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    • 2. 发明申请
    • METHOD FOR PURIFYING GRAPHENE POWDER
    • 净化石墨粉的方法
    • US20120043402A1
    • 2012-02-23
    • US13211609
    • 2011-08-17
    • Jae Kap LEEKyoung-Il LEE
    • Jae Kap LEEKyoung-Il LEE
    • B02C15/00
    • B82Y40/00B82Y30/00C01B32/196C01P2004/64
    • An easy and effective method for purifying graphene powder by removing magnetic impurities, wherein magnetic impurities are incorporated during the process of fabricating the graphene powder, is provided. The method for purifying graphene powder, the method including: (1) ball-milling a graphite material to form graphene powder; (2) dispersing the graphene powder in a solvent to form a suspension; and (3) separating magnetic impurities during stirring the suspension, by using a magnet, Wherein the magnetic impurities were incorporated into the graphene powder during ball-milling from the balls and dispersed in the suspension.
    • 提供了一种通过去除在制造石墨烯粉末的过程中并入磁性杂质的磁性杂质来净化石墨烯粉末的简单有效的方法。 石墨烯粉末的净化方法,该方法包括:(1)对石墨材料进行球磨以形成石墨烯粉末; (2)将石墨烯粉末分散在溶剂中以形成悬浮液; 和(3)通过使用磁体在搅拌悬浮液期间分离磁性杂质,其中在从球中球磨过程中将磁性杂质掺入石墨烯粉末中并分散在悬浮液中。
    • 6. 发明授权
    • Method for purifying graphene powder
    • 石墨烯粉末的净化方法
    • US08672246B2
    • 2014-03-18
    • US13211609
    • 2011-08-17
    • Jae Kap LeeKyoung-Il Lee
    • Jae Kap LeeKyoung-Il Lee
    • B02C19/00
    • B82Y40/00B82Y30/00C01B32/196C01P2004/64
    • An easy and effective method for purifying graphene powder by removing magnetic impurities, wherein magnetic impurities are incorporated during the process of fabricating the graphene powder, is provided. The method for purifying graphene powder, the method including: (1) ball-milling a graphite material to form graphene powder; (2) dispersing the graphene powder in a solvent to form a suspension; and (3) separating magnetic impurities during stirring the suspension, by using a magnet, Wherein the magnetic impurities were incorporated into the graphene powder during ball-milling from the balls and dispersed in the suspension.
    • 提供了一种通过去除在制造石墨烯粉末的过程中并入磁性杂质的磁性杂质来净化石墨烯粉末的简单有效的方法。 石墨烯粉末的净化方法,该方法包括:(1)对石墨材料进行球磨以形成石墨烯粉末; (2)将石墨烯粉末分散在溶剂中以形成悬浮液; 和(3)通过使用磁体在搅拌悬浮液期间分离磁性杂质,其中在从球中球磨过程中将磁性杂质掺入石墨烯粉末中并分散在悬浮液中。
    • 8. 发明授权
    • Atomic force microscope cantilever including field effect transistor and method for manufacturing the same
    • 原子力显微镜悬臂包括场效应晶体管及其制造方法
    • US07344908B2
    • 2008-03-18
    • US11614489
    • 2006-12-21
    • Moon Suhk SuhJin-Koog ShinChurl Seung LeeKyoung IL Lee
    • Moon Suhk SuhJin-Koog ShinChurl Seung LeeKyoung IL Lee
    • H01L21/00
    • G01Q60/30G01Q60/38
    • The present invention relates to an AFM (atomic force microscope) cantilever including a field effect transistor (FET) and a method for manufacturing the same; and, more particularly, to a method for manufacturing an AFM cantilever including an FET formed by a photolithography process, wherein an effective channel length of the FET is a nano-scale. Therefore, The present invention can easily implement a simulation for manufacturing the AFM cantilever including the FET by accurately controlling the effective channel length. And also, the present invention can manufacture the AFM cantilever including the FET having the effective channel ranging several tens to several hundreds nanometers by applying the low price photolithography device, thereby enhancing an accuracy and yield of the manufacturing process and drastically reducing process costs.
    • 本发明涉及包括场效应晶体管(FET)的AFM(原子力显微镜)悬臂及其制造方法; 更具体地,涉及一种制造包括通过光刻工艺形成的FET的AFM悬臂的方法,其中FET的有效沟道长度是纳米尺度。 因此,本发明可以通过精确地控制有效通道长度来容易地实现用于制造包括FET的AFM悬臂的模拟。 并且,本发明还可以通过应用低价光刻装置来制造包括具有几十到几百纳米的有效通道的FET的AFM悬臂,从而提高制造工艺的精度和产量,并显着降低工艺成本。
    • 9. 发明申请
    • ATOMIC FORCE MICROSCOPE CANTILEVER AND METHOD FOR MANUFACTURING THE SAME
    • 原子力显微镜及其制造方法
    • US20080011066A1
    • 2008-01-17
    • US11614492
    • 2006-12-21
    • Moon Suhk SuhJin-Koog ShinChurl Seung LeeKyoung Il Lee
    • Moon Suhk SuhJin-Koog ShinChurl Seung LeeKyoung Il Lee
    • G01B5/28
    • G01Q60/38G01Q70/12
    • The present invention relates to various types of atomic force microscope (AFM) cantilevers formed by using a photolithography process and an etching process and a method for manufacturing the same, the AFM cantilever includes a handling unit made of a semiconductor substrate, a cantilever unit extendedly formed on a bottom surface of the handling unit in a shape of a rod, a probe unit formed in a shape of a vertically protruded peak by being extendedly formed on one side surface of the cantilever unit and a probe being in contact with a surface of an object to be analyzed by being formed on the peak of the probe unit. Therefore, the present invention has an advantage that the probe of several hundred nanometers can easily formed through a general photolithography process as well as it can easily obtain a natural resonance frequency of the designed cantilever by easily setting a thickness of the cantilever member.
    • 本发明涉及通过使用光刻工艺和蚀刻工艺形成的各种原子力显微镜(AFM)悬臂及其制造方法,该AFM悬臂包括由半导体衬底制成的处理单元,延伸的悬臂单元 在所述处理单元的底面上形成为杆的形状,通过在所述悬臂单元的一个侧面上延伸地形成为垂直突出的形状的探针单元和与所述悬臂单元的表面接触的探针 通过形成在探针单元的峰上来分析的物体。 因此,本发明的优点在于,通过通常的光刻工艺容易地形成数百纳米的探针,并且通过容易地设定悬臂构件的厚度,可以容易地获得设计的悬臂的固有共振频率。