Weed regimes in agro-ecosystems in the changing climate scenarioA review
DOI:
https://doi.org/10.59797/ija.v60i4.4490Keywords:
----Abstract
Changes in temperature, and the amount, intensity, frequency, and distribution of rainfall, collectively known as climate change, can have beneficial or adverse effects on weeds interfering with agriculture. Implicit in discussion of weed management and climate change is the assumption that we know what to do in relation to soil and crop management, but these strategies might not apply to the unexpected future climate change conditions, particularly weed menace. There is confusion in interpreting weed management for the weather fluctuation in a region, as there is a clear-cut distinction between climate change and climate variability. Soil warming could enhance the availability of certain elements in the soil by faster ion-diffusion rate and the soil-moisture stress could boom weed proliferation. Judicious agronomic practices would partially help to offset weed pressure, but climate may have over-riding influence on weeds, as they share the same trophic level with crops. Implications of climate change would be identical with crops, aggravating the crop-weed competition. Many of the most troublesome weeds in crop ecosystems follow C pathway. As atmospheric CO increases, it is conceivable that competitive ability of 4 2 weeds could be similar to C crops, such as rice, if there is no dearth of soil moisture and nutrients. From a weed- 3 management perspective, C weeds would flourish under the increased temperature scenario and pose serious 4 yield limitation. It is speculated that reduced water availability due to recurrent/unforeseen droughts would alter the competitive balance between crops and some weed species, intensifying the crop-weed competition pressure. Research conducted indicated that a rise in temperature would benefit C weeds but not the rising CO levels. 4 2References
Alberto, A.M.P., Ziska, L.H., Cervancia, C.R. and Manalo, P.A. 1996. The influence of increasing carbon dioxide and temperature on competitive interactions between a C3 crop, rice (Oryza sativa) and a C4 weed (Echinochloa glabrescens). Australian Journal of Plant Physiology 23(6): 795802.
Anderson, D.M., Swanton, C.J., Hall, J.C. and Mersey, B.G. 1993. The influence of temperature and relative humidity on the efficacy of glufosinate-ammonium. Weed Research 33: 139
Batlla, D. and Benech-Arnold, R.L. 2004. Seed dormancy loss assessed by changes in population hydrotime parameters. Development of a predictive model. Seed Science Research 14: 27786.
Bazzaz, F.A., Garbutt, K. and Williams, W.E. 1985. Effect of increased atmospheric carbon dioxide concentration on plant communities. (In) Strain, B.R., and Cure, J.D (Eds.) Direct effects of increasing carbon dioxide on vegetation. United States Department of Energy p. 168.
Beestman, G.B. and Deming, J.M. 1974. Dissipation of acetanilide herbicides from soils. Agronomy Journal 66(2): 30811.
Brinkley, T.R. and Bomford, M. 2002. Agricultural sleeper weeds: what is the potential threat? (Australia, Bureau of Rural Sciences, Canberra). www.southwestnrm.org.au/.../brinkleytr-bomford-m-2002-agricultural
Cavero, J., Zaragoza, C., Suso, M.L. and Pard, A. 1999. Competition between maize and Datura stramonium in an irrigated field under semi-arid conditions. Weed Research 39: 22540.
Chamberlain, J. and Gittens, A. 2004. Parthenium weed-management: challenges, opportunities and strategies. Parthenium action group. The State of Queensland Department of Natural Resources, Mines and Energy, Brisbane, Australia, p. 82.
Chauhan, B.S., Prabhjyot-Kaur, Mahajan, G., Randhawa, R.K., Singh, H. and Kang, M.S. 2014. Global warming and its possible impact on agriculture in India. Advances in Agronomy 123: 6521.
Cray, J.A., Bell, A.N.W., Bhaganna, P., Mswaka, A.Y., Timson, D.J. and Hallsworth, J.E. 2013. The biology of habitat dominance; can microbes behave as weeds? Microbial Biotechnology 6: 45392.
Crossman, N.D., Bryan, B.A. and Cooke, D.A. 2011. An invasive plant and climate change threat index for weed risk management: Integrating habitat distribution pattern and dispersal process. Ecological Indicators 11: 18398.
Cure, J.D. and Cock, B.A. 1986. Crop responses to carbon dioxide doubling: a literature survey. Agricultural and Forest Meteorology 38(13): 12745.
Doley, D. 1977. Parthenium weed (Parthenium hysterophorus L.): gas exchange characteristics as a basis for prediction of its geographical distribution. Australian Journal of Agricultural Research 28(3): 44960.
Dukes, J.S. and Mooney, H.A. 1999. Does global change increase the success of biological invaders? Tree 14(4): 13537.
Fuhrer, J. 2003. Agro-ecosystem responses to combinations of elevated CO2, ozone, and global climate change. Agriculture, Ecosystems and Environment 97: 120.
Guo, P. and Al-Khatib, K. 2003. Temperature effects on germination and growth of redroot pigweed (Amaranthus retroflexus), Palmer amaranth (A. palmeri), and common waterhemp (A. rudis). Weed Science 51(6): 86975.
Houghton, J.T., Ding, Y. and Griggs, D.J. 2001. Climate Change 2001: The Scientific Basis. Contribution of Working Group I to the Third Assessment Report of the Intergovernmental Panel on Climate Change Cambridge University Press, Cambridge.
Hyvonen, T. 2011. Impact of temperature and germination time on the success of a C4 weed in a C3 crop. Amaranthus retroflexus and spring Barley. Agricultural and Food Science
: 18390.
Jain, A.K. 1993. Allergenic pollen grains of
