Effects of different nitrogen application rates on dry matter accumulation, distribution and yield of grape under alternate partial root-zone drip irrigation.

doi:10.13287/j.1001-9332.202105.023

Abstract

Abstract: To get an optimal mode of irrigation and nitrogen supply for table grape production in North China, a pot experiment was conducted to investigate the effects of different irrigation modes and N application rates on dry matter accumulation and distribution, yield, water use efficiency, and nitrogen use efficiency of table grape. The irrigation modes included conventional drip irrigation (CDI, with sufficient irrigation), alternate partial root-zone drip irrigation (ADI, with 50% amount of the irrigation water of CDI) and fixed partial root-zone drip irrigation (FDI, with 50% amount of the irrigation water of CDI). The nitrogen application rates were set at 0.4 (N₁), 0.8 (N₂) and 1.2 (N₃) g·kg^-1 dry soil. The results showed that compared with CDI, ADI and FDI reduced new shoot pruning amount by 34.8% and 11.2%, respectively. New shoot pruning amount increased with increasing N application rates, being highest under CDIN₃. Dry matter accumulation of ADI was the highest, being 5.1% and 12.8% higher than CDI and FDI. Dry matter accumulation was higher under N₂ and N₃ than N₁. Compared with CDI and FDI, leaf to fruit ratio reduced but harvest index significantly increased in ADI, while those variables showed no significant difference among diffe-rent N application rates. The ratio of pruning amount to the biomass accumulated in the current year in ADIN₂ was the lowest among the treatments. Compared with CDI and FDI, ADI increased grape fruit yield by 6.0% and 10.4%, respectively. Fruit yield was enhanced with increasing nitrogen application rates under the same irrigation condition, with the highest yield under the ADIN₂ and ADIN₃. Water use efficiency (WUE) increased significantly in ADI compared with CDI and FDI, with the highest value being observed in ADI coupled with N₂ or N₃. Nitrogen use efficiency (NUE) showed a trend of ADI＞CDI＞FDI. In addition, NUE decreased with increasing nitrogen supply level across the irrigation modes. In conclusion, ADIN₂could reduce the redundant growth of grape tree, promote the transfer of dry matter to fruit, which increased yield and use efficiency of both water and nitrogen, which is a suitable coupling water and nitrogen supply mode for grape production in northern China.

Key words: redundant growth, dry matter accumulation and distribution, yield, water use efficiency, nitrogen use efficiency

CHEN Li-nan, LIU Xiu-chun, SUN Zhan-xiang, RONG Chuan-sheng, ZHOU Yan-qi, SHU Liang-zuo. Effects of different nitrogen application rates on dry matter accumulation, distribution and yield of grape under alternate partial root-zone drip irrigation.[J]. Chinese Journal of Applied Ecology, 2021, 32(5): 1807-1815.

References

[1] 马丽, 赵文东, 孙凌俊, 等. 辽宁省鲜食葡萄栽培现状. 北方果树, 2017(4): 45-46 [Ma L, Zhao W-D, Sun L-J, et al. Cultivation status of fresh grapevine in Liaoning Province. Northern Fruits, 2017(4): 45-46]
[2] 武良, 张卫峰, 陈新平, 等. 中国农田氮肥投入和生产效率.中国土壤与肥料, 2016(4): 76-83 [Wu L, Zhang W-F, Chen X-P, et al. Nitrogen fertilizer input and nitrogen use efficiency in Chinese farmland. Soil and Fertilizer Sciences in China, 2016(4): 76-83]
[3] Kang SZ, Hao XM, Du TS, et al. Improving agricultural water productivity to ensure food security in China under changing environment: From research to practice. Agricultural Water Management, 2017, 179: 5-17
[4] 康绍忠, 张建华, 梁宗锁, 等. 控制性交替灌溉——一种新的农田节水调控思路. 干旱地区农业研究, 1997, 15(1): 1-5 [Kang S-Z, Zhang J-H, Liang Z-S, et al. The controlled alternative irrigation: A new approach for water saving regulation in farmland. Agricultural Research in the Arid Areas, 1997, 15(1): 1-5]
[5] 康绍忠, 潘英华, 石培泽, 等. 控制性作物根系分区交替灌溉的理论与试验. 水利学报, 2001(11): 80-86 [Kang S-Z, Pan Y-H, Shi P-Z, et al. Controlled root-divided alternative irrigation: Theory and experiments. Journal of Hydraulic Engineering, 2001(11): 80-86]
[6] 张文东, 赵志成, 李曼, 等. 交替滴灌对日光温室黄瓜光合作用及抗氧化酶活性的影响. 植物生理学报, 2017, 53(11): 1997-2006 [Zhang W-D, Zhao Z-C, Li M, et al. Effect of alternate drip irrigation on photosynthesis and antioxidant enzyme activities in cucumber in solar greenhouse. Plant Physiology Journal, 2017, 53(11): 1997-2006]
[7] Souza CRD, Maroco JP, Santos TPD, et al. Partial root zone drying: Regulation of stomatal aperture and carbon assimilation in field-grown grapevines (Vitis vinifera cv. Moscatel). Functional Plant Biology, 2003, 30: 653-662
[8] Kang SZ, Zhang JH. Controlled alternate partial root-zone irrigation: Its physiological consequences and impact on water use efficiency. Journal of Experimental Botany, 2004, 55: 2437-2446
[9] Li CX, Zhou XG, Sun JS, et al. Dynamics of root water uptake and water use efficiency under alternate partial root-zone irrigation. Desalination and Water Treatment, 2014, 52: 2805-2810
[10] 刘学娜, 刘彬彬, 崔青青, 等. 交替滴灌施氮对日光温室黄瓜生长、光合特性、产量及水氮利用效率的影响.植物生理学报, 2016, 52(6): 905-916 [Liu X-N, Liu B-B, Cui Q-Q, et al. Effects of alternative drip irrigation and nitrogen fertilization on growth, photosynthesis, yield, and water-nitrogen use efficiency of cucumber in solar greenhouse. Plant Physiology Journal, 2016, 52(6): 905-916]
[11] Du SQ, Kang SZ, Li FS, et al. Water use efficiency is improved by alternate partial root-zone irrigation of apple in arid northwest China. Agricultural Water Management, 2017, 179: 184-192
[12] 毕彦勇, 高东升, 王晓英, 等. 根系分区灌溉对设施油桃生长发育、产量及品质的影响. 中国生态农业学报, 2005, 13(4): 88-90 [Bi Y-Y, Gao D-S, Wang X-Y, et al. Influences of partial root-zone irrigation on the growth and development, yield, and quality of nectarine in greenhouse. Chinese Journal of Eco-Agriculture, 2005, 13(4): 88-90]
[13] 杜太生, 康绍忠, 夏桂敏, 等. 滴灌条件下不同根区交替湿润对葡萄生长和水分利用的影响. 农业工程学报, 2005, 21(11): 51-56 [Du T-S, Kang S-Z, Xia G-M, et al. Response of grapevine growth and water use to different partial root-zone drying patterns under drip irrigation. Transactions of the Chinese Society of Agricultural Engineering, 2005, 21(11): 51-56]
[14] 张江辉, 刘洪波, 白云岗, 等. 极端干旱区滴灌葡萄水肥耦合效应研究. 土壤学报, 2018, 55(4): 804-814 [Zhang J-H, Liu H-B, Bai Y-G, et al. Coupling effect of water and fertilizer on grape under drip irrigation in extremely arid regions. Acta Pedologica Sinica, 2018, 55(4): 804-814]
[15] 黄英, 安进强, 张芮, 等. 水肥调控对设施延后栽培葡萄产量和品质的影响. 干旱地区农业研究, 2015, 33(2): 191-195 [Huang Y, An J-Q, Zhang R, et al. Effects of fertilizer-water regulation on quality and yield of green house grape under delayed cultivation. Agricultural Research in the Arid Areas, 2015, 33(2): 191-195]
[16] 何岸镕, 张芮, 安进强, 等. 水肥调控对设施延后栽培葡萄生长特性的影响. 节水灌溉, 2016(12): 27-31 [He A-R, Zhang R, An J-Q, et al. Effects of fertigation treatment on growth characteristic of greenhouse grape under delayed phonological period. Water Saving Irrigation, 2016(12): 27-31]
[17] 魏钦平, 刘松忠, 张强, 等. 苹果幼树根域局部灌溉的水分运转特性. 中国农业科学, 2012, 45(12): 2530-2536 [Wei Q-P, Liu S-Z, Zhang Q, et al. Chara-cteristics of water transportation for apple trees submitted by partial root-zone irrigation. Scientia Agricultura Sinica, 2012, 45(12): 2530-2536]
[18] Poni S, Tagliavinini M, Neri D, et al. Influence of root pruning and water stress on growth and physiological factors of potted apple, grape, peach and pear trees. Scientia Horticulturae, 1992, 52: 223-226
[19] Stoll M, Loveys B, Dry P. Hormonal changes induced by partial root-zone drying of irrigated grapevine. Journal of Experimental Botany, 2000, 51: 1627-1634
[20] 梁宗锁, 康绍忠, 石培泽, 等. 隔沟交替灌溉对玉米根系分布和产量的影响及其节水效益. 中国农业科学, 2000, 45(6): 26-32 [Liang Z-S, Kang S-Z, Shi P-Z, et al. Effect of alternate furrow irrigation on maize production, root density and water-saving benefit. Scientia Agricultura Sinica, 2000, 45(6): 26-32]
[21] 昌小平, 王嬛, 杨莉. 变水条件下不同抗旱性的冬小麦品种苗期根系活力及其水分状况的变化. 植物生理学通讯, 1996, 32(3): 178-182 [Chang X-P, Wang X, Yang L. Changes of root activity and water state at seeding stage of winter wheat varieties with different drought-resistance under different water conditions. Plant Physiology Communications, 1996, 32(3): 178-182]
[22] Loveys BR, Grant J, Dry PR, et al. Progress in the development of partial root-zone drying. The Australian Grape Grower and Winemaker, 1997, 402: 18-20
[23] 周青云, 王仰仁, 孙书洪. 根系分区交替滴灌条件下葡萄根系分布特征及生长动态. 农业机械学报, 2011, 42(9): 59-63 [Zhou Q-Y, Wang Y-R, Sun S-H. Distribution characteristic and growing dynamic of grape vine roots under alternate partial root zone drip irrigation. Transactions of the Chinese Society of Agricultural Machinery, 2011, 42(9): 59-63]
[24] Zhang Q, Wu S, Chen C, et al. Regulation of nitrogen forms on growth of eggplant under partial root-zone irrigation. Agricultural Water Management, 2014, 142: 56-65
[25] Chen C, Xu F, Zhu JR, et al. Nitrogen forms affect root growth, photosynthesis, and yield of tomato under alternate partial root-zone irrigation. Journal of Plant Nutrition and Soil Science, 2016, 179: 104-112
[26] 张强, 徐飞, 王荣富, 等. 控制性分根交替灌溉下氮形态对番茄生长、果实产量及品质的影响. 应用生态学报, 2014, 25(12): 3547-3555 [Zhang Q, Xu F, Wang R-F, et al. Effects of nitrogen forms on the growth, yield and fruit quality of tomato under controlled alternate partial root zone irrigation. Chinese Journal of Applied Ecology, 2014, 25(12): 3547-3555]
[27] 周秀杰, 王海红, 束良佐, 等. 局部根区水分胁迫下氮形态与供给部位对玉米幼苗生长的影响. 应用生态学报, 2010, 21(8): 2017-2024 [Zhou X-J, Wang H-H, Shu L-Z, et al. Effects of nitrogen form and its supply position on maize seedling growth under partial root-zone water stress. Chinese Journal of Applied Ecology, 2010, 21(8): 2017-2024]
[28] 杨启良, 周兵, 刘小刚, 等. 亏缺灌溉和施氮对小桐子根区硝态氮分布及水分利用的影响. 农业工程学报, 2013, 29(4): 142-150 [Yang Q-L, Zhou B, Liu X-G, et al. Effect of deficit irrigation and nitrogen fertili- zer application on soil nitrate-nitrogen distribution in root-zone and water use of Jatropha curcas L. Transactions of the Chinese Society of Agricultural Engineering, 2013, 29(4): 142-150]
[29] Shu LZ, Liu R, Min W, et al. Regulation of soil water threshold on tomato plant growth and fruit quality under alternate partial root-zone drip irrigation. Agricultural Water Management, 2020, 238: 1-8
[30] 杨启良, 张富仓, 刘小刚, 等. 控制性分根区交替滴灌对苹果幼树形态特征与根系水分传导的影响. 应用生态学报, 2012, 23(5): 1233-1239 [Yang Q-L, Zhang F-C, Liu X-G, et al. Effects of controlled alternate partial root-zone drip irrigation on apple seedling morphological characteristics and root hydraulic conductivity. Chinese Journal of Applied Ecology, 2012, 23(5): 1233-1239]
[31] 于坤, 郁松林, 刘怀锋, 等. 滴灌方式对‘赤霞珠'葡萄幼苗根冠功能的调控效应. 应用生态学报, 2015, 26(5): 1335-1342 [Yu K, Yu S-L, Liu H-F, et al. Effects of drip irrigation methods on the regulation between root and crown function of ‘Cabernet Sauvignon' seedlings. Chinese Journal of Applied Ecology, 2015, 26(5): 1335-1342]
[32] 杨启良, 张富仓, 刘小刚, 等. 沟灌方式和水氮对玉米产量与水分传导的影响. 农业工程学报, 2011, 27(1): 15-21 [Yang Q-L, Zhang F-C, Liu X-G, et al. Effects of different furrow irrigation patterns, water and nitrogen supply levels on hydraulic conductivity and yield of maize. Transactions of the Chinese Society of Agricultural Engineering, 2011, 27(1): 15-21]
[33] 李培岭, 张富仓. 膜下分区交替滴灌和施氮对棉花干物质累积与氮肥利用的影响. 应用生态学报, 2013, 24(2): 416-422 [Li P-L, Zhang F-C. Coupling effects of partitioning alternative drip irrigation with plastic mulch and nitrogen fertilization on cotton dry matter accumulation and nitrogen use. Chinese Journal of Applied Ecology, 2013, 24(2): 416-422]
[34] Liu R, Yang Y, Wang YS, et al. Alternate partial root-zone drip irrigation with nitrogen fertigation promoted tomato growth, water and fertilizer-nitrogen use efficiency. Agricultural Water Management, 2020, 233: 1-8