公开(公告)号：US20130199612A1

公开(公告)日：2013-08-08

申请号：US13677733

申请日：2012-11-15

Applicant: Korea Institute of Science and Technology

Inventor： Ho Won JANG ,  Seok Jin YOON ,  Deok Ha WOO ,  Jin Sang KIM ,  Hyo Jin KWON ,  Chong Yun KANG ,  Ji Won CHOI

IPC: H01L31/0232

CPC classification number: H01L31/02327 ,  B82Y30/00 ,  C03C17/42 ,  C03C2217/425 ,  C03C2217/73 ,  C03C2217/76 ,  H01L31/02168 ,  H01L31/02366 ,  H02S40/10 ,  Y02E10/50 ,  Y10S977/755 ,  Y10T428/24355

Abstract: Provided are a hydrophobic antireflective substrate, a method for manufacturing the same, and a solar cell module including the same. The hydrophobic antireflective substrate includes: a substrate; a nanostructured layer having nanostructured portions formed on the substrate and nanoporous portions formed between the nanostructured portions; and a hydrophobic coating film formed on the nanostructured portions. The method for manufacturing a hydrophobic antireflective substrate includes: forming a nanostructured layer having nanostructured portions and nanoporous portions formed between the nanostructured portions on a substrate; and forming a hydrophobic coating film on the nanostructured portions. In the hydrophobic antireflective substrate disclosed herein, a porous nanostructured layer is formed on the substrate and a hydrophobic coating film is formed on the nanostructured layer, so that the hydrophobic antireflective substrate has ultra-hydrophobic property corresponding to a large water droplet contact angle.

Abstract translation: 提供了一种疏水性抗反射基板，其制造方法以及包括该防反射基板的太阳能电池模块。 疏水性抗反射基板包括：基板; 具有形成在所述基板上的纳米结构部分和形成在所述纳米结构部分之间的纳米多孔部分的纳米结构层; 以及形成在纳米结构部分上的疏水涂膜。 制造疏水性抗反射基板的方法包括：在基板上形成具有纳米结构部分和形成在纳米结构部分之间的纳米多孔部分的纳米结构层; 并在纳米结构部分上形成疏水性涂膜。 在本文公开的疏水性抗反射基板中，在基板上形成多孔纳米结构化层，在纳米结构层上形成疏水性涂膜，疏水性防反射基板具有对应于大的水滴接触角的超疏水性。

公开(公告)号：US20140217404A1

公开(公告)日：2014-08-07

申请号：US14250821

申请日：2014-04-11

Applicant: KOREA INSTITUTE OF SCIENCE AND TECHNOLOGY

Inventor： Ho Won JANG ,  Seok Jin YOON ,  Jin Sang KIM ,  Chong Yun KANG ,  Ji Won CHOI ,  Hi Gyu MOON

IPC: G01N27/12

CPC classification number: G01N27/127 ,  B82Y15/00 ,  B82Y40/00

Abstract: The present disclosure provides a gas sensor including: a substrate; an electrode formed on the substrate; and a gas-sensing layer formed on the electrode, wherein the gas-sensing layer is a self-heating nanocolumnar structure having nanocolumns formed on the electrode and inclined with respect to the electrode with an angle of 60-89° and gas diffusion pores formed between the nanocolumns. The gas sensor according to the present disclosure requires no additional heater since it self-heats owing to the nanocolumnar structure and exhibits superior gas sensitivity even when no heat is applied from outside. Also, it can be mounted on mobile devices such as mobile phones because it consumes less power.

Abstract translation: 本公开提供了一种气体传感器，包括：基板; 形成在基板上的电极; 以及形成在所述电极上的气体感测层，其中所述气体感测层是具有在所述电极上形成的纳米柱并且以60-89°的角度相对于所述电极倾斜并且形成气体扩散孔的自加热纳米柱结构 在纳米柱之间。 根据本公开的气体传感器不需要额外的加热器，因为其由于纳米柱状结构而自发加热，并且即使在从外部没有加热时也显示出优异的气体灵敏度。 此外，它可以安装在诸如移动电话的移动设备上，因为它消耗更少的功率。

公开(公告)号：US20130098754A1

公开(公告)日：2013-04-25

申请号：US13692821

申请日：2012-12-03

Applicant: Korea Institute of Science and Technology

Inventor： Ji Won CHOI ,  Seok Jin YOON ,  Won Kook CHOI ,  Jin Sang KIM ,  Chong Yun KANG ,  Ho Won JANG ,  Keun JUNG

IPC: C23C14/08

CPC classification number: C23C14/086 ,  C23C14/08 ,  C23C14/3414 ,  H01B1/08

Abstract: Disclosed are a transparent conductive composition including a material of the following formula, a target, a transparent conductive thin film using the target, and a method for fabricating the same. The disclosed transparent conductive composition and transparent conductive thin film have superior conductivity (low resistivity) and high light transmittance. Especially, they may be usefully applied for the flexible electronic devices, which may be called the core of the future display industry, because they have low resistivity of not greater than 10−3 Ω·cm and a high light transmittance of at least 90% even when deposition is carried out at room temperature. AlxZn1-xO In the above formula, x is within the range of 0.04≦x≦0.063.

Abstract translation: 公开了一种透明导电组合物及其制造方法，该导电组合物包括下式的材料，靶材，使用该靶材的透明导电薄膜。 所公开的透明导电组合物和透明导电薄膜具有优异的导电性（低电阻率）和高透光率。 特别地，它们可以有用地应用于可能被称为未来显示器行业的核心的柔性电子器件，因为它们具有不大于10-3Ω·cm的低电阻率和至少90％的高透光率 即使在室温下进行沉积也是如此。 AlxZn1-xO在上式中，x在0.04 @ x @ 0.063的范围内。