91��Ƶר��

��̵ع��-Ұ��ѹۿ��ձ��Ӱ��

��֮�£�̩��һλ��޹��绪��ò�续��˼��

2024��12��23�գ�He has thus managed to offend black people and anti-racists without making any compensating gains among white voters attracted to Reform, presumably the object of his manoeuvres.

��̵ع��-Ұ��ѹۿ��ձ��Ӱ��

33ֻ�϶ٱ��ھ�ֵ��10%

��ͨ��2022��ҵ��ҵ��2022��ĩ��Ͻ��ҵ�ʲ��ܶ�12.22��Ԫ��ͬ��8.47%��8.85��Ԫ��ͬ��12.49%��8.49��Ԫ��ͬ��7.93%��ڱ��շ��˻��ʲ�6.44��Ԫ��ͬ��9.1%��ȫ��Ͻ��г�ʵ�ֱ��1527.7��Ԫ��ͬ��7.1%��ѡ̨��Դ��⼸���㲻�ܴ��2021-02-19 01:25��̫ƽ��̫ƽ�� Ƶ��Ȼ2020��Ӱ�죬ȫ��»��Դ�г��Ǹ��һ�鵰�⡣��2020��ĵ��ļ��Ⱥͽ��괺��ǰ�󣬸��ӿ��һ��ʵ��ֵ�Լѵĳ��ͣ��е��Դ�ͳ��е��쳵��е��Ѿ��У��еĲŸոշ��ɷ��ϵ��ǣ�ÿһ���Ŀǰ��š��Ĳ����ѡ��Դ�Ļ��⼸���Բ��ܴ��˹��Model Y��SUV��Model 3��˲��ۼۣ�33.99-36.99��2021��Ԫ��˹��ʽ��ȫ�¹��Model Y��Ҳ��˹��ĵڶ��ͣ��Ϊ��ǰModel 3�ڹ��ڵĴ��ɹ��Ҳʹ��ֵܳ��Model Y��б��˳�Ȧ��Ԫ��е��õ��10��̨�Ķ��Ϣ��Ӳ��Ƕ��Ϊ��Model 3ͬƽ̨��죬��Ʒ��Ҳ��Model 3ʮ��ƣ��ͬ��ǣ�Model Y��λ��һ̨��SUV��ߴ��Ҫ��󣬳��ռ��Ϊ��ԣ��Ӧ�ļ۸�ҲҪ��һ�㣬��͸��ܰ��ۼ۷ֱ�Ϊ33.99��36.99��Ԫ��Ȼ��ˣ��ȴ��Model X��˵��۸��Ѿ��ڶ��ߴ��ˡ�Model Y��ϵƵ��|��|ͼƬ|��|��̳|��̼ұ��ۣ�33.99~36.99��ڹ��ȡ�ͼ��Ȼ��ͷ��ƶȺܸߣ��Ӳ��Model3��ԵĲ�ͬ�ģ�Model Y��SUV��ͣ��Գ��ߣ��β��̣��Զ�˿��ȷʵ�е��Model X��ֻ��û��Ÿ��Ŷ��ѡ�ͬʱ��·��ı��Ҳ��Կ��Model Y��Model 3��56mm��71mm��181mm��೤��15mm��Ȼ��ݲ��濴��ֻ�Ǽ��ף��ʵ��飬��ĳߴ�ȷʵ��Model Y�Ŀռ�ʵ��˷ǳ��ڶ��Model 3��žִٵ��ߣ��Model Y��Ӧ��˵��ʲô�ˣ���Ѿ��ﵽ��һ��SUV�Ļ��׼��Ȼ��˵��̣�Ҳ�ڳ��ԽҰ��ģʽ��䱸��ϵͳ��Ϊһ̨SUV��ͣ��˹��Model Y�ĵ��ؼ�϶ֻ��166mm��Ҳ��Model Y��һ̨�ܹ�ȥ��ԽҰ��ĳ��ͣ��Ȼ��ԺͿռ��ֲ��Model Y��ص㡣Model 3��һ��в��һ��ط��Model Y��Model 3��ͬһ��ϸ�ں��仯��󣬼�Լ�Ĳ��֡�˶��Ļ�Լ��ᴩʽ��ڣ�էһ��ƺ�ûʲô��𡣲��ϸ��֮��һЩ�Ķ��ٿ��廻��ĥɰ��ϲ��ʣ��ָ��Լ��ۡ��Ļ��ûʲôʵ��ô��ı��ܻ��߳��򣬿��ͬʱ��ֻ��ϵİ��Ҳ��ϻ��˽��Ҳ��ǲ��ˡ��е��˹��һ��Model YҲ��һ��ʽ��Σ��ţ��εĳ��о��ԱȽ�Ӳ��Ҳ��㳤��ڵذ��м��Ǵ�ƽ�ģ��м�˿�Ҳ��Էŵ��½ţ��ȫ��촰��Կռ�Ϳ��Զ��ܲ��Ա�Model3�Ѿ��Ҫ��ˣ��һ��ľ��롣��ڶ��棬��汾�͸��ܰ汾��ǰ��Ӧ�첽��+��ͬ��Ķ��ϣ��汾��317kW��Ť��545N��m��ٹ��Ϊ5.1s��߳��217km/h��ܰ汾��Ϊ339kW��Ť��623N��m��ٹ��Ϊ3.7s��߳��241km/h��߶�ʹ��Ϊ77kWh��Ԫ﮵�ض��飬��Ų��ֱ�Ϊ594km��480km��ĳ��汾��5.1s�ļ��ٳɼ��ճ��Ҳ��㹻�ˣ�ͬʱ�³��г��Ҳ��ϱ��Ͽɣ��Ȼ��ǰ��Сȱ��Ի��ڣ��ɷ��ϵ��ǣ��˹��Model Y��2021��ֵ�ù��ĵ綯��֮һ��ε��ET7��1000km��ĵ綯��㰮��𣿲��ۼ�: 44.80-52.60��1��9�գ��ڳɶ��ٰ�NIO day�ϣ�ε��ʽ��µ��׿�綯�γ��ε��eT7��ۼ�Ϊ44.80-52.60��Ԫ��λ��һ̨�д��ʹ��綯�γ��5�ף��೬��3�ף�ֱ�Ӿ��ɱ��˹��Model S��Ͼ��綯�γ��50��ĿǰҲ��һ��ˣ�ͬʱ�³��ȫ�µ�150kWh��̵�ذ��ܶ�Ҳ�ﵽ��360wh/kg��NEDC��1000km��ε��ET7��ϵƵ��|��|ͼƬ|��|��̳|��̼ұ��ۣ�44.80~52.60��ڹ��ȡ�ͼ��ϣ�eT7��屣��ε��Ʒ��ԭ�еķ�񣬲��ε��µ��Զ��ʻ��NAD��NIO Autonomous Driving��ڳ��ദ�ܹ��Զ��ʻӲ��ĺۼ��λ��ǰ�絲�Ϸ��ļ��״��ͷ�ȣ��Ӷ��ϵͳ��Ұλ��+��ӽ�+��߷ֱ��+��Զ̽��ٷ��³�δ��ʵ�ָ��١��ͣ��ӵ�ȳ��µĵ㵽��Զ��ʻ��顣�³��ĳ��߷ֱ�Ϊ5098mm/1987mm/1505mm��ﵽ��3060mm��ݺ��C��γ��ǻ��һ�µģ��ú��;��Գе��ͬʱ�³��ȫϵ��޿��ţ��Ӿ�Ч��Ҳ��Ϊ�˶��ε��eT7�ĳ��ڲ��˵ڶ��գ��ε��з��ɵ��տ��ͬʱ��ڵ��顰��10.2Ӣ��HDR��Ǳ��12.8Ӣ��AMOLED�пش��ɫ�ʡ��ֱ��ʺͶԱȶȷ��涼��˴��ټ��64ɫ�ķ�Χ�ƺ��ʽ�Ŀյ��ڣ�Ӫ��Ӿ�Ч��㹻��ʵġ��ڲ��ϣ��³��2+3��5��֣��ǰ��α��14��綯��ڡ��ɺ�ͷ��ɵ��Լ��ͨ�缼��ȣ��27��ʿ��Ƕȣ��Լ��/ͨ��/��Ħ�ȹ��ܡ�Ŀǰ��Դ�г��ˮƽ��500km��ң��緶Χ��ʵҲ��ȵģ��ε��eT7��˵�ٴν��綯��ˮƽ�ε��һ��µĸ߶ȣ��䱸��150kWh��̵�ذ��Ŀǰȫ��ߵĵ�ذ��ܶ�Ҳ�ﵽ��360wh/kg��Ͻϵ͵ķ��ϵ��ε��eT7��NEDC��Ԥ�ƽ��ɹ��Խ1000km�Ĵ�ء�ͬʱ�ٷ��ε��eT7�Ĳ��ǰ��ۼ�Ϊ44.8��Ԫ��׷��油��ǰ��ۼ�Ϊ52.6��Ԫ��BaaS��޷���͵��ۼ۷ֱ�Ϊ37.8��Ԫ��39.8��Ԫ��ĿǰҲ��ε��APP��Ԥ��Ԥ�ƽ��2022��һ��Ȼ��2021��ĩ��ʼ��ʽ��E-HS9��Դ��Ĵ��SUVָ��: 50.98-72.98��2020��ı��չ��һ��ȫ�µĴ��콢SUV-��E-HS9��º��ʽ��У��Ƴ��Ŀ�ͣ��ۼ�Ϊ50.98-72.98�򣻴��³��ļ۸��ȷʵ��ˣ��ǿ��ǵ��һ��λ�뱦��X7��GLSһ��ĺ��ʹ��綯SUV��Ǻ��Ʒ�Ƶĵ綯�콢��۸��ȼ�ͳ��һЩҲ�Ǻ��ص��ǣ�E-HS9��˺��Ʒ��ƺ�ǰհ��Ƽ��ǿ��ը�ѡ��E-HS9��Ҫ�ߺ��Ƽ�·�ߣ��ĵط��п�̨�Ǽ��ҹᴩ�Ĵ��˳��ں��Ŀռ��ܣ��˳��ڵĿƼ��ʸС��⣬��ص��ɫ��Ƥ��ľ��ΰ壬��Ͽյ��ڡ��Ǳ��̡��ܾ��µĶƸ��θкͲ�θ�Ҳ��û��˵��˵��ڣ��֮��㹻��ϸ�壬û��̫��Ӳ�ס��E-HS9�ṩ��桢��棬��У��Ƕ��䳵�ͣ��ṩ��ͬ��λ��󼰵��ڶ��ſռ䣬��Ⱥ��MPV��й�֮��޲��ڶ��棬��E-HS9��ṩ��ֶ��汾��͹��Ϊ��棬��160kW��ֵŤ��350N��m��߹��һ̨��õ��˫��ۺ��245kW��ֵŤ��450N��m��ٹ��ٽ�Ϊ4.8s��ͬʱ��п��ܺ��ӵ��7�ּ�ʻģʽ��棬��NEDC��Ϊ460km��˫��Ϊ510km��Ҳ��ճ�ʹ��ˡ��E-HS9��˵�Ǻ��߶��Դ�г��Ҫ��һ��壬ͬʱ��õĸ��ϸ��Ҳ�ܿ��з��ŶӶ��̨�콢��Ĳ��ߴ�51��ۼۣ�Ҳע����ᱻ��Ѹ�ٵĽ��ܣ��ɷ��ϵ��ǣ��һ��ܴ��ڶྪϲ�ġ��ġ�֮��С��P7��ֵ��ʵ��Լѵ��ѡ�ֲ��ۼۣ�22.99-40.99��2020��8�·ݣ�С��ʽ��Ŧ��У��Ϊ��ε��֮��ĵ��е��쳵��ĳ�Ȧ�ڿ��˵�Ƿ�ͷ��ˡ��Ӳ��﷽��С��P7��ΪС��ܹ�ע�ĳ��ͣ��ΪС��˲��ٵ��ƣ�ͬʱҲƾ��706km��̣��ͱ��һ��ڶ��ǰһ��˵��Ŀǰ��Դ��ߵ�ѡ��֮һ�ˡ�С��P7��ϵƵ��|��|ͼƬ|��|��̳|��̼ұ��ۣ�22.99~40.99��ڹ��ȡ�ͼ��ų��μ��С��P7��û��˻᲻��ȫ�µġ��Ǽʡ��Լȳ��Դ��͵�δ��У�ͬʱҲ��ʧ��ͳ��һ��ϸ�ڵľ��ѿأ��ǰ��̨��պ족��ɫ��ȻҪ��⻨��3000Ԫ��ѡװ��ã��ɫ��·��ĺ�ɫ��Χ��Ӫ��ʱ�з��Ҳ�ǲ��ʧ��ߴ緽�棬С��P7�ĳ��߷ֱ�Ϊ4880��1896��1450mm��Ϊ2998mm��ӽ�3�׵��Ӧ��̨��ӵ��ŷǳ��ɫ�Ŀռ��֣��˵��֮��ȴ�׷ױ�ʾ��Ԥ��ô��ɫ��ֱ�Ӿ��˹��Model3��Ҫ��ϲ��ٵģ��Ͼ��һ̨��ͽγ��С��P7�ĳ��ͬ��ߵ�Ҳ�Ǽ�Լ��񣬲��˴��ƽֱ��ȥ��Բ�θУ�ͬʱ��ߴ�޴��ĻҲ��Ե÷ǳ�ǰ��Ҳ�ǿ�Ȧ�ɵ㡣��忴��ȷʵ�ﵽ�˹��Դ��֮�н�Ϊ��ȵ�Ʒ�ʸС�С��P7��ص����ϵͳ��˸�ͨ��820A��漶��4��CPU��ΪXmart OS��ϵͳ�ṩ�˳��Ӳ��֧�š��ʵ��ϣ��Ļ��ɫ��Ҳ��ý�Ϊ�õ��ȫû��۸У��Ƭʽ�Ĺ��ܲ˵�Ҳ��ϵ��ܲ��ʹ��߼��ͬ��֮�бȽ��ȡ��ڶ��档С��P7�ĺ��ͺ��棬�ڶ��ܳɷ��һ��ģ��ں��ϴ��һ��ͬ��196kW��267Ps��ֵŤ��390N��m��ܰ汾��ڴ˻��һ��ǰ��Ϊ316kW��430Ps��ֵŤ��655N��m��ͳ��صľ�Ϊ��Ϊ80.9kWh��Ԫ﮵�أ��̽��562km��Ժ��汾��С��ĳ��͡����Ź��Դ�г��𽥳��ƣ��Ĵ��糵��Խ��Խ�࣬�п��ʵ��ͻ��Ĳ��ҲԽ��Խ�ࣻ��̵��Ŀ�ͣ��κ�һ��ڽ��϶��˲��ҵ�Ŀ�⣬��ҵĵ�Ҳ��ֻ��۷��棬��ΪƷ�ʸ�Ҳ�Ѿ��ﵽ�˿��͵ĳ̶ȣ�Ŀǰ��˹��ModelY��E-HS9��С��P7����Ѿ��ʽ��У��ڲ�Զ�Ľ��1000��ε��eT7Ҳ��ʽ��г��ʱԤ�ƽ��ֻ�ӿ�ֳ�һ��ո�µĳ��ͣ��һ��ڴ�һ�°ɡ��ͼ/��/�㣺̫ƽ�� ݣ�

չ��ʣ��68%

��ɲ��ܲⲹ�Գ��Բ��岹�Գ��ǲԲ��ܳ��ܳ澱��ǻ�𳾾��Բ��ɳ��ᾱ�Բ��ǳܳ��ԣ��⾱��ܱ��Բ��ܳ��ܳ澱��ǲ��ᾱ�𣬲��ܲ��ܴǳ��ܲ��⾱��ܣ��ܲԲ��󾱲⾱�Բ��ɳܲ��ܷɲ��Բ��ǳܻ�ܾ��ٲ��ܳ��ԡ��ٲ��Ǳ��ܱ�ܱ��󾱳��Բ��ܳ󲹴ǣ��ܾ��𾱳��ܲԳ�ǳܲ��𾱱��ܳ澱��ܳ󲹴ǻ��⾱�Գ澱��Բ��Ա��ܾ��Էɱ𾱲Ծ��岹��ܲ��ᾱ��ڱ�Բ��羱��

-��(��Բ�)��(��ǳ�)2��(��󲹴�)

��ǲԲ��ᾱ��Բ��ܱ��ܲ��Գ��ǳ��ᾱ��Գ�ǳܣ��辱�Բ��徱�Բ��󲹲Բ��ǲԲ��󾱲��ᾱ��ܳ�ܱ��ܲ��Գ��ᾱ��Ա��Ǳ羱��Բ��岹��󾱳��ٳܲ��Ի�ܾ��𲵳ܲ��Ա��ܾ��ɳܣ��ǳ��ᾱ��԰��ܱ��𾱳�ܲԳ��ǲ��󾱣��ɲ��Բ��󲹲Բ��󾱳�ܲԳپ��ᾱ��ԡ��󾱻��⾱�پ��󾱣��Բ��Բ��Բ��ǲԲ��ǲԲ��ܾ��ǲԲ��ܴǱ辱�Բ��𾱲��Գ��ᾱ�ٳܲ��Բ��ǲԲ��ܾ��ǳܱ��󾱳��󾱳澱��辱�Բ��徱�Բ��󲹲Բ��ǲԲ��󾱲��ᾱ��ܳ�ܱ��ܲ��Գ��ܱ�澱��ǲԱ𾱳��ܲ��Գ��Գ��ᾱ��Ա��ᾱ�Ա�Բ��岹��󾱲��ǲԲ��ܴǳ��󲹲ԣ��󾱲��󾱡��󾱻岹��ٳܡ��Գ��𾱲ⲹ�Բ��Բ��Ի徱�Բ��󾱰��Գ��𾱲ⲹ�Բ��ڲ��Բ��ԡ��ܳپ��ܰ��辱��ǲ�ܲ��ǳܱ羱15�پ��Ի�𲵳ܾ��徱�Բ��ᾱ�԰��⾱��ǳܳ��羱�Բ��Բ��ᾱ��岹�Բ��پ��Ի��ܴǳ��辱��ǣ��ǳܳ��ܳ澱�Բ��ᾱ��ܲ��ٴǲԲ��ܱ𣬰��⾱��Բ��12306�ɲ��Բ��󲹲ԡ��پ��12306��賦�󲹳�ܲԲ��ǳܱ辱��ǡ�

��(Ke)ѧ(Xue)��20230922��(Chu)��(Ban)��һ(Yi)��(Zhou)��(Lun)��(Wen)��(Dao)��(Du)2023-09-25 10:31��(Ke)ѧ(Xue)��(Wang)��(Bian)��(Yi) | ��(Feng)ά(Wei)ά(Wei)Science, 22 SEP 2023, VOLUME 381, ISSUE 6664��(Ke)ѧ(Xue)��2023��(Nian)9��(Yue)22��(Ri)��(Di)381��(Juan)��6664��(Qi)��(Tian)��(Ti)��(Hua)ѧ(Xue)AstrochemistryEndogenous CO2 ice mixture on the surface of Europa and no detection of plume activityľ(Mu)��(Wei)��(Er)��(Biao)��(Mian)��(De)��(Nei)Դ(Yuan)��(Xing)��(Gan)��(Bing)��(Hun)��(He)��(Wu)�� (Zuo)��(Zhe)��G. L. VILLANUEVA L. ROTH, K. P. HAND, L. PAGANINI, J. STANSBERRY , AND G. LIUZZI�� (Lian)��(Jie)��https://www.science.org/doi/full/10.1126/science.adg4270�� ժ(Zhai)Ҫ(Yao)��ľ(Mu)��(Wei)��(Er)��(Zai)��(Bing)��(Leng)��(De)��(Di)��(Ke)��(Xia)��(You)һ(Yi)��(Ge)��(Di)��(Xia)��(Hai)��(Yang)��(Qi)��(Hai)��(Yang)��(Nei)��(Bu)��(Qing)��(Kuang)��(Shang)��(Bu)��(Qing)��(Chu)��Ҳ(Ye)��(Bu)��(Qing)��(Chu)��(Ta)��(Shi)��(Fou)��(Yu)��(Hai)��(Mian)��(Xiang)��(Lian)��(Yan)��(Jiu)��(Zhe)��(Yong)ղ(Zhan)ķ(Mu)˹(Si)��Τ(Wei)��(Bu)̫(Tai)��(Kong)��(Wang)Զ(Yuan)��(Jing)��(Guan)��(Cha)ľ(Mu)��(Wei)��(Er)��ͨ(Tong)��(Guo)̽(Tan)��(Ce)��(Qi)��(Biao)��(Mian)��(He)��(Da)��(Qi)��(Lai)Ѱ(Xun)��(Zhao)��(Huo)Ծ(Yue)��(De)��(Wu)��(Zhi)��(Shi)��(Fang)��(Dui)��(Yu)��(Liu)��(De)��(Sou)��(Suo)û(Mei)��(You)��(Jian)��(Ce)��(Dao)ˮ(Shui)��һ(Yi)��(Yang)��(Hua)̼(Tan)��(Jia)��(Chun)��(Yi)��(Wan)��(Huo)��(Jia)��(Wan)ӫ(Ying)��(Guang)��(Fu)��(She)��(Dan)��(Jian)��(Ce)��(Liao)��(Gan)��(Bing)��(De)��(Si)��(Zhong)��(Guang)��(Pu)��(Te)��(Zheng)��(Ta)��(Men)��(De)��(Guang)��(Pu)��(Xing)״(Zhuang)��(He)��(Zai)ľ(Mu)��(Wei)��(Er)��(Biao)��(Mian)��(De)��(Fen)��(Bu)��(Biao)��(Ming)��(Er)��(Yang)��(Hua)̼(Tan)��(Yu)��(Qi)��(Ta)��(Hua)��(He)��(Wu)��(Hun)��(He)��(Zai)һ(Yi)��(Qi)��(Ji)��(Zhong)��(Zai)��(Ta)��(La)��(Di)��(Qu)��(Yan)��(Jiu)��(Zhe)��(Ren)Ϊ(Wei)��(Guan)��(Ce)��(Jie)��(Guo)��(Biao)��(Ming)̼(Tan)��(Lai)��(Zi)ľ(Mu)��(Wei)��(Er)��(Nei)��(Bu)�� Abstract��Jupiter��s moon Europa has a subsurface ocean beneath an icy crust. Conditions within the ocean are unknown, and it is unclear whether it is connected to the surface. We observed Europa with the James Webb Space Telescope (JWST) to search for active release of material by probing its surface and atmosphere. A search for plumes yielded no detection of water, carbon monoxide, methanol, ethane, or methane fluorescence emissions. Four spectral features of carbon dioxide (CO2) ice were detected; their spectral shapes and distribution across Europa��s surface indicate that the CO2 is mixed with other compounds and concentrated in Tara Regio. We interpret these observations as indicating that carbon is sourced from within Europa.The distribution of CO2 on Europa indicates an internal source of carbon��(Er)��(Yang)��(Hua)̼(Tan)��(Zai)ľ(Mu)��(Wei)��(Er)��(Shang)��(De)��(Fen)��(Bu)��(Biao)��(Ming)��(Liao)̼(Tan)��(De)��(Nei)��(Bu)��(Lai)Դ(Yuan)�� (Zuo)��(Zhe)��SAMANTHA K. TRUMBO AND MICHAEL E. BROWN�� (Lian)��(Jie)��https://www.science.org/doi/full/10.1126/science.adg4155�� ժ(Zhai)Ҫ(Yao)��ľ(Mu)��(Wei)��(Er)��(Di)��(Xia)��(Hai)��(Yang)��(Hua)ѧ(Xue)��(Cheng)��(Fen)��(Zai)��(Hen)��(Da)��(Cheng)��(Du)��(Shang)��(Shi)δ(Wei)֪(Zhi)��(De)��(Yi)ǰ(Qian)��(Zai)ľ(Mu)��(Wei)��(Er)��(Biao)��(Mian)��(Jian)��(Ce)��(Dao)��(Er)��(Yang)��(Hua)̼(Tan)��(Dan)��(Wu)��(Fa)ȷ(Que)��(Ding)��(Ta)��(Shi)��(Lai)��(Zi)��(Di)��(Xia)��(Hai)��(Yang)��(Hua)ѧ(Xue)��(You)ײ(Zhuang)��(Ji)��(Dai)��(Lai)��(De)��(Huan)��(Shi)��(You)ײ(Zhuang)��(Ji)��(Dai)��(Lai)��(De)��(Wu)��(Zhi)��(De)��(Fu)��(She)��(Chu)��(Li)��(Zai)��(Biao)��(Mian)��(Chan)��(Sheng)��(De)��(Yan)��(Jiu)��(Zhe)��(Li)��(Yong)ղ(Zhan)ķ(Mu)˹(Si)��Τ(Wei)��(Bu)̫(Tai)��(Kong)��(Wang)Զ(Yuan)��(Jing)��(Huo)��(De)��(De)��(Guan)��(Ce)��(Shu)��(Ju)��(Hui)��(Zhi)��(Liao)ľ(Mu)��(Wei)��(Er)��(Shang)��(Er)��(Yang)��(Hua)̼(Tan)��(De)��(Fen)��(Bu)ͼ(Tu)��(Ta)��(Men)��(Zai)��(Ta)��(La)��(Di)��(Qu)��(Fa)��(Xian)��(Liao)��(Gao)Ũ(Nong)��(Du)��(De)��(Er)��(Yang)��(Hua)̼(Tan)��(Zhe)��(Shi)��(Zui)��(Jin)��(Zhong)��(Xin)��(Di)��(Biao)��(De)��(Di)��(Xing)��(Zhe)��(Biao)��(Ming)��(Er)��(Yang)��(Hua)̼(Tan)��(Lai)Դ(Yuan)��(Yu)��(Nei)��(Bu)̼(Tan)Դ(Yuan)��(Yan)��(Jiu)��(Zhe)��(Ren)Ϊ(Wei)��(Er)��(Yang)��(Hua)̼(Tan)��(Shi)��(Zai)��(Hai)��(Yang)��(Nei)��(Bu)��(Xing)��(Cheng)��(De)��(Jin)��(Guan)��(Bu)��(Neng)��(Pai)��(Chu)��(Er)��(Yang)��(Hua)̼(Tan)��(Shi)ͨ(Tong)��(Guo)��(Hai)��(Yang)��(You)��(Ji)��(Wu)��(Huo)̼(Tan)��(Suan)��(Yan)��(De)��(Fu)��(She)��(Fen)��(Jie)ת(Zhuan)��(Hua)��(Zai)��(Hai)��(Yang)��(Biao)��(Mian)��(Xing)��(Cheng)��(De)�� Abstract��Jupiter��s moon Europa has a subsurface ocean, the chemistry of which is largely unknown. Carbon dioxide (CO2) has previously been detected on the surface of Europa, but it was not possible to determine whether it originated from subsurface ocean chemistry, was delivered by impacts, or was produced on the surface by radiation processing of impact-delivered material. We mapped the distribution of CO2 on Europa using observations obtained with the James Webb Space Telescope (JWST). We found a concentration of CO2 within Tara Regio, a recently resurfaced terrain. This indicates that the CO2 is derived from an internal carbon source. We propose that the CO2 formed in the internal ocean, although we cannot rule out formation on the surface through radiolytic conversion of ocean-derived organics or carbonates.��(Hua)ѧ(Xue)ChemistrySolid-solvent processing of ultrathin, highly loaded mixed-matrix membrane for gas separation��(Gu)��(Rong)��(Chu)��(Li)��(Chao)��(Bao)��(Gao)��(Fu)��(He)��(Hun)��(He)��(Ji)��(Zhi)Ĥ(Mo)��(Yong)��(Yu)��(Qi)��(Ti)��(Fen)��(Li)�� (Zuo)��(Zhe)��GUINING CHEN, CAILING CHEN, YANAN GUO, ZHENYU CHU, YANG PAN, GUOZHEN LIU, GONGPING LIU , YU HAN, WANQIN JIN, AND NANPING XU�� (Lian)��(Jie)��https://www.science.org/doi/full/10.1126/science.adi1545�� ժ(Zhai)Ҫ(Yao)��(Yi)��(Fei)ʯ(Shi)��(He)��(Jin)��(Shu)��(You)��(Ji)��(Gu)��(Jia)��MOF��Ϊ(Wei)��(Dai)��(Biao)��(De)��(Na)��(Mi)��(Duo)��(Kong)��(Jing)��(Ti)��(Cai)��(Liao)��(Zi)Ȼ(Ran)��(Bao)��(Han)��(Lian)��(Xu)��(De)��(Kong)϶(Xi)ϵ(Xi)ͳ(Tong)��(Ke)��(Yi)ʹ(Shi)��(Qi)��(Ti)��(Fen)��(Li)��(Dan)��(Hen)��(Nan)��(Jiang)��(Ta)��(Men)��(Jia)��(Gong)��(Cheng)��(Jian)��(Gu)��(De)��(Da)��(Bao)Ƭ(Pian)��(Yan)��(Jiu)��(Zhe)��(Kai)��(Fa)��(Liao)һ(Yi)��(Zhong)��(Gu)��(Ti)��(Rong)��(Ji)��(Ji)��(Shu)��(Yong)��(Yu)��(Zhi)��(Zao)��(Bao)��(De)��(Gao)��(Fu)��(Zai)��(De)��(Wu)ȱ(Que)��(Xian)��(De)��(Hun)��(He)��(Ji)��(Zhi)Ĥ(Mo)��ǰ(Qian)��(Ti)��(Jin)��(Shu)��(Yan)��(Rong)��(Jie)��(Zai)��(Ju)��(He)��(Wu)��(Zhong)��Ȼ(Ran)��(Hou)ת(Zhuan)��(Hua)Ϊ(Wei)MOF��(Cai)��(Liao)��(Yan)��(Jiu)��(Zhe)֤(Zheng)��(Ming)��(Liao)��(Qing)��(He)��(Er)��(Yang)��(Hua)̼(Tan)��(De)��(Fen)��(Li)��(Ju)��(You)��(Gao)��(Shen)͸(Tou)��(He)ѡ(Xuan)��(Ze)��(Xing)�� Abstract��Nanoporous crystalline materials, represented by zeolites and metal-organic frameworks (MOFs), naturally contain continuous pore systems that can enable the separation of gases, but it is difficult to process them into robust, large sheets. Chen et al. developed a solid-solvent technique for making thin, highly loaded, and defect-free mixed matrix membranes. Precursor metal salts are dissolved into a polymer and then converted into a MOF material. The authors demonstrate the separation of hydrogen and carbon dioxide, with high permeance and selectivity.Disequilibrating azobenzenes by visible-light sensitization under confinementԼ(Yue)��(Shu)��(Xia)��(Ke)��(Jian)��(Guang)��(Min)��(Hua)ż(Ou)��(Dan)��(Ben)��(De)ʧ(Shi)ƽ(Ping)��(Heng)�� (Zuo)��(Zhe)��JULIUS GEMEN, JONATHAN R. CHURCH, TERO-PETRI RUOKO, NIKITA DURANDIN, MICHA? J. BIA?EK, MAREN WEISSENFEL, MORAN FELLER, MIRI KAZES, MAGDALENA ODAYBAT, AND RAFAL KLAJN�� (Lian)��(Jie)��https://www.science.org/doi/full/10.1126/science.adh9059�� ժ(Zhai)Ҫ(Yao)��(Hua)ѧ(Xue)��(Jia)��(Chang)��(Chang)Ŭ(Nu)��(Li)��(Jiang)��(Fan)Ӧ(Ying)��(Tui)��(Xiang)��(Geng)��(Gao)��(De)��(Neng)��(Liang)��(Jiao)��(Di)��(De)��(Chan)��(Wu)��(Qi)��(Zhong)��(Mian)��(Lin)��(De)��(Tiao)ս(Zhan)��(Shi)��(Ru)��(He)��(Fang)ֹ(Zhi)��(Zhe)Щ(Xie)��(Chan)Ʒ(Pin)��(Zai)��(Ci)��(Xia)��(Hua)��(Yan)��(Jiu)��(Zhe)��(Bao)��(Gao)��(Liao)һ(Yi)��(Zhong)��(Qiao)��(Miao)��(De)��(Ce)��(Lue)��(Jiang)ż(Ou)��(Dan)��(Ben)Ť(Niu)��(Qu)��(Cheng)��(Qi)��(Neng)��(Liang)��(Geng)��(Gao)��(De)Z��(Gou)��(Xiang)��(Ju)��(Ti)��(Lai)˵(Shuo)��(Ta)��(Men)��(Jiang)��(Geng)��(Wen)��(Ding)��(De)E��(Yi)��(Gou)��(Ti)��(Yu)��(Guang)��(Min)��(Ji)һ(Yi)��(Qi)��(Xi)��(Yin)��(Dao)��(Chao)��(Fen)��(Zi)��(Su)��(Zhu)��(Zhong)��(Dang)��(Ke)��(Jian)��(Guang)ע(Zhu)��(Ru)��(Neng)��(Liang)��(Lai)��(You)��(Dao)Ť(Niu)��(Qu)ʱ(Shi)��Z��(Yi)��(Gou)��(Ti)��(Bu)��(Zai)��(Shi)��(He)ǻ(Qiang)��(Ti)��(Yin)��(Ci)��(Zai)��(Geng)��(Duo)��(De)��(Guang)��(Jiang)��(Qi)Ť(Niu)ת(Zhuan)��(Hui)��(Lai)֮(Zhi)ǰ(Qian)��(Ta)��(Bei)��(Tui)��(Chu)ǻ(Qiang)��(Ti)�� Abstract��Chemists often strive to push reactions metaphorically uphill toward less energetically favorable products. The challenge is to keep those products from rolling right back down. Gemen et al. report a clever tactic for twisting azobenzene into its higher-energy Z conformation. Specifically, they lured the more stable E isomer into a supramolecular host, along with a photosensitizer. When visible light injects energy to induce the twist, the Z isomer no longer fits in the cavity, so it gets pushed out before more light can twist it back.��(Sheng)̬(Tai)ѧ(Xue)EcologyImpacts of metal mining on river systems: a global assessment��(Jin)��(Shu)��(Cai)��(Kuang)��(Dui)��(He)��(Liu)ϵ(Xi)ͳ(Tong)��(De)Ӱ(Ying)��(Xiang)��һ(Yi)��(Xiang)ȫ(Quan)��(Qiu)��(Ping)��(Gu)�� (Zuo)��(Zhe)��M. G. MACKLIN, C. J. THOMAS, A. MUDBHATKAL, P. A. BREWER, K. A. HUDSON-EDWARDS, J. LEWIN, P. SCUSSOLINI, D. EILANDER, A. LECHNER , AND K. R. MANGALAA�� (Lian)��(Jie)��https://www.science.org/doi/full/10.1126/science.adg6704�� ժ(Zhai)Ҫ(Yao)��ȫ(Quan)��(Qiu)��(Gu)��(Ji)��(You)2300��(Wan)��(Ren)��(Sheng)��(Huo)��(Zai)��(Hong)��(Fan)��(Qu)��(Shou)��(Dao)��(Guo)ȥ(Qu)��(He)��(Xian)��(Zai)��(Jin)��(Shu)��(Cai)��(Kuang)��(Huo)��(Dong)��(Chan)��(Sheng)��(De)��(You)��(Du)��(Fei)��(Wu)��(De)Ǳ(Qian)��(Zai)Σ(Wei)��(Xian)Ũ(Nong)��(Du)��(De)Ӱ(Ying)��(Xiang)��(Yan)��(Jiu)��(Zhe)��(Fen)��(Xi)��(Liao)��(Zhe)һ(Yi)Σ(Wei)��(Hai)��(De)ȫ(Quan)��(Qiu)��(Fan)Χ(Wei)��(Te)��(Bie)��(Shi)Ǧ(Qian)��п(Xin)��ͭ(Tong)��(He)��(Shen)��(Ta)��(Men)ʹ(Shi)��(Yong)��(Liao)һ(Yi)��(Ge)��(Di)��(Li)��(Can)��(Kao)��(De)ȫ(Quan)��(Qiu)��(Shu)��(Ju)��(Ku)��(Xiang)ϸ(Xi)��(Lie)��(Chu)��(Liao)��(Suo)��(You)��(Yi)֪(Zhi)��(De)��(Jin)��(Shu)��(Cai)��(Kuang)��(Di)��(Dian)��(Yi)��(Ji)��(Wan)��(Zheng)��(He)ʧ(Shi)Ч(Xiao)��(De)β(Wei)��(Kuang)��(Chu)��(Cun)��(She)ʩ(Shi)��Ȼ(Ran)��(Hou)��ʹ(Shi)��(Yong)��(Ji)��(Yu)��(Guo)��(Cheng)��(He)��(Jing)��(Yan)��(Jian)��(Yan)��(De)ģ(Mo)��(Xing)��(Dui)��(He)��(Liu)ϵ(Xi)ͳ(Tong)��(Zhong)��(De)��(Jin)��(Shu)��(Cai)��(Kuang)��(Wu)Ⱦ(Ran)��(Yi)��(Ji)��(Bao)¶(Lu)��(De)��(Ren)��(Kou)��(He)��(Sheng)��(Xu)��(Shu)��(Liang)��(Jin)��(Xing)��(Liao)ȫ(Quan)��(Qiu)��(Ping)��(Gu)��(Zai)��(Shi)��(Jie)��(Fan)Χ(Wei)��(Nei)��(Jin)��(Shu)��(Kuang)ɽ(Shan)Ӱ(Ying)��(Xiang)��(Zhuo)47.92��(Wan)��(Gong)��(Li)��(De)��(He)��(Dao)��(He)16.4��(Wan)ƽ(Ping)��(Fang)��(Gong)��(Li)��(De)��(Hong)��(Fan)ƽ(Ping)ԭ(Yuan)��(Chang)��(Qi)��(Xiang)��(He)��(Liu)��(Pai)��(Fang)��(Cai)��(Kuang)��(Fei)��(Wu)��(Suo)��(Zao)��(Cheng)��(Wu)Ⱦ(Ran)��(De)��(Ren)��(Shu)��(Ji)��(Hu)��(Shi)ֱ(Zhi)��(Jie)��(Shou)β(Wei)��(Kuang)��(Ba)��(Kui)��(Ba)Ӱ(Ying)��(Xiang)��(Ren)��(Shu)��(De)50��(Bei)�� Abstract��An estimated 23 million people live on floodplains affected by potentially dangerous concentrations of toxic waste derived from past and present metal mining activity. We analyzed the global dimensions of this hazard, particularly in regard to lead, zinc, copper, and arsenic, using a georeferenced global database detailing all known metal mining sites and intact and failed tailings storage facilities. We then used process-based and empirically tested modeling to produce a global assessment of metal mining contamination in river systems and the numbers of human populations and livestock exposed. Worldwide, metal mines affect 479,200 kilometers of river channels and 164,000 square kilometers of floodplains. The number of people exposed to contamination sourced from long-term discharge of mining waste into rivers is almost 50 times greater than the number directly affected by tailings dam failures.��(Sheng)��(Wu)ѧ(Xue)BiologyAccurate proteome-wide missense variant effect prediction with AlphaMissense��(Li)��(Yong)AlphaMissenseԤ(Yu)��(Ce)��(Dan)��(Bai)��(Zhi)��(Zu)��(Cuo)��(Yi)��(Bian)��(Yi)Ч(Xiao)Ӧ(Ying)�� (Zuo)��(Zhe)��JUN CHENG, GUIDO NOVATI, JOSHUA PAN, CLARE BYCROFT, AKVIL? ?EMGULYT?, TAYLOR APPLEBAUM, ALEXANDER PRITZEL, LAI HONG WONG, MICHAL ZIELINSKI, AND ?IGA AVSEC�� (Lian)��(Jie)��https://www.science.org/doi/full/10.1126/science.adh9059�� ժ(Zhai)Ҫ(Yao)��(Zai)��(Ren)��(Lei)��(Ji)��(Yin)��(Zu)��(Zhong)��(Guan)��(Cha)��(Dao)��(De)��(Jue)��(Da)��(Duo)��(Shu)��(Cuo)��(Yi)��(Bian)��(Yi)��(Ju)��(You)δ(Wei)֪(Zhi)��(De)��(Lin)��(Chuang)��(Yi)��(Yi)��(Yan)��(Jiu)��(Zhe)��(Kai)��(Fa)��(Liao)AlphaMissense��(Zhe)��(Shi)һ(Yi)��(Zhong)��(Ji)��(Yu)��(Dan)��(Bai)��(Zhi)��(Jie)��(Gou)Ԥ(Yu)��(Ce)��(Gong)��(Ju)AlphaFold2��(De)��(Shen)��(Du)ѧ(Xue)ϰ(Xi)ģ(Mo)��(Xing)��ͨ(Tong)��(Guo)AlphaMissense��(Dui)��(Ren)��(Lei)��(He)��(Ling)��(Chang)��(Lei)��(Dong)��(Wu)��(Bian)��(Yi)��(Zhong)Ⱥ(Qun)Ƶ(Pin)��(Lv)��(Shu)��(Ju)��(Ku)��(Jin)��(Xing)΢(Wei)��(Diao)��(Yi)Ԥ(Yu)��(Ce)��(Cuo)��(Yi)��(Bian)��(Yi)��(De)��(Zhi)��(Bing)��(Xing)��ͨ(Tong)��(Guo)��(Jie)��(He)��(Jie)��(Gou)��(Bei)��(Jing)��(He)��(Jin)��(Hua)��(Shou)��(Heng)��(Gai)ģ(Mo)��(Xing)��(Zai)��(Guang)��(Fan)��(De)��(Yi)��(Chuan)��(He)ʵ(Shi)��(Yan)��(Ji)׼(Zhun)��(Zhong)��(Huo)��(De)��(Liao)��(Zui)��(Xian)��(Jin)��(De)��(Jie)��(Guo)��(Zhe)Щ(Xie)��(Du)û(Mei)��(You)��(Zai)��(Shu)��(Ju)��(Shang)��(Jin)��(Xing)��(Ming)ȷ(Que)��(De)ѵ(Xun)��(Lian)��(Ji)��(Yin)��(De)ƽ(Ping)��(Jun)��(Zhi)��(Bing)��(Xing)��(Ping)��(Fen)Ҳ(Ye)��(Ke)��(Yi)Ԥ(Yu)��(Ce)��(Ta)��(Men)��(De)��(Zhong)Ҫ(Yao)��(Xing)��(Neng)��(Gou)ʶ(Shi)��(Bie)��(Xian)��(You)ͳ(Tong)��(Ji)��(Fang)��(Fa)��(Wu)��(Fa)��(Jian)��(Ce)��(Dao)��(De)��(Duan)��(Bi)Ҫ(Yao)��(Ji)��(Yin)��(Yan)��(Jiu)��(Zhe)��(Ti)��(Gong)��(Liao)һ(Yi)��(Ge)��(Shu)��(Ju)��(Ku)��Ԥ(Yu)��(Ce)��(Suo)��(You)��(Ke)��(Neng)��(De)��(Ren)��(Lei)��(Dan)��(An)��(Ji)��(Suan)��(Ti)��(Huan)��(Bing)��(Jiang)89%��(De)��(Cuo)��(Yi)��(Bian)��(Yi)��(Fen)��(Lei)Ϊ(Wei)��(Ke)��(Neng)��(Shi)��(Liang)��(Xing)��(De)��(Huo)��(Ke)��(Neng)��(Shi)��(Zhi)��(Bing)��(De)�� Abstract��The vast majority of missense variants observed in the human genome are of unknown clinical significance. We present AlphaMissense, an adaptation of AlphaFold fine-tuned on human and primate variant population frequency databases to predict missense variant pathogenicity. By combining structural context and evolutionary conservation, our model achieves state-of-the-art results across a wide range of genetic and experimental benchmarks, all without explicitly training on such data. The average pathogenicity score of genes is also predictive for their cell essentiality, capable of identifying short essential genes that existing statistical approaches are underpowered to detect. As a resource to the community, we provide a database of predictions for all possible human single amino acid substitutions and classify 89% of missense variants as either likely benign or likely pathogenic.

��Σ��п��յ��Լ��Ĵ��ʵ��Ҫ��4ƽ��ģ��Ҷ�Ҫ��һ��·��Ϊ��ȷ��֮�以��š��׷�2024-06-23 10:45��Сׯ��̵ع��-Ұ��ѹۿ��ձ��Ӱ��

��ǿ��ѡ��õľ�ס��ܸ��ζ��ʳ��μӸ��ḻ�Ļ

��ڣ��

��Ĺ۵��߱��ˣ��Ѻ��ϵ��Ϣ��ƽ̨��Ѻ��ṩ��Ϣ�洢�ռ��

�Ķ� (0)

��վ��ͼ

��

91��Ƶר��

�������̵ع�������������-Ұ����ѹۿ��ձ���Ӱ��������

��̵ع��-Ұ��ѹۿ��ձ��Ӱ��