Poly(vinyl chloride)-g-poly(oxyethylene methacrylate) (PVC-g-POEM) 가지형 공중합체를 원자전달라디칼 중합을 통해 합성하여 전기변색소자의 전해질에 적용하였다. 가소화된 고분자 전해질은 가소제로서 propylene carbonate (PC)/ethylene carbonate (EC) 혼합물을 도입하여 제조하였으며, Lithium tetrafluoroborate (LiBF4), lithium perchlorate (LiCIO4), lithium iodide (LiI) and lithium bistrifluoromethanesulfonimide (LiTFSI)를 사용하여 염의 종류에 따른 영향을 조사하였다. 광각 x-선 산란(WAXS)과 시차주사 열량법(DSC) 측정 결과 고분자 전해질의 구조와 유리전이온도(Tg)가 변하였고, 이는 POEM 내의 에테르의 산소와 리튬염 사이의 상호작용으로 인해 변했다는 것을 FT-IR 분광법을 통하여 확인하였다. 투과전자현미경(TEM) 측정 결과 PVC-g-POEM 가지형 공중합체의 미세상분리 구조가 PC/EC와 리튬염의 도입에도 변하지 않는 것을 관찰하였다. 가소화된 고분자 전해질은 poly(3-hexylthiophene) (P3HT) 전도성 고분자를 이용한 전기변색소자에 적용되었다.

This study aims to analyze the situation and behavioral characteristic of nonpoint pollution sources by examining and analyzing the basic data such as the hydraulic and hydrologic characteristics and land use situation of the basin, and provide basic design data for basin management by calculating the soil loss rate due to rainfall effluents, for the Golji Stream basin located at Jeongseon, Gangwon province. For this, this study applied the SWAT model to the object basin, established input data for the model through parameter estimation and sensitivity analysis, and conducted a simulation. This study confirmed the suitability of the model by conducting a verification with the actually measured spillage being the basic of simulation results, analyzed that the maintenance of the sub-basin #15 with 34644.37 ton/yr of soil loss rate calculated by sub-basins in the object basin should be conducted first, and showed that there happened about 14,800 times of difference from the sub-basin #1 with 2.33 ton/yr of soil loss rate, the lowest. It is judged that this result should be considered as very important to set the priority order of basin management in a large basin and should be considered reasonably when applied to the work.

This study was conducted to investigate plant body temperature response of soybean (Glycine max) to saline stress. Two-weeks-old seedlings of soybean in V1 growth stage were treated with 0, 10, 20, 40, 80 and 160 mM of NaCl for salt stress. Thermal images acquired using Flir T-420 (US) were obtained at 4 days after treatment. Soybean leaf temperature increased with increasing NaCl concentration, resulting in significant positive correlation between soybean leaf temperature and stress intensity (P < 0.01). Leaf temperature of soybean was significantly different at 160 mM of NaCl, where no visual symptom was observed. Therefore, soybean leaf temperature can be used for evaluating the response of soybean to salt stress as a non-destructive and phenomic parameter. Non-destructive diagnosis of soybean leaf temperature may be a key parameter in a high throughput screening (HTS) system in breeding program for salt stress tolerance soybean cultivars.