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Tytuł artykułu

Effects of Carbon Dioxide Concentration on the Growth and Physiology of Albizia saman (Jacq.) Merr

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Języki publikacji
EN
Abstrakty
EN
This study was conducted to determine the effects of CO2 concentration on the growth and physiology of rain tree (Albizia saman (Jacq.) Merr), by increasing the CO2 concentration in a greenhouse automated system. The objective of this study was to evaluate the response of rain tree to CO2 in terms of growth and physiology. CO2 at an average concentration of 800 μmol mol-1 was injected daily for 2 h from 9 am to 11 am. The seedlings were placed in a greenhouse during the control trial with a mean ambient CO2 concentration of 400 μmol mol-1. In this study, the entire randomised block design has been applied, and growth was observed every 30 days for 120 days. Almost all seedling growth parameters were significant under elevated and ambient concentrations. The leaf area in the control samples (400 ppm of CO2) was 243.37 cm2, and this value increased to 277.30 cm2 in the sample treated with 800 ppm of CO2. The biomass increased, and the original wet weight ratio and root dry weight of the canopy and the principal (9.06 and 10.12 g, respectively) increased to 9.7 and 16.06 g, respectively, after treatment. Physiology was analysed in terms of relative levels of photosynthesis, stomatal conductance and water use efficiency (WUE). Such parameters increased in the principal treatment of CO2 (800 ppm), whilst the CO2 content and transpiration levels declined. As the CO2 concentration increased, the value of the levels of photosynthesis and stomatal conductance in both samples increased. As the photosynthesis levels increased, the WUE activity increased. However, as photosynthesis levels decreased, the WUE activity also decreased. Transpiration levels but also rely on a certain age if the increased photosynthesis WUE has decreased.
Słowa kluczowe
Rocznik
Strony
302--311
Opis fizyczny
Bibliogr. 50 poz., rys.
Twórcy
  • Department of Agrotechnology, Faculty of Agriculture, Universitas Islam Riau, Pekanbaru, 28284 Indonesia
Bibliografia
  • 1. Ainsworth, Elizabeth A., Rogers A. 2007. The Response of photosynthesis and stomatal conductance to rising [CO2]: Mechanisms and Environmental Interactions. Plant, Cell and Environment, 30(3), 258–270.
  • 2. Ainsworth, Elizabeth A., Stephen 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. New Phytologist, 165(2), 351–72.
  • 3. Azam, Andaleeb, Ikhtiar K., Abid Mahmood, Abdul Hameed. 2013. Yield, chemical composition and nutritional quality responses of carrot, radish and turnip to elevated atmospheric carbon dioxide. Journal of the Science of Food and Agriculture, 93(13), 3237–44.
  • 4. Baker, J. T., Allen, L. H. Jr, Boote, K. J. 1990a. Growth and yield responses of rice to carbon dioxide concentration. Journal of Agricultural Science, 115: 313–320.
  • 5. Baker, J T., Allen L.H. 1993. Contrasting crop species responses to CO2 and temperature: rice, soybean and citrus. Vegetatio, 104: 239–60.
  • 6. Bolinder, M. A., Angers, D. A., Belanger, G., Michaud, R., Laverdiere, M. R. 2002. Root biomass and shoot to root ratios of perennial forage crops in eastern Canada Can. J. Plant Sci, 82, 731−737.
  • 7. Burgess, Patrick, Bingru H. 2014. Growth and physiological responses of creeping bentgrass (Agrostis stolonifera) to elevated carbon dioxide concentrations. Horticulture Research, (April), 14021. https://doi.org/10.1038/hortres.2014.21.
  • 8. Cha, S., Chae H,M., Lee S.H., Shim J.K. 2017. Effect of elevated atmospheric CO2 concentration on growth and leaf litter decomposition of Quercus acutissima and Fraxinus rhynchophylla. Plos One, 12(2), e0171197.
  • 9. Cornwell, W.K., Cornelissen, J.H.C., Amatangelo, K., Dorrepaal, E., Eviner, V.T., Godoy, O. 2008. Plant species traits are the predominant control on litter decomposition rates within biomes worldwide. Ecol Lett, 11(10), 1065–71.
  • 10. Cotrufo, M.F., Ineson, P., Rowland, A.P. 1994. Decomposition of tree leaf litters grown under elevated CO2 effect of litter quality. Plant Soil, 163(1), 121–130.
  • 11. Czubaszek, R. 2019. Exchange of carbon dioxide between the atmosphere and the maize field fertilized with digestate from agricultural biogas plant. Journal of Ecological Engineering, 20(1), 145–151.
  • 12. Dahlan, EN. 2013. Humanized green city. Bogor, Indonesia: IPB dan PT. Eigerindo MPI.
  • 13. Doni F., Anizan Isahak, Che Radziah Che Mohd Zain, and Wan Mohtar Wan Yusoff. 2014. Physiological and growth response of rice plants (Oryza sativa L.) to Trichoderma spp. Inoculants. AMB Express, 4(1), 45.
  • 14. Drake, P.L., Froend, R.H., Franks, P.J. 2013. Smaller, faster stomata: Scaling of stomatal size, rate of response, and stomatal conductance. Journal of Experimental Botany, 64(2), 495–505.
  • 15. Dugas, W.A., Prior S.A., Rogers, H.H. 1997. Transpiration from sorghum and soybeen growing under ambient and elevated CO2 concentrations. Agricultural and Forest Meteorology, 83(96), 37–48.
  • 16. Farquhar, S.G.D, Von Caemmerer. 1982. Modelling of photosynthetic response to environmental conditions. In Physiological plant ecology II. Water relations and carbon assimilation. Encyclopedia of Plant Physiology. Berlin: Springer-Verlag: Berlin.
  • 17. Fathurrahman, Mohd. Nizam Mohd. Said, Wan Juliana Wan Ahmad, Febri Doni, CMZ Che Radziah. 2015. Germination and seedling response of rain tree plants (Albizia saman Jacq. Merr) to seed priming using hot water. Eco. Env. & Cons., 21(3), 73–77.
  • 18. Fathurrahman, F., M.S. Nizam, W.A. Wan Juliana, Febri Doni & C.M.Z. Che Radziah. 2016. Growth improvement of rain tree (Albizia saman Jacq. Merr) seedlings under elevated concentration of carbon dioxide (CO2). J. of Pure And Applied Microbiology, 10(3), 1911–1917.
  • 19. Fathurrahman F. 2023. Growth and genetic characteristics of cucumber (Cucumis sativus L.) Cultivar mercy f1 hybrid and mutant populations. SABRAO J. Breed. Genet., 55(2), 485–494.
  • 20. Franks, P.J. 2013. Tansley review sensitivity of plants to changing atmospheric CO2 concentration: from the geological past to the next century. New Phytologist, 197, 1077–1094.
  • 21. Gao, Ji, H. Xue, Seneweera, S.P. Li, Zong,Y.Z., Dong, Q, Lin, E.D., Hoa X.Y. 2015. Leaf photosynthesis and yield components of mung bean under fully open-air elevated (CO2). Journal of Integrative Agriculture, 14(5), 977–983.
  • 22. Giri, A.B. Armstrong, Rajashekar, C.B. 2016. Elevated carbon dioxide level suppresses nutritional quality of lettuce and spinach. American Journal of Plant Sciences, 7 (January), 246–258.
  • 23. Haniff, M.H. 2006. Gas exchange of excised oil palm (Elaeis guineensis) Fronds. Asian Journal of Plant Sciencies, 5, 9–13.
  • 24. Hetherington, Alistair, Ian Woodward M.F. 2003. The role of stomata in sensing and driving environmental change. Nature, 424(6951), 901–908.
  • 25. IPCC. 2013a. Annex III: Glossary [Planton, S. (ed.)]. In: Climate Change: The Physical Science.
  • 26. John, G. P., Scoffoni, C., Sack, L. 2013. Allometry of cells and tissues within leaves. American Journal of Botany, 100(10), 1936–1948.
  • 27. Keay, M. 2007. Energy: The long view. The further backward you look, the further forward you can see. Oxford Institute for Energy Studies.
  • 28. Kimbal, B.A. 1983. Carbon Dioxide and Agricultural Yield: An Assemblage and Analysis of 430 Prior Observations. Agron. J., 75, 779–788.
  • 29. Lawson, T., Blatt M.R. 2014. Stomatal size, speed, and responsiveness impact on photosynthesis and water use efficiency. Plant Physiology, 164(4), 1556–1570.
  • 30. Lin Jinxing, Jach, M.E., Ceulemans R. 2001. Stomatal density and needle anatomy of scots pine (Pinus sylvestris) are affected by elevated CO2. New Phytologist, 150(3), 665–674.
  • 31. Loladze, I. 2002. Rising atmospheric CO2 and human nutrition: Toward globally imbalanced plant stoichiometry. Trends in Ecology and Evolution, 17(10), 457–461.
  • 32. Lopes, A., Ferreira, A.B., Pantoja, P.O., Parolin, P., Piedade, M.T.F. 2015. Combined effect of elevated CO2 leveland temperature on germination and initial growth of Montrichardia arborescens (L.) Schott (Araceae): a microcosm experiment. Hydrobiologia, 1–12.
  • 33. Medlyn, B.E., Bbarton C.V.M., Broadmeadow, M.S., Ceulemans, J.R., De Angelis P.M., Forstreuter, Freeman, M. 2001. Stomatal conductance of forest species after long-term exposure to elevated CO2 concentration: A synthesis. New Phytologist, 149(2), 247–264.
  • 34. Meinzer, F.C., Goldstein, G., Holbrook, N.M., Cavelier, J. 1997. Control of transpiration from the upper canopy of a tropicai forest: the role of stomatal, boundary layer and hydraulic architecture components. Plant Cell and Environment, 20, 1242–1252.
  • 35. Monda, K., Araki, H., Kuhara, S., Ishigaki, G., Akashi, R., Negi, J., Kojima, M. 2016. Enhanced stomatal conductance by a spontaneous Arabidopsis tetraploid, Me-0, Results from increased stomatal size and greater stomatal aperture. Plant Physiology, 170(March), 1450.
  • 36. Parry, M.A., Andralojc P.J., Mitchell, R.A., Madgwick, P., Keys A.J. 2003. Manipulation of rubisco: the amount, activity, function and regulation. J. Exp. Bot., 54(386), 1321–33.
  • 37. Pleijel, H., Gelang, J., Sild, E., Danielsson, H.,Younis, S., Karlsson, P.E., Wallin, G., Skärby, L., Selldén, G. 2000. Effects of elevated carbon dioxide, ozone and water availability on spring wheat growth and yield. Physiologia Plantarum, 108(1), 61–70.
  • 38. Prior, Stephen A., Brett Runion, G., Christopher Marble, S., Hugo, H. Rogers, Charles, H., Gilliam, Allen Torbert, H. 2011. A review of elevated atmospheric CO2 effects on plant growth and water relations: implications for horticulture. HortScience, 46(2), 158–162.
  • 39. Pritchard, S.G., Rogers, H.H., Prior S.A., Peterson C.M. 1999. Elevated CO2 and plant sturcture: A review. Global Change Biology, 5, 807–837.
  • 40. Reich, P.B., Hobbie, S.E., Lee, T.D. 2014. Plant growth enhancement by elevated CO2 eliminated by joint water and nitrogen limitation. Nature Geosci, 7(12), 920–924.
  • 41. Reverchon, F., Xu, Z., Blumfield, T.J., Chen, C., Abdullah, K.M. 2012. Impact of global climate change and fireon the occurrence and function of understorey legumes in forest ecosystems. J. Soils Sediments, 12(2), 150–160.
  • 42. Schaffer, B.W., Anthony S.C. 1999. Atmospheric CO2 Enrichment, root restriction, photosynthesis, and drymatter partitioning in subtropical and tropical fruit crops. HortScience: a publication of the American Society for Horticultural Science, 34, 1033–1037.
  • 43. Sharma, N., Sinha P.G., Bhatnagar A.K. 2014. Effect of elevated (CO2) on cell structure and function in seed plants. Climate Change and Environmental Sustainability, 2(2), 69–104.
  • 44. Staples, G.W., Elevitch, C.R. 2006. Samanea saman, rain tree. species profiles for pacific island agroforestry. Permanent Agriculture Resources (PAR).
  • 45. Taylor, B.R., Parkinson, D., Parsons, W.F.J. 1989. Nitrogen and lignin content as predictors of litter decayratesa microcosm test. Ecology, 70(1), 97–104.
  • 46. Teng, N., Jin, B., Wang, Q., Hao, H., Ceulemans, R., Kuang, T., Lin, J. 2009. No detectable maternal effects of elevated CO2 on arabidopsis thaliana over 15 generations. PLoS One, 4(6),1–9.
  • 47. Thongbai, P., Kozai, T., Ohyama, K. 2010. CO2 and air circulation effects on photosynthesis and transpiration of tomato seedlings. Scientia Horticulturae, 126, 338–344.
  • 48. Wright, D.F., Boorse, T. 2011. Environmental Science: toward a sustainable future, 11th Edition Richard. Gordon College Online purchase.
  • 49. Wu, D.X, G.X., Wang, Y.F., Bai, Liao J.X. 2004. Effects of elevated CO2 concentration on growth, water use, yield and grain quality of wheat under two soil water levels. Agriculture, Ecosystems & Environment, 104(3), 493–507.
  • 50. Wustman, B.A., Oksanen, E., Karnosky, D.F., Noormets, A., Isebrands, J.G., Pregitzer, K.S., Hendrey, G.R., Sober, J., Podila, G.K. 2001. Effects of elevated CO2 and O3 on aspen clones of varying o3 sensitivity. Developments in Environmental Science, 3(C), 391–409.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-118bab8c-4da4-49f7-a9a1-88f117a83b75
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