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밀 유전자원의 농업형질과 SSR마커를 이용한 다양성 분석
신명재(Myoung-Jae Shin),오미애(Miae Oh),김경민(Kyung-Min Kim),왕샤오한(Xiaohan Wang),김성훈(Seong-Hoon Kim),한세희(Seahee Han),Kebede Taye Desta(Kebede Taye Desta ),최유미(Yu-Mi Choi),윤혜명(Hye-myeong Yoon),이윤정(Yoonjung Lee) 한국육종학회 2022 한국육종학회지 Vol.54 No.4
Breeders typically use core collections of a specific trait or core collections selected by a few genotypes to efficiently select breeding materials or to study functional genes. As a result, many accessions have been deemed redundant or duplicated and are no longer considered for use. This study aimed to investigate the agronomical characteristics and genetic diversity of 1,514 previously unused and unstudied wheat germplasms and to confirm their value as breeding materials using population structure analysis. The performance of these wheat germplasms was compared with that of 8,878 wheat breeding materials and 72 known Korean wheat cultivars. The results of agronomic trait diversity comparison showed that the germplasm populations used for breeding research did not completely encompass the unused germplasm populations. The agronomic traits of wheat germplasms varied greatly. ANOVA and PCA results revealed the greatest differences in growth habits (CV=0.339), panicle length (CV=0.330), and awn length (CV=0.296). To accurately assess the value of unused wheat germplasms as breeding materials, 106 SSR markers were extracted from the analysis of four representative Korean cultivars: Geuru, Geumgang, Uri, and Jokyoung. Among these, 24 SSR markers were chosen, and 129 wheat resources were subjected to population structure analysis, which revealed five subpopulations. Most of the 34 germplasms that originated in Korea were distributed in subpopulation 1 (18 accessions, 52.9%) and subpopulation 4 (12 accessions, 35.3%). Subgroups 2, 3, and 5 differed significantly in agronomic traits and genotypes, indicating their potential as breeding materials. The findings of this study could serve as a foundation for breeders and aid in the discovery and utilization of new wheat breeding materials.
유나영(Na Young You),이민정(Min Jung Lee),신명재(Myeong Jae Shin),조홍현(Hong Hyun Cho) 대한설비공학회 2022 대한설비공학회 학술발표대회논문집 Vol.2022 No.6
In this study, the photothermal conversion characteristics of CNT, Fe₃O₄, and SiC nanofluids were ezperimetally investigated to select a heat transfer fluid for the direct absorption solar collecting method. The concentrations of CNT, Fe₃O₄, and SiC nanofluids used for the experiment were 0.002wt%, 0.075wt%, and 0.02wt%, ant which the optical absorption reached the critical point. The maximum absorption efficiency of 0.002wt% CNT, 0.075wt% Fe₃O₄ and 0.02wt% SiC nanofluids were measured to be 80.8%, 77.8%, and 72.3%. In addition, the photothermal conversion efficiency of 0.002wt% CNT, 0.075wt% Fe₃O₄, and 0.02wt% SiC nanofluids were measured to be 90.03%, 84.38%, and 93.26%. From these results, it is judged that the CNT nanofluid is economically advantageous compared to Fe₃O₄ and SiC nanofluids to improve photothermal conversion characteristics. However, when using CNT nanofluids for the direct absorption solar collection method, the long-term high-temperature dispersion stability is low and using the low concentration of CNT nanofluid is disadvantageous. Therefore, there is a need for future research to select a suitable nanofluid for the direct absorption solar collecting method by evaluating the light-to-heat conversion characteristics, economic feasibility, and dispersion stability.
유나영(Na Young You),이민정(Min Jung Lee),신명재(Myeong Jae Shin),조홍현(Hong Hyun Cho) 대한설비공학회 2022 대한설비공학회 학술발표대회논문집 Vol.2022 No.6
In this study, the photothermal conversion characteristics of CNT, Fe₃O₄, and SiC nanofluids were ezperimetally investigated to select a heat transfer fluid for the direct absorption solar collecting method. The concentrations of CNT, Fe₃O₄, and SiC nanofluids used for the experiment were 0.002wt%, 0.075wt%, and 0.02wt%, ant which the optical absorption reached the critical point. The maximum absorption efficiency of 0.002wt% CNT, 0.075wt% Fe₃O₄ and 0.02wt% SiC nanofluids were measured to be 80.8%, 77.8%, and 72.3%. In addition, the photothermal conversion efficiency of 0.002wt% CNT, 0.075wt% Fe₃O₄, and 0.02wt% SiC nanofluids were measured to be 90.03%, 84.38%, and 93.26%. From these results, it is judged that the CNT nanofluid is economically advantageous compared to Fe₃O₄ and SiC nanofluids to improve photothermal conversion characteristics. However, when using CNT nanofluids for the direct absorption solar collection method, the long-term high-temperature dispersion stability is low and using the low concentration of CNT nanofluid is disadvantageous. Therefore, there is a need for future research to select a suitable nanofluid for the direct absorption solar collecting method by evaluating the light-to-heat conversion characteristics, economic feasibility, and dispersion stability.