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¶øÒ»µ©Ñ¦±¦îμ޸øÁ˼ֱ¦Óñ£¬¼ÖÀ¼µÄÀûÒæ¾Í»á´ó´óÊÜË𡣡¶¿Æѧ¡·£¨20221104³ö°æ£©Ò»ÖÜÂÛÎĵ¼¶Á2022-11-08 16:15¡¤¿ÆѧÍø±àÒë | ·ëάάScience, 4 November 2022, Volume 378 Issue 6619¡¶¿Æѧ¡·2022Äê11ÔÂ4ÈÕ£¬µÚ378¾í6619ÆÚÎïÀíѧPhysicsEvidence for neutrino emission from the nearby active galaxy NGC 1068À´×Ô¸½½ü»î¶¯ÐÇϵNGC 1068µÄÖÐ΢×Ó·¢ÉäÖ¤¾Ý¡ø ×÷ÕߣºICECUBE COLLABORATION, R. ABBASIM. ACKERMANNJ. ADAMSJ. A. AGUILARM. AHLERSM. AHRENSJ. M. ALAMEDDINEC. ALISPACH, P. ZHELNIN Authors Info & Affiliations, etc.¡ø Á´½Ó£ºhttps://www.science.org/doi/10.1126/science.abg3395¡ø ÕªÒª£º¿Æѧ¹Û²âÖ¤Ã÷Á˸ßÄÜÖÐ΢×ÓµÄÃÖÉ¢±³¾°£¬ËüÃÇÒѱ»È·ÈÏÓÚºÓÍâÆðÔ´¡£µ«ºÜÄÑÈ·¶¨Ôì³ÉÕâÒ»±³¾°µÄ¸ö±ðÀ´Ô´¡£¡°±ùÁ¢·½¡±ºÏ×÷ÏîÄ¿ÖØзÖÎöÁËÌìÌåÎïÀíÖÐ΢×ӵĵ½´ï·½Ïò£¬È»ºóÑ°ÕÒµãÔ´¡£ËûÃÇ´Ó¸½½üµÄ»î¶¯ÐÇϵNGC 1068£¨¼´Messier 77£©Öз¢ÏÖÁËÖÐ΢×Ó·¢ÉäµÄÖ¤¾Ý¡£ËüµÄÐÔÖÊÓë2018Äê·¢ÏÖµÄÖÐ΢×ÓÔ´TXS 0506+056Óкܴó²»Í¬£¬ÕâʹµÃÑо¿ÈËÔ±ÈÏΪ£¬¿ÉÄÜÓв»Ö¹Ò»¸öÖÖȺ¶ÔÖÐ΢×Ó±³¾°×ö³öÁ˹±Ïס£¡ø Abstract£ºObservations have shown a diffuse background of high-energy neutrinos, which is known to be of extragalactic origin. However, it has been difficult to identify individual sources that contribute to this background. The IceCube Collaboration reanalyzed the arrival directions of astrophysical neutrinos and then searched for point sources. They identified evidence for neutrino emission from NGC 1068 (also known as Messier 77), a nearby active galaxy. Its properties are quite different from TXS 0506+056, which was found to be a neutrino source in 2018, leading the investigators to suggest that there might be more than one population contributing to the neutrino background.Robust multi-qubit quantum network node with integrated error detection¾ßÓм¯³É´íÎó¼ì²âÐÔÄܵij°ô¶àÁ¿×Ó±ÈÌØÁ¿×ÓÍøÂç½Úµã¡ø ×÷ÕߣºP. -J. STAS, Y. Q. HUAN, B. MACHIELSE, E. N. KNALL, A. SULEYMANZADE, B. PINGAULTM. SUTULA, S. W. DING, C. M. KNAUT, M. D. LUKIN, etc¡ø Á´½Ó£ºhttps://www.science.org/doi/10.1126/science.add9771¡ø ÕªÒª£º¿ª·¢Á¿×ÓÍøÂçºÍ³¤¾àÀëͨÐÅÁ¿×ÓÐÅÏ¢µÄÄÜÁ¦ÐèÒª¾ßÓиßЧ¹â½Ó¿ÚºÍ³¤´æ´¢Ê±¼äµÄÁ¿×Ó´æ´¢½Úµã¡£½ð¸ÕʯɫÖÐÐľßÓнϳ¤µÄÏà¸Éʱ¼äºÍ¸ßЧµÄ¹âѧ½çÃ棬ÊÇʵÏÖÕâһĿ±êµÄÀíÏë²ÄÁÏ¡£×÷ÕßÀûÓýð¸ÕʯÖеĹè¿Õ룬²¢½«ÕâЩÌØÐÔ¼¯³Éµ½µ¥¸öÆ÷¼þÖС£ËûÃÇÑÝʾÁËÖÖÊÙÃü³¬¹ý2ÃëµÄÁ¿×Ó´æ´¢Æ÷ºÍË«Á¿×Óλ¼Ä´æÆ÷Á¿×Ó̬µÄÈ«¹âѧ¿ØÖÆ¡£¸Ãƽ̨¾ßÓÐÄÚÖõĴíÎó¼ì²âÄÜÁ¦£¬Îª¿ÉÀ©Õ¹Á¿×ÓÍøÂçµÄ·¢Õ¹ÌṩÁ˹ãÀ«µÄÇ°¾°¡£¡ø Abstract£ºThe ability to develop quantum networks and communicate quantum information over long distances requires quantum memory nodes with efficient optical interfaces and long memory times. Because of their long coherence times and efficient optical interface, color centers in diamond are promising candidates to achieve this goal. Stas et al. use silicon vacancies in diamond and integrated the properties into a single device (see the Perspective by Gangloff). The authors demonstrate a quantum memory with a lifetime exceeding 2 seconds and full optical control of the quantum states of the two-qubit register. With the capability of built-in error detection, such a platform is promising for the development of scalable quantum networks. ¡ªÆøºòClimateUnprecedented fire activity above the Arctic Circle linked to rising temperatures±±¼«È¦ÉÏ¿ÕÇ°ËùδÓеĻðÔֻÓëÆøÎÂÉÏÉýÓйءø ×÷ÕߣºADRI? DESCALS, DAVID L. A. GAVEAU, ALEIXANDRE VERGER, DOUGLAS SHEIL, DAISUKE NAITO, AND JOSEP PE?UELAS¡ø Á´½Ó£ºhttps://www.science.org/doi/10.1126/science.abn9768¡ø ÕªÒª£º±±¼«µÄ»ðÔÖ¿ÉÒÔ´ÓÓÀ¾Ã¶³ÍÁÄàÌ¿µØÊͷųö´óÁ¿µÄ̼¡£ÎÀÐǹ۲âÏÔʾ£¬2019ÄêºÍ2020Äê´ó»ðÉÕ»ÙÁËÔ¼470Íò¹«ÇêÄàÌ¿µØ£¬Õ¼Õû¸ö1982-2020ÄêÆÚ¼äÎ÷²®ÀûÑDZ±¼«µØÇøÉÕ»Ù×ÜÃæ»ýµÄ44%¡£2020ÄêµÄÏÄÌìÊÇËÄÊ®ÄêÀ´×îÎÂůµÄÏÄÌ죬´ó»ðÉÕ»ÙÁËÇ°ËùδÓеĴóÃæ»ý¸»º¬Ì¼µÄÍÁÈÀ¡£Ñо¿±íÃ÷£¬½ü¼¸Ê®ÄêÀ´ÓëζÈÏà¹ØµÄ»ðÔÖÒòËØÓÐËùÔö¼Ó£¬²¢È·¶¨ÁËÕâЩÒòËØÓëÄêȼÉÕÃæ»ýÖ®¼äµÄ½üÖ¸Êý¹Øϵ¡£ÔÚ±¾ÊÀ¼ÍÖÐÒ¶֮ǰ£¬Ëæ×ÅÆøºò±äů£¬±±¼«µÄ´ó»ð¿ÉÄÜ»áÔٴη¢Éú£¬ÒòΪζÈÇ÷ÊÆÕýÔÚ´ïµ½Ò»¸öãÐÖµ£¬¼´Î¶ȵÄС·ùÉÏÉýÓëȼÉÕÃæ»ýµÄÖ¸ÊýÔö³¤Ïà¹Ø¡£¡ø Abstract£ºArctic fires can release large amounts of carbon from permafrost peatlands. Satellite observations reveal that fires burned ~4.7 million hectares in 2019 and 2020, accounting for 44% of the total burned area in the Siberian Arctic for the entire 1982¨C2020 period. The summer of 2020 was the warmest in four decades, with fires burning an unprecedentedly large area of carbon-rich soils. We show that factors of fire associated with temperature have increased in recent decades and identified a near-exponential relationship between these factors and annual burned area. Large fires in the Arctic are likely to recur with climatic warming before mid-century, because the temperature trend is reaching a threshold in which small increases in temperature are associated with exponential increases in the area burned.The January 2022 eruption of Hunga Tonga-Hunga Ha¡¯apai volcano reached the mesosphereÌÀ¼Ó»ðɽÅç·¢ÎïÖʵ½´ïÖмä²ã¡ø ×÷ÕߣºSIMON R. PROUD, ANDREW T. PRATA, AND SIMEON SCHMAUS¡ø Á´½Ó£ºhttps://www.science.org/doi/10.1126/science.abo4076¡ø ÕªÒª£º´ó¹æÄ£¡¢±¬Õ¨ÐԵĻðɽ±¬·¢¿ÉÒÔ½«»ðɽ»Ò¡¢ÆøÌåºÍË®µÈÎïÖÊÅ×ÈëƽÁ÷²ã£¬¶Ô´óÆø³É·ÖºÍÆøºò²úÉú¿É²âÁ¿µÄÓ°Ïì¡£×÷ÕßʹÓÃÁË2022Äê1ÔÂÌÀ¼Ó»ðɽÅç·¢µÄµØÇòͬ²½ÎÀÐÇͼÏñ£¬ÕâÊÇÓмǼÒÔÀ´×î´óµÄÅç·¢Ö®Ò»£¬ÏÔʾÆä»ðɽÔÆ´ïµ½ÁË57¹«ÀïµÄ¸ß¶È£¬Ô¶Ô¶³¬¹ýƽÁ÷²ã£¬½øÈëÖмä²ã£¬¸ßÓÚ֮ǰ¼Ç¼µÄÈκλðɽÓðÁ÷¡£ÕâÊǵÚÒ»´Î¿´µ½ÓðÁ÷´©Í¸Æ½Á÷²ã¶¥¡£¡ø Abstract£ºLarge, explosive volcanic eruptions can loft material such as ash, gases, and water all the way into the stratosphere, with measurable impacts on atmospheric composition and climate. Proud et al. used geostationary satellite images of the January 2022 Hunga-Tonga volcano eruption, one of the largest eruptions ever recorded, to show that its volcanic cloud reached an altitude of 57 kilometers, well past the stratosphere and into the mesosphere and higher than any volcanic plume previously recorded. This is the first time a plume has been seen to penetrate the stratopause.ÉúÃü¿ÆѧLife ScienceOn-demand cell-autonomous gene therapy for brain circuit disordersϸ°û×ÔÖ÷»ùÒò°´ÐèÖÎÁÆÄԻطÎÉÂÒ¡ø ×÷ÕߣºYICHEN QIU, NATHANAEL O¡¯NEILL, BENITO MAFFEICLARA ZOURRAY, AMANDA ALMACELLAS-BARBANOJ, JENNA C. CARPENTER, GABRIELE LIGNANI, etc.¡ø Á´½Ó£ºhttps://www.science.org/doi/10.1126/science.abq6656¡ø ÕªÒª£º½üÈý·ÖÖ®Ò»µÄñ²ðﻼÕ߶ÔÄ¿Ç°¿ÉÓõĿ¹ñ²ðïÒ©ÎïûÓз´Ó¦¡£¿Æѧ¼ÒÒѾ­Ìá³öÁ˼¸ÖÖ»ùÒòÖÎÁÆ·½·¨£¬µ«ÕâЩ·½·¨ÍùÍù²»¼ÓÇø±ðµØÕë¶ÔÌض¨´óÄÔÇøÓòµÄËùÓÐÉñ¾­Ôª¡£×÷Õß¿ª·¢ÁËÒ»ÖÖ»ùÒòÖÎÁƲßÂÔ£¬¿ÉÒÔ×ÔÎÒÑ¡ÔñÔÚ²¡ÀíÉϹý¶È»îÔ¾µÄÉñ¾­Ôª£¬²¢ÔÚ±Õ»·ÖÐϵ÷ËüÃǵÄÐË·ÜÐÔ¡£ËûÃǽ«±àÂë¼ØͨµÀµÄKCNA1»ùÒòÖÃÓÚÒ»ÖÖ¼´Ê±ÔçÆÚ»ùÒòÆô¶¯×ӵĿØÖÆ֮ϣ¬¸ÃÆô¶¯×ӵĻîÐÔÓÉÇ¿ÁÒµÄÉñ¾­Ôª·ÅµçÆô¶¯¡£Ò»µ©´óÄԻط»î¶¯»Ö¸´µ½»ùÏßˮƽ£¬ÖÎÁƾͻá×Ô¶¯¹Ø±Õ¡£ÕâÖÖ·½·¨Ô­ÔòÉÏ¿ÉÒÔÓÃÓÚÖÎÁÆÈκÎÉñ¾­¾«ÉñÕÏ°­£¬ÆäÖÐÖ»ÓÐÒ»¸öÉñ¾­ÔªÑÇȺÔÚ²¡ÀíÉϹý¶È»îÔ¾¡£¡ø Abstract£ºNearly one-third of epilepsy patients do not respond to currently available anti-epileptic drugs. Several gene therapy approaches have been suggested, but these methods tend to indiscriminately target all neurons in a given brain region. Qiu et al. developed a gene therapy strategy that self-selects neurons that are pathologically overactive and down-regulates their excitability in a closed loop. They put the KCNA1 gene, which encodes a potassium channel, under the control of an immediate early gene promoter with activity that is switched on by intense neuronal firing. The treatment switches itself off once brain circuit activity has returned to baseline. This approach could in principle be used to treat any neuropsychiatric disorder in which only a subpopulation of neurons is pathologically overactive.The control of carpel determinacy pathway leads to sex determination in cucurbitsÐÄƤ¾ö¶¨Í¨Â·µÄ¿ØÖƾö¶¨¹ÏÀàÐÔ±ðÑ¡Ôñ¡ø ×÷ÕߣºSIQI ZHANG, FENG-QUAN TAN, XCHING-HUI CHUNGFILIP SLAVKOVICRAVI SURESHBHAI DEVANI, CHRISTELLE TROADEC, FABIEN MARCEL, HALIMA MORINC?LINE CAMPS, ABDELHAFID¡ø Á´½Ó£ºhttps://www.science.org/doi/10.1126/science.add4250¡ø ÕªÒª£ºÔÚ¹ÏÀàÖУ¬»¨×î³õÊÇË«ÐÔÐÔ·¢ÓýµÄ£¬µ«½øÒ»²½µÄ·¢Óýµ¼ÖÂÐÄƤ»òÐÛÈï·¢ÓýµÄÍ£ÖÍ£¬Ê¹³ÉÊìµÄ»¨Ï¸»¯ÎªÐÛÐÔ»ò´ÆÐÔ¡£Ö»Óдƻ¨²Å»á³ö¹Ï¡£ZhangµÈÈËÒѾ­È·¶¨Á˲ÎÓëÁ½ÐÔԭʼ»¨±ä³ÉÐÛÐÔ»ò´ÆÐÔ»¨µÄ»ùÒò¡£Ð¿Ö¸×ªÂ¼Òò×ÓWIP1»á¸ÉÈÅÐÄƤµÄ·¢Óý£¬Ê¹ÐÛ»¨µÃÒÔ¼ÌÐø·¢Óý¡£Ïà·´£¬Ò»ÖÖÓë²úÉú¼¤ËØÒÒÏ©ÓйصÄøµÄ±í´ï£¬¿ÉÄÜÊÇÓÉÉú³¤ËØÐźÅÖ§³ÖµÄ£¬Ö§³ÖºÍ´Ù½ø´Æ»¨µÄ·¢Óý¡£Ñо¿½á¹û±íÃ÷£¬ÐÔ±ð»ùÒòµÄ½ø»¯¸ÉÈÅÁË»¨µÄ·ÖÉú¹¦ÄÜ£¬µ¼ÖÂÁ˵¥ÐÔ»¨µÄ·¢Óý¡£¡ø Abstract£ºIn melons, flowers initially develop bisexually, but further development brings arrest of either carpel or stamen development, refining mature flowers into male or female. Only the female flowers produce melons. Zhang et al. have identified the genes involved in turning the bisexual primordial flower into either a male or female flower. The zinc finger transcription factor WIP1 interferes with carpel development, allowing male flower development to proceed. Conversely, expression of an enzyme involved in producing the hormone ethylene, perhaps supported by auxin signaling, supports and promotes female flower development. The findings suggest that sex genes evolved to interfere with flower meristematic function, leading to unisexual flower development.