覆盖旱种对水稻产量与品质的影响

doi:10.3724/SP.J.1006.2010.00276

Abstract

Abstract:

Plastic film or straw mulching cultivation under non-flooded condition has been considered as a new water-saving technique in rice production. This study aimed to investigate the yield performance in terms of quality and quantity under such practices. Two super rice cultivars, Wujing 15 (a japonica cultivar) and Liangyoupeijiu (an indica hybrid cultivar) were used with four cultivation treatments from transplanting to maturity: traditional flooding as control (TF), no-flooded plastic film mulching (PM), non-flooded wheat straw mulching (SM), and no flooding and no mulching (NM). Compared with that under TF, grain yield showed some reduction under all the non-flooded cultivations but differed largely among the treatments. The reduction in yield was 38.7–46.5% under NM, 9.8–17.4% under PM, and 1.7–7.0% under SM. The difference in grain yield was significant between NM and TF or between PM and TF, and was not significant between SM and TF. SM significantly improved milling, appearance, and cooking qualities, whereas PM or NM decreased these qualities. SM also significantly increased the peak viscosity and breakdown value, and reduced setback value, and PM or NM had the opposite effect. The two cultivars showed similar trends in quality and quantity of rice yield. SM significantly increased root oxidation activity, leaf photosynthetic rate, and activities of key enzymes in sucrose-to-starch conversion in grains during the grain filling period, whereas PM and NM significantly reduced these parameters. The results indicate that SM could not only maintain a high grain yield, but also improve quality of rice. Increases in leaf photosynthetic rate, root activity, and activities of the key enzymes involved in the sucrose-starch metabolic pathway in grains under SM contributed to a higher grain yield and better quality of rice.

Key words: Rice, Non-flooded plastic film mulching cultivation, Non-flooded wheat straw mulching cultivation, Grain yield, Grain quality

ZHANG Zi-Chang,SUN Xiao-Lin,CHEN Ting-Ting,LIU Li-Jun,YANG Jian-Chang.

Effects of Non-flooded Mulching Cultivation on the Yield and Quality of Rice

[J].Acta Agron Sin, 2010, 36(2): 285-295.

References

[1] Fageria N K. Plant tissue test for determination of optimum concentration and uptake of nitrogen at different growth stages in low land rice. Commun Soil Sci Plant Anal, 2003, 34: 259–270

[2] Fageria N K. Yield physiology of rice. J Plant Nutr, 2007, 30: 843–879

[3] Belder P, Bouman B A M, Cabangon R, Guoan L, Quilang E J P, Li Y, Spiertz J H J, Tuong T P. Effect of water-saving irrigation on rice yield and water use in typical lowland conditions in Asia. Agric Water Manage, 2004, 65: 193–210

[4] Belder P, Spiertz J H J, Bouman B A M, Lu G, Tuong T P. Nitrogen economy and water productivity of lowland rice under water-saving irrigation. Field Crops Res, 2005, 93: 169–185

[5] Borrell A, Garside A, Fukai S. Improving efficiency of water use for irrigated rice in a semi-arid tropical environment. Field Crops Res, 1997, 52: 231–248

[6] Liu X J, Wang J C, Lu S H, Zhang F S, Zeng X Z, Ai Y W, Peng S B, Christie P. Effects of non-flooded mulching cultivation on crop yield, nutrient uptake and nutrient balance in rice-wheat cropping systems. Field Crops Res, 2003, 83: 297–311

[7] Huang Y-D(黄义德), Zhang Z-L(张自立), Wei F-Z(魏凤珍), Li J-C(李金才). Ecophysiological effect of dry-cultivated and plastic film-mulched rice planting. Appl Ecol (应用生态学报), 1999, 10(3): 305–308 (in Chinese with English abstract)

[8] Liang Y-C(梁永超), Hu F(胡锋), Yang M-C(杨茂成), Zhu X-L(朱遐亮), Wang G-P(王广平), Wang Y-L(王永乐). Mechanisms of high yield and irragation water use efficiency of rice in plastic film muched dryland. Sci Agric Sin (中国农业科学), 1999, 32(1): 26–32 (in Chinese with English abstract)

[9] Fan M S, Liu X J, Jiang R F, Zhang F S, Lu S H, Zeng X Z, Christie P. Crop yields, internal nutrient efficiency, and changes in soil properties in rice-wheat rotations under non-flooded mulching cultivation. Plant Soil, 2005, 277: 265–276

[10] Lu X H, Wu L H, Pang L J, Li Y S, Wu J G, Shi C H, Zhang F S. Effects of plastic film mulching cultivation under non-flooded condition on rice quality. J Sci Food Agric, 2007, 87: 334–339

[11] Liu T-X(刘天学), Ji X-E(纪秀娥). Effects of crop straw burning on oil organic matter and soil microbes. Soil (土壤), 2003, 35(4): 347–348 (in Chinese)

[12] Miura Y, Kanna T. Emissions of trace gases (CO₂, CO, CH₄, and N₂O) resulting from rice straw burning. Soil Sci Plant Nutr, 1997, 43: 849–854

[13] Liu X J, Ai Y W, Zhang F S, Lu S H, Zeng X Z, Fan M S. Crop production, nitrogen recovery and water use efficiency in rice-wheat rotation as affected by non-flooded mulching cultivation (NFMC). Nutr Cycl Agroecosyst, 2005, 71: 289–299

[14] Zhang J-D(章骏德), Liu G-P(刘国屏), Shi Y-N(施永宁). Experimental Method for Plant Physiology (植物生理实验法). Nanchang: Jiangxi People’s Publisher, 1982. pp 52–57 (in Chinese)

[15] Supervising Department of Quality and Technology of China (国家质量技术监督局). The National Standard of the People’s Republic of China (中华人民共和国国家标准). Good Quality of Rice Grain (优质稻谷). GB/T17891-1999, 1999 (in Chinese)

[16] Ministry of Agriculture, The People’s Republic of China (中华人民共和国农业部). Good Quality and Edible Rice Grains (优质食用稻米). NY147-88, 1988 (in Chinese)

[17] Han Y P, Xu M L, Liu X Y, Yan C J, Korban S S, Chen X L, Gu M H. Genes coding for starch branching enzymes are major contributors to starch viscosity characteristics in waxy rice (Oryza sativa L.). Plant Sci, 2004, 166: 357–364

[18] Yang J-C(杨建昌), Wang Z-Q(王志琴), Chen Y-F(陈义芳), Cai Y-X(蔡一霞), Liu L-J(刘立军), Zhu Q-S(朱庆森). Preliminary studies of grain yield and quality of dry-cultivated rice. Jiangsu Agric Res (江苏农业研究), 2000, 21(3): 1–5 (in Chinese with English abstract)

[19] Hasegawa T, Fujimura S, Shimono H, Iwama K, Jiteuyama Y. Rice growth and developing limited by root zone temperature. In: Morita S, ed. Proceedings of the Sixth Symposium of the International Society for Root Research. Nagoya, Japan: Published by Japanese Society for Root Research (JSRR), 2001. pp 520–521

[20] Funaba M, Ishibashi Y, Molla A H, Iwanami K, Iwaya-Inoue M. Influence of low/high temperature on water status in developing and maturing rice grains. Plant Prod, 2006, 9: 347–354

[21] Liu L-J(刘立军), Yuan L-M(袁莉民), Wang Z-Q(王志琴), Xu G-W(徐国伟), Chen Y(陈云). Preliminary studies on physiological reason and countermeasure of lodging in dry-cultivated rice. Chin J Rice Sci (中国水稻科学), 2002, 16(3): 225–230 (in Chinese with English abstract)

[22] Cheng F-M(程方民), Jiang D-A(蒋德安), Wu P(吴平), Shi C-H(石春海). The dynamic change of starch synthesis enzymes during the grain filling stage and effects of temperature upon on it. Acta Agron Sin (作物学报), 2001, 27(2): 201–206 (in Chinese with English abstract)

[23] Cheng F-M(程方民), Zhong L-J(钟连进), Sun Z-X(孙宗修). Effect of temperature at grain filling stage on starch biosynthetic metabolism in developing rice grains of early-indica. Sci Agric Sin (中国农业科学), 2003, 36(5): 492–501 (in Chinese with English abstract)

[24] Zhong X-H(钟旭华), Huang N-R(黄农荣). Preliminary study on the relationship between rice grain chalkiness and root activity at grain-filling stage. Chin J Rice Sci (中国水稻科学), 2005, 19(5): 471–474 (in Chinese with English abstract)

[25] Dong M-H(董明辉), Sang D-Z(桑大志), Wang P(王朋), Zhang W-J(张文杰), Yang J-C(杨建昌). Difference in chalky characters of the grains at different positions within a rice panicle. Acta Agron Sin (作物学报), 2006, 32(1): 101–111 (in Chinese with English abstract)

[26] Li Y S, Wu L H, Lu X H, Zhao L M, Fan Q L, Zhang F S. Soil microbial biomass as affected by non-flooded plastic mulching cultivation in rice. Biol Fert Soils , 2006, 43: 107–111

[27] Kato T. Change of sucrose synthase activity in developing endosperm of rice cultivars. Crop Sci, 1995, 35: 827–831

[28] Ahmadi A, Baker D A. The effect of water stress on the activities of key regulatory enzymes of the sucrose to starch pathway in wheat. Plant Growth Regul, 2001, 35: 81–91

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