密度与氮素对夏播棉氮素吸收利用的影响

doi:10.3724/SP.J.1006.2024.34123

作物学报 ›› 2024, Vol. 50 ›› Issue (6): 1584-1596.doi: 10.3724/SP.J.1006.2024.34123

密度与氮素对夏播棉氮素吸收利用的影响

徐泽(), 吴莘玲, 刘震宇, 李涵佳, 冷鑫华, 吴天凡, 陈媛, 张祥, 陈德华^*()

扬州大学江苏省作物遗传生理国家重点实验室培育点 / 粮食作物现代产业技术协同创新中心, 江苏扬州 225009

收稿日期:2023-07-14 接受日期:2024-01-12 出版日期:2024-06-12 网络出版日期:2024-02-20
通讯作者: * 陈德华, E-mail: cdh@yzu.edu.cn
作者简介:E-mail: 544252305@qq.com
基金资助:
国家重点研发计划项目(2018YFD0100400);国家重点研发计划项目(2017YFD0201300)

Effects of planting density with nitrogen rate on regulation of nitrogen utilization in summer direct seeded cotton

XU Ze(), WU Xin-Ling, LIU Zhen-Yu, LI Han-Jia, LENG Xin-Hua, WU Tian-Fan, CHEN Yuan, ZHANG Xiang, CHEN De-Hua^*()

Jiangsu Key Laboratory of Crop Genetics and Physiology / Co-innovation Center for Modern Production Technology of Grain Crops, Yangzhou University, Yangzhou 225009, Jiangsu, China

Received:2023-07-14 Accepted:2024-01-12 Published:2024-06-12 Published online:2024-02-20
Contact: * E-mail: cdh@yzu.edu.cn
Supported by:
National Key Research and Development Program of China(2018YFD0100400);National Key Research and Development Program of China(2017YFD0201300)

摘要/Abstract

摘要：

为明确密度氮素对夏播棉氮素吸收利用的影响, 2019—2020年于扬州大学遗传生理重点实验室以特早熟品种中棉所425为材料, 2019年采用裂区设计, 以密度为主处理, 设60,000株 hm^-2、90,000株 hm^-2、120,000株 hm^-23个水平, 以施氮量为副区, 设施纯氮0 kg hm^-2、90 kg hm^-2、150 kg hm^-2、210 kg hm^-24个水平; 2020年采用单因素随机区组设计, 设置生产对照CK (90,000株 hm^-2; 180 kg hm^-2氮素), 在120,000株 hm^-2密度下, 设施纯氮0 kg hm^-2、90 kg hm^-2、150 kg hm^-2、210 kg hm^-24个水平, 研究密度与氮素处理对此种植方式下产量及其构成以及氮素吸收利用的影响。结果表明, 在120,000株 hm^-2密度下配合施氮150 kg hm^-2夏播棉籽棉产量显著提高, 达4147.8~5119.2 kg hm^-2; 生殖器官干物重达2605.6~2863.6 kg hm^-2且占比达50%以上; 生殖器官氮素积累量显著增加, 达45.97~60.70 kg hm^-2; 氮素利用率显著提高, 氮肥回收利用率达42.58%~44.17%, 氮肥农学利用率达7.16~21.34 kg (kg N)^-1, 氮素生理利用率达19.16~24.03 kg (kg N)^-1, 氮肥偏生产力达21.12~34.13 kg (kg N)^-1, 回归分析进一步表明氮肥回收利用率、氮肥农学利用率、氮素生理利用率与产量呈显著以上水平线性正相关; 喷施脱叶催熟剂前吐絮率达43.59%~60.76%, 喷施脱叶催熟剂后可达到正常吐絮的要求。因此, 高密中氮配合有利于夏播棉氮素的吸收利用, 可为棉花高产高效和减氮提供技术支撑。

关键词: 夏播棉, 密度, 氮素, 氮素利用率

Abstract:

In order to clarify the effects of planting density with nitrogen rate on regulation of nitrogen utilization in summer direct seeded cotton, the CCRI 425 were used as the experimental materials in the Key Laboratory of Genetics and Physiology of Yangzhou University in 2019 and 2020. Density were used as the main treatments in 2019 and three levels of density of 60,000 plants hm^-2, 90,000 plants hm^-2, and 120,000 plants hm^-2 were set. Nitrogen application rate as the secondary treatments and four levels of convention nitrogen application rate (0 kg hm^-2, 90 kg hm^-2, 150 kg hm^-2, and 210 kg hm^-2) were conducted. Production application (90,000 plants hm^-2, 180 kg hm^-2nitrogen application rate) was used as the CK. Under the density of 120,000 plants hm^-2, there were four levels of convention nitrogen application rate (0 kg hm^-2, 90 kg hm^-2, 150 kg hm^-2, and 210 kg hm^-2). The results showed that cotton seed yield was increased, reaching 4147.8-5119.2 kg hm^-2, at the density of 12×10⁴ plants hm^-2 with nitrogen application of 150 kg hm^-2. The dry matter of reproductive organs was 2605.6-2863.6 kg hm^-2 and accounted for over 50% of the total dry matter weight. Nitrogen accumulation in reproductive organs was significantly increased, reaching 45.97-60.70 kg hm^-2. Nitrogen use efficiency was significantly increased, nitrogen recovery efficiency (NRE) was 42.58%-44.17%, agronomic nitrogen use efficiency (aNUE) was 7.16-21.34 kg (kg N)^-1, physiological nitrogen use efficiency (pNUE) was 19.16-24.03 kg (kg N)^-1, partial productivity of nitrogen fertilizer (NPP) was 21.12-34.13 kg (kg N)^-1. Regression analysis further showed that nitrogen recovery efficiency, nitrogen agronomic efficiency, nitrogen physiological efficiency, and physiological efficiency were linearly positively correlated with yield. The percentage of open bolls reached 43.59%-60.76% before spraying defoliation and ripening agent and the normal flocculation rate could be achieved after spraying defoliation and ripening agent. Therefore, high-density with medium nitrogen rate is beneficial to nitrogen absorption and utilization, which provides the technical support for high yield, high efficient production, and nitrogen reduction in cotton.

Key words: summer direct seeded cotton, planting density, nitrogen, nitrogen utilization rate

徐泽, 吴莘玲, 刘震宇, 李涵佳, 冷鑫华, 吴天凡, 陈媛, 张祥, 陈德华. 密度与氮素对夏播棉氮素吸收利用的影响[J]. 作物学报, 2024, 50(6): 1584-1596.

XU Ze, WU Xin-Ling, LIU Zhen-Yu, LI Han-Jia, LENG Xin-Hua, WU Tian-Fan, CHEN Yuan, ZHANG Xiang, CHEN De-Hua. Effects of planting density with nitrogen rate on regulation of nitrogen utilization in summer direct seeded cotton[J]. Acta Agronomica Sinica, 2024, 50(6): 1584-1596.

图/表 15

表1

表2

图1

表3

表4

表5

表6

图2

表7

表8

图3

表9

表10

表11

表12

参考文献 31

[1]	汪宏伟. 我国棉花产业现状及长江流域棉区转型升级的思考. 棉花科学, 2019, 41(3): 2-5.
	Wang H W. The current situation of China’s cotton industry and reflections on the transformation and upgrading of cotton areas in the Yangtze River Basin. Cotton Sci, 2019, 41(3): 2-5. (in Chinese with English abstract)
[2]	Luo Z, Liu H, Li W P, Zhao Q, Dai J L, Tian L W, Dong H Z. Effects of reduced nitrogen rate on cotton yield and nitrogen use efficiency as mediated by application mode or plant density. Field Crops Res, 2018, 218: 150-157.
[3]	王雷山. 播期和密度对夏直播棉花氮代谢的影响. 华中农业大学硕士学位论文,湖北武汉, 2016.
	Wang L S. Effect of Sowing Date and Planting Density on Nitrogen Metabolism of Cotton under Summer Direct Sowing. MS Thesis of Huazhong Agricultural University, Wuhan, Hubei, China, 2016. (in Chinese with English abstract)
[4]	姬攀攀, 李洪菊, 罗冬玉, 侯玲, 罗艳萍, 杨芳, 王富, 吴吉平, 周家华. 种植密度对夏直播棉花生长及产量的影响. 湖北农业科学, 2019, 58(12): 31-33.
	Ji P P, Li H J, Luo D Y, Hou L, Luo Y P, Yang F, Wang F, Wu J P, Zhou J H. Effects of planting density on growth and yield of summer direct-seeding cotton. Hubei Agric Sci, 2019, 58(12): 31-33. (in Chinese with English abstract)
[5]	Dai J L, Li W J, Tang W, Zhang D M, Li Z H, Lu H Q, Egrinya E A, Dong H Z. Manipulation of dry matter accumulation and partitioning with plant density in relation to yield stability of cotton under intensive management. Field Crops Res, 2015, 180: 207-215.
[6]	王子胜, 吴晓东, 郭文琦, 徐敏, 那艳斌, 张雷, 周治国. 种植密度对东北特早熟棉区棉花生物量和氮素累积的影响. 棉花学报, 2012, 24: 35-43. doi: 10.11963/cs120105
	Wang Z S, Wu X D, Guo W Q, Xu M, Na Y B, Zhang L, Zhou Z G. Effects of planting density on biomass and nitrogen accumulation in cotton, northeast China. Cotton Sci, 2012, 24: 35-43. (in Chinese with English abstract)
[7]	娄善伟, 高云光, 郭仁松, 赵强, 张巨松. 不同栽培密度对棉花植株养分特征及产量的影响. 植物营养与肥料学报, 2010, 16: 953-958.
	Lou S W, Gao Y G, Guo R S, Zhao Q, Zhang J S. Effects of planting density on nutrition characteristics and yield of cotton. Plant Nutr Fert Sci, 2010, 16: 953-958. (in Chinese with English abstract)
[8]	李鹏程, 董合林, 刘爱忠, 刘敬然, 李如义, 孙淼, 李亚兵, 毛树春. 应用¹⁵N研究氮肥运筹对棉花氮素吸收利用及产量的影响. 植物营养与肥料学报, 2015, 21: 590-599.
	Li P C, Dong H L, Liu A Z, Liu J R, Li R Y, Sun M, Li Y B, Mao S C. Effects of nitrogen fertilizer application strategy on N uptake, utilization and yield of cotton using ¹⁵N trace technique. J Plant Nutr Fert, 2015, 21: 590-599. (in Chinese with English abstract)
[9]	Fu Q L, Yu J Y, Chen Y X. Effect of nitrogen applications on dry matter and nitrogen partitioning in rice and nitrogen fertilizer requirements for rice production. J Zhejiang Univ, 2000, 26: 399-403.
[10]	王士红, 杨中旭, 史加亮, 李海涛, 宋宪亮, 孙学振. 增密减氮对棉花干物质和氮素积累分配及产量的影响. 作物学报, 2020, 46: 395-407. doi: 10.3724/SP.J.1006.2020.94074
	Wang S H, Yang Z X, Shi J L, Li H T, Song X L, Sun X Z. Effects of increasing planting density and decreasing nitrogen rate on dry matter, nitrogen accumulation and distribution, and yield of cotton. Acta Agron Sin, 2020, 46: 395-407. (in Chinese with English abstract) doi: 10.3724/SP.J.1006.2020.94074
[11]	张田野. 化肥零增长行动实施效果及问题研究. 中国农业科学院硕士学位论文,北京, 2021.
	Zhang T Y. Study on the Effect and Problems of Zero Growth Action of Chemical Fertilizer. MS Thesis of Chinese Academy of Agricultural Sciences, Beijing, China, 2021. (in Chinese with English abstract)
[12]	朱倩倩, 武雪萍, 张淑香, 许咏梅, 吉丽丽, 赵来明, 李小伟, 马文新. 化肥减量有机替代对新疆滴灌棉花产量及土壤养分的影响. 新疆农业科学, 2020, 57: 2135-2143. doi: 10.6048/j.issn.1001-4330.2020.11.022
	Zhu Q Q, Wu X P, Zhang S X, Xu Y M, Ji L L, Zhao L M, Li X W, Ma W X. Effects of reducing chemical fertilizer and organic fertilizer supplement on the yield and soil nutrient of drip irrigation cotton in Xinjiang. Xinjiang Agric Sci, 2020, 57: 2135-2143. (in Chinese with English abstract)
[13]	唐江华, 苏丽丽, 徐文修, 孟令贻, 王晨, 田文强, 张俊尧, 王家勇. 氮肥减施对棉花产量、干物质生产与氮素吸收利用的影响. 干旱地区农业研究, 2023, 41(2): 86-95.
	Tang J H, Su L L, Xu W X, Meng L Y, Wang C, Tian W Q, Zhang J Y, Wang J Y. Effects of nitrogen fertilizer reduction on cotton yield, dry matter production and nitrogen uptake and utilization. Agric Res Arid Areas, 2023, 41(2): 86-95. (in Chinese with English abstract)
[14]	Zhang D M, Li W J, Xin C S, Tang W, Egrinya E A, Dong H Z. Lint yield and nitrogen use efficiency of field-grown cotton vary with soil salinity and nitrogen application rate. Field Crops Res, 2012, 138: 63-70.
[15]	张允昔, 陈宜, 崔爱花, 夏绍南, 杨磊, 鲁速明, 董合林. 不同施氮量对棉花产量和氮肥利用率的影响. 江西农业大学学报, 2014, 36: 1202-1206.
	Zhang Y X, Chen Y, Cui A H, Xia S N, Yang L, Lu S M, Dong H L. The effects of different nitrogen application rates on cotton yield and nitrogen use efficiency. Acta Agric Univ Jiangxiensis, 2014, 36: 1202-1206. (in Chinese with English abstract)
[16]	宋兴虎. 氮肥用量对夏直播棉花产量形成和养分利用的影响. 华中农业大学硕士学位论文,湖北武汉, 2017.
	Song X H. Effect of N Rate on Yield Formation and Nutrients Utilization of Summer Direct Seeding Cotton. MS Thesis of Huazhong Agricultural University, Wuhan, Hubei, China, 2017. (in Chinese with English abstract)
[17]	刘佳敏, 汪洋, 褚旭, 齐欣, 王慢慢, 赵亚南, 叶优良, 黄玉芳. 种植密度和施氮量对小麦-玉米轮作体系下周年产量及氮肥利用率的影响. 作物杂志, 2021, (1): 143-149.
	Liu J M, Wang Y, Chu X, Qi X, Wang M M, Zhao Y N, Ye Y L, Huang Y F. Effects of planting density and nitrogen application rate on annual yield and nitrogen use efficiency of wheat-maize rotation system. Crops, 2021, (1): 143-149. (in Chinese with English abstract)
[18]	薛晓萍, 王建国, 郭文琦, 陈兵林, 尤军, 周治国. 氮素水平对初花后棉株生物量、氮素累积特征及氮素利用率动态变化的影响. 生态学报, 2006, 26: 3631-3640.
	Xue X P, Wang J G, Guo W Q, Chen B L, You J, Zhou Z G. Effect of nitrogen applied levels on the dynamics of biomass, nitrogen accumulation and nitrogen fertilization recovery rate of cotton after initial flowering. Acta Ecol Sin, 2006, 26: 3631-3640. (in Chinese with English abstract)
[19]	谭京红, 张露萍, 吴启侠, 朱建强, 张在镇. 基于不同肥源的棉花减氮施肥效果比较研究. 作物杂志, 2019, (1): 134-140.
	Tan J H, Zhang L P, Wu Q X, Zhu J Q, Zhang Z Z. Comparative research on the effects of reducing nitrogen from different fertilizers on cotton. Crops, 2019, (1): 134-140. (in Chinese with English abstract)
[20]	王士红. 增密减氮对棉花产量品质的影响及氮高效生理基础研究. 山东农业大学博士学位论文,山东泰安, 2019.
	Wang S H. Effects of Increasing Plant Density and Decreasing Nitrogen Rate on Yield and Quality of Cotton, and Physiological Mechanisms of Nitrogen Efficient Utilization. PhD Dissertation of Shandong Agricultural University, Tai’an, Shandong, China, 2019. (in Chinese with English abstract)
[21]	刘瑞显, 史伟, 徐立华, 杨长琴, 郭文琦, 张培通. 种植密度对棉花干物质、氮素累积与分配的影响. 江苏农业学报, 2011, 27: 250-257.
	Liu R X, Shi W, Xu L H, Yang C Q, Guo W Q, Zhang P T. Effects of planting density on dry matter and nitrogen accumulation and distribution of cotton. Jiangsu J Agric Sci, 2011, 27: 250-257. (in Chinese with English abstract)
[22]	刘瑞显, 史伟, 徐立华, 杨长琴, 郭文琦, 张培通. 长江下游棉区抗虫杂交棉适宜密度研究. 棉花学报, 2010, 22: 634-638. doi: 10.11963/cs100620
	Liu R X, Shi W, Xu L H, Yang C Q, Guo W Q, Zhang P T. Planting density of insect-resistant hybrid cotton in lower reaches of Yangtze River Valley. Cotton Sci, 2010, 22: 634-638. (in Chinese with English abstract)
[23]	支晓宇, 毛树春, 韩迎春, 李亚兵, 杜文丽, 李小新, 王国平, 范正义, 杨北方, 冯璐. 密度对棉花产量及棉铃内部产量构成的影响. 棉花学报, 2015, 27: 216-222. doi: 10.11963/issn.1002-7807.201503004
	Zhi X Y, Mao S C, Han Y C, Li Y B, Du W L, Li X X, Wang G P, Fan Z Y, Yang B F, Feng L. Effects of cultivars and planting density on yield components and seed characteristics in cotton. Cotton Sci, 2015, 27: 216-222. (in Chinese with English abstract) doi: 10.11963/issn.1002-7807.201503004
[24]	董合林, 李鹏程, 刘爱忠, 王润珍. 华北平原一熟春棉干物质积累与养分吸收特性. 中国棉花, 2012, 39(12): 19-22. doi: 10.11963/issn.1000-632X.20121206
	Dong H L, Li P C, Liu A Z, Wang R Z. Characteristics of dry matter accumulation and nutrients uptake of spring-sown cotton under sole cropping in the north China Plain. China Cotton, 2012, 39(12): 19-22. (in Chinese with English abstract)
[25]	郑剑超, 闫曼曼, 张巨松, 高丽丽, 石洪亮, 郑慧, 张玉玲. 遮荫条件下氮肥运筹对棉花生长和氮素积累的影响. 植物营养与肥料学报, 2016, 22: 94-103.
	Zheng J C, Yan M M, Zhang J S, Gao L L, Shi H L, Zheng H, Zhang Y L. Effects of nitrogen application on growth and nitrogen accumulation of cotton under shading condition. Plant Nutr Fert Sci, 2016, 22: 94-103. (in Chinese with English abstract)
[26]	Chen W P, Hou Z N, Wu L S, Liang Y C, Wei C Z. Effects of salinity and nitrogen on cotton growth in arid environment. Plant Soil, 2010, 326: 61-73.
[27]	陈广桂, 韦林洪. 我国化肥产业氮磷污染及防治对策. 农业环境与发展, 2012, 29(5): 63-66.
	Chen G G, Wei L H. Nitrogen and phosphorus pollution in China’s fertilizer industry and its prevention and control measures. Agro-Environ Dev, 2012, 29(5): 63-66. (in Chinese with English abstract)
[28]	龚双凤, 马兴旺, 索俊宇, 陈宝燕, 朱靖蓉, 何万义, 杨涛. 氮肥运筹对机采棉养分吸收及产量的影响. 新疆农业科学, 2015, 52: 1216-1223.
	Gong S F, Ma X W, Suo J Y, Chen B Y, Zhu J R, He W Y, Yang T. Nitrogen fertilizer management of regulation of cotton yield and nutrient uptake in the machine pick cotton patterns. Xinjiang Agric Sci, 2015, 52: 1216-1223. (in Chinese with English abstract)
[29]	Ahmad S. 氮肥和种植密度对晚播棉花根系生长和氮代谢的影响. 华中农业大学硕士学位论文,湖北武汉, 2020.
	Ahmad S. Effect of Nitrogen Fertilizer and Planting Density on Root Growth and Nitrogen Metabolism in Late Sown Cotton. MS Thesis of Huazhong Agricultural University, Wuhan, Hubei, China, 2020. (in Chinese with English abstract)
[30]	平文超, 张永江, 刘连涛, 孙红春, 李存东. 不同密度对棉花根系生长与分布的影响. 棉花学报, 2011, 23: 522-528. doi: 10.11963/cs110606
	Ping W C, Zhang Y J, Liu L T, Sun H C, Li C D. Effects of planting densities on the growth and distribution of root in cotton. Cotton Sci, 2011, 23: 522-528. (in Chinese with English abstract)
[31]	张宸, 梁悦, 殷昊, 张应榕, 陈波浪. 氮肥形态和品种对棉花根系形态与氮素积累的影响. 新疆农业科学, 2023, 60: 823-831. doi: 10.6048/j.issn.1001-4330.2023.04.005
	Zhang C, Liang Y, Yin H, Zhang Y R, Chen B L. Effects of nitrogen forms and varieties on root morphology and nitrogen accumulation of cotton. Xinjiang Agric Sci, 2023, 60: 823-831. (in Chinese with English abstract) doi: 10.6048/j.issn.1001-4330.2023.04.005

Metrics

Viewed

Full text

Abstract

Cited

Shared

Discussed

处理 Treatment	密度 Density (plant hm^-2)	单株成铃数 Bolls per plant	单铃重 Single boll weight (g)	籽棉产量 Seed cotton yield (kg hm^-2)	皮棉产量 Lint yield (kg hm^-2)	衣分 Lint percentage (%)
P1N0	56,415.8 a	7.4 cd	4.8 c	2760.6 ef	911.0 e	33.17 b
P1N1	58,013.7 a	8.9 abc	5.4 ab	2983.6 e	963.4 d	33.41 b
P1N2	56,036.9 a	9.5 ab	5.5 ab	3135.0 de	1061.9 cd	33.87 b
P1N3	57,748.0 a	10.0 a	5.7 a	3420.0 d	1078.3 cd	31.53 b
P2N0	84,812.1 a	6.3 d	4.7 c	2841.1 e	909.2 e	32.47 b
P2N1	85,022.4 a	7.5 cd	5.3 ab	3577.5 c	1308.7 b	36.58 a
P2N2	86,184.3 a	8.2 bc	5.7 a	4206.6 b	1360.7 b	32.35 a
P2N3	85,439.6 a	7.5 cd	5.4 ab	3645.0 c	1288.9 b	35.36 ab
P3N0	118,675.7 a	6.2 de	4.7 c	2818.0 e	1134.4 c	33.25 b
P3N1	116,442.3 a	7.9 cd	5.2 b	4929.6 a	1840.5 a	37.34 a
P3N2	116,574.7 a	7.9 cd	5.4 ab	5119.2 a	1972.8 a	38.54 a
P3N3	117,684.5 a	6.4 d	5.3 ab	4070.4 b	1470.4 b	36.12 a
F值F-value
密度处理Density (P)	NS	50.94^**	NS	121.96^**	147.43^**	NS
氮处理Nitrogen (N)	NS	NS	4.21^*	6.81^*	6.07^*	NS
密度处理×氮处理P×N	NS	NS	NS	7.23^**	6.77^**	NS

处理 Treatment	密度 Density (plants hm^-2)	单株成铃数 Bolls per plant	单铃重 Single boll weight (g)	籽棉产量 Seed cotton yield (kg hm^-2)	皮棉产量 Lint yield (kg hm^-2)	衣分 Lint percentage (%)
CK	85,366.4 a	9.1 a	4.5 ab	3685.5 b	1405.9 b	38.15 a
P3N0	117,457.9 a	5.6 d	4.1 b	2755.2 c	1019.7 c	37.01 b
P3N1	115,698.3 a	6.9 bc	4.6 ab	3808.8 ab	1558.4 ab	40.92 a
P3N2	116,637.4 a	7.1 b	4.9 a	4174.8 a	1718.0 a	41.15 a
P3N3	118,547.8 a	6.5 c	4.5 ab	3510.0 b	1325.9 bc	37.77 ab

处理 Treatment	烂铃个数 Rotten bolls	烂铃率 Rate of rotten bolls (%)	脱落率 Shedding rate (%)
P1N0	0.5 a	2.6 a	63.2 ab
P1N1	0.4 a	1.9 a	57.1 b
P1N2	0.4 a	2.5 a	61.3 ab
P1N3	0.3 ab	2.4 a	58.8 b
P2N0	0.3 ab	1.9 a	63.6 ab
P2N1	0.4 a	1.8 a	68.2 a
P2N2	0.3 ab	1.5 a	65.6 ab
P2N3	0.3 ab	1.5 a	65.5 ab
P3N0	0.3 ab	1.4 a	71.4 a
P3N1	0.2 ab	1.1 b	72.2 a
P3N2	0.2 ab	1.1 b	70.1 a
P3N3	0.3 ab	1.4 a	69.5 a
F值F-value
密度处理Density (P)	NS	NS	13.56^*
氮处理Nitrogen (N)	NS	NS	NS
密度处理×氮处理P×N	NS	NS	NS

处理 Treatment	烂铃个数 Rotten bolls	烂铃率 Rate of rotten bolls (%)	脱落率 Shedding rate (%)
CK	0.3 a	1.5 a	65.5 a
P3N0	0.2 a	1.3 a	67.4 a
P3N1	0.2 a	1.8 a	62.7 a
P3N2	0.2 a	1.7 a	69.5 a
P3N3	0.3 a	2.2 a	65.3 a

处理 Treatment	日期Date (month/day)
处理 Treatment	7/30	8/15	8/30	9/20
P1N0	17.5 cd	164.1 f	1196.8 cd	1857.9 e
P1N1	19.6 c	196.4 d	1348.6 b	2203.4 c
P1N2	20.8 c	239.0 cd	1567.0 b	2290.8 c
P1N3	25.4 bc	257.0 bcd	1609.4 ab	2668.8 b
P2N0	19.4 c	180.9 e	1205.8 c	2021.7 d
P2N1	25.8 bc	224.4 cd	1533.2 b	2269.8 c
P2N2	32.0 bc	356.0 bc	1500.4 b	2507.0 bc
P2N3	34.2 ab	271.4 bcd	1476.6 b	2824.6 a
P3N0	18.6 c	176.1 e	1208.6 c	2064.9 d
P3N1	36.2 ab	390.2 b	1744.5 ab	2848.8 a
P3N2	44.6 a	588.4 a	1955.5 a	2863.6 a
P3N3	35.4 ab	191.2 d	1156.4 c	1940.4 de
F值F-value
密度处理Density (P)	20.71^**	314.05^**	49.90^**	269.40^**
氮处理Nitrogen (N)	NS	17.08^**	14.51^**	11.14^**
密度处理×氮处理P×N	3.82^*	17.75^**	12.83^**	9.79^**

密度与氮素对夏播棉氮素吸收利用的影响

Effects of planting density with nitrogen rate on regulation of nitrogen utilization in summer direct seeded cotton

RichHTML

PDF

摘要/Abstract

引用本文

使用本文

图/表 15

参考文献 31

相关文章 15

Metrics

本文评价

推荐阅读 10

关于本刊

在线期刊

作者中心

相关单位

联系我们

处理 Treatment	营养器官Nutritive organ				生殖器官Reproductive organ
处理 Treatment	7/30^†	8/15	8/30	9/20	7/30	8/15	8/30	9/20
P1N0	24.76 f	58.54 c	59.82 d	65.27 bc	3.37 cd	6.80 ef	23.05 e	28.18 e
P1N1	36.97 d	57.92 c	68.54 c	69.69 b	3.69 c	10.28 e	24.87 e	34.02 de
P1N2	39.67 d	63.53 c	72.79 c	73.35 b	3.99 c	10.62 e	31.13 d	41.71 cd
P1N3	46.15 c	66.57 c	75.86 c	78.50 b	4.17 c	12.38 de	34.10 cd	42.04 cd
P2N0	23.46 f	51.3 cd	56.86 de	74.35 b	3.41 cd	7.75 ef	28.96 de	34.40 de
P2N1	55.62 b	77.28 b	89.55 b	98.10 a	5.68 b	14.15 cd	34.73 cd	44.68 c
P2N2	59.07 b	77.60 b	93.65 ab	99.86 a	6.64 ab	16.27 bc	38.59 bc	45.67 c
P2N3	60.32 b	81.11 b	96.98 ab	100.46 a	6.21 ab	15.86 c	35.85 cd	45.32 c
P3N0	27.07 e	42.56 d	65.43 cd	75.23 b	2.53 d	9.43 e	24.69 e	38.92 d
P3N1	81.64 a	91.98 a	105.82 ab	110.95 a	6.98 ab	18.32 b	44.14 ab	52.35 bc
P3N2	80.80 a	90.97 a	104.39 ab	107.32 a	8.07 a	20.42 a	45.71 a	60.70 a
P3N3	83.71 a	95.21 a	109.41 a	113.39 a	6.80 ab	16.36 bc	40.71 abc	54.80 b
F值F-value
密度处理Density (P)	111.07^**	168.49^**	342.37^**	NS	594.45^**	664.34^**	482.56^**	1248.50^**
氮处理Nitrogen (N)	69.14^**	38.46^**	34.45^**	17.43^*	43.41^**	374.36^**	257.34^**	47.17^**
密度处理×氮处理P×N	21.75^**	34.64^**	26.38^**	NS	22.17^**	38.16^**	45.60^**	16.49^**

处理 Treatment	氮肥回收利用率 NRE (%)	氮肥农学利用率 aNUE (kg kg^-1N)	氮素生理利用率 pNUE (kg kg^-1N)	氮肥偏生产力 NPP (kg kg^-1N)
P1N1	14.41 d	2.48 de	10.26 d	33.15 bc
P1N2	12.90 de	2.50 de	15.61 cde	20.90 d
P1N3	11.40 e	3.14 d	17.09 cd	16.29 de
P2N1	37.81 b	8.18 bc	18.03 c	39.75 b
P2N2	24.52 c	9.10 b	20.78 b	28.04 c
P2N3	17.63 cd	3.83 d	17.03 cd	17.36 d
P3N1	35.72 bc	23.46 a	21.70 b	54.77 a
P3N2	42.58 a	21.34 ab	24.03 a	34.13 bc
P3N3	30.50 bc	5.96 c	16.56 cd	19.38 d
F值F-value
密度处理Density (P)	262.64^**	693.04^**	90.25^**	41.93^**
氮处理Nitrogen (N)	42.92^**	108.94^**	51.24^**	726.10^**
密度处理×氮处理P×N	62.92^**	503.38^**	31.32^**	56.97^**

处理 Treatment	氮肥回收利用率 NRE (%)	氮肥农学利用率 aNUE (kg kg^-1N)	氮素生理利用率 pNUE (kg kg^-1N)	氮肥偏生产力 NPP (kg kg^-1N)
CK	18.34 bc	3.80 b	15.09 b	15.43 c
P3N1	54.28 a	8.72 a	15.79 b	32.00 a
P3N2	44.17 a	7.16 ab	19.16 a	21.12 b
P3N3	22.61 b	2.74 b	12.55 b	12.71 d

年份 Year	氮肥利用率 Nitrogen use efficiency	与籽棉产量的回归关系 Correlation between nitrogen use efficiency and seed cotton yield	相关系数 Correlation coefficient
2019	氮肥回收利用率Nitrogen recovery efficiency	y = 0.0128x-24.508	0.8104^**
	氮肥农学利用率Agronomic nitrogen use efficiency	y = 0.01x-29.964	0.9291^**
	氮素生理利用率Physiological nitrogen use efficiency	y = 0.0048x-0.6406	0.8938^**
	氮肥偏生产力Partial productivity of nitrogen fertilizer	y = 0.0086x-4.3975	0.2627
2020	氮肥回收利用率Nitrogen recovery efficiency	y = 1028.5x+3439.9	0.6343^*
	氮肥农学利用率Agronomic nitrogen use efficiency	y = 69.857x+3403.2	0.7026^**
	氮素生理利用率Physiological nitrogen use efficiency	y = 102.4x+2192.4	0.9989^**
	氮肥偏生产力Partial productivity of nitrogen fertilizer	y = 14.479x+3500.6	0.4453^*

处理 Treatment	2019		2020
处理 Treatment	喷施前 Before application of harvest aid	喷施后 After application of harvest aid	喷施前 Before application of harvest aid	喷施后 After application of harvest aid
P1N0	58.23 b	81.02 a	—	—
P1N1	60.95 ab	83.01 a	—	—
P1N2	69.97 a	85.28 a	—	—
P1N3	64.96 ab	81.73 a	—	—
P2N0	56.54 b	76.47 ab	—	—
P2N1	57.29 b	80.95 a	—	—
P2N2	60.12 ab	84.96 a	—	—
P2N3	58.90 b	82.11 a	—	—
P3N0	51.25 bc	74.18 ab	35.60 b	69.97 ab
P3N1	53.28 bc	73.57 ab	43.62 ab	68.08 ab
P3N2	60.76 ab	81.83 a	43.59 ab	78.95 a
P3N3	59.25 ab	82.41 a	42.48 ab	75.53 a
CK	—	—	49.58 a	83.22 a

[1]	付景, 马梦娟, 张骐飞, 段居琦, 王越涛, 王付华, 王生轩, 白涛, 尹海庆, 王亚. 干湿交替灌溉和施氮量对粳稻光合特性和氮素吸收利用的影响[J]. 作物学报, 2024, 50(7): 1787-1804.
[2]	宁宁, 余新颖, 秦梦倩, 娄洪祥, 王宗铠, 王春云, 贾才华, 徐正华, 王晶, 蒯婕, 汪波, 赵杰, 周广生. 关键栽培措施对菜籽油综合品质的影响[J]. 作物学报, 2024, 50(6): 1554-1567.
[3]	胡明明, 丁峰, 彭志芸, 向开宏, 李郁, 张宇杰, 杨志远, 孙永健, 马均. 多元化种植模式下秸秆还田配合水氮管理对水稻产量形成与氮素吸收利用的影响[J]. 作物学报, 2024, 50(5): 1236-1252.
[4]	刘成敏, 门雅琦, 秦都林, 闫晓宇, 张乐, 孟浩, 苏寻雅, 孙学振, 宋宪亮, 毛丽丽. 长期秸秆还田下施氮量对棉花产量和氮素利用的影响[J]. 作物学报, 2024, 50(4): 1043-1052.
[5]	王吕, 吴玉红, 秦宇航, 淡亚彬, 陈浩, 郝兴顺, 田霄鸿. 紫云英稻秸秆协同还田与氮肥减量配施对水稻干物质积累、氮素转运及产量的影响[J]. 作物学报, 2024, 50(3): 756-770.
[6]	聂晓玉, 李真, 王天尧, 周元委, 徐正华, 王晶, 汪波, 蒯婕, 周广生. 种植密度对角果期弱光胁迫油菜籽粒油脂积累的影响[J]. 作物学报, 2024, 50(2): 493-505.
[7]	谢炜, 贺鹏, 马宏亮, 雷芳, 黄秀兰, 樊高琼, 杨洪坤. 秋闲期秸秆覆盖与施磷对冬小麦氮素吸收利用的影响[J]. 作物学报, 2024, 50(2): 440-450.
[8]	刘世洁, 杨习文, 马耕, 冯昊翔, 韩志栋, 韩潇杰, 张晓燕, 贺德先, 马冬云, 谢迎新, 王丽芳, 王晨阳. 灌水和施氮对冬小麦根系特征及氮素利用的影响[J]. 作物学报, 2023, 49(8): 2296-2307.
[9]	李慧, 王旭敏, 刘苗, 刘朋召, 李巧丽, 王小利, 王瑞, 李军. 基于夏玉米产量和氮素利用的水氮减量方案优选[J]. 作物学报, 2023, 49(5): 1292-1304.
[10]	刘昕萌, 程乙, 刘玉文, 庞尚水, 叶秀芹, 卜艳霞, 张吉旺, 赵斌, 任佰朝, 任昊, 刘鹏. 黄淮海区域现代夏玉米品种产量与资源利用效率的差异分析[J]. 作物学报, 2023, 49(5): 1363-1371.
[11]	吴希, 王家瑞, 郝淼艺, 张宏军, 张仁和. 种植密度对不同生育期玉米品种光温资源利用率和产量的影响[J]. 作物学报, 2023, 49(4): 1065-1078.
[12]	舒泽兵, 罗万宇, 蒲甜, 陈国鹏, 梁冰, 杨文钰, 王小春. 基于高产与高效条件下鲜食玉米鲜食大豆带状间作田间配置技术优化[J]. 作物学报, 2023, 49(4): 1140-1150.
[13]	王雪, 谷淑波, 林祥, 王威雁, 张保军, 朱俊科, 王东. 微喷补灌水肥一体化对冬小麦产量及水分和氮素利用效率的影响[J]. 作物学报, 2023, 49(3): 784-794.
[14]	杨俊芳, 王宙, 乔麟轶, 王亚, 赵宜婷, 张宏斌, 申登高, 王宏伟, 曹越. 基于高密度遗传图谱的蓖麻种子大小性状QTL定位[J]. 作物学报, 2023, 49(3): 719-730.
[15]	刘俊华, 吴正锋, 党彦学, 于天一, 郑永美, 万书波, 王才斌, 李林. 密度对不同株型花生单粒精播群体质量及产量的影响[J]. 作物学报, 2023, 49(2): 459-471.

处理 Treatment	日期Date (month/day)
处理 Treatment	7/30	8/15	8/30	9/20
CK	29.0 b	235.6 b	1671.7 b	2079.9 ab
P3N0	18.2 d	205.9 d	1314.0 c	1593.6 b
P3N1	31.3 b	283.0 ab	1722.6 ab	2392.9 ab
P3N2	38.1 a	331.7 a	1922.6 a	2605.6 a
P3N3	30.3 b	200.1 c	1438.8 c	1896.3 b

处理 Treatment	营养器官Nutritive organ				生殖器官Reproductive organ
处理 Treatment	7/30	8/15	8/30	9/20	8/15	8/30	9/20
CK	43.18 ab	71.62 bc	91.28 a	109.33 a	17.10 ab	26.33 a	34.98 b
P3N0	27.59 c	61.20 c	75.12 b	86.59 b	13.89 b	18.72 b	25.24 d
P3N1	45.90 ab	88.53 ab	93.20 a	110.91 a	19.17 a	27.17 a	43.89 ab
P3N2	37.55 b	70.98 bc	86.81 ab	107.13 a	19.80 a	31.36 a	45.97 a
P3N3	49.09 a	90.60 a	100.65 a	112.23 a	14.04 b	24.82 a	32.60 bc