公开(公告)号：US08067341B2

公开(公告)日：2011-11-29

申请号：US10805044

申请日：2004-03-19

申请人： Hee Tae Jung ,  Sang Yup Lee ,  Dae Hwan Jung ,  Byung Hun Kim ,  Young Koan Ko

发明人： Hee Tae Jung ,  Sang Yup Lee ,  Dae Hwan Jung ,  Byung Hun Kim ,  Young Koan Ko

IPC分类号： C40B60/00

CPC分类号： G01N33/54353 ,  B82Y30/00 ,  G01N33/551 ,  Y10S977/742

摘要： Carbon nanotube (CNT) films, patterns and biochips and methods of making the same are provided. Such a biochip comprises a bio-receptor attached by means of an exposed chemical functional group on a surface of a high density CNT film or pattern produced by repeated lamination of CNTs on a substrate with exposed amine groups. Various types of CNT-biochips may be fabricated by bonding of bio-receptors to a CNT pattern (or film) containing exposed carboxyl groups or modified by various chemical functional groups. Further, the CNT-biochip may be used to measure an electrical or electrochemical signal using both conductor and semiconductor properties of the CNT, thereby not needing labeling. Upon fluorescent measurement of DNA hybridization using such a CNT-DNA chip it is possible to show more distinct signals useful for genotyping, mutation detection, pathogen identification and the like.

摘要翻译： 提供了碳纳米管（CNT）膜，图案和生物芯片及其制造方法。 这样的生物芯片包括通过暴露的化学官能团在高密度CNT膜的表面上附着的生物受体或通过在具有暴露的胺基的基底上重复层压CNT而产生的图案。 可以通过将生物受体结合到包含暴露的羧基或被各种化学官能团修饰的CNT图案（或膜）来制造各种类型的CNT-生物芯片。 此外，CNT-生物芯片可以用于使用CNT的导体和半导体性质来测量电或电化学信号，从而不需要标记。 在使用这种CNT-DNA芯片进行DNA杂交的荧光测量时，可能显示更有用于基因分型，突变检测，病原体鉴定等的不同信号。

公开(公告)号：US07670831B2

公开(公告)日：2010-03-02

申请号：US10860544

申请日：2004-06-03

申请人： Sang Yup Lee ,  Hee Tae Jung ,  Dae Hwan Jung ,  Young Koan Ko ,  Do Hyun Kim ,  Seok Jae Lee ,  Byung Hun Kim ,  Jae Shin Lee

发明人： Sang Yup Lee ,  Hee Tae Jung ,  Dae Hwan Jung ,  Young Koan Ko ,  Do Hyun Kim ,  Seok Jae Lee ,  Byung Hun Kim ,  Jae Shin Lee

IPC分类号： C12M1/00 ,  C12Q1/00 ,  C12Q1/68 ,  C12M1/34

CPC分类号： G01N33/5438 ,  B82Y30/00 ,  C12Q1/001 ,  G01N33/551 ,  Y10S977/742 ,  Y10S977/745 ,  Y10S977/746 ,  Y10S977/747 ,  Y10S977/748 ,  Y10T156/10

摘要： Conductive carbon nanotubes (CNTs) obtained by dotting carboxylated CNTs with metal nanocrystals by chemical functional groups, are described, as well as a method for fabricating a pattern or film of the conductive CNTs which involves repeatedly depositing conductive CNTs on a substrate to achieve high surface density. A biosensor is described, in which bioreceptors that bind to target biomolecules are selectively attached to conductive CNTs or a conductive CNT pattern or film. By use of the conductive biosensor, various target biomaterials that bind or react with the bioreceptors can be precisely measured directly or by electrochemical signals at large amounts in one step. Additionally, the biosensor can be used for an electrical detection method capable of providing precise measurement results even with a small amount of source material.

摘要翻译： 描述了通过化学官能团将金属纳米晶体的羧化CNT点缀的导电碳纳米管（CNT），以及用于制造导电CNT的图案或膜的方法，其包括在基板上反复沉积导电CNT以实现高表面 密度。 描述了生物传感器，其中结合靶生物分子的生物感受器选择性地连接到导电CNT或导电CNT图案或膜。 通过使用导电生物传感器，可以在一个步骤中直接或通过大量的电化学信号精确测量与生物感受器结合或反应的各种靶生物材料。 此外，生物传感器可以用于即使使用少量源材料也能够提供精确测量结果的电检测方法。

公开(公告)号：US20100009432A1

公开(公告)日：2010-01-14

申请号：US10860544

申请日：2004-06-03

申请人： Sang Yup Lee ,  Hee Tae Jung ,  Dae Hwan Jung ,  Young Koan Ko ,  Do Hyun Kim ,  Seok Jae Lee ,  Byung Hun Kim ,  Jae Shin Lee

发明人： Sang Yup Lee ,  Hee Tae Jung ,  Dae Hwan Jung ,  Young Koan Ko ,  Do Hyun Kim ,  Seok Jae Lee ,  Byung Hun Kim ,  Jae Shin Lee

IPC分类号： C12M1/34 ,  B05D5/12 ,  B32B37/02 ,  C12Q1/00 ,  C12Q1/68 ,  C07K2/00 ,  C12Q1/48

CPC分类号： G01N33/5438 ,  B82Y30/00 ,  C12Q1/001 ,  G01N33/551 ,  Y10S977/742 ,  Y10S977/745 ,  Y10S977/746 ,  Y10S977/747 ,  Y10S977/748 ,  Y10T156/10

摘要： Conductive carbon nanotubes (CNTs) obtained by dotting carboxylated CNTs with metal nanocrystals by chemical functional groups, are described, as well as a method for fabricating a pattern or film of the conductive CNTs which involves repeatedly depositing conductive CNTs on a substrate to achieve high surface density. A biosensor is described, in which bioreceptors that bind to target biomolecules are selectively attached to conductive CNTs or a conductive CNT pattern or film. By use of the conductive biosensor, various target biomaterials that bind or react with the bioreceptors can be precisely measured directly or by electrochemical signals at large amounts in one step. Additionally, the biosensor can be used for an electrical detection method capable of providing precise measurement results even with a small amount of source material.

摘要翻译： 描述了通过化学官能团将金属纳米晶体的羧化CNT点缀的导电碳纳米管（CNT），以及用于制造导电CNT的图案或膜的方法，其包括在基板上反复沉积导电CNT以实现高表面 密度。 描述了生物传感器，其中结合靶生物分子的生物感受器选择性地连接到导电CNT或导电CNT图案或膜。 通过使用导电生物传感器，可以在一个步骤中直接或通过大量的电化学信号精确测量与生物感受器结合或反应的各种靶生物材料。 此外，生物传感器可以用于即使使用少量源材料也能够提供精确测量结果的电检测方法。

公开(公告)号：US08610884B2

公开(公告)日：2013-12-17

申请号：US13498798

申请日：2012-01-11

申请人： Hee Tae Jung ,  Yun Ho Kim ,  Dae Woo Kim ,  Hyeon Su Jeong

发明人： Hee Tae Jung ,  Yun Ho Kim ,  Dae Woo Kim ,  Hyeon Su Jeong

IPC分类号： G01N1/00

CPC分类号： B82Y30/00 ,  B82Y40/00 ,  C01B32/186 ,  G01N21/21 ,  G01N21/8422 ,  G01N2021/8427 ,  G02B1/08

摘要： The present invention relates to a method for optical visualization of graphene domains, and more particularly to a method for optical visualization of graphene domains, which can optically visualize the domains and domain boundaries of graphene by forming on a substrate a graphene layer to be measured, forming a liquid crystal layer on the formed graphene layer, and then measuring the optical properties of the formed nematic liquid crystal layer. The method for optical visualization of graphene domains according to the invention uses a liquid crystal-coating method, which is simpler and easier than a conventional method for observing graphene domains. Thus, the method of the invention is simple, time-saving and inexpensive and, at the same time, enables very-large-area graphene domains to be observed with a polarizing microscope or the like. Therefore, the inventive method will be very useful in the research of graphene's properties.

摘要翻译： 本发明涉及一种用于石墨烯畴的光学可视化的方法，更具体地说，涉及一种用于石墨烯畴的光学可视化的方法，该方法可通过在衬底上形成待测量的石墨烯层来光学地可视化石墨烯的畴和畴边界， 在形成的石墨烯层上形成液晶层，然后测定形成的向列型液晶层的光学性质。 根据本发明的石墨烯畴的光学可视化方法使用液晶涂覆方法，其比用于观察石墨烯畴的常规方法更简单和更容易。 因此，本发明的方法简单，节省时间并且便宜，并且同时能够利用偏光显微镜等观察极大面积的石墨烯畴。 因此，本发明的方法在石墨烯性质的研究中将是非常有用的。

公开(公告)号：US20130162977A1

公开(公告)日：2013-06-27

申请号：US13498798

申请日：2012-01-11

申请人： Hee Tae Jung ,  Yun Ho Kim ,  Dae Woo Kim ,  Hyeon Su Jeong

发明人： Hee Tae Jung ,  Yun Ho Kim ,  Dae Woo Kim ,  Hyeon Su Jeong

IPC分类号： G01N1/28 ,  G01N1/44

CPC分类号： B82Y30/00 ,  B82Y40/00 ,  C01B32/186 ,  G01N21/21 ,  G01N21/8422 ,  G01N2021/8427 ,  G02B1/08

摘要： The present invention relates to a method for optical visualization of graphene domains, and more particularly to a method for optical visualization of graphene domains, which can optically visualize the domains and domain boundaries of graphene by forming on a substrate a graphene layer to be measured, forming a liquid crystal layer on the formed graphene layer, and then measuring the optical properties of the formed nematic liquid crystal layer. The method for optical visualization of graphene domains according to the invention uses a liquid crystal-coating method, which is simpler and easier than a conventional method for observing graphene domains. Thus, the method of the invention is simple, time-saving and inexpensive and, at the same time, enables very-large-area graphene domains to be observed with a polarizing microscope or the like. Therefore, the inventive method will be very useful in the research of graphene's properties.

摘要翻译： 本发明涉及一种用于石墨烯畴的光学可视化的方法，更具体地说，涉及一种用于石墨烯畴的光学可视化的方法，该方法可通过在衬底上形成待测量的石墨烯层来光学地可视化石墨烯的畴和畴边界， 在形成的石墨烯层上形成液晶层，然后测定形成的向列型液晶层的光学性质。 根据本发明的石墨烯畴的光学可视化方法使用液晶涂覆方法，其比用于观察石墨烯畴的常规方法更简单和更容易。 因此，本发明的方法简单，节省时间并且便宜，并且同时能够利用偏光显微镜等观察极大面积的石墨烯畴。 因此，本发明的方法在石墨烯性质的研究中将是非常有用的。

公开(公告)号：US20090314350A1

公开(公告)日：2009-12-24

申请号：US12477375

申请日：2009-06-03

申请人： Hee Tae Jung ,  Jae Hyun Lee ,  Dae Woo Kim ,  Hong Jang

发明人： Hee Tae Jung ,  Jae Hyun Lee ,  Dae Woo Kim ,  Hong Jang

IPC分类号： H01L51/44 ,  H01L51/48 ,  H01L51/46

CPC分类号： H01L51/0023 ,  B82Y10/00 ,  H01L51/0036 ,  H01L51/0037 ,  H01L51/0047 ,  H01L51/4253 ,  H01L51/442 ,  H01L51/447 ,  Y02E10/549 ,  Y02P70/521

摘要： An organic solar cell and a method of manufacturing the same. This invention relates to a method of manufacturing an organic solar cell including forming nano patterns on a photoactive layer using a nanoimprinting process, and applying a cathode electrode material on the photoactive layer having the nano patterns so that the cathode electrode material infiltrates the nano patterns of the photoactive layer, thus increasing electron conductivity and efficiently forming a pathway for the transfer of electrons, and to an organic solar cell manufactured through the method. This method reduces loss of photocurrent occurring as a result of aggregation of an electron acceptor material and improves molecular orientation of an electron donor in the nanoimprinting process to thus increase cell efficiency. Thereby, the organic solar cell having high efficiency is manufactured at low cost through a simple manufacturing process. The method can be applied to the fabrication of organic solar cells which use an environmentally friendly and recyclable energy source.

摘要翻译： 一种有机太阳能电池及其制造方法。 本发明涉及一种制造有机太阳能电池的方法，其包括使用纳米压印工艺在光敏层上形成纳米图案，并且在具有纳米图案的光敏层上施加阴极电极材料，使得阴极电极材料渗入纳米图案 光活性层，从而增加电子传导性并且有效地形成用于电子转移的途径，以及通过该方法制造的有机太阳能电池。 该方法减少了由于电子受体材料的聚集而产生的光电流的损失，并改善了纳米压印工艺中电子给体的分子取向，从而提高了电池效率。 因此，通过简单的制造工艺以低成本制造高效率的有机太阳能电池。 该方法可以应用于使用环境友好和可循环利用的能源的有机太阳能电池的制造。