Difference in Growth Characteristics, Utilization of Temperature and Illumination of Double- Cropping High Quality Late Rice in Different Ecological Regions of the Lower Reaches of the Yangtze River

doi:10.16819/j.1001-7216.2020.9117

Abstract

Abstract:

【Objective】Under machine-transplanting conditions, four different types of late rice cultivars with high quality were used to investigate the differences of yield, growth characteristics, utilization of temperature and illumination. The results will lay a theoretical basis for the selection of double-cropping late rice varieties suitable for different ecological regions in the lower reaches of the Yangtze River. 【Method】The yield, growth duration, dry matter accumulation, and utilization of temperature and illumination of double-cropping late rice were comparatively studied using four kinds of rice varieties as test materials namely indica conventional rice, indica hybrid rice, japonica conventional rice and Changyou japonica hybrid rice (20 varieties in total, selected between 2016 and 2017, all of which were high-quality rice in the lower reaches of the Yangtze River as double-cropping late rice). The experiment was carried out in two cities, Fuyang, Zhejiang Province (30.05º N, 119.95º E, 17.93 m above sea level) and Lujiang, Anhui Province (31.15º N, 117.16º E, 14 m above sea level). 【Result】The yield of the four-types of late rice at high latitude was higher than that at low latitude. The yield of indica conventional rice, indica hybrid rice, japonica conventional rice, and Changyou japonica hybrid rice grown in Lujiang, Anhui Province was 11.1%, 12.9%, 6.6% and 12.4% higher than that in Fuyang, Zhejiang Province. When planted in the same places, Changyou japonica hybrid rice had the highest yield, and conventional indica rice had the lowest. The growth period was longer and dry matter accumulation was higher at high latitudes. When planted at high altitudes, the indica hybrid rice growth duration was the longest (10.4 d), and the increase in dry matter accumulation was the largest in conventional japonica rice (11.93% in full heading stage and 9.44% in mature stage). When planted in the same place, the dry matter accumulation was higher in hybrid rice than conventional rice. There was no significant difference in effective accumulated temperature between the filling stage and the whole growth duration of indica rice, but the sunshine hours, solar radiation, and its utilization rate were significantly higher at high latitudes. The effective accumulated temperature decreased significantly in the filling stage and the whole growth stage of japonica rice, but the change of accumulated sunshine hours was not obvious, while the accumulated solar radiation increased significantly at high latitudes. These were consistent with the changing trend of the utilization rate of the temperature and light resources. When planted at the same latitude, the growth period, dry matter accumulation, temperature and light resource utilization rate of japonica rice were higher than those of indica rice. 【Conclusion】Late indica rice could make full use of temperature and light resources in order to improve its yield when planted in Lujiang, Anhui Province, but the difference of the utilization efficiency in the temperature and light resources of late japonica rice was not obvious. The yield of late japonica rice in Lujiang, Anhui Province increased because of the extension of the growth duration and the increase of dry matter accumulation.

Key words: double-season late rice, yield, latitude, growth characteristics, utilization of temperature and illumination

摘要：

【目的】研究在机插条件下长江下游不同生态区各类型优质晚稻产量、生长特性和温光利用的差异,为选择适宜在该地区作为双季种植的优质晚稻品种提供参考依据。【方法】以2016年和2017年筛选适合长江下游机插的双季优质晚稻为材料(常规籼稻、杂交籼稻、常规粳稻和常优杂粳共20个品种),比较在机插条件下浙江富阳(30.05°N, 119.95°E,海拔17.9 m)与安徽庐江(31.15ºN, 117.16ºE,海拔14 m)两个生态区在产量、生育期、干物质积累以及温光利用方面的差异。【结果】各类型晚稻产量高纬度试点均高于低纬度试验点。与浙江富阳点相比,安徽庐江点种植的常规籼稻、杂交籼稻、常规粳稻、常优杂粳稻产量分别高11.1%、12.9%、6.6%和12.4%。同一试点种植时,常优杂粳产量最高,常规籼稻最低。高纬度点种植时,生育期延长,干物质积累量增加。高纬度点生育期延长杂交籼稻最长(10.4 d),干物质积累量高纬度点增幅常规粳稻最大(齐穗期和成熟期分别增加11.93%和9.44%)。同一试点种植时,干物质积累量杂交稻大于常规稻。籼稻灌浆期和全生育期累积的有效积温两个纬度点差异不明显,但日照时数和太阳辐射及其利用率均是高纬度点显著高;粳稻灌浆期和全生育期累积的有效积温高纬度点明显较低,累积日照时数高纬度点变化不明显,而累积太阳辐射则显著增加;温光资源利用率的变化趋势与此一致;同一试点种植时,生育期、干物质积累量以及温光资源利用率均是粳稻大于籼稻。【结论】晚籼稻在安徽庐江点种植时能充分利用温光资源从而提高产量,晚粳稻对温光资源利用率差异不明显,安徽庐江点产量增加的原因是生育期延长和干物质增加。

关键词: 双季晚稻, 产量, 纬度, 生长特性, 温光利用

CLC Number:

Chunmei XU, Lilun YUAN, Song CHEN, Guang CHU, Weifa YE, Yuhua DING, Danying WANG, Xiufu ZHANG. Difference in Growth Characteristics, Utilization of Temperature and Illumination of Double- Cropping High Quality Late Rice in Different Ecological Regions of the Lower Reaches of the Yangtze River[J]. Chinese Journal OF Rice Science, 2020, 34(5): 457-469.

徐春梅, 袁立伦, 陈松, 褚光, 叶为发, 丁玉华, 王丹英, 章秀福. 长江下游不同生态区双季优质晚稻生长特性和温光利用差异[J]. 中国水稻科学, 2020, 34(5): 457-469.

Figures/Tables 10

References 35

[1]	吴比, 胡伟, 邢永忠. 中国水稻遗传育种历程与展望[J]. 遗传, 2018, 40(10): 841-857.
	Wu B, Hu W, Xing Y Z.The history and prospect of rice genetic breeding in China[J]. Hereditas, 2018, 40(10): 841-857. (in Chinese with English abstract)
[2]	Wu J, Deng Q Y, Yuan D Y, Shaowu Q I.Progress of super hybrid rice research in China[J].Chinese Science Bulletin, 2016(35): 3787-3796.
[3]	方华舟, 项智锋. 水稻秸秆堆沤肥对优质水稻产量及质量的影响[J]. 中国土壤与肥料, 2019(1): 62-70.
	Fang H Z, Xiang Z F.Influence of rice straw wet compost on yield and quality of high quality rice[J]. China Soil and Fertilizer, 2019(1): 62-70. (in Chinese with English abstract)
[4]	程鸿燕, 韩渊怀. 大米食味品质的研究及其育种进展[J]. 山西农业大学学报: 自然科学版, 2016, 36(12): 800-896.
	Cheng H Y, Han Y H.Rice eating quality research and breeding progress[J]. Journal of Shanxi Agricultural University: Natural Science Edition, 2016, 36(12): 800-896. (in Chinese with English abstract)
[5]	王才林, 张亚东, 朱镇, 姚姝, 赵庆勇, 陈涛, 周丽慧, 赵凌. 优良食味粳稻新品种南粳9108的选育与利用[J]. 江苏农业科学, 2013, 41(9): 86-88
	Wang C L, Zhang Y D, Zhu Z, Yao S, Zhao Q Y, Chen T, Zhou L H, Zhao L.Breeding and utilization of high quality rice Nanjing 9108[J]. Jiangsu Agricultural Science, 2013, 41(9): 86-88. (in Chinese).
[6]	杨秉臻, 金涛, 陆建飞. 长江中下游地区近20年水稻生产与优势的变化[J]. 江苏农业科学, 2018, 46(19): 62-67.
	Yang B Z, Jin T, Lu J F.Changes of rice production and advantage in the middle and lower reaches of the Yangtze River in the past 20 years[J]. Jiangsu Agricultural Science, 2018, 46(19): 62-67. (in Chinese)
[7]	张军, 张洪程, 霍中洋, 李国业, 董啸波, 花劲, 郭保卫, 周培建, 程飞虎, 黄大山, 陈忠平, 陈国梁, 戴其根, 许轲, 魏海燕, 高辉. 不同栽培方式对双季晚粳稻产量及温光利用的影响[J]. 中国农业科学, 2013, 46(10): 2130-2141.
	Zhang J, Zhang H C, Huo Z Y, Li G Y, Dong X B, Hua X B, Hua J, Guo B W, Zhou P J, Cheng F H, Huang D S, Chen Z P, Chen G L, Dai Q G, Xu K, Wei H Y, Gao H.Effects of cultivation methods on yield and utilization of temperature and light of late Japonica rice in southern double cropping rice areas[J]. Scientia Agricultura Sinica, 2013, 46(10): 2130-2141. (in Chinese with English abstract)
[8]	胡香玉, 钟旭华, 彭碧琳, 黄农荣, 潘俊峰, 梁开明, 刘彦卓, 傅友强. 减氮条件下高产水稻品种的产量形成和氮素利用特征[J].核农学报, 2019, 33(12): 2460-2471.
	Hu X Y, Zhong X H, Peng B L, Huang N R, Pan J F, Liang K M, Liu Y Z, Fu Y Q.Yield formation and characteristics of nitrogen utilization in high-yielding rice varieties under reduced nitrogen input[J]. Journal of Nuclear Agricultural Sciences, 2019, 33(12): 2460-2471. (in Chinese with English abstract)
[9]	Wu L L, Shen Y, Huang L Y, Sun F, Zhu G L, Li G H, Fahad S, Peng S B, Wang F.Physiological mechanisms underlying the high-grain yield and high-nitrogen use efficiency of elite rice varieties under a low rate of nitrogen application in China[J]. Frontiers in Plant Science, 2016, 7: 1024.
[10]	李泽华, 马旭, 李秀昊, 陈林涛, 李宏伟, 袁志成. 水稻栽植机械化技术研究进展[J]. 农业机械学报, 2018, 5: 1-20.
	Li Z H, Ma X, Li X H, Chen L T, Li H W, Yuan Z C.Research progress of rice transplanting mechanization[J]. Agricultural Machinery, 2018, 5: 1-20. (in Chinese with English abstract)
[11]	蔡金平, 肖丽萍, 刘木华, 叶洋洋, 李涛斌, 陈雄飞. 水稻机械化移栽技术发展现状与展望[J]. 农机化研究, 2018, 10: 6-10.
	Cai J P, Xiao L P, Liu M H, Ye Y Y, Li T B, Chen X F.Design and simulation analysis on integrated tobacco stalk pulling and shredding machine[J]. Journal of Agricultural Mechanization Research, 2018, 10: 6-10. (in Chinese with English abstract)
[12]	龚金龙, 邢志鹏, 胡雅杰, 张洪程, 戴其根, 霍中洋, 许轲, 魏海燕, 高辉. 籼、粳超级稻光合物质生产与转运特征的差异[J]. 作物学报, 2014, 40(3): 497-510.
	Gong J L, Xing Z P, Hu Y J, Zhang H C, Dai Q G, Huo Z Y, Xu K, Wei H Y, Gao H.Difference of characteristics of photosynthesis, matter production and translocation between indica and japonica super rice[J]. Acta Agronomica Sinica, 2014, 40(3): 497-510. (in Chinese with English abstract)
[13]	魏金连, 潘晓华, 邓强辉. 不同生育阶段夜温升高对双季稻产量的影响[J]. 应用生态学报, 2010, 21(2): 331-337.
	Wei J L, Pan X H, Deng Q H.Effects of nighttime temperature increase at different growth stages on double season rice grain yield[J]. Chinese Journal of Applied Ecology, 2010, 21(2): 331-337. (in Chinese with English abstract)
[14]	邹应斌. 水稻品种生育期的研究: Ⅰ水稻品种生育期变化类型及其特点[J]. 湖南农学院报, 1983(3): 1-11.
	Zou Y B.A study on the growth stage of rice varieties-1: the types and characteristics of stage variation[J].Journal of Hunan Agricultural College, 1983(3): 1-11. (in Chinese with English abstract)
[15]	李秀芬, 贾燕, 黄元才, 臧鑫. 播栽期对水稻产量和产量构成因素及生育期的影响[J]. 生态学杂志, 2004, 23(5): 98-100.
	Li X F, Jia Y, Huang Y C, Zang X.Effects of seeding time on grain yield, yield components and growth duration in different rice varieties[J]. Chinese Journal of Ecology, 2004, 23(5): 98-100. (in Chinese with English abstract)
[16]	何瑞银, 罗汉亚, 李玉同, 汪小函, 张璐. 水稻不同种植方式的比较试验与评价[J]. 农业工程学报, 2008, 24(1): 167-171.
	He R Y, Luo H Y, Li Y T, Wang X H, Zhang L.Comparison and analysis of different rice planting methods in China[J]. Transactions of the CSAE, 2008, 24(1): 167-171. (in Chinese with English abstract)
[17]	张祖建, 张洪熙, 杨建昌, 宋云生, 赵步洪, 季红娟, 朱庆森. 江苏近50年粳稻安全齐穗期的变化[J]. 作物学报, 2011, 37(1): 146-151.
	Zhang Z J, Zhang H X, Yang J C, Song Y S, Zhao B H, Ji H J, Zhu Q S.Changes of safe dates for full heading in japonica rice over past 50 years in Jiangsu Province[J]. Acta Agronomica Sinica, 2011, 37(1): 146-151. (in Chinese with English abstract)
[18]	夏科. 粳稻不同类型品种产量烟花特点及高产特性特征研究[D]. 扬州: 扬州大学, 2007.
	Xia K.Rules of yield evolution and the characteristics of high yield in different types of japonica rice[D]. Yangzhou: Yangzhou University, 2007. (in Chinese with English abstract)
[19]	陈书涛, 王让会, 许遐祯, 项瑛, 陈海山. 气温及降水变化对江苏省典型农业区小麦、水稻生育期的影响[J].中国农业气象, 2011, 32(2): 235-239.
	Chen S T, Wang R H, Xu X Z, Xiang Y, Chen H S.Impacts of variations in air temperature and precipitation on the growth stages of winter and rice in typical agricultural zones of Jiangsu Province[J]. Chinese Journal of Agrometeorology, 2011, 32(2): 235-239. (in Chinese with English abstract)
[20]	郎有忠,窦永秀,王美娥,张祖建,朱庆森. 水稻生育期对籽粒产量及品质的影响[J]. 作物学报, 2012, 38(3): 528-534.
	Lang Y Z, Dou Y X, Wang M E, Zhang Z J, Zhu Q S.Effects of growth duration on grain yield and quality in rice (Oryza sativa L.)[J]. Acta Agronomica Sinica, 2012, 38(3): 528-534. (in Chinese with English abstract)
[21]	Barlow E W B, Boersma L, Young J L. Photosynthesis, transpiration, and leaf elongation in corn seedling at suboptimal soil temperature[J]. Agronomy Journal, 1977, 69(1): 95-100.
[22]	Baker D G, Sharratt B S, Chiang H C, Zandlo H A, Ruschy D L.Base temperature selection for the prediction of European corn borer instars by the growing degree day method[J]. Agricultural＆Forest Meteorology, 1984, 32(1): 55-58.
[23]	Islam M S, Morison J I L. Influence of solar radiation and temperature on irrigated rice grain yield in Bangladesh[J]. Field Crops Research, 1992, 30(1-2): 13-28.
[24]	Peng S, Huang J, Sheehy J E, Laza R C, Visperas R M, Zhong X, Centeno G S, K Hush G S, Cassman K G. Rice yield decline with higher night temperature from global warming[J]. Proceedings of the National Academy of Science of USA, 2004, 101: 9971-9997.
[25]	王夫玉, 张洪程, 赵新华, 段详茂, 丁艳锋, 黄丕生, 鲁光荣, 王根球. 温光对水稻籽粒充实度的影响[J]. 中国农业科学, 2001, 34(4): 396-402.
	Wang F Y, Zhang H C, Zhao X H, Duan X M, Ding Y F, Huang P S, Lu G R, Wang G Q.Study on the effects of temperature and illumination on grade of filled grain in rice[J]. Scientia Agricultura Sinica, 2001, 34(4): 396-402. (in Chinese with English abstract)
[26]	童平, 杨世民, 马均, 吴合洲, 傅泰露, 李敏, 王明田. 不同水稻品种在不同光照条件下的光合特性及干物质积累[J]. 应用生态学报, 2008, 19(3): 505-511.
	Tong P, Yang S M, Ma J, Wu H Z, Fu T L, Li M, Wang M T.Photosynthetic characteristics and dry matter accumulation of hybrid rice varieties under different light conditions[J]. Chinese Journal of Applied Ecology, 2008, 19(3): 505-511. (in Chinese with English abstract)
[27]	张洪程, 许轲, 张军, 李国业, 董啸波, 花劲, 周培健, 程飞虎, 黄大山, 陈忠平, 陈国梁, 方明珍, 戴其根, 霍中洋, 魏海燕, 高辉. 双季晚粳稻生产力及相关生态生理特征[J]. 作物学报, 2014, 40(2): 283-300.
	Zhang H C, Xu K, Zhang J, Li G Y, Dong X B, Hua J, Zhou P J, Chen F H, Huang D S, Chen Z P, Cheng G L, Fang M Z, Dai Q G, Huo Z Y, Wei H Y, Gao H.Productivity and eco-physiological characteristics of late japonica rice in double-cropping system[J]. Acta Agronomica Sinica, 2014, 40(2): 283-300. (in Chinese with English abstract)
[28]	曾勇军, 石庆华, 潘晓华, 韩涛. 长江中下游双季稻高产株型特征初步研究[J]. 作物学报, 2009, 35(3): 546-551.
	Zeng Y J, Shi Q H, Pan X H, Han T.Preliminary study on the plant type characteristics of double cropping rice in middle and lower reaches of Changjiang River[J]. Acta Agronomica Sinica, 2009, 35(3): 546-551.(in Chinese with English abstract)
[29]	Deng F, Wang L, Ren W J, Mei X F, Li S X.Optimized nitrogen managements and polyaspartic acid urea improved dry matter production and yield of indica hybrid rice[J]. Soil Tillage Research, 2015, 145: 1-9.
[30]	吴文革, 周永进, 张健美, 陈刚, 许有尊, 李胜群, 左庆, 叶为发, 余友玲, 杨成林, 孙雪原. 杂交中籼稻钵苗机插群体特征及产量形成优势分析[J]. 核农学报, 2016, 30(7): 1427-1434.
	Wu W G, Zhou Y J, Zhang J M, Chen G, Xu Y Z, Li S Q, Zuo Q, Ye W F, Yu Y L, Yang C L, Sun X Y.Analysis on population characteristics and yield formation advantages of pot-seedling mechanical transplanting middle-season indica hybrid rice[J]. Journal of Nuclear Agricultural Sciences, 2016, 30(7): 1427-1434. (in Chinese with English abstract)
[31]	刘桃菊, 殷新佑, 戚昌瀚, 唐建军, 陈美球. 气候变化与水稻生长发育及产量形成关系的模拟研究[J]. 应用生态学报, 2005, 16(3): 486-490.
	Liu T J, Yin X Y, Qi C H, Tang J J, Chen M Q.Relationships between climate change and rice development and its yield formation: A simulation study[J]. Chinese Journal of Applied Ecology, 2005, 16(3): 486-490. (in Chinese with English abstract)
[32]	岳伟, 陈金华, 阮新民, 陈曦, 陈砚涛, 王珍. 安徽省沿江地区双季稻光热资源利用效率变化特征及对气象产量的影响[J]. 中国生态农业学报, 2019, 27(6): 929-940.
	Yue W, Chen J H, Ruan X M, Chen X, Chen Y T, Wang Z.Variation in characteristics of light and heat resource utilization efficiency of double-season rice and its impact on meteorological yield along the Yangtze River in Anhui Province[J]. Chinese Journal of Eco-Agriculture, 2019, 27(6): 929-940. (in Chinese with English abstract)
[33]	陈波, 周年兵, 郭保卫, 舒鹏, 张洪程, 霍中洋, 程飞虎, 花劲, 黄大山, 陈忠平, 陈恒, 刘云发, 廖世亮. 江西双季晚稻不同纬度产量、生育期及温光资源利用的差异[J]. 中国农业科学, 2017, 50(8): 1403-1415.
	Chen B, Zhou N B, Guo B W, Shu P, Zhang H C, Huo Z Y, Cheng F H, Hua J, Huang D S, Chen Z P, Chen H, Liu Y F, Liao S L.Differences of double-crossing late rice in yield, growth stage and utilization of temperature and illumination in different latitudes of Jiangxi Province[J]. Scientia Agricultura Sinica, 2017, 50(8): 1403-1415. (in Chinese with English abstract)
[34]	李杰, 张洪程, 董洋阳, 倪晓诚, 杨波, 龚金龙, 常勇, 戴其根, 霍中洋, 许轲, 魏海燕. 不同生态区栽培方式对水稻产量、生育期及温光利用的影响[J]. 中国农业科学, 2011, 44(13): 2661-2672.
	Li J, Zhang H C, Dong Y Y, Ni X C,Yang B, Gong J L, Chang Y, Dai Q G, Huo Z Y, Xu K, Wei H Y.Effects of cultivation methods on yield, growth stage and utilization of temperature and illumination of rice in different ecological regions[J]. Scientia Agricultura Sinica, 2011, 44(13): 2661-2672. (in Chinese with English abstract)
[35]	Nagarajan S, Jagadish S V K, Hari Prasad A S, Thomar A K, Anand A, Pal M, Agarwal P K. Local climate affects growth, yield and grain quality of aromatic and non-aromatic rice in northwestern India[J]. Agriculture, Ecosystems and Environment, 2010, 138: 274-281.

变异来源 Source of variation	自由度 df	平方和 Sum of square	均方 Mean square	F值 F-value	F_0.05	F_0.01
年份Year	1	0.26	0.26	4.05 ns	4.17	7.56
纬度 Latitude	1	6.95	6.95	378.16**	4.17	7.56
类型 Type	3	25.39	8.64	460.52**	2.92	4.51
年份×纬度Year × Latitude	1	0.04	0.04	1.07 ns	4.17	7.56
年份×类型Year × Type	3	0.12	0.04	1.07 ns	2.92	4.51
纬度×类型 Latitude × Type	3	0.95	0.32	17.17**	2.92	4.51
年份×纬度×类型Year × Latitude ×Type	3	0.08	0.03	1.40 ns	2.92	4.51
误差 Error	15	0.55	0.02
总变异 Total	47	34.54

变异来源 Source of variation	自由度 df	平方和 Sum of square	均方 Mean square	F值 F-value	F_0.05	F_0.01
年份Year	1	0.26	0.26	4.05 ns	4.17	7.56
纬度 Latitude	1	6.95	6.95	378.16**	4.17	7.56
类型 Type	3	25.39	8.64	460.52**	2.92	4.51
年份×纬度Year × Latitude	1	0.04	0.04	1.07 ns	4.17	7.56
年份×类型Year × Type	3	0.12	0.04	1.07 ns	2.92	4.51
纬度×类型 Latitude × Type	3	0.95	0.32	17.17**	2.92	4.51
年份×纬度×类型Year × Latitude ×Type	3	0.08	0.03	1.40 ns	2.92	4.51
误差 Error	15	0.55	0.02
总变异 Total	47	34.54

品种类型 Type of variety	试验地 Site	纬度 Latitude /°	有效穗数 Effective panicle number/(×10⁴·hm^-2)	每穗粒数 Spikelet number per panicle	总颖花量 Total number of spikelets /(×10⁴·hm^-2)	结实率 Filled-grain percentage/%	千粒重 1000-grain weight/g	实际产量 Actual yield /(t·hm^-2)
杂交籼稻 IHR	安徽庐江 Lujiang, Anhui Province	31.15	384.79 a	124.51 b	4.78 a	82.35 a	24.91 a	9.00 a
	浙江富阳 Fuyang, Zhejiang Province	30.05	334.17 b	148.22 a	4.89 a	82.32 a	23.97 a	8.44 b
常规籼稻 ICR	安徽庐江 Lujiang, Anhui Province	31.15	351.92 a	114.38 b	4.05 a	80.99 a	26.96 a	7.90 a
	浙江富阳 Fuyang, Zhejiang Province	30.05	297.08 b	129.25 a	3.81 a	80.48 a	25.70 b	7.11 b
常优杂粳 CYJHR	安徽庐江 Lujiang, Anhui Province	31.15	390.37 a	127.80 b	4.99 a	74.68 a	27.32 a	9.79 a
	浙江富阳 Fuyang, Zhejiang Province	30.05	290.32 b	144.63 a	4.20 a	80.92 a	27.18 a	8.67 b
常规粳稻 JCR	安徽庐江 Lujiang, Anhui Province	31.15	419.23 a	109.87 b	4.56 a	82.79 a	27.08 a	9.59 a
	浙江富阳 Fuyang, Zhejiang Province	30.05	319.47 b	124.27 a	3.97 b	87.25 a	27.39 a	8.53 b

品种类型 Type of variety	试验地 Site	纬度 Latitude /°	有效穗数 Effective panicle number/(×10⁴·hm^-2)	每穗粒数 Spikelet number per panicle	总颖花量 Total number of spikelets /(×10⁴·hm^-2)	结实率 Filled-grain percentage/%	千粒重 1000-grain weight/g	实际产量 Actual yield /(t·hm^-2)
杂交籼稻 IHR	安徽庐江 Lujiang, Anhui Province	31.15	384.79 a	124.51 b	4.78 a	82.35 a	24.91 a	9.00 a
	浙江富阳 Fuyang, Zhejiang Province	30.05	334.17 b	148.22 a	4.89 a	82.32 a	23.97 a	8.44 b
常规籼稻 ICR	安徽庐江 Lujiang, Anhui Province	31.15	351.92 a	114.38 b	4.05 a	80.99 a	26.96 a	7.90 a
	浙江富阳 Fuyang, Zhejiang Province	30.05	297.08 b	129.25 a	3.81 a	80.48 a	25.70 b	7.11 b
常优杂粳 CYJHR	安徽庐江 Lujiang, Anhui Province	31.15	390.37 a	127.80 b	4.99 a	74.68 a	27.32 a	9.79 a
	浙江富阳 Fuyang, Zhejiang Province	30.05	290.32 b	144.63 a	4.20 a	80.92 a	27.18 a	8.67 b
常规粳稻 JCR	安徽庐江 Lujiang, Anhui Province	31.15	419.23 a	109.87 b	4.56 a	82.79 a	27.08 a	9.59 a
	浙江富阳 Fuyang, Zhejiang Province	30.05	319.47 b	124.27 a	3.97 b	87.25 a	27.39 a	8.53 b

品种类型 Type of variety	试验地 Site	纬度 Latitude /°	播种期 S (Month-Day)	移栽期 T (Month-Day)	齐穗期 H (Month-Day)	成熟期 M (Month-Day)	播种-齐穗期天数 S-H/d	齐穗-成熟期天数 H-M/d	全生育期天数 Growth duration/d
杂交籼稻 IHR	安徽庐江 Lujiang, Anhui Province	31.15	06-26	07-15	09-02–9-14 (09-09)	10-16–10-30 (10-25)	75.2 a	46.5 a	121.7 a
杂交籼稻 IHR	浙江富阳 Fuyang, Zhejiang Province	30.05	06-27	07-19	09-01–9-14 (09-08)	10-4–10-26 (10-18)	73.5 a	39.8 b	113.3 b
常规籼稻 ICR	安徽庐江 Lujiang, Anhui Province	31.15	06-26	07-15	09-06–9-12 (09-09)	10-16–11-5 (10-28)	75.7 a	48.5 a	124.2 a
常规籼稻 ICR	浙江富阳 Fuyang, Zhejiang Province	30.05	06-27	07-19	09-06–9-15 (09-12)	10-10–10-26 (10-18)	77.3 a	36.5 b	113.8 b
常优杂粳 CYJHR	安徽庐江 Lujiang, Anhui Province	31.15	06-26	07-15	09-15–9-20 (09-17)	11-9–11-15 (11-12)	83.5 a	55.5 b	139.0 a
常优杂粳 CYJHR	浙江富阳 Fuyang, Zhejiang Province	30.05	06-27	07-19	09-10–9-12 (09-11)	11-2–11-13 (11-7)	76.0 b	57.5 a	133.5 b
常规粳稻 JCR	安徽庐江 Lujiang, Anhui Province	31.15	06-26	07-15	09-09–9-21 (09-15)	10-24–11-13 (11-6)	81.8 a	51.2 b	133.0 a
常规粳稻 JCR	浙江富阳 Fuyang, Zhejiang Province	30.05	06-27	07-19	09-06–9-12 (09-10)	10-22–11-3 (11-3)	75.0 b	54.5 a	129.5 b