All Issue

2023 Vol.68, Issue 3 Preview Page
Effects of Increasing Air Temperatures and CO2 Concentrations on Herbicide Efficacy of Acalypha australis and Phytotoxicity of Soybean Crops

대기온도와 CO2 농도 증가에 따른 우점잡초 깨풀의 제초제 약효 및 콩 약해 변화

Hyo-Jin Lee1
,
Hyun-Hwa Park2
,
Ye-Geon Kim1
,
Do-Jin Lee3
,
Yong-In Kuk4*
이 효진1
,
박 현화2
,
김 예건1
,
이 도진3
,
국 용인4*
1MS Student, Dep. of Oriental Medicine Resources, Sunchon National Univ., Suncheon 57922, Republic of Korea
2Ph. D Student, Dep. of Oriental Medicine Resources, Sunchon National Univ., Suncheon 57922, Republic of Korea
3Professor, Dep. of Agricultural Education, Sunchon National Univ., Suncheon 57922, Republic of Korea
4Professor, Dep. of Oriental Medicine Resources, Sunchon National Univ., Suncheon 57922, Republic of Korea
1순천대학교 석사과정
2순천대학교 박사과정
3순천대학교 농업교육과 교수
4순천대학교 바이오한약자원학과 교수
*Corresponding Author
1 September 2023. pp. 121-133
PDF XML Citation
Abstract

The purpose of this study was to improve weed management systems under varying carbon dioxide concentrations and temperatures by evaluating the growth of Acalypha australis and observing the efficacy of four foliar and four soil herbicides, as well as measuring phytotoxicity in soybean crops treated with these herbicides. In both growth chamber and greenhouse conditions, plant height and shoot fresh weight of Acalypha australis increased as temperature increased. The variable to maximum fluorescence ratio (Fv/Fm), relative electron transport rate (ETR), plant height, leaf area, and shoot fresh weight of Acalypha australis were higher at carbon dioxide concentrations of 800 ppm than at 400 ppm. The efficacy of a foliar herbicide, glufosinate, on Acalypha australis was lower at 30°C than at 20°C and 25°C in the growth chamber condition and was also lower at 29°C than at 21°C and 25°C in greenhouse conditions. In contrast, mecoprop efficacy on Acalypha australis was lower at 20°C and 25°C than at 30°C in growth chamber conditions and lower at 21°C and 25°C than at 29°C in greenhouse conditions. Glyphosate efficacy was lower at 21°C than at 25°C and 29°C under greenhouse conditions. With soil herbicides, metolachlor and ethalfluraline, efficacies were higher at relatively high temperatures under both growth chamber and greenhouse conditions. However, in the case of linuron, the difference in efficacy was not observed under varying temperatures in both growth chamber and greenhouse conditions. When ¼ of the recommended glyphosate rates were applied to Acalypha australis, efficacy was lower under 800 ppm carbon dioxide concentrations than under 400 ppm. In contrast, when ¼ of the recommended rate of bentazone was applied to Acalypha australis, efficacy was higher under 800 ppm carbon dioxide concentrations than under 400 ppm. Despite application rates, glufosinate efficacy differed insignificantly under different carbon dioxide concentrations. When applied at ¼ of the recommended rate, the efficacy of ethalfuralin was higher under 800 ppm carbon dioxide concentrations than under 400 ppm. However, efficacies of other herbicides were not different despite varying carbon dioxide concentrations. Soybean phytotoxicity in crops treated with the recommended rate and twice the recommended rate of soil herbicides was not significantly different regardless of temperature and carbon dioxide concentrations. Overall, weed efficacy of some herbicides decreased in response to different temperatures and carbon dioxide concentrations. Therefore, new weed management methods are required to ensure high rates of weed control in conditions affected by climate change.

Keywords
Acalypha australis
climate change
CO2
growth
herbicide
temperatures
References
1
Ainsworth, E. A. and S. P. Long. 2005. What have we learned from 15 years of free-air CO2 enrichment (FACE)? A meta-analytic review of the responses of photosynthesis, canopy properties and plant production to rising CO2. Pest Management Science 165(2) : 351-372. 10.1111/j.1469-8137.2004.01224.x15720649
2
Al-Johani, N. S., A. A. Aytah, T. Boutraa, and S. Arabia. 2012. Allelopathic impact of two weeds, Chenopodium murale and Malva parviflora on growth and photosynthesis of barley (Hordeum vulgare L.). Pakistan Journal of Botany 44(6) : 1865-1872.
3
Aruna, V. and M. Jugulam. 2016. Impact of climate change factors on weeds and herbicide efficacy. Advances in Agronomy 135 : 107-146. 10.1016/bs.agron.2015.09.002
4
Awasthi, J. P., K. S. Paraste, M. Rathore, M. Varun, D. Jaggi, and B. Kumar. 2018. Effect of elevated CO2 on Vigna radiata and two weed species: yield, physiology and crop-weed interaction. Crop and Pasture Science 69(6) : 617-631. 10.1071/CP17192
5
Bajwa, A. A., H. Wang, B. S. Chauhan, and S. W. Adkins. 2019. Effect of elevated carbon dioxide concentration on growth, productivity and glyphosate response of parthenium weed (Parthenium hysterophorus L.). Pest Management Science 75(11) : 2934-2941. 10.1002/ps.540330854793
6
Bradley, B. A., D. M. Blumenthal, D. S. Wilcove, and L. H. Ziska. 2010. Predicting plant invasions in an era of global change. Trends in Ecology & Evolution 25(5) : 310-318. 10.1016/j.tree.2009.12.00320097441
7
Bridges, J. W. 2008. The history of the discovery and development of the pyrethroid insecticides. Environmental Toxicology and Chemistry 27(4) : 1098-1108.
8
Devine, M. D., S. O. Duke, and C. Fedtke. 1993. Foliar absorption of herbicides. In Physiology of Herbicide Action; Prentice-Hall: Englewood Cliffs. NJ, USA. pp. 29-52.
9
Dong, X. and H. Sun. 2016. Effect of temperature and moisture on degradation of herbicide atrazine in agricultural soil. International Journal of Agriculture and Environmental Research 2 : 150-157.
10
Dukes, J. S. and H. A. Mooney. 1999. Does Global Change Increase the Success of Biological Invaders? Trends in Ecology & Evolution 14 : 135-139. 10.1016/S0169-5347(98)01554-710322518
11
Ganie, Z., M. Jugulam, and A. Jhala. 2017. Temperature influences efficacy, absorption, and translocation of 2,4-D or glyphosate in glyphosate-resistant and glyphosate-susceptible common ragweed (Ambrosia artemisiifolia) and giant ragweed (Ambrosia trifida). Weed Science 65(5) : 588-602. 10.1017/wsc.2017.32
12
Hatfield, J. L., K. J. Boote, B. A. Kimball, L. H. Ziska, R. C. Izaurralde, D. R. Ort, A. M. Thomson, and D. Wolfe. 2011. Climate impacts on agriculture: implications for crop production. Agronomy Journal 103(2) : 351-370. 10.2134/agronj2010.0303
13
Jang, S. J. and Y. I. Kuk. 2020. Occurrence distribution of an exotic plant Ipomoea hederacea and soybean growth and yield reductions caused by its occurrence densities. Research on Crops 20 : 76-81.
14
Jang, S. J., D. J. Lee, and Y. I. Kuk. 2019. Soybean growth and yield reductions caused by Quamoclit coccinea at varying density. Research on Crops 20 : 301-305. 10.31830/2348-7542.2019.044
15
Johnson, B. C. and B. G. Young. 2002. Influence of temperature and relative humidity on the foliar activity of mesotrione. Weed Science 50(2) : 157-161. 10.1614/0043-1745(2002)050[0157:IOTARH]2.0.CO;2
16
Kudsk, P. and J. L. Kristensen. 1992. Effect of Environmental Factors on Herbicide Performance. In Proceedings of the First International Weed Control Congress. Victoria, Australia: Weed Science Society of Victoria pp. 173-186.
17
Lee, J. S. 2011. Combined effect of elevated CO2 and temperature on the growth and phenology of two annual C3 and C4 weedy species. Agriculture, Ecosystems & Environment 140 : 484-491. 10.1016/j.agee.2011.01.013
18
Lobell, D. B., M. B. Burke, C. Tebaldi, M. D. Mastrandrea, W. P. Falcon, and R. L. Naylor. 2008. Prioritizing climate change adaptation needs for food security in 2030. Science 319(5863) : 607-610. 10.1126/science.115233918239122
19
Lobell, D. B. and S. M. Gourdji. 2012. The influence of climate change on global crop productivity. Plant Physiology 160(4) : 1686-1697. 10.1104/pp.112.20829823054565PMC3510102
20
Long, S. P., E. A. Ainsworth., A. D. Leakey., J. Nosberger, and D. R. Ort. 2006. Food for thought: lower-than-expected crop yield stimulation with rising CO2 concentrations. Science 312(5782) : 1918-1921. 10.1126/science.111472216809532
21
Long, Y. H., R. T. Li, and X. M. Wu. 2014. Degradation of S-metolachlor in soil as affected by environmental factors. Journal of Soil Science and Plant Nutrition 14 : 189-198. 10.4067/S0718-95162014005000015
22
Manea, A., M. R. Leishman, and P. O. Downey. 2011. Exotic C4 grasses have increased tolerance to glyphosate under elevated carbon dioxide. Weed Science 59 : 28-36. 10.1614/WS-D-10-00080.1
23
Matzrafi, M., B. Seiwert, T. Reemtsma, B. Rubin, and Z. Peleg. 2016. Climate change increases the risk of herbicide-resistant weeds due to enhanced detoxification. Planta 244 : 1217-1227. 10.1007/s00425-016-2577-427507240
24
Nguyen, T., A. A. Bajwa, S. Navie, C. O'donnell, and S. Adkins. 2017. Parthenium weed (Parthenium hysterophorus L.) and climate change: the effect of CO2 concentration, temperature, and water deficit on growth and reproduction of two biotypes. Environmental Science and Pollution Research 24 : 10727-10739. 10.1007/s11356-017-8737-728283983
25
Pline, W. A., J. Wu, and K. K. Hatzios. 1999. Effects of temperature and chemical additives on the response of transgenic herbicide-resistant soybeans to glufosinate and glyphosate applications. Pesticide Biochemistry and Physiology 65(2) : 119-131. 10.1006/pest.1999.2437
26
Ramesh, K., A. Matloob, F. Aslam, S. K. Florentine, and B. S. Chauhan. 2017. Weeds in a changing climate: vulnerabilities, consequences, and implications for future weed management. Frontiers in Plant Science 8 : 95. 10.3389/fpls.2017.00095
27
SAS (Statistical Analysis System). 2000. SAS/STAT Users Guid, Version 7. Statistical Analysis System Institute. Cary, NC, USA.
28
Seneviratne, S., N. Nicholls, D. Easterling, C. Goodess, S. Kanae, J. Kossin, Y. Luo, J. Marengo, K. McInnes, M. Rahimi, M. Reichstein, A. Sorteberg, C. Vera, X. Zhang, L. V. Alexander, S. Allen, G. Benito, T. Cavazos, J. Clague, D. Conway, P. M. Della-Marta, M. Gerber, S. Gong, B. N. Goswami, M. Hemer, C. Huggel, V. D. H. Bart, V. V. Kharin, A. Kitoh, A. M. G. Klein Tank, G. Li, S. J. Mason, W. McGuire, V. O. Geert Jan, B. Orlowsky, S. Smith, W. Thiaw, A. Velegrakis, P. Yiou, T. Zhang, T. Zhou, and F. W. Zwiers. 2012. Changes in climate extremes and their impacts on the natural physical environment. pp. 109-230. 10.1017/CBO9781139177245.006
29
Song, S. B., J. S. Lee, J. R. Kang, J. Y. Ko, M. C. Seo, K. S. Woo, B. G. Oh, and M. H. Nam. 2009. The growth and yield of soybeen as affected by competitive density of Digitaria sanguinalis. Korean Journal of Weed Science 29(4) : 323-327.
30
Song, S. B., J. S. Lee, J. R. Kang, J. Y. Ko, M. C. Seo, K. S. Woo, B. G. Oh, and M. H. Nam. 2010. The growth and yield of soybean as affected by competitive density of Cuscuta pentagona. Korean Journal of Weed Science 30 : 390-395. 10.5660/KJWS.2010.30.4.390
31
Strachan, S. D., M. S. Casini, K. M. Heldreth, J. A. Scocas, S. J. Nissen, B. Bukun, R. B. Lindenmayer, D. L. Shaner, P. Westra, and G. Brunk. 2010. Vapor movement of synthetic auxin herbicides: aminocyclopyrachlor, aminocyclopyrachlor-methyl ester, dicamba, and aminopyralid. Weed Science 58(2) : 103-108. 10.1614/WS-D-09-00011.1
32
Varanasi, A., P. V. V. Prasad, and M. Jugulam. 2015. Impact of climate change factors on weeds and herbicide efficacy. Advances in Agronomy 135 : 107-146. 10.1016/bs.agron.2015.09.002
33
Won, J. G., K. S. Jang, J. E. Hwang, O. H. Kwon, S. G. Jeon, and S. G. Park, 2011. Competitiveness and yield loss of red pepper by densities of Echinochloa crus-galli (L.) P. Beauv. and Chenopodium album L. Korean Journal of Weed Science 31(1) : 71-77. 10.5660/KJWS.2011.31.1.071
34
Yoo, J. H., B. C. Moon, I. Y. Lee, and D. H. Kim. 2012. Effect of Acalypha australis occurrence on soybean growth and economic threshold level of Acalypha australis. Weed & Turfgrass Science 1(4) : 13-17 10.5660/WTS.2012.1.4.013
35
Ziska, L. H., D. M. Blumenthal, G. B. Runion, and E. R. Hunt. 2011. Invasive species and climate change: an agronomic perspective. Climatic Change 105 : 13-42. 10.1007/s10584-010-9879-5
36
Ziska, L. H. and L. L. McConnell. 2016. Climate change, carbon dioxide, and pest biology: monitor, mitigate, manage. Journal of Agricultural and Food Chemistry 64(1) : 6-12. 10.1021/jf506101h25671793
37
Ziska, L. H., S. S. Faulkner, and J. Lydon. 2004. Changes in biomass and root: shoot ratio of field-grown Canada thistle (Cirsium arvense), anoxious, invasive weed, with elevated CO2: implications for control with glyphosate. Weed Science 52 : 584-588. 10.1614/WS-03-161R
38
Ziska, L. H. and J. R. Teasdale. 2000. Sustained growth and increased tolerance to glyphosate observed in a C3 perennial weed, quackgrass (Elytrigia repens), grown at elevated carbon dioxide. Australian Journal of Plant Physiology 27 : 159-164. 10.1071/PP99099
Information
  • Publisher :The Korean Society of Crop Science
  • Publisher(Ko) :한국작물학회
  • Journal Title :The Korean Journal of Crop Science
  • Journal Title(Ko) :한국작물학회지
  • Volume : 68
  • No :3
  • Pages :121-133
  • Received Date : 2023-07-21
  • Revised Date : 2023-07-26
  • Accepted Date : 2023-07-26
  • DOI :https://doi.org/10.7740/kjcs.2023.68.3.121
Journal Informaiton The Korean Journal of Crop Science The Korean Journal of Crop Science
Online Submission
  • NRF
  • KOFST
  • KISTI Current Status
  • KISTI Cited-by
  • crosscheck
  • orcid
  • open access
  • ccl
Journal Informaiton Journal Informaiton - close