{"newsList":[{"detailid":30414551,"title":"全球最大纳米科技实验装置向用户开放","content":"","addtime":0,"bigclass":180400,"smallclass":180421,"thirdclass":0,"newstype":41000,"newstypesub":42000,"imgurl":"","htmlpath":"https://xincailiao.ofweek.com/news/2019-10/ART-180421-8110-30414551.html","summery":"10月22日至24日,第五届二维材料国际会议在苏州举行。在会议期间了解到,坐落在苏州市工业园区的纳米科技真空互联综合实验装置(NANO-X)已开始面向国内外用户开放。据介绍,这是我国首个基于真空互联技术的纳米科技大型实验装置,也是目前全球范围内规模最大的纳米科技实验装置","metakeywords":"纳米,新材料纳米科技实验装置","bigType":{"typeid":180400,"typename":"新材料","urlcode":180400,"nameAB":"xincailiao"},"smallType":{"typeid":180421,"typename":"高分子材料","urlcode":180421,"nameAB":"polymers"},"pictureMiddlePath":"","region":0,"pictureurl":"","keywords":"","addtimeStr":"2019-10-30 09:53:49","explain":"","toapp":0,"toapptop":0,"toapptoutiao":0,"toappjinghua":0,"toIndustryAppTop":0,"listpic1":"","listpic2":"","listpic3":"","intervalStr":"2019-10-30 09:53","channelStr":"产业新闻","timestamp":0,"toapptoutiaotimestamp":0,"endaddtime":0},{"detailid":30414463,"title":"国内首架四座电动飞机首飞成功!","content":"","addtime":0,"bigclass":180400,"smallclass":180423,"thirdclass":0,"newstype":41000,"newstypesub":75008,"imgurl":"","htmlpath":"https://xincailiao.ofweek.com/news/2019-10/ART-180423-8140-30414463.html","summery":"28日上午,我国自主研制的首架四座电动飞机RX4E飞机在沈阳财湖机场首飞成功。","metakeywords":"碳纤维材料,电动飞机","bigType":{"typeid":180400,"typename":"新材料","urlcode":180400,"nameAB":"xincailiao"},"smallType":{"typeid":180423,"typename":"复合材料","urlcode":180423,"nameAB":"composite"},"pictureMiddlePath":"","region":0,"pictureurl":"","keywords":"","addtimeStr":"2019-10-29 16:05:36","explain":"","toapp":0,"toapptop":0,"toapptoutiao":0,"toappjinghua":0,"toIndustryAppTop":0,"listpic1":"","listpic2":"","listpic3":"","intervalStr":"2019-10-29 16:05","channelStr":"产业新闻","timestamp":0,"toapptoutiaotimestamp":0,"endaddtime":0},{"detailid":30414437,"title":"JSR研发新型轮胎橡胶 将轮胎耐磨性提高50%以上","content":"","addtime":0,"bigclass":180400,"smallclass":180423,"thirdclass":0,"newstype":41000,"newstypesub":75008,"imgurl":"","htmlpath":"https://xincailiao.ofweek.com/news/2019-10/ART-180423-8140-30414437.html","summery":"据外媒报道,随着电气化、网联化和自动驾驶汽车等下一代汽车技术趋势的不断发展,对轮胎性能的要求也在发生着变化。除了需要提高燃油效率之外,轮胎还必须具备高强度、耐磨性和耐久性。为了满足此类需求,日本JSR","metakeywords":"JSR,轮胎,橡胶","bigType":{"typeid":180400,"typename":"新材料","urlcode":180400,"nameAB":"xincailiao"},"smallType":{"typeid":180423,"typename":"复合材料","urlcode":180423,"nameAB":"composite"},"pictureMiddlePath":"","region":0,"pictureurl":"","keywords":"","addtimeStr":"2019-10-29 15:04:49","explain":"","toapp":0,"toapptop":0,"toapptoutiao":0,"toappjinghua":0,"toIndustryAppTop":0,"listpic1":"https://images.ofweek.com/Upload/NewsList/201910/15723327614781382719632072758564.png","listpic2":"","listpic3":"","intervalStr":"2019-10-29 15:04","channelStr":"产业新闻","timestamp":0,"toapptoutiaotimestamp":0,"endaddtime":0},{"detailid":30414380,"title":"遇水即粘:“新型水中万能胶”研制成功","content":"","addtime":0,"bigclass":180400,"smallclass":180424,"thirdclass":0,"newstype":41000,"newstypesub":75008,"imgurl":"","htmlpath":"https://xincailiao.ofweek.com/news/2019-10/ART-180424-8140-30414380.html","summery":"传统黏合剂在水中实施黏结时会被基质表面的水化层阻隔,由此极大地降低了黏合剂的黏附作用。天津大学刘文广教授团队通过仿生技术设计了一种水促发的新型超支化聚合物通用黏合剂(HBPA)。该黏合剂最大特点在于遇水即粘,打破了水化层的限制,可应用于多种材质的黏合,堪称“水中万能胶”","metakeywords":"新材料,新型水中万能胶","bigType":{"typeid":180400,"typename":"新材料","urlcode":180400,"nameAB":"xincailiao"},"smallType":{"typeid":180424,"typename":"前沿新材料","urlcode":180424,"nameAB":"qianyan"},"pictureMiddlePath":"","region":0,"pictureurl":"","keywords":"","addtimeStr":"2019-10-29 10:56:27","explain":"","toapp":0,"toapptop":0,"toapptoutiao":0,"toappjinghua":0,"toIndustryAppTop":0,"listpic1":"https://images.ofweek.com/Upload/NewsList/201910/15723178112376318987296206002743.jpg","listpic2":"","listpic3":"","intervalStr":"2019-10-29 10:56","channelStr":"产业新闻","timestamp":0,"toapptoutiaotimestamp":0,"endaddtime":0},{"detailid":30414220,"title":"锂电涂布设备、浆料混合产线入选重大技术装备目录公示","content":"","addtime":0,"bigclass":180400,"smallclass":180420,"thirdclass":0,"newstype":41000,"newstypesub":75008,"imgurl":"","htmlpath":"https://xincailiao.ofweek.com/news/2019-10/ART-180420-8140-30414220.html","summery":"日前,国家工信部网站对2019年版入选首台(套)重大技术装备推广应用指导目录的产品进行公示,公示时间截止到11月24日。根据相关政策,入选该目录的产品将获得相应的保费补贴资金,以鼓励企业积极提高制造装备整体水平","metakeywords":"正负极浆料,锂离子","bigType":{"typeid":180400,"typename":"新材料","urlcode":180400,"nameAB":"xincailiao"},"smallType":{"typeid":180420,"typename":"金属材料","urlcode":180420,"nameAB":"metal"},"pictureMiddlePath":"","region":0,"pictureurl":"","keywords":"","addtimeStr":"2019-10-28 15:29:33","explain":"","toapp":0,"toapptop":0,"toapptoutiao":0,"toappjinghua":0,"toIndustryAppTop":0,"listpic1":"https://images.ofweek.com/Upload/NewsList/201910/15722479183641047358375556056396.jpg","listpic2":"","listpic3":"","intervalStr":"2019-10-28 15:29","channelStr":"产业新闻","timestamp":0,"toapptoutiaotimestamp":0,"endaddtime":0},{"detailid":30414135,"title":"日本诺奖得主研发出氮化镓逆变器首次成功应用于电动汽车","content":"","addtime":0,"bigclass":180400,"smallclass":180421,"thirdclass":0,"newstype":41000,"newstypesub":75008,"imgurl":"","htmlpath":"https://xincailiao.ofweek.com/news/2019-10/ART-180421-8140-30414135.html","summery":"日本一研究团队24日宣布,他们利用半导体材料氮化镓(GaN)研发的逆变器,已首次成功应用在电动汽车上,有望让电动汽车节能20%以上。这一研究团队由2014年诺贝尔物理学奖得主之一、日本名古屋大学教授天野浩领导","metakeywords":"氮化镓逆变器,诺奖","bigType":{"typeid":180400,"typename":"新材料","urlcode":180400,"nameAB":"xincailiao"},"smallType":{"typeid":180421,"typename":"高分子材料","urlcode":180421,"nameAB":"polymers"},"pictureMiddlePath":"","region":0,"pictureurl":"","keywords":"","addtimeStr":"2019-10-28 10:49:46","explain":"","toapp":0,"toapptop":0,"toapptoutiao":0,"toappjinghua":0,"toIndustryAppTop":0,"listpic1":"https://images.ofweek.com/Upload/NewsList/201910/15722309102762875484513091628364.jpg","listpic2":"","listpic3":"","intervalStr":"2019-10-28 10:49","channelStr":"产业新闻","timestamp":0,"toapptoutiaotimestamp":0,"endaddtime":0},{"detailid":30413939,"title":"锑化物半导体:打开红外芯片新技术大门的“金钥匙”","content":"","addtime":0,"bigclass":180400,"smallclass":180424,"thirdclass":0,"newstype":41000,"newstypesub":75008,"imgurl":"","htmlpath":"https://xincailiao.ofweek.com/news/2019-10/ART-180424-8140-30413939.html","summery":"发展锑化物半导体已成为我国第四代半导体核心技术发展的战略性方向之一。","metakeywords":"半导体,锑化物半导体","bigType":{"typeid":180400,"typename":"新材料","urlcode":180400,"nameAB":"xincailiao"},"smallType":{"typeid":180424,"typename":"前沿新材料","urlcode":180424,"nameAB":"qianyan"},"pictureMiddlePath":"","region":0,"pictureurl":"","keywords":"","addtimeStr":"2019-10-26 09:09:20","explain":"","toapp":0,"toapptop":0,"toapptoutiao":0,"toappjinghua":0,"toIndustryAppTop":0,"listpic1":"https://images.ofweek.com/Upload/NewsList/201910/15720522688696833582626037236583.png","listpic2":"","listpic3":"","intervalStr":"2019-10-26 09:09","channelStr":"产业新闻","timestamp":0,"toapptoutiaotimestamp":0,"endaddtime":0},{"detailid":30413846,"title":"中国首个量子计算机:2020年底推出中国首个量子计算机","content":"","addtime":0,"bigclass":180400,"smallclass":0,"thirdclass":0,"newstype":41000,"newstypesub":75008,"imgurl":"","htmlpath":"https://xincailiao.ofweek.com/news/2019-10/ART-180400-8140-30413846.html","summery":"合肥本源量子计算科技有限责任公司创始人郭国平对包括第一财经在内的媒体采访团透露了上述信息。在各方支持下,争取在2020年底推出中国首个量子计算机,它将包含6个量子芯片,随时随地可以网络访问。公司主营业务分为4大板块,分别是:量子芯片、量子测控、量子软件和量子云","metakeywords":"量子,计算机","bigType":{"typeid":180400,"typename":"新材料","urlcode":180400,"nameAB":"xincailiao"},"pictureMiddlePath":"","region":0,"pictureurl":"","keywords":"","addtimeStr":"2019-10-25 15:04:41","explain":"","toapp":0,"toapptop":0,"toapptoutiao":0,"toappjinghua":0,"toIndustryAppTop":0,"listpic1":"https://images.ofweek.com/Upload/NewsList/201910/15719872278848473539745416997688.jpg","listpic2":"","listpic3":"","intervalStr":"2019-10-25 15:04","channelStr":"产业新闻","timestamp":0,"toapptoutiaotimestamp":0,"endaddtime":0},{"detailid":30413725,"title":"我国首次实现仿生合成方法烷基化","content":"","addtime":0,"bigclass":180400,"smallclass":180421,"thirdclass":0,"newstype":41000,"newstypesub":75008,"imgurl":"","htmlpath":"https://xincailiao.ofweek.com/news/2019-10/ART-180421-8140-30413725.html","summery":"近日,南开大学元素有机化学国家重点实验室汪清民教授课题组发明了由醛或酮对氮杂芳环碳氢键进行直接烷基化的新方法,为新药和新材料的研发提供了一种高效实用的方法,已申请发明专利。介绍该工作的论文发表于国际知名学术刊物《科学·进展》(Science Advances)上","metakeywords":"烷基化,新材料","bigType":{"typeid":180400,"typename":"新材料","urlcode":180400,"nameAB":"xincailiao"},"smallType":{"typeid":180421,"typename":"高分子材料","urlcode":180421,"nameAB":"polymers"},"pictureMiddlePath":"","region":0,"pictureurl":"","keywords":"","addtimeStr":"2019-10-25 09:54:16","explain":"","toapp":0,"toapptop":0,"toapptoutiao":0,"toappjinghua":0,"toIndustryAppTop":0,"listpic1":"https://images.ofweek.com/Upload/NewsList/201910/15719685041124852410836733739760.jpg","listpic2":"","listpic3":"","intervalStr":"2019-10-25 09:54","channelStr":"产业新闻","timestamp":0,"toapptoutiaotimestamp":0,"endaddtime":0},{"detailid":30413717,"title":"结构泡沫混合材料轻量化潜力 车辆可减重40多公斤","content":"","addtime":0,"bigclass":180400,"smallclass":180422,"thirdclass":0,"newstype":41000,"newstypesub":75008,"imgurl":"","htmlpath":"https://xincailiao.ofweek.com/news/2019-10/ART-180422-8140-30413717.html","summery":"德国汉高(Henkel)携手RLE International工程咨询公司,全面检测和验证高性能结构泡沫塑料,在汽车车身和封闭部件轻量化方面的应用潜力。研究表明,与传统纯金属结构相比,采用含结构泡沫和增强材料的纤维增强聚合物组件,每辆汽车可减重40多公斤。","metakeywords":"结构泡沫混合材料,新材料","bigType":{"typeid":180400,"typename":"新材料","urlcode":180400,"nameAB":"xincailiao"},"smallType":{"typeid":180422,"typename":"无机非金属材料","urlcode":180422,"nameAB":"inorganic"},"pictureMiddlePath":"","region":0,"pictureurl":"","keywords":"","addtimeStr":"2019-10-25 09:46:15","explain":"","toapp":0,"toapptop":0,"toapptoutiao":0,"toappjinghua":0,"toIndustryAppTop":0,"listpic1":"https://images.ofweek.com/Upload/NewsList/201910/15719681183555889716650396261866.png","listpic2":"","listpic3":"","intervalStr":"2019-10-25 09:46","channelStr":"产业新闻","timestamp":0,"toapptoutiaotimestamp":0,"endaddtime":0},{"detailid":30413695,"title":"Dymax戴马斯新加坡公司获得IATF 16949符合性证明","content":"","addtime":0,"bigclass":180400,"smallclass":180424,"thirdclass":0,"newstype":41000,"newstypesub":42000,"imgurl":"","htmlpath":"https://xincailiao.ofweek.com/news/2019-10/ART-180424-8110-30413695.html","summery":"快速光固化材料和设备的领先制造商Dymax戴马斯集团的新加坡公司Dymax Asia Pacific Pte Ltd(以下简称Dymax AP)获得IATF 16949:2016汽车行业质量管理体系符","metakeywords":"快速光固化材料","bigType":{"typeid":180400,"typename":"新材料","urlcode":180400,"nameAB":"xincailiao"},"smallType":{"typeid":180424,"typename":"前沿新材料","urlcode":180424,"nameAB":"qianyan"},"pictureMiddlePath":"","region":0,"pictureurl":"","keywords":"","addtimeStr":"2019-10-25 09:26:19","explain":"","toapp":0,"toapptop":0,"toapptoutiao":0,"toappjinghua":0,"toIndustryAppTop":0,"listpic1":"","listpic2":"","listpic3":"","intervalStr":"2019-10-25 09:26","channelStr":"产业新闻","timestamp":0,"toapptoutiaotimestamp":0,"endaddtime":0},{"detailid":30413601,"title":"汽车领域新材料开发:环保型聚乳酸复合材料或将取代碳纤维","content":"","addtime":0,"bigclass":180400,"smallclass":180423,"thirdclass":0,"newstype":41000,"newstypesub":75008,"imgurl":"","htmlpath":"https://xincailiao.ofweek.com/news/2019-10/ART-180423-8140-30413601.html","summery":"(图源:Polymaker 官网)据外媒报道,Polymaker宣布,推出三种新型基于聚碳酸酯的3D打印材料,每一种都具有独特的性能,通常用于汽车行业。Polymaker将与科思创合作,将新材料推向市场","metakeywords":"新材料,环保型聚乳酸,复合材料","bigType":{"typeid":180400,"typename":"新材料","urlcode":180400,"nameAB":"xincailiao"},"smallType":{"typeid":180423,"typename":"复合材料","urlcode":180423,"nameAB":"composite"},"pictureMiddlePath":"","region":0,"pictureurl":"","keywords":"","addtimeStr":"2019-10-24 15:39:44","explain":"","toapp":0,"toapptop":0,"toapptoutiao":0,"toappjinghua":0,"toIndustryAppTop":0,"listpic1":"https://images.ofweek.com/Upload/NewsList/201910/15719027812141674380935062710401.png","listpic2":"","listpic3":"","intervalStr":"2019-10-24 15:39","channelStr":"产业新闻","timestamp":0,"toapptoutiaotimestamp":0,"endaddtime":0},{"detailid":30413389,"title":"SK海力士公布新款DRAM 称实现单晶圆存储量最大","content":"","addtime":0,"bigclass":180400,"smallclass":180424,"thirdclass":0,"newstype":41000,"newstypesub":42000,"imgurl":"","htmlpath":"https://xincailiao.ofweek.com/news/2019-10/ART-180424-8110-30413389.html","summery":"SK海力士宣布了开发基于第三代1Z纳米(10nm)工艺的DDR4动态随机存储器(DRAM),称将实现单一芯片标准内世界最大容量的16GB,即在一张晶圆中能生产的存储量达到现存的DRAM中最大。","metakeywords":"SK海力士,新材料,DRAM,芯片","bigType":{"typeid":180400,"typename":"新材料","urlcode":180400,"nameAB":"xincailiao"},"smallType":{"typeid":180424,"typename":"前沿新材料","urlcode":180424,"nameAB":"qianyan"},"pictureMiddlePath":"","region":0,"pictureurl":"","keywords":"","addtimeStr":"2019-10-23 17:01:32","explain":"","toapp":0,"toapptop":0,"toapptoutiao":0,"toappjinghua":0,"toIndustryAppTop":0,"listpic1":"https://images.ofweek.com/Upload/NewsList/201910/15718212369465833582549846892421.png","listpic2":"","listpic3":"","intervalStr":"2019-10-23 17:01","channelStr":"产业新闻","timestamp":0,"toapptoutiaotimestamp":0,"endaddtime":0},{"detailid":30413312,"title":"医用“超级涂层”诞生","content":"","addtime":0,"bigclass":180400,"smallclass":180424,"thirdclass":0,"newstype":41000,"newstypesub":75008,"imgurl":"","htmlpath":"https://xincailiao.ofweek.com/news/2019-10/ART-180424-8140-30413312.html","summery":"近日,天津大学张雷、齐海山团队成功合成“贻贝仿生多功能蛋白材料”,该材料同时具备高黏附、抗菌污、防雾等多项功能,成为应用于医疗设备和体内植入器件的“超级涂层”。目前,该“超级涂层”已经申请到国家专利,相关成果发表于国际权威期刊《化学通讯》和《应用材料和界面》","metakeywords":"超级图层,新材料","bigType":{"typeid":180400,"typename":"新材料","urlcode":180400,"nameAB":"xincailiao"},"smallType":{"typeid":180424,"typename":"前沿新材料","urlcode":180424,"nameAB":"qianyan"},"pictureMiddlePath":"","region":0,"pictureurl":"","keywords":"","addtimeStr":"2019-10-23 11:45:43","explain":"","toapp":0,"toapptop":0,"toapptoutiao":0,"toappjinghua":0,"toIndustryAppTop":0,"listpic1":"https://images.ofweek.com/Upload/NewsList/201910/15718023507376359643966583301834.jpg","listpic2":"","listpic3":"","intervalStr":"2019-10-23 11:45","channelStr":"产业新闻","timestamp":0,"toapptoutiaotimestamp":0,"endaddtime":0},{"detailid":30413282,"title":"阿贡团队开发新电解质 提升锂离子电池中硅负极的性能","content":"","addtime":0,"bigclass":180400,"smallclass":180422,"thirdclass":0,"newstype":41000,"newstypesub":75008,"imgurl":"","htmlpath":"https://xincailiao.ofweek.com/news/2019-10/ART-180422-8140-30413282.html","summery":"?据外媒报道,美国能源部阿贡国家实验室的研究人员,开发出新型电解质混合物和一种简单的添加剂,可以增加硅负极的表面和整体稳定性,有望应用于下一代锂离子电池。","metakeywords":"电解质,新材料","bigType":{"typeid":180400,"typename":"新材料","urlcode":180400,"nameAB":"xincailiao"},"smallType":{"typeid":180422,"typename":"无机非金属材料","urlcode":180422,"nameAB":"inorganic"},"pictureMiddlePath":"","region":0,"pictureurl":"","keywords":"","addtimeStr":"2019-10-23 10:57:03","explain":"","toapp":0,"toapptop":0,"toapptoutiao":0,"toappjinghua":0,"toIndustryAppTop":0,"listpic1":"https://images.ofweek.com/Upload/NewsList/201910/1571799569696415532565360526572.png","listpic2":"","listpic3":"","intervalStr":"2019-10-23 10:57","channelStr":"产业新闻","timestamp":0,"toapptoutiaotimestamp":0,"endaddtime":0},{"detailid":30412783,"title":"全球第一艘3D打印火箭将下线测试,计划2021年发射","content":"","addtime":0,"bigclass":180400,"smallclass":180420,"thirdclass":0,"newstype":41000,"newstypesub":75008,"imgurl":"","htmlpath":"https://xincailiao.ofweek.com/news/2019-10/ART-180420-8140-30412783.html","summery":"在航空航天制造领域,3D打印技术一直在不断渗透其中并赋能更多零部件的设计和制造。据外媒报道,最近,由Relativity Space公司打造的第一艘真正意义上的3D打印火箭——Terren-1接近完工,不久后将会送往密西西比州进行测试","metakeywords":"3D打印,技术","bigType":{"typeid":180400,"typename":"新材料","urlcode":180400,"nameAB":"xincailiao"},"smallType":{"typeid":180420,"typename":"金属材料","urlcode":180420,"nameAB":"metal"},"pictureMiddlePath":"","region":0,"pictureurl":"","keywords":"","addtimeStr":"2019-10-21 11:30:42","explain":"","toapp":0,"toapptop":0,"toapptoutiao":0,"toappjinghua":0,"toIndustryAppTop":0,"listpic1":"https://images.ofweek.com/Upload/NewsList/201910/15716287269176886500630465826806.jpg","listpic2":"","listpic3":"","intervalStr":"2019-10-21 11:30","channelStr":"产业新闻","timestamp":0,"toapptoutiaotimestamp":0,"endaddtime":0},{"detailid":30412432,"title":"芬兰研发成功可替代塑料新材料:人造合成蜘蛛丝 能降解更环保","content":"","addtime":0,"bigclass":180400,"smallclass":180423,"thirdclass":0,"newstype":41000,"newstypesub":75008,"imgurl":"","htmlpath":"https://xincailiao.ofweek.com/news/2019-10/ART-180423-8140-30412432.html","summery":"近日,据外媒报道,芬兰阿尔托大学的发表在美国《科学进展》杂志上的一项研究指出,他们利用木质纤维和人造蜘蛛丝研发出新型生物基材料,该新型生物基材料具有高强度、高刚度及高柔韧性等特点,性能优于当今大多数合成和天然材料","metakeywords":"新材料,新型生物基材料","bigType":{"typeid":180400,"typename":"新材料","urlcode":180400,"nameAB":"xincailiao"},"smallType":{"typeid":180423,"typename":"复合材料","urlcode":180423,"nameAB":"composite"},"pictureMiddlePath":"","region":0,"pictureurl":"","keywords":"","addtimeStr":"2019-10-18 15:20:03","explain":"","toapp":0,"toapptop":0,"toapptoutiao":0,"toappjinghua":0,"toIndustryAppTop":0,"listpic1":"https://images.ofweek.com/Upload/NewsList/201910/15713831905266721797775979456343.jpg","listpic2":"","listpic3":"","intervalStr":"2019-10-18 15:20","channelStr":"产业新闻","timestamp":0,"toapptoutiaotimestamp":0,"endaddtime":0},{"detailid":30412123,"title":"下一代Galaxy Fold屏幕材质将使用超薄柔性玻璃","content":"","addtime":0,"bigclass":180400,"smallclass":180423,"thirdclass":0,"newstype":41000,"newstypesub":75008,"imgurl":"","htmlpath":"https://xincailiao.ofweek.com/news/2019-10/ART-180423-8140-30412123.html","summery":"ETNews援引消息人士的话称,三星可能会在明年修复Galaxy Fold最为突出的缺陷之一,将放弃透明聚酰亚胺解决方案,转向柔性超薄玻璃(UTG)。消息人士称,三星显示器已经在为其下一代可折叠智能手机制造可折叠显示器,并补充说另一家名为DOWOO INSYS的公司也开始为三星生产第一批UTG面板","metakeywords":"新材料,超薄柔性玻璃,Galaxy Fold","bigType":{"typeid":180400,"typename":"新材料","urlcode":180400,"nameAB":"xincailiao"},"smallType":{"typeid":180423,"typename":"复合材料","urlcode":180423,"nameAB":"composite"},"pictureMiddlePath":"","region":0,"pictureurl":"","keywords":"","addtimeStr":"2019-10-17 15:25:45","explain":"","toapp":0,"toapptop":0,"toapptoutiao":0,"toappjinghua":0,"toIndustryAppTop":0,"listpic1":"https://images.ofweek.com/Upload/NewsList/201910/15712973254678912705632784298707.jpg","listpic2":"","listpic3":"","intervalStr":"2019-10-17 15:25","channelStr":"产业新闻","timestamp":0,"toapptoutiaotimestamp":0,"endaddtime":0},{"detailid":30411941,"title":"柔性透明导电膜赋能视联网,视频将被重新定义","content":"","addtime":0,"bigclass":180400,"smallclass":180423,"thirdclass":0,"newstype":25000,"newstypesub":10000,"imgurl":"","htmlpath":"https://xincailiao.ofweek.com/news/2019-10/ART-180423-8440-30411941.html","summery":"5G时代的来临,不仅带来了万物互联的概念,还让视频被重新定义。随着视联网的发展,更多新服务、新内容、新体验等创新性的科技产品陆续出现,我们将迎来万物皆屏的新时代。与此同时,AI技术的发展促使社会迈入智能时代,更多终端和应用场景将由设备连接,表现形式更具多样性","metakeywords":"柔性透明导电膜,视频,显示技术","bigType":{"typeid":180400,"typename":"新材料","urlcode":180400,"nameAB":"xincailiao"},"smallType":{"typeid":180423,"typename":"复合材料","urlcode":180423,"nameAB":"composite"},"pictureMiddlePath":"","region":0,"pictureurl":"","keywords":"","addtimeStr":"2019-10-17 08:41:37","explain":"","toapp":0,"toapptop":0,"toapptoutiao":0,"toappjinghua":0,"toIndustryAppTop":0,"listpic1":"https://images.ofweek.com/Upload/NewsList/201910/15712730428225102330269515220369.jpg","listpic2":"","listpic3":"","intervalStr":"2019-10-17 08:41","channelStr":"市场研究","timestamp":0,"toapptoutiaotimestamp":0,"endaddtime":0},{"detailid":30411535,"title":"港科大研发电子燃料 可在几分钟内给电动汽车充满电","content":"","addtime":0,"bigclass":180400,"smallclass":180421,"thirdclass":0,"newstype":41000,"newstypesub":75008,"imgurl":"","htmlpath":"https://xincailiao.ofweek.com/news/2019-10/ART-180421-8140-30411535.html","summery":"在一项由中国香港科技大学(HKUST)领导的跨大学研究计划中,成功研发出一种环保型可充电液体燃料,有望在全球范围内引起轰动。该燃料可在几分钟内为电动汽车充满电,将是现有电池技术的一大进步,因为现有的电池技术仍需要数小时才能给汽车充满电","metakeywords":"电子燃料,新材料","bigType":{"typeid":180400,"typename":"新材料","urlcode":180400,"nameAB":"xincailiao"},"smallType":{"typeid":180421,"typename":"高分子材料","urlcode":180421,"nameAB":"polymers"},"pictureMiddlePath":"","region":0,"pictureurl":"","keywords":"","addtimeStr":"2019-10-15 10:23:11","explain":"","toapp":0,"toapptop":0,"toapptoutiao":0,"toappjinghua":0,"toIndustryAppTop":0,"listpic1":"https://images.ofweek.com/Upload/NewsList/201910/15711061693431329866918583693326.jpg","listpic2":"","listpic3":"","intervalStr":"2019-10-15 10:23","channelStr":"产业新闻","timestamp":0,"toapptoutiaotimestamp":0,"endaddtime":0}]}