北方冬麦区CO2浓度增高与氮肥互作对冬小麦生理特性和产量的影响

doi:10.3864/j.issn.0578-1752.2015.24.009

摘要/Abstract

摘要： 【目的】阐明CO₂浓度增高与氮肥互作对冬小麦生理和产量的影响，为客观评估气候变化背景下冬小麦生产潜力提供理论依据。【方法】2011—2014年利用开放式CO₂富集系统（FACE）平台，采用盆栽方法，研究冬小麦“中麦175”在不同CO₂浓度及高低氮肥水平下（高浓度CO₂ 550 mg·L^-1和大气浓度390 mg·L^-1；高氮N1，0.16 g·kg^-1和低氮N0，0 g·kg^-1）的生育进程、光合特征及产量变化。CO₂富集处理于每年返青-成熟期间进行，通气时间为每日6:30—18:30，夜间不通气。CO₂浓度通过计算机程序控制，并根据具体风向和风速控制释放管电磁阀的开合度，实现预定设置浓度。【结果】盆栽试验表明与大气CO₂浓度相比，高浓度CO₂加快了冬小麦生育进程，拔节期提前1 d，开花期可提前1—2 d，全生育期可缩短3—5 d，高氮肥处理对生育进程具有延迟作用，开花期延长1—2 d，灌浆期可延长4—5 d，同步缓解高浓度CO₂对生育进程的加快作用；高浓度CO₂使叶片光合速率提高13.7%，产量平均提高16.0%，且在高氮肥下光合速率的增幅比低氮肥相对提高2.5%，蒸腾速率提高13.5%；试验中单独高氮较低氮的增产效果达到50%，高于单独高浓度CO₂较大气浓度的增产效果；高浓度CO₂对产量构成中穗粒数和千粒重提高明显，高浓度CO₂较大气浓度穗粒数增加3.69%，单独高氮处理较低氮处理平均穗粒数增加3.43%，即CO₂肥效起到了增加穗粒数的作用并略高于单独氮肥处理，高氮和高CO₂双重促进下的穗粒数最多，达到38.37粒/穗，低氮和低CO₂处理的穗粒数水平最低，可见CO₂和氮肥互作对穗粒数的促进相对更明显，各自单独施用的促进作用彼此差异不大，但低氮、大气CO₂浓度处理的穗粒数则相对较低；与大气CO₂浓度相比，高浓度CO₂的千粒重增加5.3%，高氮高浓度CO₂处理的千粒重大约提高7.3%，说明氮肥的施用促进了高浓度CO₂对千粒重的提升效果。【结论】高浓度CO₂可提高冬小麦产量，且与氮肥有明显的正向互作关系，高氮肥处理可降低CO₂浓度升高对生育期的加快作用，提高光合能力，促进CO₂肥效的发挥；CO₂对冬小麦产量的提高主要是缘于CO₂浓度升高有利于穗粒数和千粒重的增加，育种中可以做综合性考虑和应用。

关键词: 冬小麦, FACE, CO₂, 氮肥, 产量

Abstract: 【Objective】This study aims to elucidate the interactive effects of elevated CO₂ concentration [CO₂] and different nitrogen applications on phenology, photosynthesis and yield of winter wheat, then to provide theoretical understanding for objective assessment on the potential yield of winter wheat under climate change conditions.【Method】The experiment was conducted from 2011-2014 using a Free Air CO₂ Enrichment (FACE) facility with pot experiment and winter wheat cultivar “Zhongmai 175”. Each pot was filled with 45 kg of sieved soil. The treatments were set at elevated [CO₂] of 550 mg·L^-1 and ambient [CO₂] of 390 mg·L^-1，nitrogen fertilizer applied at N1, 0.16g·kg^-1 soil and N0, 0 g·kg^-1 soil. The changes of phenology, physiology and yield of winter wheat were investigated. The elevated CO₂feeding was in operation from regreen to maturity stage each year and injected time from 6:30-18:30 each day, and no CO₂ was released at night. The [CO₂] was controlled through computer program and could synchronously adjust with wind speed and direction time by a solenoid valve in a release pipe, then it achieved the expected [CO₂].【Result】The pot experiment results indicated that elevated [CO₂] accelerated the growth process of winter wheat compared with ambient [CO₂], jointing stage speeded up of 1 day, flowering period can be 1-2 days in advance, and the whole growth duration was shortened 3-5 days under the same fertilizer level. While as the high nitrogen could prolong the growth duration, the flowering period can be extended by 1-2 days, filling period by 4-5 days, synchronous alleviated the accelerative effects of elevated [CO₂] on growth process; High [CO₂] enhanced winter wheat yield about 16.0% via increased grain number per spike and grains weight significantly, and photosynthesis of flag leaves was enhanced by 13.7% compared with ambient [CO₂]. Under elevated [CO₂] conditions, higher application of nitrogen fertilizer could increase the yield of winter wheat about 50%，enhance the photosynthesis increase rate about 2.5% and transpiration about 13.5% compared with low nitrogen fertilizer supply. That means the nitrogen fertilization can not only promote the high [CO₂] positive effect, but still plays a more important role to maintain a stable and higher yield of winter wheat even with [CO₂] enrichment conditions; Moreover, elevated [CO₂] can increase the grain number per spike by 3.69% compared with ambient [CO₂], higher nitrogen increased by 3.43% compared with low nitrogen, the dual role of high nitrogen and high [CO₂] increase grain number highest of 38.37 grains/ear, low nitrogen and ambient [CO₂] treatment had the lowest level of spike grain numbers, which indicated high [CO₂] has the slightly higher positive effects than that of a purely nitrogen treatment on grain number. Dual effects of high [CO₂] and nitrogen had the most positive effects on grain number, but the effects had no obvious difference if these measures are used separately. High [CO₂] increased grain weight by 5.3%, and if it combined with high nitrogen that the grain weight could increase 7.3%. All these showed that nitrogen promoted the positive effects of high [CO₂] on grain weight.【Conclusion】Therefore, under future climate change conditions, higher [CO₂] has positive effects to enhance yield of winter wheat and has obvious positive interactions with nitrogen, high nitrogen can extend the growth period which mitigate the shorten growth duration by higher [CO₂], improve photosynthesis and promote CO₂ fertilization effects. Higher [CO₂] could increase yield via high grain number per spike and grains weight which could be considered for wheat breeding.

Key words: winter wheat, FACE, CO₂, nitrogen, yield

居辉，姜帅，李靖涛，韩雪，高霁，秦晓晨，林而达. 北方冬麦区CO₂浓度增高与氮肥互作对冬小麦生理特性和产量的影响[J]. 中国农业科学, 2015, 48(24): 4948-4956.

JU Hui, JIANG Shuai, LI Jing-tao, HAN Xue, GAO Ji, QIN Xiao-chen, LIN Er-da. Interactive Effects of Elevated CO₂ and Nitrogen on the Physiology and Yield of Winter Wheat in North Winter Wheat Region of China[J]. Scientia Agricultura Sinica, 2015, 48(24): 4948-4956.

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参考文献

[1] IPCC AR5 (The Fifth Assessment Report of Intergovernmental Panel on Climate Change). Climat Change: The Physical Science Basis. Summary for Policy Makers. Report of Working Group I of the Inter- governmental Panel on Climate Change. UK: Cambridge University Press, 2013.

[2] Schmidhuber J, Tubiello F N. Global food security under climate change. Proceedings of the National Academy of Sciences, 2007, 104(50): 19703-19708.

[3] Baker J T. Yield responses of southern US rice cultivars to CO₂ and temperature. Agricultural and Forest Meteorology, 2004, 122(3): 129-137.

[4] 姜帅, 居辉, 韩雪, 刘勤. CO₂肥效及水肥条件对作物影响研究进展. 核农学报, 2013, 27(11): 1783-1789.

Jiang S, Ju H, Han X, Liu Q. Effects of CO₂fertilization, water and nutrient conditions on crops: A review. Journal of Nuclear Agricultural Science, 2013, 27(11): 1783-1789. (in Chinese)

[5] Amthor J S. Effects of atmospheric CO₂ concentration on wheat yield: Review of results from experiments using various approaches to control CO₂ concentration. Field Crops Research, 2001, 73(1): 1-34.

[6] Ainsworth E A, Leakey A D, Ort D R, Long S P. FACE-ing the facts: Inconsistencies and interdependence among field, chamber and modeling studies of elevated [CO₂] impacts on crop yield and food supply. New Phytologist, 2008, 179(1): 5-9.

[7] Kimball B A, Kobayashi K, Bindi M. Responses of agricultural crops to free-air CO₂ enrichment. Advances in Agronomy, 2002, 77: 293-368.

[8] Bloom A J, Burger M, Kimball B A, Pinter Jr P J. Nitrate assimilation is inhibited by elevated CO₂ in field-grown wheat. Nature Climate Change, 2014, 4(6): 477-480.

[9] Challinor A J, Wheeler T R. Use of a crop model ensemble to quantify CO₂ stimulation of water-stressed and well-watered crops. Agricultural and Forest Meteorology, 2008, 148(6): 1062-1077.

[10] Nam H S, Kwak J H, Lim S S, Choi W J, Lee S I, Lee D S, Lee K S, Kim H Y, Lee S M, Matsushima M. Fertilizer N uptake of paddy rice in two soils with different fertility under experimental warming with elevated CO₂. Plant and Soil, 2013, 369(1/2): 563-575.

[11] Reich P B, Hobbie S E, Lee T, Ellsworth D S, West J B, Tilman D, Knops J M H, Naeem S, Trost J. Nitrogen limitation constrains sustainability of ecosystem response to CO₂. Nature, 2006, 440(7086): 922-925.

[12] Lee K S, Kim H Y, Lee S M, Matsushima M. Fertilizer N uptake of paddy rice in two soils with different fertility under experimental warming with elevated CO₂. Plant Soil, 2013, 369: 563-575.

[13] Pongratz J, Lobell D B, Cao L, Caldeira K. Crop yields in a geoengineered climate. Nature Climate Change, 2012, 2(2): 101-105.

[14] Taub D R, Wang X. Why are nitrogen concentrations in plant tissues lower under elevated CO₂? A critical examination of the hypotheses. Journal of Integrative Plant Biology, 2008, 50(11): 1365-1374.

[15] 杨连新, 王余龙, 李世峰, 黄建晔, 董桂春, 朱建国, 刘钢, 韩勇. 开放式空气二氧化碳浓度增高对小麦物质生产与分配的影响. 应用生态学报, 2007, 18(2): 339-346.

Yang L X, Wang Y L, Li S F, Huang J Y, Dong G C, Zhu J G, Liu G, Han Y. Effects of free-air CO₂ enrichment (FACE) on dry matter production and allocation in wheat. Chinese Journal of Applied Ecology, 2007, 18(2): 339-346. (in Chinese)

[16] 金善宝.中国小麦学. 北京: 中国农业出版社, 1996.

Jin S B. Chinese Wheat. Beijing: China Agriculture Press, 1996. (in Chinese)

[17] 赵广才. 中国小麦种植区划研究（一）. 麦类作物学报, 2010, 30(5): 886-895.

Zhao G C. Study on Chinese wheat planting regionalization（Ⅰ）. Journal of Triticeae Crops, 2010, 30(5): 886-895. (in Chinese)

[18] 韩雪, 郝兴宇, 王贺然, 林而达. FACE条件下冬小麦生长特征及产量构成的影响. 中国农学通报, 2012, 22(36): 154-159.

Han X, Hao X Y, Wang H R, Lin E D. Effect of free air CO₂ enrichment (FACE) on the growth and grain yield of winter wheat. Chinese Agricultural Science Bulletin, 2012, 22(36): 154-159. (in Chinese)

[19] Reuveni J, Bugbee B. Very high CO₂ reduces photosynthesis, dark respiration and yield in wheat. Annals of Botany, 1997, 80(4): 539-546.

[20] Yand P, Wu W B, Li Z G, Yu Q Y, Inatsu M, Liu Z H, Tang P Q, Zha Y, Kimoto M, Tang H. Simulated impact of elevated CO₂, temperature, and precipitation on the winter wheat yield in the North China plain. Regional Environmental Change, 2014, 14(1): 61-74.

[21] 黄建晔, 杨洪建, 杨连新, 刘红江, 董桂春, 朱建国, 王余龙. 开放式空气CO₂浓度增加(FACE)对水稻产量形成的影响及其与氮的互作效应. 中国农业科学, 2004, 37(12): 1824-1830.

Huang J Y, Yang H J, Yang L X, Liu H J, Dong G C, Zhu J G, Wang Y L. Effects of free-air CO₂ enrichment (FACE) on yield formation of rice (Oryza sativa L.) and its interaction with nitrogen. Scientia Agricultura Sinica, 2004, 37(12): 1824-1830. (in Chinese)

[22] 许育彬, 沈玉芳, 李世清. CO₂浓度升高和施氮对冬小麦光合面积及粒叶比的影响. 中国生态农业学报, 2013, 21(9): 1049-1056.

Xu Y B, Shen Y F, Li S Q. Effects of elevated CO₂ and nitrogen application on photosynthetic area and gain-leaf ratio of winter wheat. Chinese Journal of Eco-Agriculture, 2013, 21(9): 1049-1056. (in Chinese)

[23] 李伏生, 康绍忠, 张富仓. CO₂浓度、氮和水分对春小麦光合、蒸散及水分利用效率的影响. 应用生态学报, 2003, 14(3): 387-393.

Li F S, Kang S Z, Zhang F C. Effects of CO₂enrichment, nitrogen and water on photosynthesis, evapotranspiration and water use efficiency of spring wheat. Chinese Journal of Applied Ecology, 2003, 14(3): 387-393. (in Chinese)

[24] 李伏生, 康绍忠. CO₂浓度和氮素水平对春小麦水分利用效率的研究. 作物学报, 2002, 28(6): 835-840.

Li F S, Kang S Z. Effects of CO₂ concentration and nitrogen level on water use efficiency in spring wheat. Acta Agronomica Sinica, 2002, 28(6): 835-840. (in Chinese)

[25] Nam H S, Kwak J H, Lim S S, Choi W J, Lee S I, Lee D S, Lee K S, Kim H Y, Lee S M, Matsushima M. Fertilizer N uptake of paddy rice in two soils with different fertility under experimental warming with elevated CO₂. Plant and Soil, 2013, 369(1/2): 563-575.

[26] 张绪成, 于显枫, 王红丽, 马一凡. 高大气CO2浓度下氮素对小麦叶片光合能量分配的调节. 作物学报, 2011, 37(6): 1069-1076.

Zhang X C, Yu X F, Wang H L, Ma Y F. Regulation of nitrogen level on photosynthetic energy partitioning in wheat leaves under elevated atmospheric CO₂ concentration. Acta Agronomica Sinica, 2011, 37(6): 1069-1076. (in Chinese)

[27] 马红亮, 朱建国, 谢祖彬, 刘钢, 张雅丽, 曾青. 开放式空气CO₂浓度升高对冬小麦生长和吸收的影响. 作物学报, 2006, 31(12): 1634-1639.

Ma H L, Zhu J G, Xie Z B, Liu G, Zhang Y L, Zeng Q. Effects of free-air carbon enrichment on growth and uptake of nitrogen in winter wheat. Acta Agronomica Sinica, 2006, 31(12): 1634-1639. (in Chinese)

[28] Hymus G J, Baker N R, Long S P. Growth in elevated CO₂ can both decrease and increase photochemistry and photoinhibition of photosynthesis in a predictable manner. Dactylis glomerata grown in two levels of nitrogen nutrition. Plant Physiology, 2001, 127(3): 1204-1211.

[29] 张杰, 王备战, 冯晓, 李国强, 赵巧丽, 胡峰, 郑国清. 氮肥调控对冬小麦干物质量、产量和氮素利用效率的影响. 麦类作物学报, 2014, 34(4): 516-520.

Zhang J, Wang B Z, Feng X, Li G Q, Zhao Q L, Hu F, Zheng G Q. Effects of nitrogen fertilizer management on the dry matter quantity, yield and N utilization in winter wheat. Journal of Triticeae Crops, 2014, 34(4): 516-520. (in Chinese)

[30] 李强, 王朝辉, 李富翠, 戴健, 李孟华, 何刚, 曹群虎, 段长林, 鱼昌为. 氮肥管理与地膜覆盖对旱地冬小麦产量和氮素利用效率的影响. 作物学报, 2014, 40(1): 93-100.

Li Q, Wang C H, Li F C, Dai J, Li M H, He G, Cao Q H, Duan C L, Yu C W. Effects of nitrogen fertilizer management on yield and nitrogen use efficiency in winter wheat growing on dryland with plastic film mulching. Acta Agronomica Sinica, 2014, 40(1): 93-100. (in Chinese)

北方冬麦区CO₂浓度增高与氮肥互作对冬小麦生理特性和产量的影响

Interactive Effects of Elevated CO₂ and Nitrogen on the Physiology and Yield of Winter Wheat in North Winter Wheat Region of China

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