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公开(公告)号:KR101180640B1
公开(公告)日:2012-09-18
申请号:KR1020100046392
申请日:2010-05-18
Applicant: 한국과학기술원
IPC: G03F7/20 , H01L21/027
Abstract: 본 발명은 형광패턴 형성방법에 있어서,a)기재 상에 가교반응형 폴리머 광산발생제, 형광체 및 유기용매로 이루어진 화학증폭형포토레지스트 조성물을 코팅하고 패턴된 포토마스크를 올린 후 노광하는 단계;b)상기 노광한 후 후열반응(postbaking)으로 형광패턴을 형성하는 단계;
를 포함하는 형광패턴 형성방법에 관한 것이다.
또한 본 발명은 형광패턴 형성방법에 있어서, 기재 상에 광민감성 가교형 폴리머, 형광체 및 유기용매로 이루어진 비화학증폭형 포토레지스트 조성물을 코팅하고 패턴된 포토마스크를 올린 후 노광하는 단계를 포함하는 형광패턴형성방법에 관한 것이다.Abstract translation: 一种形成荧光图案的方法,包括以下步骤:a)将包含交联反应型聚合物光酸产生剂,荧光材料和有机溶剂的化学放大光刻胶组合物涂布在基底上, )曝光后通过烘烤形成荧光图案;
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Patent Agency Ranking12.发明授权
公开(公告)号:KR101113035B1
公开(公告)日:2012-02-27
申请号:KR1020100046386
申请日:2010-05-18
Applicant: 한국과학기술원
Abstract: 본 발명은 기재 및 기재상에 형광체를 함유하는 경화층에 의해 기준패턴이 형성되고,
상기 기준패턴 상부에 나노 또는 마이크로 크기의 입자, 와이어 또는 이들의 혼합물의 표면에 형광체로 코팅하여 제조되는 복합 분산체가 임의로 분산된 분산패턴이 형성된 복제방지 라벨 및 이의 제조방법에 관한 것이다.-
公开(公告)号:KR1020110006836A
公开(公告)日:2011-01-21
申请号:KR1020090064423
申请日:2009-07-15
Applicant: 한국과학기술원
CPC classification number: G09F3/0376 , B82B3/0004 , G09F3/0292 , G09F3/0294 , G09F2003/0277
Abstract: PURPOSE: A method of manufacturing a copy protection label and an authenticity determination method are provided to prevent simple physical copy by applying optional pattern as well as an optical property to a label. CONSTITUTION: Dispersing elements selected from nano or micro sized wire or nano micro sized particle and a mixture of them are distributed on a distributing pattern. A target pattern indicates the observation criteria, including direction and position, of left and right side of the distributed pattern.
Abstract translation: 目的:提供一种制造复制保护标签和真实性确定方法,以通过将可选图案以及光学性质应用于标签来防止简单的物理复制。 构成:选自纳米或微尺寸线或纳米微粒尺寸的颗粒及其混合物的分散元件分布在分布图案上。 目标模式表示分布模式的左侧和右侧的观察标准,包括方向和位置。
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公开(公告)号:KR1020140116305A
公开(公告)日:2014-10-02
申请号:KR1020130030725
申请日:2013-03-22
Applicant: 한국과학기술원
Abstract: One embodiment of the present invention relates to a method and a system for super resolution imaging based on fluorescence resonance energy transfer. The method for super resolution imaging based on fluorescence resonance energy transfer includes a step of selecting an appropriate FRET (Fluorescence resonance energy transfer) pair and setting a suitable microscope environment; a step of injecting a donor among a pair of FRET donor in a sample to be observed; a step of injecting or expressing an acceptor among FRET pairs around the donor; a step of recording the luminescence signal of the sample injected with the FRET pair; and a step of generating a fluorescent image by analyzing the luminescence signal.
Abstract translation: 本发明的一个实施例涉及一种基于荧光共振能量转移的超分辨率成像方法和系统。 基于荧光共振能量转移的超分辨率成像方法包括选择合适的FRET(荧光共振能量转移)对并设置合适的显微镜环境的步骤; 在待观察的样品中的一对FRET供体中注入供体的步骤; 在供体周围的FRET对中注射或表达受体的步骤; 记录注射了FRET对的样品的发光信号的步骤; 以及通过分析发光信号产生荧光图像的步骤。
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公开(公告)号:KR1020140106856A
公开(公告)日:2014-09-04
申请号:KR1020130021003
申请日:2013-02-27
Applicant: 한국과학기술원
CPC classification number: C07K19/00
Abstract: The present invention relates to a PYP protein for analyzing expression or quantity of a protein and a method for analyzing expression or quantity of a protein using the PYP protein. The method for analyzing expression or quantity of a protein according to the present invention can quickly and accurately detect expression of a target protein and simply measure the quantity and purity. Also, the present invention causes no problems even if mixing tag systems and can be applicable to eukaryotic protein expression systems as well as prokaryotic protein expression systems, thereby providing the best availability for high throughput screening of protein expression. Thus, the method for analyzing expression or quantity of a protein according to the present invention can be useful in protein studies.
Abstract translation: 本发明涉及用于分析蛋白质的表达或数量的PYP蛋白质和使用PYP蛋白质分析蛋白质的表达或量的方法。 根据本发明的用于分析蛋白质的表达或数量的方法可以快速且准确地检测目标蛋白的表达,并且简单地测量数量和纯度。 此外,即使混合标签系统,本发明也不会产生问题,并且可以应用于真核生物蛋白质表达系统以及原核蛋白质表达系统,从而为蛋白质表达的高通量筛选提供最佳可用性。 因此,根据本发明的用于分析蛋白质的表达或量的方法可用于蛋白质研究。
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公开(公告)号:KR1020090005972A
公开(公告)日:2009-01-14
申请号:KR1020080063424
申请日:2008-07-01
Applicant: 한국과학기술원
Abstract: A manufacturing method of binary alloy nanostructure is provided to have a simple process and reproducibility and to mass-produce a binary alloy nanowire or a nano belt of a uniform-size which is not cohered on a mono crystal substrate. A manufacturing method of binary alloy nanostructure comprises steps of: using two materials selected from a first material to a third material, a mixture of the two materials selected from the first material to the third material or a third material as precursor; heat-treating a mono crystal substrate of a semiconductor or a non-conductor positioned at a back-end of a furnace and the precursor positioned at a front-end of the furnace at a state that inert gas flows; forming a binary alloy monocrystal nanowire or a nano belt on the mono crystal substrate. The first material includes metal oxide, metal material or metal halide of one metal comprising binary alloy of the binary alloy nanostructure which is a binary alloy nanowire or a binary alloy nano belt. The second material includes metal oxide, metal material or metal halide of the other metal comprising the binary alloy. The third material includes the binary alloy material of the binary alloy.
Abstract translation: 提供二元合金纳米结构的制造方法具有简单的工艺和再现性,并且批量生产未结合在单晶衬底上的均匀尺寸的二元合金纳米线或纳米带。 二元合金纳米结构的制造方法包括以下步骤:使用选自第一材料至第三材料的两种材料,选自第一材料至第三材料的两种材料或第三材料作为前体的混合物; 在惰性气体流动的状态下,对位于炉后端的半导体或非导体的单晶衬底进行热处理,所述前体位于炉的前端; 在单晶衬底上形成二元合金单晶纳米线或纳米带。 第一种材料包括金属氧化物,金属材料或一种金属的金属卤化物,其包括二元合金纳米结构二元合金纳米线或二元合金纳米带的二元合金。 第二种材料包括金属氧化物,金属材料或包含二元合金的其它金属的金属卤化物。 第三种材料包括二元合金的二元合金材料。
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