KOSEN 한인과학기술자네트워크

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네트워크

네트워크

다양한 연구실 탐방기사 보기
다양한 연구실 탐방기사 보기

전기전자

차세대 디스플레이 연구실

2019-10-23 org.kosen.entty.User@3f3365fa
   
 
 
디스플레이의 switching 소자로써 사용되는 박막트랜지스터 (Thin Film Transistors : TFTs)에서 반도체 물질을 유기물로 제작하면 소자의 유연성과 값싼 공정을 얻을 수 있다. 이렇게 유기물을 반도체물질로 제작된 박막트랜지스터를 유기박막트랜지스터(Organic Thin Film Transistors : OTFTs)라고 한다.
 
 
 
다양한 Flexible electronic 응용
낮은 제작 비용
낮은 제작 온도
대면적 유리		 낮은 carrier mobility와 switching speed
소자 특성의 불안정성
 
       
   
 
기존의 액정 디스플레이는 유리 기판을 사용하기 때문에, 무게와 장소에 많은 제약을 받을 수 밖에 없고, 디스플레이 모양이 제작 후 변형되지 못한다는 단점을 가지고 있다. 이러한 문제점들을 기판의 재료를 유리 기판에서 플라스틱 기판을 사용하면서 극복할 수 있다. 하지만 기판을 flexible한 기판으로 바꿈으로 인한 휨휨 변형 시와 같은 물리적인 외부 충격에 의해 액정의 배향이 변형되어 화질이 저하되고, 접합된 상/하 기판이 쉽게 분리되어 버린다는 단점 등 새로운 문제점이 발생된다.
이에 물리적으로 불안정한 기존의 Flexible LCD의 문제점을 극복하는 방법 중 하나로 PILC(Pixel Isolated Liquid Crystal) mode를 제안하였고, 연구가 진행되고 있다. PILC mode는 화소 단위로 격벽을 형성하여 액정을 화소 안에 고립화시켜 외부 충격으로부터 액정 배향의 안정성을 확보 할 수 있으며. 액정과 고분자의 비등방 상분리의 방법을 이용하여 형성되는 Polymer Layer를 이용하여 상/하 기판을 강하게 접합하여 물리적 안정성을 확보 할 수 있다.
 
 
 
 
 
       
   
 
Microlenses are small lenses, generally with diameters less than a millimetre (mm) and often as small as 10 micrometres (μm). The small sizes of the lenses means that a simple design can give good optical quality but sometimes unwanted effects arise due to optical diffraction at the small features. A typical microlens may be a single element with one plane surface and one spherical convex surface to refract the light. Because microlenses are so small, the substrate that supports them is usually thicker than the lens and this has to be taken into account in the design. More sophisticated lenses may use aspherical surfaces and others may use several layers of optical material to achieve their design performance. A different type of microlens has two flat and parallel surfaces and the focusing action is obtained by a variation of refractive index across the lens. These are known as gradient-index (GRIN) lenses. Some microlenses achieve their focusing action by both a variation in refractive index and by the surface shape. Another class of microlens, sometimes known as micro-Fresnel lenses, focus light by refraction in a set of concentric curved surfaces. Such lenses can be made very thin and lightweight. Binary-optic microlenses focus light by diffraction. They have grooves with stepped edges or multilevels that approximate the ideal shape. They have advantages in fabrication and replication. Microlens arrays contain multiple lenses formed in a one-dimensional or two-dimensional array on a supporting substrate. If the individual lenses have circular apertures and are not allowed to overlap they may be placed in a hexagonal array to obtain maximum coverage of the substrate. However there will still be gaps between the lenses which can only be reduced by making the microlenses with non-circular apertures.
 
 
 
       
   
 
In the 17th century, Robert Hooke and Antonie van Leeuwenhoek both developed techniques to make small glass lenses for use with their microscopes. Hooke melted small filaments of glass and allowed the surface tension in the molten glass to form the smooth spherical surfaces required for lenses.[1] The principle has been repeated by etching patterns into material such as photoresist and melting the resist to form arrays of multiple lenses.[2][3] Advances in technology have enabled microlenses to be designed and fabricated to close tolerances by a variety of methods. In most cases multiple copies are required and these can be formed by moulding or embossing from a master lens array. The ability to fabricate arrays containing thousands or millions of precisely spaced lenses has led to an increased number of applications. The optical efficiency of diffracting lenses depends on the shape of the groove structure and, if the ideal shape can be approximated by a series of steps or multilevels, the structures may be fabricated usingtechnology developed for the integrated circuit industry. This area is known as binary optics. Microlenses in recent imaging chips have attained smaller and smaller sizes. The Canon EOS-1Ds Mark III packs 21.1 million microlenses onto its CMOS imaging chip, one per photosite, each just 6.4 micrometer across. An announced Sony DSLR 24.6MP image sensor will have even smaller microlenses. Microlenses can be also made from liquids.
 
 
 
 
 
       
   
 
Single microlenses are used to couple light to optical fibres while microlens arrays are often used to increase the light collection efficiency of CCD arrays. They collect and focus light that would have otherwise fallen on to the non-sensitive areas of the CCD. Microlens arrays are also used in some digital projectors, to focus light to the active areas of the LCD used to generate the image to be projected. Combinations of microlens arrays have been designed that have novel imaging properties, such as the ability to form an image at unit magnification and not inverted as is the case with conventional lenses. Microlens arrays have been developed to form compact imaging devices for applications such as photocopiers and mobile-phone cameras. Another application is in 3D imaging and displays. In 1902 Frederick Ives proposed the use of an array of alternately transmitting and opaque strips to define the viewing directions for a pair of interlaced images and hence enable the observer to see a 3D stereoscopic image. The strips were later replaced by Hess with an array of cylindrical lenses known as a lenticular screen, to make more efficient use of the illumination. More recently, the availability of arrays of spherical microlenses has enabled Gabriel Lippmann’s idea for integral photography to be explored and demonstrated.
 
 
 
       
   
 
In order to characterise microlenses it is necessary to measure parameters such as the focal length and quality of transmitted wavefront. Special techniques and new definitions have been developed for this. For example, because it is not practical to locate the principal planes of such small lenses, measurements are often made with respect to the lens or substrate surface. Where a lens is used to couple light into an optical fibre the focused wavefront may exhibit spherical aberration and light from different regions of the microlens aperture may be focused to different points on the optical axis. It is useful to know the distance at which the maximum amount of light is concentrated in the fibre aperture and these factors have led to new definitions for focal length. To enable measurements on microlenses to be compared and parts to be interchanged, a series of international standards has been developed to assist users and manufacturers by defining microlens properties and describing appropriate measurement methods.
 
 
 
       
   
 
Examples of microoptics are to be found in nature ranging from simple structures to gather light for photosynthesis in leaves to compound eyes in insects. As methods of forming microlenses and detector arrays are further developed then the ability to mimic optical designs found in nature will lead to new compact optical systems.

국가

대한민국

소속기관

한양대학교 (학교)

연락처

02-2220-2314 http://displaylab.hanyang.ac.kr/

책임자

유창재 cjyu@hanyang.ac.kr

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