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| 双低两用核不育水稻96-5-2S冷水灌溉繁殖技术研究 | |
| 引用本文: | 徐孟亮,梁满中,刘贵权,陈良碧,周广洽,周观祥,邱秀兰,黄四齐.双低两用核不育水稻96-5-2S冷水灌溉繁殖技术研究[J].应用生态学报,2003,14(8):1305-1308. |
| 作者姓名: | 徐孟亮 梁满中 刘贵权 陈良碧 周广洽 周观祥 邱秀兰 黄四齐 |
| 作者单位: | 1. 湖南师范大学生命科学学院,长沙,410081 2. 湖南省郴州市种子公司,郴州,423000 3. 湖南省郴州市农业局,郴州,423000 |
| 基金项目: | 国家自然科学基金 ( 39370 0 78),教育部高校骨干教师 ( 2 50 0 0 117),湖南省生命科学联合研究中心( 2 5990 2 2 5),湖南省教育厅和湖南省两系办资助项目 |
| 摘 要: | 为解决临界温度双低两用核不育水稻96—5—2S繁殖困难的问题,利用地下水对其进行了冷水灌溉繁殖试验.结果表明,用不同温度的冷水从其雌雄蕊形成期(Ⅳ)至花粉内容物充实期(Ⅶ)连续灌溉15d。水深保持在18~22cm,其结实率与产量随灌溉水温升高而降低.当平均灌溉水温为18.5~19.8℃时。结实率可达40.5%~57.6%。产量可达3.30~4.35t·hm^-2;当平均灌溉水温为20.5~21.3℃时,结实率与产量锐减,分别为2.5%~10.4%与0.21~0.90t·hm^-2;当平均灌溉水温为22.3~23.5℃时。结实率与产量均为0.当灌溉水温(平均为19.8℃)与灌溉时期(Ⅳ~Ⅶ期)相同时,昼夜深灌(18~22cm)处理的结实率与产量极显著高于其昼夜浅灌(7~10cm)处理.当灌溉水温(平均为19.8℃)与灌溉水深(18~22cm)相同时,灌溉时间长(Ⅱ、Ⅲ~Ⅶ期,20~25d)、短(Ⅳ~Ⅶ期,15d)处理的结实率与产量无明显差异.用地下冷水灌溉可以繁殖临界温度双低两用核不育水稻96—5—2S。主要技术指标是灌溉水温18~20℃,灌溉时期为Ⅳ~Ⅶ期。灌溉水深为18~22cm. |
| 关 键 词: | 冷水灌溉 繁殖 双低两用核不育水稻 临界温度 地下水 |
| 文章编号: | 1001-9332(2003)08-1305-04 |
| 修稿时间: | 2001年5月29日 |
Multiplication technique of rice T(P)GMS line with double low critical temperature values using cold water irrigation |
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| XU Mengliang ,LIANG Manzhong ,LIU Guiquan ,CHEN Liangbi ,ZHOU Guangqia ,ZHOU Guanxiang ,QIU Xiulan ,HUANG Shiqi.Multiplication technique of rice T(P)GMS line with double low critical temperature values using cold water irrigation[J].Chinese Journal of Applied Ecology,2003,14(8):1305-1308. | |
| Authors: | XU Mengliang LIANG Manzhong LIU Guiquan CHEN Liangbi ZHOU Guangqia ZHOU Guanxiang QIU Xiulan HUANG Shiqi |
| Institution: | Life Science College, Hunan Normal University, Changsha 410081, China. xumengliang@263.net |
| Abstract: | In this paper, cold-water irrigation multiplication technique was used to solve the difficulty of multiplying rice TGMS line 96-5-2S(Oryza sative L.) with double low critical temperature values under natural air temperature condition. The results indicated that irrigating rice TGMS line 96-5-2S with different temperature underground cold water from the stage of pistil and stamen primordia differentiation to the stage of pollen filling for 15 days, and keeping the water depth 18-22 cm, the seed set rate of 96-5-2S decreased with increasing irrigating water temperature. When the average temperature of irrigation water was 18.5-19.8 degrees C, the seed set rate ranged from 40.5% to 57.6%, and the yield ranged from 3.30 t.hm-2 to 4.35 t.hm-2. While the temperature was 20.5-21.3 degrees C, the seed set rate and yield sharply decreased to 2.5-10.4% and 0.21-0.90 t.hm-2, respectively. When the average temperature was 22.3-23.5 degrees C, both the seed set rate and yield were zero. Under the same irrigation water temperature (average 19.8 degrees C) and the same irrigating period (phase IV to phase VII), the seed set rate and yield of 96-5-2S with deep water irrigation (18-22 cm) was very significantly higher than those of 96-5-2S with shallow water irrigation (7-10 cm). Under the conditions of same irrigation water temperature (average 19.8 degrees C) and same water depth (18-22 cm) but different irrigating periods (15 days from phase IV to phase VII, 20 days from phase III to phase VII, and 25 days from phase II to phase VII), the difference of seed set rate and yield of 96-5-2S between 15-day treatment and 20-25-day treatment was not significantly different. It is confident that 96-5-2S could multiply with underground cold water irrigation. The main technique index was that irrigating water temperature should be 18-20 degrees C, irrigating period should be from phase IV to phase VII, and irrigating water depth should be 18-22 cm. |
| Keywords: | Cold water irrigation Multiplication Rice T(P)GMS line with double low critical temperature values Critical temperature Underground water |
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