[논문]기후분포가 다른 재배지에서 생장한 겉보리 생육, 수량 및 품질 비교

박현화; 이효진; 김예건; 김대욱; 국용인

doi:10.7740/kjcs.2023.68.2.069

[국내논문] 기후분포가 다른 재배지에서 생장한 겉보리 생육, 수량 및 품질 비교
Comparative Analysis of Growth, Yield, and Grain Quality of Hulled Barley Grown Under Different Meteorological Conditions in South Korea 원문보기

Korean journal of crop science = 韓國作物學會誌, v.68 no.2, 2023년, pp.69 - 80

박현화 (순천대학교 식물생산과학부) , 이효진 (순천대학교 자원식물개발학과) , 김예건 (순천대학교 자원식물개발학과) , 김대욱 (농촌진흥청 국립식량과학원) , 국용인 (순천대학교 바이오한약자원학과)

초록
AI-Helper

본 연구는 기후분포가 다른 3개 그룹 지역(G1, G2, G3)에 겉보리를 파종하고, 월동 전(12월), 월동 후(2월) 및 출수기(4월)에 생육과 수확기(6월)에 수량 차이를 조사하였고, 이들 그룹 지역간 생육과 수량차이와 작물생육기 기상요인과 출수기에 토양화학성과 잎 무기성분과 관련성을 조사하였다. 또한 수확기에는 그룹 지역간에 수확한 겉보리 종자의 일반성분, 무기물 및 아미노산 함량을 조사하였다. 월동 전, 후 분얼수는 G1지역이 G2와 G3지역에 비해 높았다. 그러나 출수기의 분얼수와 지상부 건물중은 G2와 G3 지역이 G1지역에 비해 높았다. 재생기, 유수형성기 및 출수일의 경우 G2 지역은 G1과 G3지역에 비해 다소 늦었다. 그러나 엽록소 함량(SPAD값)은 그룹 간에 차이가 없었다. 수량의 경우 G2지역이 G1과 G3지역에 비해 9~15% 감소하였다. G2지역의 수량 감소는 수수, 영화수 및 등숙율 감소에 기인되는 것으로 판단된다. 또한 G2지역에서 수량이 감소했던 것은 G2지역이 작물 생육기에 최고, 최저 및 일 평균기온이 G1과 G3지역에 비해 낮았기 때문인 것으로 판단된다. 그러나 토양 내 무기성분은 G2지역에서 G1과 G3 지역에 비해 높았다. 식물체의 무기성분 함량은 G1지역에서 G2와 G3 지역에 비해 높은 경향이었다. Cu, K, Mg 및 P와 같은 무기물 함량은 G3 지역에서 그리고 조단백질과 대부분 아미노산은 G2 지역에서 다른 지역에 비해 상대적으로 낮은 경향을 보였다. 따라서 재배한계지 G1지역은 주산지 G3 지역에 비해 겉보리 수량과 일반성분, 아미노산 및 무기물 함량 등에 부정적인 영향없이 안정적으로 재배가 가능한 것으로 판단된다.

Abstract ▼ AI-Helper

This study investigated the differences in barley growth at different growth stages (Dec, Feb, and Apr) and the yield at harvest in three groups (G1, G2, and G3) with different climates. Additionally, we measured meteorological differences between areas during the growing season to determine which factors were related to growth and yield differences. We evaluated the chemical composition of soil and the mineral content in leaves during the heading stages. We also recorded the main constituents, amino acids, and mineral compositions of barley seeds grown in different areas. Tiller number/m2 in G1 areas was higher than in G2 and G3 when measured before and after overwintering. However, tiller number/m2 and dry aboveground plant parts/m2 in G2 and G3 areas were higher than in G1. Regrowth, panicle formation, and heading days in G2 areas occurred slightly later than in G1 and G3. However, there was no difference in chlorophyll content (SPAD value) between groups. The yield in G1 areas was 9~15% less than in G1 and G3. The decrease in yield in G2 areas could be due to lower panicle number, spikelet number, and ripening rate. In addition, the decrease in yield in G2 areas is likely because maximum, minimum, and average daily temperatures during the growing season were lower than those in G1 and G3. However, mineral nutrients in the soil were higher in the G2 area than in G1 and G3. The overall mineral content in plants tended to be higher in G1 areas than in G2 and G3. Mineral content such as Cu, K, Mg, and P in G3 areas and crude protein and most amino acids in G2 areas tended to be relatively low compared to other areas. Thus, the G1 area may be suitable for barley cultivation without adverse impacts on barley yield, main constituents, amino acids, and mineral contents compared to the main producing areas in G3.

Keyword

표/그림 (12)

그림 Fig. 1. Experimental areas (G1, G2, and G3) in this study.
표 Table 1. Growth of hulled barley plants in different group areas before overwintering (December).
표 Table 2. Growth, regrowth, and panicle formation days of hulled barley plants in different group areas after overwintering (February).
표 Table 3. Growth, heading days, and chlorophyll content (SPAD value) of hulled barley plants in different group areas at the heading stage (April).
표 Table 4. Yield components and yield of hulled barley plants in different group areas at harvest.
그림 Fig. 2. Maximum (A), minimum (B), daily average temperatures (C), and precipitation (D) in different group areas during the experimental period.
표 Table 5. Soil moisture content and temperature in December, February, and April in different group areas.
표 Table 6. Chemical components in the soil in different group areas tested during the heading stage grown hulled barley.
표 Table 7. Nutrient levels in plants during the heading stage grown hulled barley in different group areas.
표 Table 8. Moisture, ash, and biochemical component level in hulled barley seeds in different group areas.
표 Table 9. Amino acid content in hulled barley seeds in different group areas.
표 Table 10. Mineral content in hulled barley seeds in different group areas.

참고문헌 (40)

Ahn, S. H., D. W. Kim, H. S. Lee, J. H. Jeong, H. Y. Jeong, W. H.？Hwang, J. S. Baek, K. J. Choi, I. B. Choi, H. K. Park, J. T.？Youn, and G. J. Kim. 2017. Changes in physicochemical？properties in wheat grains as influenced by average temperature rise during ripening stage. Journal of Korean Society？of International Agriculture. 29(1) : 50-55.
Alberdi, M. and L. J. Corcuera. 1991. Cold acclimation in plants.？Phytochemistry 30 : 3177-3184.
Araya, A., G. Hoogenboom, E. Luedeling, K. M. Hadgu, I.？Kisekka, and L. G. Martorano, 2015. Assessment of maize？growth and yield using crop models under present and future？climate in southwestern Ethiopia. Agricultural and Forest？Meteorology. 214 : 252-265.

상세보기
Araya, A., I. Kisekka, X. Lin, P. V. Vara Prasad, P. H. Gowda, C.？Rice, and A. Andales. 2017. Evaluating the impact of future？climate change on irrigated corn production in Kansas. J.？Climate Risk Management. 17 : 139-154.
Araya, A., P. V. V. Prasad, Z. Zambreski, P. H. Gowda, I. A.？Ciampitti, and A. Girma. 2020. Spatial analysis of the impact？of climate factors and adaptation strategies on productivity of？wheat in Ethiopia. Science of The Total Environment. 731 : 139094.
Asseng, S., I. Foster, and N.C. Turner. 2011. The impact of？temperature variability on wheat yields. Glob. Global Change？Biology. 17 : 997-1012.
Brisson, N., P. Gate, D. Gouache, G. Charmet, F.-X. Oury, and F.？Huard. 2010. Why are wheat yields stagnating in Europe? A？comprehen sive data analysis for France. Field Crops？Research. 119 : 201-212.

상세보기
Carr, S. J., G. S. P. Ritchie, and W. M. Porter. 1991. A soil test for？aluminium toxicity in acidic subsoils of yellow earths in？Western Australia. Australian Journal of Agricultural Research.？42 : 875-892.

상세보기
Cha, J. H. and K. S. Kim. 1989. Agriculture, Forestry and？Meteorology; Sunjin Culture: Seoul, Korea. pp. 201-307.
Choi, D. H. and S. H. Yun. 1989. Agroclimatic zone and？characters of the area subject to climatic disaster in Korea.？Korean Journal of Crop Science. 34 (Suppl. S2) : 13-33.
Clausen, S. K., G. Frenck, L. G. Linden, T. N. Mikkelsen, C.？Lunde, and R. B. Jorgensen. 2011. Effects of single and multi-factor treatments with elevated temperature, CO 2 and ozone？on oilseed rape and barley. Journal of Agronomy Crop？Science. 197 : 4421-453.
Collins, M., R. Knutti, J. Arblaster, J. L. Dufresne, T. Fichefet, P.？Friedlingstein, X. Gao, W. J. Gutowski, T. Johns, G. Krinner,？M. Shongwe, C. Tebaldi, A. J. Weaver, and M. Wehner. 2013.？Long-term Climate Change: Projections, Commitments and？Irreversibility. In Climate Change 2013-The Physical Science？Basis: Contribution of Working Group I to the Fifth Assessment Report of the Intergovernmental Panel on Climate？Change; Cambridge University Press: Cambridge, UK. 12 : 1029-1136
Dijkman, T. J., M. Birkved, H. Saxe, H. Wenzel, and M. Z.？Hauschild. 2017. Environmental impacts of barley cultivation？under current and future climatic conditions. Journal of？Cleaner Production. 140 : 644-653.
Dawson, I. K., J. Russell, W. Powell, B. Steffenson, W. T. B.？Thomas, and R. Waugh. 2015. Barley: A translational model？for adaptation to climate change. New Phytologist. 206 :？913-931.

상세보기
Farooqi, A. B., A. H. Khan, and H. Mir. 2005. Climate change？perspective in Pakistan. Pakistan Journal of Meteorology. 2 :？11-21.
Fowler, D. B. and R. J. Carles. 1979. Growth, development, and？cold tolerance of fall acclimated cereal grains. Crop Science.？19 : 915-922.
Gammans, M., P. Merel, and A. Ortiz-Bobea. 2017. Negative？impacts of climate change on cereal yields: Statistical？evidence from France. Environmental Research Letters. 12 : 54007.

상세보기
Ha, Y. W. 2000. Barley, Ruderal Development Administration.？Geomogmunhasa. pp. 81-82.
IPCC. 2013. Climate Change 2013: The Physical Science Basis.？In Contribution of Working Group I to the Fifth Assessment？Report of the Intergovernmental Panel on Climate Change;？Cambridge University Press: Cambridge, MA, UK.
Kim, D. J., J. H. Kin, J. H. Roh, and J. I. Yun. 2012. Geographical？Migration of Winter Barley in the Korean Peninsula under the？RCP8.5 Projected Climate Condition. Korean Journal of？Agricultural and Forest Meteorology. 14 : 161-169.
Kim, Y. G., H. H. Park, H. J. Lee, H. K. Kim, and Y. I. Kuk. 2022.？Growth, yield and grain quality of barley (Hordeum vulgare？L.) grown across South Korean farmland with different？temperature distributions. Agronomy. 12 : 2731.
Ko, J., C. T. Ng, S. Jeong, J. H. Kim, B. Lee, and H. Y. Kim. 2019.？Impacts of regional climate change on barley yield and its？geographical variation in South Korea. International Agrophysics.？33 : 81-96.

상세보기
Kononova, M. M. 1996. Soil Organic Matter: Its Nature, Its Role？in Soil Formation and in Soil Fertility; Pergamon Press:？Oxford, UK.
Kumar, R., V. Singh, S. K. Pawar, P. K. Singh, A. Kaur, and D.？Sharma. 2017. Abiotic Stress and Wheat Grain Quality: A？Comprehensive Review. In Wheat Production in Changing？Environments; Springer: New York, NY, USA, pp. 63-87.
Lee, S. H., I. H. Heo, K. M. Lee, S. Y. Kim, Y. S. Lee, and W. T.？Kwon. 2008. Impacts of climate change on phenology and？growth of crops: In the case of Naju. Journal of the Korean？Geographical Society. 43 : 20-35.
Lobell, D. B., W. Schlenker, and J. Costa-Roberts. 2011. Climate？trends and global crop production since 1980. Science.？333(6042) : 616-620.

상세보기
Mora, C., A. G. Fraizier, R. J. Longman, R. S. Dacks, M. M.？Walton, E. J. Tong, J. J. Sanchez, L. R. Kaiser, Y. O. Srender,？J. M. Anderson, C. M. Amberosino, I. F. Silva, L. M. Giuseffi,？and T. W. Giambelluca. 2013. The projected timing of climate？departure from recent variability. Nature. 502 : 183-188.

상세보기
Newton, A. C., A. J. Flavell, T. S. George, P. Leat, B.？Mullholland, L. Ramsay, C. Revoredo-Giha, J. Russell, B. J.？Steffenson, J. S. Swanston, W. T. B. Thomas, R. Waugh, P. J.？White, and I. J. Bingham. 2011. Crops that feed the world 4.？Barley: A resilient crop? Strengths and weaknesses in the？context of food security. Food Security. 3 : 141-178.

상세보기
Ohara, I. and A. Shujiro. 1979. Comparison of protein precipitants for the determination of free amino acids in plasma.？Agricultural and Biological Chemistry. 43 : 1473-1478.

상세보기
Park, H. H., H. J. Lee, S. W. Roh, H. Hwangbo, and Y. I. Kuk, 2022. Evaluation of cultivation limit area for different types of？barley owing to climate change based on cultivation status and？area of certified seed request. The Korean Journal of Crop？Science. 67 : 95-110.
Passarella, V. S., R. Savin, and G. A. Slafer. 2008. Are？temperature effects on weight and quality of barley grains？modified by resource availability? Australian Journal of Plant？Physiology. 59 : 510-516.
Prasad, P. V. V., M. Djanaguiraman, R. Perumal, and I. A.？Ciampitti. 2015. Impact of high temperature stress on floret？fertility and individual grain weight of grain sorghum:？Sensitive stages and thresholds for temperature and duration.？Frontiers in Plant Science. 6 : 820.

상세보기
Statistical Analysis System (SAS). 2000. SAS/STAT User's？Guide, 7th ed.; Electronic Version; Statistical Analysis？System Institute: Cary, NC, USA.
Savin, R. and M. E. Nicolas. 1996. Effects of short periods of？drought and high temperature on grain growth and starch？accumulation of two malting barley cultivars. Australian？Journal of Plant Physiology. 23 : 201-210.

상세보기
Schierhorn, F., M. Hofmann, I. Adrian, H. Bobojonov, and D.？Muller. 2020. Spatially varying impacts of climate change on？wheat and barley yields in Kazakhstan. Journal of Arid？Environments. 178 : 104-164.
UNFCCC. 2010. United Nations Framework Collection on？Climate Change. In Copenhagen Accord; UNFCCC: Copenhagen,？Denmark.
Wang, Y. and M. Frei. 2011. Stressed food-The impact of abiotic？environmental stresses on crop quality. Agriculture,？Ecosystems & Environment. 141: 271-286.

상세보기
Wheeler, T. R., G. R. Batts, R. H. Ellis, P. Hadley, and J. I. L.？Morison. 1996. Growth and yield of winter wheat (Triticum？aestivum) crops in response to CO 2 and temperature. The？Journal of Agricultural Science. 127 : 37-48.
Young, K. 1998. Barley: Soil; Climatic Requirements. In Soil？Guide: A Handbook for Understanding and Managing？Agricultural Soils; Bulletin 4343; Moore, G., Ed.; Agriculture？Western Australia: South Perth, Australia.
Yun, S. H., J. N. Im, J. T. Lee, K. M. Shim, and K. H. Hwang. 2001. Climate change and coping with vulnerability of？agricultural productivity. Korean Journal of Agricultural and？Forest Meteorology 3 : 220-237.？

LOADING...

활용도 분석정보

상세보기

다운로드

내보내기

활용도 Top5 논문

해당 논문의 주제분야에서 활용도가 높은 상위 5개 콘텐츠를 보여줍니다.
더보기 버튼을 클릭하시면 더 많은 관련자료를 살펴볼 수 있습니다.

표제어: PCR

동의어: Packet Collision Rate

용어 설명 출처 목록 (6)

용어 설명: PCR은 세균 특이성이 있는 primer를 이용하여 적은 수의 세균이 있을지라도 쉽게 검출할 수 있는 유용한 방법이며, 이를 이용하여 구강 내 치면세균막이나 타액에서 직접 세균을 검출할 수 있게 되었다[8].

내보내기 구분	파일저장 인쇄 메일전송
구성항목	기본정보 상세정보 관리번호, 논문명, 저널/프로시딩명, 저자 , 발행년, 권, 호, 시작페이지, 끝페이지, 발행기관 관리번호, 논문명, 대등논문명, 저자 , 저널/프로시딩명, 발행기관, 발행년, 발행언어, 권, 호, 시작페이지, 끝페이지, ISBN, ISSN, 주제분야, 키워드, 초록(한글), 초록(영문), 저자(소속기관)
저장형식	Text(ASCII format) Excel format RefWorks Direct Export RIS format (for Reference Manager, ProCite, EndNote), Scholar's Aids, Mendeley
메일정보	받는사람 (필수) @ 보내는사람 (선택) @ 제목 내용 KISTI 검색결과 이메일 서비스
안내	총 건의 자료가 검색되었습니다. 다운받으실 자료의 인덱스를 입력하세요. (1-10,000) 검색결과의 순서대로 최대 10,000건 까지 다운로드가 가능합니다. 데이타가 많을 경우 속도가 느려질 수 있습니다.(최대 2~3분 소요) 다운로드 파일은 UTF-8 형태로 저장됩니다. 파일의 내용이 제대로 보이지 않을실 때는 웹브라우저 상단의 보기 -> 인코딩 -> 자동선택 여부를 확인하십시오. ~ Text(ASCII format) Excel format

연합인증