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1860797975401332736
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| building |
INTELEK Repository
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| collection |
Online Access
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| collectionurl |
https://intelek.unisza.edu.my/intelek/pages/search.php?search=!collection407072
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| date |
2024-08-30 11:10:08
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| format |
Restricted Document
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| id |
15220
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UniSZA
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| internalnotes |
Awal, M.A. and T. Ikeda, 2002. Recovery strategy following the imposition of episodic soil moisture deficit in stands of peanut (Arachis hypogea L.). Journal of Agronomy and Crop Science, 188: 185-192. Bouman, B.A.M., L. Feng, T.P. Tuong, G. Lu, H. Wang and Y. Feng, 2007. Exploring options to grow rice under water-short conditions in northern China using a modelling approach. II: Quantifying yield, water balance components, and water productivity. Agricultural Water Management, 88: 23-33. CheLah, M.K.B., M.N.B. Nordin, M.I. Musliania, Y.M. Khanif and M.S. Jahan, 2011. Composting increases BRIS soil health and sustains rice production on BRIS soil. Scienceasia, 37: 291-295. Donohue, S., 1998. Effect of summer 1998 Drought on Soil pH. Crop and Soil Environmental News. http://www.sites.ext.vt.edu/newsletter-archive/cses/1998-10/1998-10-02.html. Accessed on 22 Oct 2013. Garg, B.K., 2003. Nutrient uptake and management under drought: Nutrient-moisture interaction. Current Agriculture, 27: 1-8. International Rice Research Institute (IRRI), 2012. Annual Report for 2011. Los Baños, Philippines. Ismail, S., 2014. Rice: M’sia on course to self-sufficiency. Bernama, April 5, 2014. http://www.fmtborneoplus.com/category/nation/2014/04/05/rice-msia-on-course-to-self-sufficiency/ Accessed on 15 April 2014. Jahan, M.S., M.B.N. Nozulaidi, M.B.C.L. Khairi and Y.M. Khanif, 2013b. Effects of water stress on rice production: bioavailability of potassium in soil. Journal of Stress Physiology & Biochemistry, 9: 97-107. Jahan, M.S., M.B.N. Nozulaidi, M.K. Moneruzzaman, A. Ainun and N. Husna, 2014. Control of plant growth and water loss by a lack of light-harvesting complexes in photosystem-II in Arabidopsis thaliana ch1-1 mutant. Acta Physiologiae Plantarum, 36: 1627-1635. Jahan, M.S., Y. Nakamura and Y. Murata, 2011. Histochemical quantification of GSH contents in guard cells of Arabidopsis thaliana. Scienceasia, 37: 281-284. Jahan, M.S., Y.M. Khanif and U.R. Sinniah, 2013a. Effects of low water input on rice yield: Fe and Mn bioavailability in soil. Pertanika Journal of Tropical Agriculture Sciences, 36: 27-34. Jahan, M.S., Y.M. Khanif, U.R. Sinniah, M.B.N. Nozulaidi and M.B.C.L. Khairi, 2012. Bioavailability of soil nitrogen in low water input rice production. Journal of Sustainable Science and Management, 7: 207-212. Keizrul, A. and M. Azuhan, 1998. An Overview of Water Resources Utilization and Management in Malaysia. Seminar on Local Communities and the Environment II. Environment Protection Society Malaysia, Petaling Jaya. Koon, C.P. and R. Pakiam, 2014. Water rationing begins outside Malaysia capital amid drought. http://www.bloomberg.com/news/2014-02-25/water-rationing-begins-outside-malaysia-s-capital-amiddrought.html. Accessed on 19 April 2014. Kura-Hotta, M., K. Satoh and S. Katoh, 1987. Relationship between photosynthesis and chlorophyll content during leaf senescence of rice seedlings. Plant Cell Physiology, 28: 1321-1329. Nadler, A. and H. Bruvia, 1998. Physiological responses of potato plants to soil salinity and water deficit. Plant Science, 137: 43-51. Pereira, E.W., L.D. Siquera, C.A. Martinez and M. Puiatti, 2004. Gas exchange and chlorophyll fluorescence in four citrus root stocks under aluminium stress. Journal of Plant Physiology, 157: 513-520. Pirdashti, H., Z.T. Sarvestani, G. Nematzadeh and A. Ismail, 2004. Study of water stress effects in different growth stages on yield and yield components of different rice (Oryza sativa L.) cultivars. The 4th International Crop Science Congress. Brisbane, Australia. Pospisil, P., J. Skotnica and J. Naus, 1998. Low and high temperature dependence of minimum Fo and maximum Fm chlorophyll fluorescence in vivo. Biochimica et Biophysica Acta, 1363: 95-99. Sariam, O., 2004. Growth of non-flooded rice and its response to nitrogen fertilization. PhD Thesis. Department of Land Management, Faculty of Agriculture, Universiti Putra Malaysia. Sariam, O., Y.M. Khanif and T. Zahrah, 2002.Rice growth and nitrogen uptake as influenced by water management. Malaysian Journal of Soil Science, 6: 1-11. Sarwar, M.J. and Y.M. Khanif, 2005b. Techniques of water saving in rice production in Malaysia. Asian Journal of Plant Science, 4: 83–84. Sarwar, M.J. and Y.M. Khanif, 2005. Low water rice production and its effect on redox potential and soil pH. Journal of Agronomy, 4: 142–146. Sarwar, M.J. and Y.M. Khanif, 2005c. The effect of different water levels on rice yield and cu and zn concentration. Journal of Agronomy, 4: 116-121. Sarwar, M.J. and Y.M. Khanif, 2005d. Effect of water saving irrigation on yield and concentration of Ca and Mg in malaysian rice cultivation. Pakistan Journal of Biological Sciences, 8: 65-67. Sarwar, M.J., Y.M. Khanif, S.R. Syed Omar and U.R. Sinniah, 2004. The effect of different water regimes on yield and bioavailability of Phosphorus in rice production in Malaysia. Malaysian Journal of Soil Science, 8: 53-62. Sarwar, MJ., 2004. PhD Thesis. Department of Land Management, Faculty of Agriculture, Universiti Putra Malaysia. Sheela, K.R. and V.J. Alexander, 1996. Physiological response of rice varieties as influenced by soil moisture and seed hardening. Indian Journal of Plant Physiology, 38: 269-271. Syuhada, N., M.S. Jahan, M.M. Khandaker, M. Nashriyah, M. Khairi, M. Nozulaidi and M.H.B. Razali, 2014. Application of copper increased corn yield through enhancing physiological functions. Australian Journal of Basic and Applied Science, 8: 282-286.
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5976-01-FH02-FBIM-15-03226.pdf
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TEST1
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oai_dc
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https://intelek.unisza.edu.my/intelek/pages/view.php?ref=15220
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15220 https://intelek.unisza.edu.my/intelek/pages/view.php?ref=15220 https://intelek.unisza.edu.my/intelek/pages/search.php?search=!collection407072 Restricted Document Article Journal application/pdf Adobe Acrobat Pro DC 20 Paper Capture Plug-in with ClearScan 8 1.6 TEST1 2024-08-30 11:10:08 5976-01-FH02-FBIM-15-03226.pdf UniSZA Private Access Effects of Different Water Levels on Physiology and Yield of Salinity Rice Variety Australian Journal of Basic and Applied Sciences Background: Water wise rice production is the current concern. Objective: To justify the water effects on production of salinity rice cultivar, plants physiological, and yield parameters were evaluated. There were four water treatments, T1: flooding at 5 cm (control), T2: flooding at 1 cm, T3: saturated condition and T4: alternative wet and dry (AWD) and five replicates were arranged according to a completely randomized design. Yield, plant and soil parameters under different irrigation conditions were measured. Results: Different water treatments affected plant height at secondary tillering stage, yield and yield parameters of rice plants. AWD treatment decreased chlorophyll (Chl) content and Chl fluorescence in leaves. In addition, net photosynthesis rate (Pn), relative water content (RWC) decreased gradually with decreasing water content in the soil. AWD treatment reduced soil pH but increased soil electric conductivity (EC) value. Conclusion: These results suggest that AWD affected plant yield through modulating plant physiological function but saturated to 1 cm flooding condition showed no effect on rice yield and plant physiology. 9 2 339-345 Awal, M.A. and T. Ikeda, 2002. Recovery strategy following the imposition of episodic soil moisture deficit in stands of peanut (Arachis hypogea L.). Journal of Agronomy and Crop Science, 188: 185-192. Bouman, B.A.M., L. Feng, T.P. Tuong, G. Lu, H. Wang and Y. Feng, 2007. Exploring options to grow rice under water-short conditions in northern China using a modelling approach. II: Quantifying yield, water balance components, and water productivity. Agricultural Water Management, 88: 23-33. CheLah, M.K.B., M.N.B. Nordin, M.I. Musliania, Y.M. Khanif and M.S. Jahan, 2011. Composting increases BRIS soil health and sustains rice production on BRIS soil. Scienceasia, 37: 291-295. Donohue, S., 1998. Effect of summer 1998 Drought on Soil pH. Crop and Soil Environmental News. http://www.sites.ext.vt.edu/newsletter-archive/cses/1998-10/1998-10-02.html. Accessed on 22 Oct 2013. Garg, B.K., 2003. Nutrient uptake and management under drought: Nutrient-moisture interaction. Current Agriculture, 27: 1-8. International Rice Research Institute (IRRI), 2012. Annual Report for 2011. Los Baños, Philippines. Ismail, S., 2014. Rice: M’sia on course to self-sufficiency. Bernama, April 5, 2014. http://www.fmtborneoplus.com/category/nation/2014/04/05/rice-msia-on-course-to-self-sufficiency/ Accessed on 15 April 2014. Jahan, M.S., M.B.N. Nozulaidi, M.B.C.L. Khairi and Y.M. Khanif, 2013b. Effects of water stress on rice production: bioavailability of potassium in soil. Journal of Stress Physiology & Biochemistry, 9: 97-107. Jahan, M.S., M.B.N. Nozulaidi, M.K. Moneruzzaman, A. Ainun and N. Husna, 2014. Control of plant growth and water loss by a lack of light-harvesting complexes in photosystem-II in Arabidopsis thaliana ch1-1 mutant. Acta Physiologiae Plantarum, 36: 1627-1635. Jahan, M.S., Y. Nakamura and Y. Murata, 2011. Histochemical quantification of GSH contents in guard cells of Arabidopsis thaliana. Scienceasia, 37: 281-284. Jahan, M.S., Y.M. Khanif and U.R. Sinniah, 2013a. Effects of low water input on rice yield: Fe and Mn bioavailability in soil. Pertanika Journal of Tropical Agriculture Sciences, 36: 27-34. Jahan, M.S., Y.M. Khanif, U.R. Sinniah, M.B.N. Nozulaidi and M.B.C.L. Khairi, 2012. Bioavailability of soil nitrogen in low water input rice production. Journal of Sustainable Science and Management, 7: 207-212. Keizrul, A. and M. Azuhan, 1998. An Overview of Water Resources Utilization and Management in Malaysia. Seminar on Local Communities and the Environment II. Environment Protection Society Malaysia, Petaling Jaya. Koon, C.P. and R. Pakiam, 2014. Water rationing begins outside Malaysia capital amid drought. http://www.bloomberg.com/news/2014-02-25/water-rationing-begins-outside-malaysia-s-capital-amiddrought.html. Accessed on 19 April 2014. Kura-Hotta, M., K. Satoh and S. Katoh, 1987. Relationship between photosynthesis and chlorophyll content during leaf senescence of rice seedlings. Plant Cell Physiology, 28: 1321-1329. Nadler, A. and H. Bruvia, 1998. Physiological responses of potato plants to soil salinity and water deficit. Plant Science, 137: 43-51. Pereira, E.W., L.D. Siquera, C.A. Martinez and M. Puiatti, 2004. Gas exchange and chlorophyll fluorescence in four citrus root stocks under aluminium stress. Journal of Plant Physiology, 157: 513-520. Pirdashti, H., Z.T. Sarvestani, G. Nematzadeh and A. Ismail, 2004. Study of water stress effects in different growth stages on yield and yield components of different rice (Oryza sativa L.) cultivars. The 4th International Crop Science Congress. Brisbane, Australia. Pospisil, P., J. Skotnica and J. Naus, 1998. Low and high temperature dependence of minimum Fo and maximum Fm chlorophyll fluorescence in vivo. Biochimica et Biophysica Acta, 1363: 95-99. Sariam, O., 2004. Growth of non-flooded rice and its response to nitrogen fertilization. PhD Thesis. Department of Land Management, Faculty of Agriculture, Universiti Putra Malaysia. Sariam, O., Y.M. Khanif and T. Zahrah, 2002.Rice growth and nitrogen uptake as influenced by water management. Malaysian Journal of Soil Science, 6: 1-11. Sarwar, M.J. and Y.M. Khanif, 2005b. Techniques of water saving in rice production in Malaysia. Asian Journal of Plant Science, 4: 83–84. Sarwar, M.J. and Y.M. Khanif, 2005. Low water rice production and its effect on redox potential and soil pH. Journal of Agronomy, 4: 142–146. Sarwar, M.J. and Y.M. Khanif, 2005c. The effect of different water levels on rice yield and cu and zn concentration. Journal of Agronomy, 4: 116-121. Sarwar, M.J. and Y.M. Khanif, 2005d. Effect of water saving irrigation on yield and concentration of Ca and Mg in malaysian rice cultivation. Pakistan Journal of Biological Sciences, 8: 65-67. Sarwar, M.J., Y.M. Khanif, S.R. Syed Omar and U.R. Sinniah, 2004. The effect of different water regimes on yield and bioavailability of Phosphorus in rice production in Malaysia. Malaysian Journal of Soil Science, 8: 53-62. Sarwar, MJ., 2004. PhD Thesis. Department of Land Management, Faculty of Agriculture, Universiti Putra Malaysia. Sheela, K.R. and V.J. Alexander, 1996. Physiological response of rice varieties as influenced by soil moisture and seed hardening. Indian Journal of Plant Physiology, 38: 269-271. Syuhada, N., M.S. Jahan, M.M. Khandaker, M. Nashriyah, M. Khairi, M. Nozulaidi and M.H.B. Razali, 2014. Application of copper increased corn yield through enhancing physiological functions. Australian Journal of Basic and Applied Science, 8: 282-286.
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| spellingShingle |
Effects of Different Water Levels on Physiology and Yield of Salinity Rice Variety
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| summary |
Background: Water wise rice production is the current concern. Objective: To justify the water effects on production of salinity rice cultivar, plants physiological, and yield parameters were evaluated. There were four water treatments, T1: flooding at 5 cm (control), T2: flooding at 1 cm, T3: saturated condition and T4: alternative wet and dry (AWD) and five replicates were arranged according to a completely randomized design. Yield, plant and soil parameters under different irrigation conditions were measured. Results: Different water treatments affected plant height at secondary tillering stage, yield and yield parameters of rice plants. AWD treatment decreased chlorophyll (Chl) content and Chl fluorescence in leaves. In addition, net photosynthesis rate (Pn), relative water content (RWC) decreased gradually with decreasing water content in the soil. AWD treatment reduced soil pH but increased soil electric conductivity (EC) value. Conclusion: These results suggest that AWD affected plant yield through modulating plant physiological function but saturated to 1 cm flooding condition showed no effect on rice yield and plant physiology.
|
| title |
Effects of Different Water Levels on Physiology and Yield of Salinity Rice Variety
|
| title_full |
Effects of Different Water Levels on Physiology and Yield of Salinity Rice Variety
|
| title_fullStr |
Effects of Different Water Levels on Physiology and Yield of Salinity Rice Variety
|
| title_full_unstemmed |
Effects of Different Water Levels on Physiology and Yield of Salinity Rice Variety
|
| title_short |
Effects of Different Water Levels on Physiology and Yield of Salinity Rice Variety
|
| title_sort |
effects of different water levels on physiology and yield of salinity rice variety
|