDZÔÚ»úÖÆ¡£Ñо¿Ã÷£¬£¨100£©Ãæ»ù±¾Éϱȣ¨111£©Ãæ¸üÈÝÒ×Êܵ½Ë®·ÖÓÕµ¼µÄ½µ½â¡£Í¨¹ýʵÑéºÍÀíÂÛÑо¿Ïà½áºÏ£¬Ñо¿½ÒʾÁ˽µ½â»úÀí£»Ëæ×ÅǦ-µâ¼ü³¤¾àÀëµÄÑÓ³¤£¬¹Û²ìµ½Ç¿ÁÒµÄˮ𤸽£¬Õâµ¼Ö£¨100£©ÃæÉϵĦÄÏà±ä¡£Í¨¹ý¹¤³ÌÉè¼Æ£¬¿ÉÒÔ»ñµÃ¸ü¸ßµÄ£¨111£©Ãæ±íÃæ·ÖÊý£¬£¨111£©ÎªÖ÷µÄ¾§ÌåFAPbI3±¡Ä¤±íÏÖ³öÓÅÒìµÄ¿¹³±ÆøÎȶ¨ÐÔ¡£¸Ã·¢ÏÖ²ûÃ÷ÁËδ֪µÄÃæÏà¹Ø½µ½â»úÖƺͶ¯Á¦Ñ§¡£¡ø Abstract£ºA myriad of studies and strategies have already been devoted to improving the stability of perovskite films; however, the role of the different perovskite crystal facets in stability is still unknown. Here, we reveal the underlying mechanisms of facet-dependent degradation of formamidinium lead iodide (FAPbI3) films. We show that the (100) facet is substantially more vulnerable to moisture-induced degradation than the (111) facet. With combined experimental and theoretical studies, the degradation mechanisms are revealed; a strong water adhesion following an elongated lead-iodine (Pb-I) bond distance is observed, which leads to a ¦Ä-phase transition on the (100) facet. Through engineering, a higher surface fraction of the (111) facet can be achieved, and the (111)-dominated crystalline FAPbI3 films show exceptional stability against moisture. Our findings elucidate unknown facet-dependent degradation mechanisms and kinetics.΢ÉúÎïѧMicrobiologyDome1¨CJAK¨CSTAT signaling between parasite and host integrates vector immunity and development¼ÄÉú³æºÍËÞÖ÷¼äÐźŴ«µÝÕûºÏý½éÃâÒߺͷ¢Óý¡ø ×÷ÕߣºVIPIN S. RANA, CHRYSOULA KITSOU, SHRABONI DUTTA, MICHAEL H. RONZETTI, MIN ZHANG, QUENTIN BERNARD, ALEXIS A. SMITH, JULEN TOM¨¢S-CORT¨¢ZAR, XIULI YANG, UTPAL PAL, etc.¡ø Á´½Ó£ºhttps://www.science.org/doi/10.1126/science.abl3837¡ø ÕªÒª£ºòçÆðÔ´ÓÚ½ü2.25ÒÚÄêÇ°µÄÒ»ÖÖ×ÔÓÉÉú»îµÄʳ¸¯òý£¬ÒѾ­½ø»¯³ÉÒ»ÖÖ¾ßÓи߶ÈÊÊÓ¦ÐԵĵ¥ÏµÎüѪÌåÍâ¼ÄÉú³æ¡£Óë´ó¶àÊýϲ»¶µ¥Ò»¼¹×µ¶¯ÎïËÞÖ÷µÄµØÀí»î¶¯ÊÜÏÞµÄòçÖÖ²»Í¬£¬Ó²òç¿ÉÒÔ¼ÄÉúÔÚÐí¶à¼¹×µ¶¯ÎïÌåÄÚ£¬´«²¥²»Í¬µÄ²¡Ô­Ìå¡£Ó²òçÔÚÆä¶àÄêµÄÉúÃüÖÜÆÚÖÐÖ»¾­ÀúÈý´Î½øʳ»î¶¯£¬ÉãÈ¡µÄѪ²Í¼¸ºõÊÇËüÃÇÌåÖصÄ100±¶¡£ËüÃÇÌØÓеÄÉúÀíÊÊÓ¦¿ÉÄÜÊÇÓÉÆ临ÔÓµÄÎüѪºÍÓ빲ͬ½ø»¯µÄ¼¹×µ¶¯ÎïËÞÖ÷µÄÁªÏµËùÐγɵġ£òç³æÈçºÎά³ÖÆ临ÔÓµÄÅßÌ¥ºó·¢Óý³ÌÐòÒÔ¼°ËüÃǵÄý½éÄÜÁ¦µÄ·Ö×Ó»ù´¡Éв»Çå³þ¡£×÷Õß·¢ÏÖ£¬ò纬ÓÐÒ»ÖÖ¹¦ÄÜÐÔµÄJAK-STATÐźż¶Áª£¬¿ÉÓÕµ¼Ç¿ÓÐÁ¦µÄ¿¹¾ú·´Ó¦£¬Äܹ»ÏÞÖÆòç´«²¡Ô­ÌåµÄÔöÖ³¡£¸Ã;¾¶ÔÚÐí¶à½ÚÖ«¶¯ÎïÖб» UPDµÈϸ°ûÒò×ÓÑù·Ö×Ó¼¤»î¡£µ«Ó²òç»ùÒò×éÒ쳣ȱ·¦¿Éʶ±ðµÄUPDֱϵͬԴÎï¡£¡ø Abstract£ºTicks have evolved into a monophyletic group of highly adapted blood-feeding ectoparasites that originated from a clade of free-living scavenger mites nearly 225 million years ago. Unlike most geographically confined tick species that prefer a single vertebrate host, Ixodes spp. can parasitize many vertebrates and transmit diverse pathogens. Ixodid ticks undergo only three feeding events during their multiyear lifespan, ingesting blood meals that are nearly 100 times their weight. Their characteristic physiological adaptations were likely shaped by their sophisticated hematophagy and associations with coevolving vertebrate hosts. The molecular basis of how ticks maintain their complex postembryonic developmental program as well as their vectorial competence remains unclear. Ticks contain a functional JAK¨CSTAT signaling cascade that induces robust antibacterial responses capable of limiting the proliferation of tick-borne pathogens. The pathway is activated in many arthropods by cytokine-like molecules such as Unpaired (UPD). However, the Ixodes scapularis genome is unusually devoid of recognizable UPD orthologs.ApoE isoform¨C and microbiota-dependent progression of neurodegeneration in a mouse model of tauopathyTauСÊó²¡ÀíÄ£ÐͽâÎöÒÀÀµApoEÑÇÐͺÍ΢ÉúÎïȺµÄÉñ¾­ÍËÐÐÐÔ¼²²¡¡ø ×÷ÕߣºDONG-OH SEO, DAVID O¡¯DONNELL, NIMANSHA JAIN, JASON D. ULRICH, JASMIN HERZ, YUHAO LI, MACKENZIE LEMIEUX, JIYE CHENG, HAO HU,, AND DAVID M. HOLTZMAN, etc.¡ø Á´½Ó£ºhttps://www.science.org/doi/10.1126/science.add1236¡ø ÕªÒª£º´óÄÔÖÐijЩÐÎʽµÄTauµ°°×µÄ»ýÀÛÓëÉñ¾­Ï¸°ûµÄËðʧ¡¢Ñ×Ö¢ÒÔ¼°°¢¶û´Äº£Ä¬²¡ºÍÆäËû¼¸ÖÖÉñ¾­ÍËÐÐÐÔ¼²²¡µÄÈÏÖªÄÜÁ¦Ï½µÓйء£ÔØÖ¬µ°°×-E£¨APOE£©ÊÇ°¢¶û´Äº£Ä¬²¡×îÇ¿µÄÒÅ´«·çÏÕÒòËØ£¬µ÷½ÚÄÔÑ×Ö¢ºÍTau½éµ¼µÄÄÔËðÉË£»È»¶ø£¬³¦µÀ¾úȺҲµ÷½Ú´óÄÔÑ×Ö¢¡£ÔÚTau½éµ¼µÄÄÔËðÉËСÊóÄ£ÐÍÖУ¬Ñо¿Õß·¢ÏÖ£¬³¦µÀ΢ÉúÎïȺµÄ²Ù×ݵ¼ÖÂÑ×Ö¢¡¢Tau²¡ÀíºÍÄÔËðÉËÒòÐÔ±ðºÍAPOEÒÀÀµµÄ·½Ê½´ó·ù¼õÉÙ¡£¡ø Abstract£ºThe accumulation of certain forms of the tau protein in the brain is linked to loss of nerve cells, inflammation, and cognitive decline in Alzheimer¡¯s disease and several other neurodegenerative diseases. Apolipoprotein-E (APOE), the strongest genetic risk factor for Alzheimer¡¯s disease, regulates brain inflammation and tau-mediated brain damage; however, the gut microbiota also regulates brain inflammation. In a mouse model of tau-mediated brain injury, Seo et al. found that manipulation of the gut microbiota resulted in a strong reduction of inflammation, tau pathology, and brain damage in a sex- and APOE-dependent manner.ÉúÎïÎïÀíѧBiophysicsNeuromorphic functions with a polyelectrolyte-confined fluidic memristor¾Ûµç½âÖÊÊÜÏÞÁ÷ÌåÒä×èÆ÷µÄÉñ¾­ÐÎ̬¹¦ÄÜ¡ø ×÷ÕߣºTIANYI XIONG, CHANGWEI LI, XIULAN HE, BOYANG XIE, JIANWEI ZONG, YANAN JIANG, WENJIE MA, FEI WU, JUNJIE FEI, AND LANQUN MAO¡ø Á´½Ó£ºhttps://www.science.org/doi/10.1126/science.adc9150¡ø ÕªÒª£ºÀûÓÃÈ˹¤Á÷ÌåϵͳÔÙÏÖ»ùÓÚÀë×ÓͨµÀµÄÉñ¾­¹¦ÄÜÒ»Ö±ÊÇÉñ¾­ÐÎ̬¼ÆËãºÍÉúÎïҽѧӦÓõÄÒ»¸öÀíÏëÄ¿±ê¡£ÔÚÕâÏîÑо¿ÖУ¬¾Ûµç½âÖÊ-ÊÜÏÞÁ÷ÌåÒä×èÆ÷£¨PFM£©³É¹¦µØʵÏÖÁËÉñ¾­ÐÎ̬¹¦ÄÜ£¬ÆäÖÐÊÜÏ޵ľ۵ç½âÖÊ-Àë×ÓÏ໥×÷Óõ¼ÖÂÁËÖͺóµÄÀë×Ó´«Ê䣬´Ó¶øµ¼ÖÂÁËÀë×Ó¼ÇÒäЧӦ¡£²ÉÓó¬µÍÄܺĵÄPFMÄ£ÄâÁ˸÷ÖÖ²»Í¬µÄµçÂö³åģʽ¡£PFMµÄÁ÷ÌåÌØÐÔʹģÄ⻯ѧµ÷½ÚµçÂö³å³ÉΪ¿ÉÄÜ¡£¸üÖØÒªµÄÊÇ£¬»¯Ñ§-µçÐźÅתµ¼ÊÇÓɵ¥¸öPFMʵÏֵġ£ÓÉÓÚÆä½á¹¹ÓëÀë×ÓͨµÀÏàËÆ£¬PFMÊÇͨÓõģ¬Ò×ÓÚÓëÉúÎïϵͳ½Ó¿Ú£¬ÎªÍ¨¹ýÒýÈë·á¸»µÄ»¯Ñ§Éè¼Æ¹¹½¨¾ßÓи߼¶¹¦ÄܵÄÉñ¾­ÐÎ̬É豸ÆÌƽÁ˵À·¡£¡ø AbstractReproducing ion channel¨Cbased neural functions with artificial fluidic systems has long been an aspirational goal for both neuromorphic computing and biomedical applications. In this study, neuromorphic functions were successfully accomplished with a polyelectrolyte-confined fluidic memristor (PFM), in which confined polyelectrolyte¨Cion interactions contributed to hysteretic ion transport, resulting in ion memory effects. Various electric pulse patterns were emulated by PFM with ultralow energy consumption. The fluidic property of PFM enabled the mimicking of chemical-regulated electric pulses. More importantly, chemical-electric signal transduction was implemented with a single PFM. With its structural similarity to ion channels, PFM is versatile and easily interfaces with biological systems, paving a way to building neuromorphic devices with advanced functions by introducing rich chemical designs.Long-term memory and synapse-like dynamics in two-dimensional nanofluidic channels¶þάÄÉÃ×Á÷ÌåͨµÀÖеij¤Ê±¼ÇÒäºÍÍ»´¥Ñù¶¯Á¦Ñ§¡ø ×÷ÕߣºP. ROBIN, T. EMMERICH, A. ISMAIL, A. NIGU¨¨S, Y. YOU, G.-H. NAM, A. KEERTHI, A. SIRIA, A. K. GEIM, AND L. BOCQUET¡ø Á´½Ó£ºhttps://www.science.org/doi/10.1126/science.adc9931¡ø ÕªÒª£ºÍ¨¹ýÄÉÃ×¼¶¿×϶½øÐÐ΢µ÷µÄÀë×Ó´«ÊäÊÇÐí¶àÉúÎï¹ý³ÌµÄ¹Ø¼ü£¬°üÀ¨Éñ¾­´«µÝ¡£×î½üµÄ½øչʹˮºÍÀë×ÓµÄÏÞÖƳÉΪ¶þά£¬½ÒʾÁËÔÚ¸ü´ó³ß¶ÈÉÏÎÞ·¨ÊµÏֵĴ«ÊäÌØÐÔ£¬²¢Òý·¢ÁËÖØÏÖÉúÎïϵͳÀë×Ó»úеµÄÏ£Íû¡£×÷Õßͨ¹ýʵÑéÖ¤Ã÷Á˼ÇÒä³öÏÖÔÚË®µç½âÖÊÔËÊ䣨ÑÇ£©ÄÉÃ×¼¶Í¨µÀ¡£ËûÃǽÒʾÁËÁ½ÖÖÀàÐ͵ÄÄÉÃ×Á÷ÌåÒä×èÆ÷£¬È¡¾öÓÚͨµÀ²ÄÁϺÍÏÞÖÆ£¬¼ÇÒ䷶Χ´Ó·ÖÖÓµ½Ð¡Ê±¡£Ñо¿½âÊÍÁËÀë×Ó×Ô×é×°»ò±íÃæÎü¸½µÈ½çÃæ¹ý³ÌÈçºÎ³öÏÖ´óµÄʱ¼ä³ß¶È£¬Äܹ»ÓÃÄÉÃ×Á÷¿ØϵͳʵÏÖHebbianѧϰ¡£¸Ã½á¹ûΪˮµç½âоƬµÄ·ÂÉú¼ÆËãµì¶¨ÁË»ù´¡¡£¡ø Abstract£ºFine-tuned ion transport across nanoscale pores is key to many biological processes, including neurotransmission. Recent advances have enabled the confinement of water and ions to two dimensions, unveiling transport properties inaccessible at larger scales and triggering hopes of reproducing the ionic machinery of biological systems. Here we report experiments demonstrating the emergence of memory in the transport of aqueous electrolytes across (sub)nanoscale channels. We unveil two types of nanofluidic memristors depending on channel material and confinement, with memory ranging from minutes to hours. We explain how large time scales could emerge from interfacial processes such as ionic self-assembly or surface adsorption. Such behavior allowed us to implement Hebbian learning with nanofluidic systems. This result lays the foundation for biomimetic computations on aqueous electrolytic chips.

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