Flexible glass substrates with via holes for TFT backplanes

This paper looks at flexible glass substrates with via holes for TFT backplane

James Fergason, a Pioneer in Advancing of Liquid Crystal Technology

James Lee Fergason (1934 - 2008) focused his research on the liquid crystals. His studies correspond to a relevant part of the history of soft matter science and technology of liquid crystals. Here a discussion of some of his researches.Comment: Soft Matter, Liquid Crystals, Cholesterics, Nematics, Smectics, Liquid Crystal Display

Web-based interface system for bedside monitor

From face-to-face consultation to medicine at a distance, technology is changing the way medical services are delivered to the people. We are going into an era where the information is being digitized to be stored in a database. This is done in order to reduce information overlap and redundancy that are the main problems the health care sector are facing right now. More hospitals in other more advanced countries are going paperless. In order to provide better services to the critically ill patients in the ICU or CCU, a data acquisition program is developed for the acquisition of vital signs monitored in the critical care units. This work discusses the work done in extracting the data and signal from patient monitor BSM 8800 to the computer. The data are acquired using RS232C Interface Protocol. The vital signs acquired include oxygen saturation (SaCh), heart rate (HR), electrocardiograph (ECG) signal, non-invasive blood pressure (NIBP), respiration rate (RR), temperature (TEMP) and end tidal carbon dioxide (PETCO2 or ETCO2). Ventricular Premature Contraction (VPC), ST level and arrhythmia information are also acquired and displayed to provide a more thorough information on the condition of the patients. Alarm detection is also programmed so that in critical conditions the vital signs will be displayed in red for extra caution. An ECG user control is designed and embedded in the web page in order to convert and plot the ECG waveform from hexadecimal values sent from the bedside monitor. The user control has been tested its accuracy and proved its validity to reconstruct the original ECG waveform. Basic patient information can also be seen from the graphical user interface (GUI) that has been developed. Physicians and medical practitioners have to register with the system before gaining access to the system and only the physician-in-charge of the patient can see the more intricate details of the patient

Micro-sized Polymer-Dispersed Liquid Crystal for TFT array Inspections

We report a highly sensitive electro-optic modulator with low driving voltage based on the nano/micro-sized polymer-dispersed liquid crystal for TFT array inspector. The light modulator with low dielectric and high birefringence liquid crystals exhibited high defect detection sensitivity and low driving voltage at 20 nm air gap. ��� 2013 ITE and SID.This work was supported by the National Research Foundation of Korea (NRF) grant (No. 2011-0016968) funded by the Ministry of Education

Micro-sized Polymer-Dispersed Liquid Crystal Modulator for TFT array defect Inspections

We proposed low driving voltage electro-optic (EO) modulator using the nano/micro-sized polymer-dispersed liquid crystal (PDCLC) for TFT array inspector. It was obtained high efficiency performance with detection sensitivity with low driving voltage at 20��� air gap.This work was supported by the National Research Foundation of Korea (NRF) grant (No. 2011-0016968) funded by the Ministry of Education, Science and Technology of Korean government (MEST

Photo-enforced stratification of liquid crystal / monomer mixtures : principle, theory and analysis of a paintable LCD concept

To keep pace with customer demand for cost-effective flat panel displays, liquid crystal display (LCD) manufacturing technologies are required that enable the processing of larger substrates with increased production speeds. In cell-technology, currently used in all LCD factories, cells are formed by coupling two substrates, which are subsequently filled with liquid crystal (LC). However, this is a timeconsuming process that limits the shape- and substrate choice. New display designs require displays that are curved, optionally flexible, and non-rectangular in shape. This thesis describes the exploration of a new phase separation process that enables the production of Paintable LCDs. Unlike cell-technology, Paintable LCDs are produced on a single-substrate by the sequential coating and curing of multiple organic layers on top of each other. The electro-optical LC layer is confined between the substrate and a polymer sheet with the important feature that the latter is formed during processing. This in-situ polymer sheet formation is the result of a spatially-controlled photopolymerization-induced phase separation process. In this process, a film consisting of a mixture of LC and monomers is irradiated with UV light. Due to a photopolymerization rate gradient in the film and a concomittant selective phase separation of LC material at the bottom of the film, the film is transformed into a stratified morphology: a polymer film on top of an LC layer. This concept is referred to as photo-enforced stratification (PES). Interdigitated electrodes previously applied on the substrate switch the LC layer. The use of coating processes makes the Paintable LCD technology well suited for application in free form factor displays potentially produced via high-speed roll-toroll manufacturing processes. In PES two main physical processes are involved: photopolymerizationinduced diffusion and polymerization-induced phase separation. As a result of transversal diffusion of LC and monomers through the film, induced by a vertical gradient in the polymerization rate, the phase separation process is located at the bottom of the film. The phase separation at the bottom of the film leads to the formation of large LC domains randomly distributed over the substrate area, covered by a polymeric topcoat. Characterizations with polarization microscopy and surface profile measurements show that when the stratification step is preceded by a mask exposure step, morphologies are formed that can be described as regular arrays of neighboring LC-filled polymer capsules. Confocal Raman microscopy measurements on these LC-filled polymer capsules reveal that part of the LC stays isotropically dissolved in the polymer phase. Moreover, it was found that under the current process conditions microscopic LC droplets are formed, which are dispersed in the polymer near the polymer-LC interface, comparable to the morphology of PDLC displays (polymer-dispersed liquid crystal displays). A numerical PES model has been developed based on free radical polymerization rate equations, diffusion equations and the thermodynamics of phase separation. The PES model is a combination of two distinct components: The first component is a reaction-diffusion model that calculates the evolution of the concentration of the liquid crystal (LC), monomer and polymer as a function of depth in the film and time. The second component is a thermodynamic model that describes polymerization-induced phase separation (PIPS). In the model, the contribution of the entropic and enthalpic mixing (Flory-Huggins theory of mixing), elasticity of the polymer network (Flory-Rehner theory) and nematic ordering (Maier-Saupe theory) to the Gibbs free energy are included. The overall PES model is a one-dimensional model, which calculates the location and the time (conversion) at which the phase separation sets in. Moreover, it helps the prediction of trends in the morphologies that will be formed. In order to compare the model outcomes with the experimental results, the model input parameters have been determined, either by calculations or by experiments on the appropriate LC/monomers systems. The Flory-Huggins interaction parameters between the various components were estimated via the calculated solubility parameters of the components (via a group contribution theory). With the aid of photo-DSC the photopolymerization kinetics was investigated and the diffusion constants the LC and monomer species were measured with the aid of NMR spectroscopy as a function of the conversion. Both components of the PES model, the reaction-diffusion model and the phase separation model, were independently compared to experiments. With confocal Raman microscopy, the concentration profile of the LC compound was monitored insitu, during the UV irradiation. The measured changes in the LC concentration profile were found to be similar to the changes calculated by the reaction-diffusion model. Photo-DSC has been combined with in-situ optical microscopy to determine the phase diagram of the investigated LC/monomer/polymer system. The measurements showed that for the investigated system the elastic contribution of the polymer network could be neglected. The theoretical phase diagram, in which the phase separation lines were calculated by taking the mixing contributions and the contribution of nematic ordering of the LC phase into account, are in agreement with the experimental phase diagram. Subsequently, the stratification behavior as a function of the LC fraction in the initial reaction mixture was investigated experimentally. The earlier onset of phase separation as well as an increased formation of PDLC-morphology in the polymer layer at higher initial LC fraction both agree with trends calculated with the PES model. The PES model and the diffusion-, phase separation- and stratification experiments have led to a better understanding of the PES process in which the position of the onset of phase separation in the layer is controlled by polymerizationinduced diffusion. Besides a better understanding of the physical processes involved in the PES process this research has led to a simplified and improved stratification process in which the arrays of LC-filled polymer capsules are obtained via a single UV exposure step. For this purpose the alignment layer on the bottom substrate is first patterned with an adhesion promoter using offset printing. During the stratification process the polymer top layer locally forms covalent bonds with the adhesion promoter patterns. Besides a simpler manufacturing process, this results in mechanically stable morphologies, which enable the production of flexible, plastic LCDs with a free form factor