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作物学报 ›› 2012, Vol. 38 ›› Issue (10): 1930-1942.doi: 10.3724/SP.J.1006.2012.01930

• 耕作栽培·生理生化 • 上一篇    下一篇

不同生态条件下栽培方式对水稻干物质生产和产量的影响

邓飞1,王丽1,刘利1,刘代银2,任万军1, 杨文钰1,*   

  1. 1四川农业大学农业部西南作物生理生态与耕作重点实验室, 四川温江611130; 2四川省农业技术推广总站, 四川成都610041
  • 收稿日期:2012-02-27 修回日期:2012-05-20 出版日期:2012-10-12 网络出版日期:2012-07-27
  • 通讯作者: 任万军, E-mail: rwjun@126.com; 杨文钰, E-mail: wenyu.yang@263.net
  • 基金资助:

    本研究由国家粮食丰产科技工程项目(2011BAD16B05), 四川新农村建设技术集成研究与示范项目和四川农业大学优秀硕士论文培育基金资助。

Effects of Cultivation Methods on Dry Matter Production and Yield of Rice under Different Ecological Conditions

DENG Fei1,WANG Li1,LIU Li1,LIU Dai-Yin2,REN Wan-Jun1,*,YANG Wen-Yu1,*   

  1. 1 Sichuan Agricultural University, Key Laboratory of Crop Ecophysiology and Farming System in Southwest China, Ministry of P.R. China, Wenjiang 611130, China; 2 Sichuan General Popularization Centre of Agricultural Technique, Chengdu 610041, China
  • Received:2012-02-27 Revised:2012-05-20 Published:2012-10-12 Published online:2012-07-27
  • Contact: 任万军, E-mail: rwjun@126.com; 杨文钰, E-mail: wenyu.yang@263.net

摘要:

为明确不同生态条件下栽培方式对水稻物质生产及产量的影响, 采用随机区组多点试验设计, 研究了不同秧龄和移栽方式对仁寿、郫县和雅安生态点水稻干物质积累与分配、茎鞘干物质输出与转化、产量及构成因素的影响。结果表明: (1)水稻的干物质积累特性为生态条件、秧龄、移栽方式及其互作效应共同作用的结果。水稻单茎和群体干物重均受三者显著主效作用; 生态条件与秧龄互作效应极显著影响分蘖盛期至抽穗期群体干物重, 而生态条件与移栽方式、秧龄与移栽方式及三者互作则主要影响抽穗后水稻单茎和群体干物重。(2)高产水稻干物质生产特性因生态条件的变化而改变。仁寿的产量主要来自抽穗后光合产物在籽粒中的积累, 与茎鞘物质的输出和转化相关不显著; 在郫县, 茎鞘物质输出和转化对产量贡献大于在仁寿, 产量与孕穗期茎鞘干物质分配比例(r = 0.775*)显著正相关, 与成熟期茎鞘干物质分配比例(r = -0.757*)则呈显著负相关; 在雅安, 抽穗后茎鞘干物质的输出和转化与产量正相关。(3)水稻产量以仁寿最高, 较郫县和雅安高5.52%和17.65%; 秧龄和移栽方式均能影响水稻最终产量, 不同栽培方式间产量差异显著; 仁寿的栽培方式主要通过单位面积有效穗数、结实率和千粒重来影响产量, 在郫县则通过影响单位面积有效穗数和每穗颖花数实现对产量的调控, 雅安的栽培方式主要通过群体颖花量和千粒重调控产量。(4)适宜的栽培方式能有效调控水稻干物质生产, 促进产量的提高。在仁寿和郫县, 50 d秧龄单苗优化定抛有效地协调了不同生育阶段干物质积累量, 促进水稻增产; 在雅安, 50 d秧龄单苗手插具有较高穗前干物质积累量和抽穗后茎鞘干物质输出与转化效率, 增产显著。

关键词: 生态条件, 栽培方式, 水稻, 干物质生产, 产量

Abstract:

To explore the effects of cultivation methods on dry matter production and grain yield of rice under different ecological conditions, we measured dry matter accumulation, distribution, translocation, grain yield and its components in a field experiment with different seedling ages and transplanting methods in Renshou, Pixian and Ya’an using a randomized block experimental design. The results showed as follows. (1) The dry matter accumulation of rice such as dry matter weight per stem or in a population was clearly influenced by ecological condition, seedling age, transplanting method, and there were significant interactions of ecological condition and seedling age on dry matter weight of population from tillering to heading stages. Moreover, the interactions of ecological condition and transplanting method, seedling age and transplanting method, and all of the three factors mainly affected dry matter weight per stem and in a population after heading stage. (2) The diversification of dry matter production characteristics was due to the ecological condition changes. The grain yield was primarily come from the accumulation of photosynthate after heading stage in Renshou, but not significantly correlated with the dry matter translocation from stem-sheath. In Pixian, the dry matter translocation from stem-sheath affected grain yield intensely, rice yield was positively correlated with dry matter translocation ratio from stem-sheath at booting stage (r = 0.775*), but negatively with that at maturity (r = –0.757*), significantly. In addition, the dry matter redistribution from stem-sheath after heading was positively correlated with rice yield in Ya’an. (3) The yield in Renshou increased by 5.52% and 17.65% respectively, compared with that in Pixian and Ya’an. Seedling age and transplanting method had an effect on the yield, that was significantly different under the different cultivation methods. Cultivation methods influenced the yield through changing effective panicles per unit area, seed-setting rate, and 1000-grain weight in Renshou, while by changing effective panicles per unit area and spikelets per panicle in Pixian, and by changing total spikelets and 1000-grain weight in Ya’an. (4) It was suggested that, with the effective regulation of cultivation methods on rice dry matter production, a higher yield would be reached. Overall, the 50 d single seedling with optimized-broadcasting treatment could coordinate the dry matter accumulation at different growth stages to promote the grain yield in Renshou and Pixian. Furthermore, the 50 d single seedlings with hand-transplanting treatment enhanced the dry matter accumulation before heading and the dry matter translocation from stem-sheath after heading, resulting in the extraordinarily increased rice yield inYa’an.

Key words: Ecological condition, Cultivation method, Rice, Dry matter production, Yield

[1]Li J(李杰), Zhang H-C(张洪程), Dong Y-Y(董洋阳), Ni X-C(倪晓诚), Yang B(杨波), Gong J-L(龚金龙), Chang Y(常勇), Dai Q-G(戴其根), Huo Z-Y(霍中洋), Xu K(许轲), Wei H-Y(魏海燕). Effects of cultivation methods on yield, growth stage and utilization of temperature and illumination of rice in different ecological regions. Sci Agric Sin (中国农业科学), 2011, 44(13): 2661–2672 (in Chinese with English abstract)



[2]Liang T-F(梁天锋), Xu S-H(徐世宏), Liu K-Q(刘开强), Wang D-J(王殿君), Liang H(梁和), Dong D-F(董登峰), Wei S-Q(韦善清), Zhou J-M(周佳民), Hu J-M(胡钧铭), Jiang L-G(江立庚). Studies on influence of cultivation patterns on characteristics of nitrogen utilization and distribution in rice. Plant Nutr Fert Sci (植物营养与肥料学报), 2010, 16(1): 20–26 (in Chinese with English abstract)



[3]Ren W-J(任万军), Yang W-Y(杨文钰), Fan G-Q(樊高琼), Chen D-C(陈德春), Wu J-X(吴锦秀). Effect of different tillage and transplanting methods on soil fertility and root growth of rice. J Soil Water Conser (水土保持学报), 2007, 21(2): 108–110 (in Chinese with English abstract)



[4]Sanoh Y, Mano Y, Ookawa T, Hirasawa T. Comparison of dry matter production and associated characteristics between direct-sown and transplanted rice plants in a submerged paddy field and relationships to planting patterns. Field Crops Res, 2004, 87: 43–58



[5]He R-Y(何瑞银), Luo H-Y(罗汉亚), Li Y-T(李玉同), Wang X-H(汪小函), Zhang L(张璐). Comparison and analysis of different rice planting methods in China. Trans CSAE (农业工程学报), 2008, 24(1): 167–171 (in Chinese with English abstract)



[6]Luo X-W(罗锡文), Xie F-P(谢方平), Qu Y-G(区颖刚), Li B-X(李佰祥), Zheng D-K(郑丁科). Experimental investigation of different transplanting methods in paddy production. Trans CSAE (农业工程学报), 2004, 20(1): 136–139 (in Chinese with English abstract)



[7]Chen S, Cai S G, Chen X, Zhang G P. Genotypic differences in growth and physiological responses to transplanting and direct seeding cultivation in rice. Rice Sci, 2009, 16(2): 143–150



[8]Wang X(王勋), Dai T-B(戴廷波), Jiang D(姜东), Jing Q(荆奇), Cao W-X(曹卫星). Yield-formation and source-sink characteristics of rice genotypes under two different eco-environments. Chin J Appl Ecol (应用生态学报), 2005, 16(4): 615–619 (in Chinese with English abstract)



[9]Dong Z(董钻), Shen X-Y(沈秀瑛). Introduction to Crop Cultivation (作物栽培学总论). Beijing: China Agriculture Press, 2000. p 114



[10]Li X-Y(李旭毅), Sun Y-J(孙永健), Cheng H-B(程宏彪), Zheng H-Z(郑洪帧), Liu S-J(刘树金), Hu R(胡蓉), Ma J(马均). Effects of nitrogen regulation on dry matter accumulation and grain yield of rice under different cultivation models and two kinds of ecological conditions. Plant Nutr Fert Sci (植物营养与肥料学报), 2011, 17(4): 773–781 (in Chinese with English abstract)



[11]Deng F(邓飞), Wang L(王丽), Ye D-C(叶德成), Ren W-J(任万军), Yang W-Y(杨文钰). Effects of ecological conditions and cultivation methods on rice starch RVA profile characteristics and protein content. Acta Agron Sin (作物学报), 2012, 38(4): 717–724 (in Chinese with English abstract)



[12]Yang B(杨波), Ren W-J(任万军), Yang W-Y(杨文钰). Effects of density on grain yield and population growth quality of rice in the optimized seedling-broadcasting technique. Hybrid Rice (杂交水稻), 2006, 21(5): 64–68 (in Chinese with English abstract)



[13]Zhu Q-S(朱庆森), Wang Z-Q(王志琴), Zhang Z-J(张祖建), Hui D-F(惠大丰). Study on indicators of grain-filling of rice. J Jiangsu Agric Coll (江苏农学院学报), 1995, 16(2): 1–4 (in Chinese with English abstract)



[14]Tong P(童平), Yang S-M(杨世民), Ma J(马均), Wu H-Z(吴合洲), Fu T-L(傅泰露), Li M(李敏), Wang M-T(王明田). Photosynthetic characteristics and dry matter accumulation of hybrid rice varieties under different light conditions. Chin J Appl Ecol (应用生态学报), 2008, 19(3): 505–511 (in Chinese with English abstract)



[15]Ren W-J(任万军), Yang W-Y(杨文钰), Fan G-Q(樊高琼), Zhu X-M(朱雪梅), Ma Z-H(马周华), Xu J-W(徐精文). Effect of low light on dry matter accumulation and yield of rice. J Sichuan Agric Univ (四川农业大学学报), 2003, 21(4): 292–296 (in Chinese with English abstract)



[16]Li J(李杰), Zhang H-C(张洪程), Chang Y(常勇), Gong J-L(龚金龙), Guo Z-H(郭振华), Dai Q-G(戴其根), Huo Z-Y(霍中洋), Xu K(许轲), Wei H-Y(魏海燕), Gao H(高辉). Characteristics of photosynthesis and matter production of rice with different planting methods under high-yielding cultivation condition. Acta Agron Sin (作物学报), 2011, 37(7): 1235–1248 (in Chinese with English abstract)



[17]Sharma A P, Singh S P. Relationship of physiological attributes with grain yield in rice. Agric Sci Digest, 2000, 20: 191–192



[18]Yang H-J(杨惠杰), Li Y-Z(李义珍), Yang R-C(杨仁崔), Jiang Z-W(姜照伟), Zheng J-S(郑景生). Dry matter production characteristics of super high yielding rice. Chin J Rice Sci (中国水稻科学), 2001, 15(4): 265–270 (in Chinese with English abstract)



[19]Wu W-G(吴文革), Zhang H-C(张洪程), Wu G-C(吴桂成), Zhai C-Q(翟超群), Qian Y-F(钱银飞), Chen Y(陈烨), Xu J(徐军), Dai Q-G(戴其根),Xu K(许珂). Preliminary study on super rice population sink characters. Sci Agric Sin (中国农业科学), 2007, 40(2): 250–257 (in Chinese with English abstract)



[20]Wu G-C(吴桂成), Zhang H-C(张洪程), Qian Y-F(钱银飞), Li D-J(李德剑), Zhou Y-Y(周有炎), Xu J(徐军), Wu W-G(吴文革), Dai Q-G(戴其根), Huo Z-Y(霍中洋), Xu K(许轲), Gao H(高辉), Xu Z-J(徐宗进), Qian Z-H(钱宗华), Sun J-Y(孙菊英), Zhao P-H(赵品恒). Rule of grain yield components from high yield to super high yield and the characters of super-high yielding Japonica super rice. Sci Agric Sin (中国农业科学), 2010, 43(2): 266–276 (in Chinese with English abstract)



[21]Pan S-G(潘圣刚), Huang S-Q(黄胜奇), Jiang Y(江洋), Cai M-L(蔡明历), Cao C-G(曹凑贵), Tang X-R(唐湘如), Li G-X(黎国喜). Effects of rice seedling age and transplanting density on the biological characteristics of rice. Acta Agric Boreali-Sin (华北农学报), 2011, 26(3): 134–138 (in Chinese with English abstract)



[22]Ma J(马均), Zhu Q-S(朱庆森), Ma W-B(马文波), Tian Y-H(田彦华), Yang J-C(杨建昌), Zhou K-D(周开达). Studies on the photosynthetic characteristics and accumulation and transformation of assimilation product in heavy panicle type of rice. Sci Agric Sin (中国农业科学), 2003, 36(4): 375–381 (in Chinese with English abstract)



[23]Ao H-J(敖和军), Wang S-H(王淑红), Zou Y-B(邹应斌), Peng S-B(彭少兵), Tang Q-Y(唐启源), Fang Y-X(方远祥), Xiao A-M(肖安民), Chen Y-M(陈玉梅), Xiong C-M(熊昌明). Study on yield stability and dry matter characteristics of super hybrid rice. Sci Agric Sin (中国农业科学), 2008, 41(7): 1927–1936 (in Chinese with English abstract)



[24]Chen W-F(陈温福), Xu Z-J(徐正进), Zhang L-B(张龙步). Physiological Basis of Rice Breeding for Super High Yield (水稻超高产育种生理基础). Shenyang: Liaoning Science and Technology Press, 1995. pp 69–94



[25]Zou Y-B(邹应斌), Huang J-L(黄见良), Tu N-M(屠乃美), Li H-S(李合松), Huang S-P(黄升平), Zhang Y-Z(张杨珠). Effects of the VSW cultural method on yield formation and physiological characteristics in double cropping hybrid rice. Acta Agron Sin (作物学报), 2001, 27(3): 343–350 (in Chinese with English abstract)



[26]Ling Q-H(凌启鸿), Zhang H-C(张洪程), Cai J-Z(蔡建中), Su Z-F(苏祖芳), Ling L(凌励). Investigation on the population quality of high yield and its optimizing control programme in rice. Sci Agric Sin (中国农业科学), 1993, 26(6): 1–11 (in Chinese with English abstract)

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