Influence of Crop Nutrition on Grain Yield, Seed Quality and Water Productivity under Two Rice Cultivation Systems

doi:10.1016/S1672-6308(13)60113-4

Abstract

Abstract:

The system of rice intensification (SRI) is reported to have advantages like lower seed requirement, less pest attack, shorter crop duration, higher water use efficiency and the ability to withstand higher degree of moisture stress than traditional method of rice cultivation. With this background, SRI was compared with traditional transplanting technique at Indian Agricultural Research Institute, New Delhi, India during two wet seasons (2009–2011). In the experiment laid out in a factorial randomized block design, two methods of rice cultivation [conventional transplanting (CT) and SRI] and two rice varieties (Pusa Basmati 1 and Pusa 44) were used under seven crop nutrition treatments, viz. T1, 120 kg/hm2 N, 26.2 kg/hm2 P and 33 kg/hm2 K; T2, 20 t/hm2 farmyard manure (FYM); T3, 10 t/hm2 FYM + 60 kg/hm2 N; T4, 5 t/hm2 FYM + 90 kg/hm2 N; T5, 5 t/hm2 FYM + 60 kg/hm2 N + 1.5 kg/hm2 blue green algae (BGA); T6, 5 t/hm2 FYM + 60 kg/hm2 N + 1.0 t/hm2 Azolla, and T7, N0P0K0 (control, no NPK application) to study the effect on seed quality, yield and water use. In SRI, soil was kept at saturated moisture condition throughout vegetative phase and thin layer of water (2–3 cm) was maintained during the reproductive phase of rice, however, in CT, standing water was maintained in crop growing season. Results revealed that CT and SRI gave statistically at par grain yield but straw yield was significantly higher in CT as compared to SRI. Seed quality was superior in SRI as compared to CT. Integrated nutrient management (INM) resulted in higher plant height with longer leaves than chemical fertilizer alone in both the rice varieties. Grain yield attributes such as number of effective tillers per hill, panicle length and panicle weight of rice in both the varieties were significantly higher in INM as compared to chemical fertilizer alone. Grain yields of both the varieties were the highest in INM followed by the recommended doses of chemical fertilizer. The grain yield and its attributes of Pusa 44 were significantly higher than those of Pusa Basmati 1. The seed quality parameters like germination rate and vigor index as well as N uptake and soil organic carbon content were higher in INM than those in chemical fertilizer alone. CT rice used higher amount of water than SRI, with water saving of 37.6% to 34.5% in SRI. Significantly higher water productivity was recorded in SRI as compared to CT rice.

Key words: rice, crop nutrition, grain yield, seed quality, system of rice intensification, water productivity

Y. V. SINGH, K. K. SINGH, S. K. SHARMA. Influence of Crop Nutrition on Grain Yield, Seed Quality and Water Productivity under Two Rice Cultivation Systems[J]. RICE SCIENCE, DOI: 10.1016/S1672-6308(13)60113-4 .

References

Abdulbaki A A, Anderson J D. 1973. Vigour determination in soybean seed by multiple criteria. Crop Sci, 13: 630–633.
Africare, Oxfarm America, WWF-ICRISAT. 2010. More Rice for People, More Water for Planet: System of Rice Intensification (SRI). WWF-ICRISAT, Hyderabad, India.
Anbumozhi V, Yamaji E, Tabuchi T. 1998. Rice crop growth and yield as influenced by changes in ponding water depth, water regime and fertigation level. Agric Water Manag, 37: 241–253.
Bloom A J. 1997. Nitrogen as a limiting factor: Crop acquisition of ammonium and nitrate. In: Jackson L E. Ecology in Agriculture. London: Academic Press: 145–172.
Briones A M, Okabe S, Umemiya Y, Ramsing N B, Reichardt W, Okuyama H. 2003. Ammonia-oxidizing bacteria on root biofilms and their possible contribution to N use efficiency of different rice cultivars. Plant Soil, 250: 335–348.
Chapagain T, Yamaji E. 2010. The effects of irrigation method, age of seedling and spacing on crop performance, productivity and water-wise rice production in Japan. Paddy Water Environ, 8(1): 81–90.
Chaphale S D, Chaphale B S, Yeerne A Z, Laniewar A D. 2000. Effect of green manuring on soil properties and yield performance of rice. J Soil Crops, 10(1): 136–140.
Dixit K G, Gupta B R. 2000. Effect of farm yard manure, chemical and biofertilizers on yield and quality of rice (Oryza sativa L.) and soil properties. J Ind Soc Soil Sci, 48(4): 773–780.
Dobermann A. 2004. A critical assessment of the system of rice intensification. Agric Syst, 79: 261–281.
Fernandes E C M, Uphoff N. 2002. Summary from conference reports. In: Assessment of the System of Rice Intensification (SRI). Proceedings of an International Conference, Sanya, China, April 1–4: 33–39.
Gomez K A, Gomez A A. 1984. Statistical Procedures for Agriculture Research. 2nd edn. John Willey & Sons, Inc.: 357–423.
Gunri S K, Pal S K, Chaudhry A. 2004. Effect of nitrogen application and spacing on yield of rice (Oryza sativa) in foothills of West Bengal. Ind J Agron, 49(4): 248–250.
Husain M M, Haque M A, Khan M A I, Rashid M M, Islam M F. 2003. Direct wet-seeded method of establishment of rice under irrigated condition. Agriculturist, 1(1): 106–113.
International Seed Testing Association (ISTA). 1999. International rules for seed testing. Seed Sci Technol, 27: 340.
Jackson M L. 1973. Soil Chemical Analysis. New Delhi, India: Prentice Hall of India Pvt. Ltd.
Jennings P R, Coffman W R, Kaufman H E. 1979. Rice Improvement. Los Banos, Philippines: IRRI: 186.
Kabir H, Uphoff N. 2007. Results of disseminating the system of rice intensification with farmer field school methods in Northern Myanmar. Exp Agric, 43: 463–476.
Kato Y, Okami M, Katsura K. 2009. Yield potential and water use efficiency of aerobic rice (Oryza sativa L.) in Japan. Field Crops Res, 113: 328–334.
Katsura K, Okami M, Mizunuma H, Kato Y. 2010. Radiation use efficiency, naccumulation and biomass production of high-yielding rice in aerobic culture. Field Crops Res, 117: 81–89.
Lu W F, Chen W, Duan B W, Guo W M, Lu Y, Lantin R S, Wassmann R, Neue H U. 2000. Methane emissions and mitigation options in irrigated rice fields in southeast China. Nutr Cycling Agroecosyst, 58: 65–73.
Makino A, Hayakawa T, Feng Ma J, Ando H, Kondo M, Terao T, Masaki S, Kaneta Y, Mae T, Hayashi H, Ohyama T. 2006. Improvement of productivity and quality of rice in relation to nutrition and physiology. Jpn J Soil Sci Plant Nutr, 77: 361–365.
Mao Z. 1993. Principle and Technique of Water Saving Irrigation for Rice. Wuhan: Wuhan University of Hydraulic and Electric Engineering. (in Chinese)
Mao Z. 1996. Environmental impact of water-saving irrigation for rice. In: Irrigation Scheduling: From Theory to Practice. Proceedings of the ICID/FAO Workshop on Irrigation Scheduling, 12–13 September 1995. Rome: FAO, Rome.
McDonald A J, Hobbs P R, Riha S J. 2006. Does the system of rice intensification outperform conventional best management? A synopsis of the empirical record. Field Crops Res, 96: 31–36.
Meena H N, Shivay Y S. 2010. Productivity of short-duration summer forage crops and their effect on succeeding aromatic rice in conjunction with gypsum-enriched urea. Ind J Agron, 55(1): 11–15.
Mhaskar N V, Thorat S T. 2005. Effect of nitrogen levels on NPK uptake and grain yield of aromatic rice varieties under Konkani condition. J Soil Crops, 15(1): 206–209.
Mishra A, Salokhe V M. 2008. Seedling characteristics and early growth of transplanted rice under different water regimes. Exp Agric, 44: 365–383.
Mishra A, Salokhe V M. 2010. The effects of planting pattern and water regime on root morphology, physiology and grain yield of rice. J Agron Crop Sci, 196: 368–378.
Nemoto K, Morita S, Baba T. 1995. Shoot and root development in rice related to the phyllochron. Crop Sci, 35: 24–29.
Oo N M L, Shivay Y S, Kumar D. 2007. Effect of nitrogen and sulphur fertilization on yield attributes productivity and nutrient uptake of aromatic rice (Oryza sativa L.). Ind J Agric Sci, 77(11): 772–775.
Prasad R, Shivay Y S, Kumar D, Sharma S N. 2006. Learning by Doing Exercises in Soil Fertility: A Practical Manual for Soil Fertility. New Delhi, India: Division of Agronomy, Indian Agricultural Research Institute.
Sahrawat K L. 2004. Organic matter accumulation in submerged soils. Adv Agron, 81: 169–201.
Sandhu S S, Mahal S S, Vashist K K, Buttar G S, Brar A S, Singh M. 2012. Crop and water productivity of bed transplanted rice as influenced by various levels of nitrogen and irrigation in northwest India. Agric Water Manag, 104: 32–39.
Sasaki R, Hoshikawa K. 1997. Changes in energy dependence and morphological characteristics with the development of rice nursling seedlings raised under different light and temperature conditions. Jpn J Crop Sci, 66: 252–258.
Sasaki R. 2004. Characteristics and seedling establishment of rice nursling seedlings. Jpn Agric Res Qua, 38: 7–13.
Sato S, Uphoff N. 2007. A review of on-farm evaluation of system of rice intensification (SRI) methods in eastern Indonesia. CAB Reviews. Wallingford, UK: Commonwealth Agricultural Bureau International: 67–87.
Satyanarayana A, Thiyagarajan T M, Uphoff N. 2007. Opportunities for water saving with higher yield from the system of rice intensification. Irrig Sci, 25: 99–115.
Senthilkumar K, Bindraban P S, Thiyagarajan T M, de Ridder N, Giller K E. 2008. Modified rice cultivation in Tamil Nadu, India: Yield gains and farmers’ (lack of) acceptance. Agric Syst, 98: 82–94.
Shivay Y S, Kumar D, Prasad R. 2008. Effect of zinc-enriched urea on productivity, zinc uptake and efficiency of an aromatic rice-wheat cropping system. Nutr Cycling Agroecosyst, 81(3): 229–243.
Shrirame M D, Rajgire H J, Rajgire A H. 2000. Effect of spacing and seedling number per hill on growth attributes and yield of rice hybrids under lowland condition. J Soil Crops, 10: 109–113.
Singh G, Kumar T, Kumar V, Kumar R G, Sharma R. 2002. Effect of integrated nutrient management on transplanted rice and its residual effect on succeeding wheat in rainfed lowlands. Ind J Agron, 47(3): 311–317.
Singh Y V. 2013. Crop and water productivity as influenced by rice cultivation methods under organic and inorganic sources of nutrient supply. Paddy Water Environ, 13: 531–542.
Singh Y V, Mandal B K. 1997. Nutrition of rice (Oryza sativa) through Azolla, organic materials and urea. Ind J Agron, 42(4): 626–633.
Singh Y V, Singh B V, Pabbi S, Singh P K. 2007. Impact of organic farming on yield and quality of basmati rice and soil properties. In: 9th Scientific Conference on Organic Agriculture at University of Hohenheim, Stuttgart, Germany: 935–939.
Singh Y V, Singh K K, Dhar S. 2011. Productivity of wheat and soil carbon status under integrated use of organic and inorganic fertilizers. Ann Agric Res, 32(1/2): 6–11.
Sinha S K, Talati J. 2007. Productivity impacts of the system of rice intensification (SRI): A case study in West Bengal, India. Agric Water Manag, 87: 55–60.
Stoop W A, Uphoff N, Kassam A. 2002. A review of agricultural research issue raised by the system of rice intensification (SRI) from Madagascar: Opportunities for improving system for resource poor farmers. Agric Syst, 71: 249–274.
Stoop W A. 2005. The System of Rice Intensification (SRI): Results from exploratory field research in Ivory Coast: Research needs and prospects for adaptation to diverse production systems of resource-poor farmers. West African Rice Development Association (WARDA), Bouaké, Ivory Coast.
Suryavanshi Priyanka, Singh Y V, Prasanna R, Bhatia Arti, Shivay Y S. 2013. Pattern of methane emission and water productivity under different methods of rice crop establishment. Paddy Water Environ, 13: 321–329.
Takahashi J, Shoji S, Nogi T, Wada G. 1973. The fate of fertilizer nitrogen applied to the paddy field and its absorption by rice plant: 5. The fate of basal nitrogen in the paddy field and its absorption by rice plant under the various cultural conditions. Proc Crop Sci Soc Japan, 42: 91–96. (in Japanese with English abstract)
Thakur A K. 2010. Critiquing SRI criticism: Beyond skepticism with empiricism. Curr Sci, 98: 1294–1299.
Thakur A K, Rath S, Roychowdhury S, Uphoff N. 2010a. Comparative performance of rice with system of rice intensification (SRI) and conventional management using different plant spacing. J Agron Crop Sci, 196: 146–159.
Thakur A K, Uphoff N, Antony E. 2010b. An assessment of physiological effects of system of rice intensification (SRI) practices compared with recommended rice cultivation practices in India. Exp Agric, 46: 77–98.
Tuong T P, Bouman B A M, Mortimer M. 2005. More rice, less water-integrated approaches for increasing water productivity in irrigated rice-based systems in Asia. Plant Prod Sci, 8: 231–241.
Thiyagarajan T M, Senthikumar K, Sindraban P S, Hengsdijk H, Ramasamy S, Velu V, Durgadevi D, Vogindarajan K, Priyadarshini R, Sudhalakshmi C, Mishra P T, Gayathry G. 2002. Crop management options for increasing water productivity in rice. J Agric Resour Manag, 7(4): 169–181.
Tsujimoto Y, Horie T, Randriamihary H, Shiraiwa T, Homma K. 2009. Soil management: The key factors for higher productivity in the fields utilizing the system of rice intensification (SRI) in the central highland of Madagascar. Agric Sys, 100: 61–71.
Uphoff N, Randriamiharisoa R. 2002. Reducing water use in irrigated rice production with the Madagascar system of rice intensification (SRI). In: Bouman B A M. Water-wise Rice Production. Los Ba?os, Philippines: International Rice Research Institute: 151–166.
Uphoff N. 2003. Higher yields with fewer external inputs? The system of rice intensification and potential contributions to agricultural sustainability. Int J Agric Sustain, 1: 38–50.
Zhao L M, Wu L H, Li Y S, Lu X H, Zhu D F, Uphoff N. 2009. Influence of the system of rice intensification on rice yield and nitrogen and water use efficiency with different N application rates. Exp Agric, 45: 275–286.
Zhao L M, Wu L H, Li Y S, Animesh S, Zhu D F, Uphoff N. 2010. Comparisons of yield, water use efficiency, and soil microbial biomass as affected by the system of rice intensification. Comm Soil Sci Plant Anal, 41(1): 1–12.
Zhao X Q, Zhao S P, Shi W M. 2008. Enhancement of NH4+ uptake by NH3- in relation to expression of nitrate induced genes in rice (Oryza sativa) roots. Pedosphere, 18: 86–91.

[1]	Prathap V, Suresh KUMAR, Nand Lal MEENA, Chirag MAHESHWARI, Monika DALAL, Aruna TYAGI. Phosphorus Starvation Tolerance in Rice Through a Combined Physiological, Biochemical and Proteome Analysis [J]. Rice Science, 2023, 30(6): 8-.
[2]	Serena REGGI, Elisabetta ONELLI, Alessandra MOSCATELLI, Nadia STROPPA, Matteo Dell’ANNO, Kiril PERFANOV, Luciana ROSSI. Seed-Specific Expression of Apolipoprotein A-I_Milano Dimer in Rice Engineered Lines [J]. Rice Science, 2023, 30(6): 6-.
[3]	Sundus ZAFAR, XU Jianlong. Recent Advances to Enhance Nutritional Quality of Rice [J]. Rice Science, 2023, 30(6): 4-.
[4]	Kankunlanach KHAMPUANG, Nanthana CHAIWONG, Atilla YAZICI, Baris DEMIRER, Ismail CAKMAK, Chanakan PROM-U-THAI. Effect of Sulfur Fertilization on Productivity and Grain Zinc Yield of Rice Grown under Low and Adequate Soil Zinc Applications [J]. Rice Science, 2023, 30(6): 9-.
[5]	FAN Fengfeng, CAI Meng, LUO Xiong, LIU Manman, YUAN Huanran, CHENG Mingxing, Ayaz AHMAD, LI Nengwu, LI Shaoqing. Novel QTLs from Wild Rice Oryza longistaminata Confer Rice Strong Tolerance to High Temperature at Seedling Stage [J]. Rice Science, 2023, 30(6): 14-.
[6]	LIN Shaodan, YAO Yue, LI Jiayi, LI Xiaobin, MA Jie, WENG Haiyong, CHENG Zuxin, YE Dapeng. Application of UAV-Based Imaging and Deep Learning in Assessment of Rice Blast Resistance [J]. Rice Science, 2023, 30(6): 10-.
[7]	Md. Forshed DEWAN, Md. AHIDUZZAMAN, Md. Nahidul ISLAM, Habibul Bari SHOZIB. Potential Benefits of Bioactive Compounds of Traditional Rice Grown in South and South-East Asia: A Review [J]. Rice Science, 2023, 30(6): 5-.
[8]	Raja CHAKRABORTY, Pratap KALITA, Saikat SEN. Phenolic Profile, Antioxidant, Antihyperlipidemic and Cardiac Risk Preventive Effect of Chakhao Poireiton (A Pigmented Black Rice) in High-Fat High-Sugar induced Rats [J]. Rice Science, 2023, 30(6): 11-.
[9]	LI Qianlong, FENG Qi, WANG Heqin, KANG Yunhai, ZHANG Conghe, DU Ming, ZHANG Yunhu, WANG Hui, CHEN Jinjie, HAN Bin, FANG Yu, WANG Ahong. Genome-Wide Dissection of Quan 9311A Breeding Process and Application Advantages [J]. Rice Science, 2023, 30(6): 7-.
[10]	JI Dongling, XIAO Wenhui, SUN Zhiwei, LIU Lijun, GU Junfei, ZHANG Hao, Tom Matthew HARRISON, LIU Ke, WANG Zhiqin, WANG Weilu, YANG Jianchang. Translocation and Distribution of Carbon-Nitrogen in Relation to Rice Yield and Grain Quality as Affected by High Temperature at Early Panicle Initiation Stage [J]. Rice Science, 2023, 30(6): 12-.
[11]	Nazaratul Ashifa Abdullah Salim, Norlida Mat Daud, Julieta Griboff, Abdul Rahim Harun. Elemental Assessments in Paddy Soil for Geographical Traceability of Rice from Peninsular Malaysia [J]. Rice Science, 2023, 30(5): 486-498.
[12]	Ammara Latif, Sun Ying, Pu Cuixia, Noman Ali. Rice Curled Its Leaves Either Adaxially or Abaxially to Combat Drought Stress [J]. Rice Science, 2023, 30(5): 405-416.
[13]	Liu Qiao, Qiu Linlin, Hua Yangguang, Li Jing, Pang Bo, Zhai Yufeng, Wang Dekai. LHD3 Encoding a J-Domain Protein Controls Heading Date in Rice [J]. Rice Science, 2023, 30(5): 437-448.
[14]	Lu Xuedan, Li Fan, Xiao Yunhua, Wang Feng, Zhang Guilian, Deng Huabing, Tang Wenbang. Grain Shape Genes: Shaping the Future of Rice Breeding [J]. Rice Science, 2023, 30(5): 379-404.
[15]	Zhang Guomei, Li Han, Liu Shanshan, Zhou Xuming, Lu Mingyang, Tang Liang, Sun Lihua. Water Extract of Rice False Smut Balls Activates Nrf2/HO-1 and Apoptosis Pathways, Causing Liver Injury [J]. Rice Science, 2023, 30(5): 473-485.