浅埋滴灌条件下灌溉定额对玉米根系形态特征和生理特性的影响

doi:10.11924/j.issn.1000-6850.casb2021-1077

中国农学通报 ›› 2022, Vol. 38 ›› Issue (18): 12-19.doi: 10.11924/j.issn.1000-6850.casb2021-1077

所属专题：生物技术；玉米

浅埋滴灌条件下灌溉定额对玉米根系形态特征和生理特性的影响

郭子赫¹(), 杨恒山¹(), 赵培军², 张玉芹¹, 刘晶¹, 包额尔敦³, 张瑞富¹, 李媛媛¹, 李丹丹¹, 秦江¹

¹内蒙古民族大学农学院/内蒙古自治区饲用作物工程技术研究中心,内蒙古通辽 028042
²乌兰察布市农林科学研究所,内蒙古乌兰察布 012000
³通辽市农牧科学研究所,内蒙古通辽 028000

收稿日期:2021-11-15 修回日期:2021-03-17 出版日期:2022-06-25 发布日期:2022-07-14
通讯作者: 杨恒山
作者简介:郭子赫,男,1996年出生,内蒙古通辽人,硕士研究生,研究方向：作物高产高效栽培生理。通信地址：028042 内蒙古自治区通辽市科尔沁区霍林河大街西536号内蒙古民族大学农学院作物栽培实验室,E-mail： guozihe99@163.com。
基金资助:
国家自然科学基金“西辽河平原灌区玉米浅埋滴灌土壤次生盐渍化机制及调控”(31860353);内蒙古自治区“科技兴蒙”行动重点专项“内蒙古东部玉米高效节能水肥一体化技术研究”(KJXM2020001-05);内蒙古自治区自然科学基金“浅埋滴灌下玉米田水盐运移规律及调控途径”(2019MS03073)

Effects of Irrigation Quota on Morphological and Physiological Characteristics of Maize Root Under Shallow-buried Drip Irrigation

GUO Zihe¹(), YANG Hengshan¹(), ZHAO Peijun², ZHANG Yuqin¹, LIU Jing¹, BAO Eerdun³, ZHANG Ruifu¹, LI Yuanyuan¹, LI Dandan¹, QIN Jiang¹

¹Agricultural College of Inner Mongolia University for Nationalities /Engineering Research Center of Feed Crops in Inner Mongolia Autonomous Region, Tongliao, Inner Mongolia 028042
²Institute of Agriculture and Forestry of Ulanqab, Ulanqab, Inner Mongolia 012000
³Research Institute of Agriculture and Animal Husbandry Science in Tongliao, Tongliao, Inner Mongolia 028000

Received:2021-11-15 Revised:2021-03-17 Online:2022-06-25 Published:2022-07-14
Contact: YANG Hengshan

摘要/Abstract

摘要：

为研究浅埋滴灌条件下灌溉定额对玉米根系形态特征和生理特性的影响。以‘农华101’为供试品种,在浅埋滴灌条件下,灌溉定额设1600 m³/hm²(W1)、2000 m³/hm²(W2)和2400 m³/hm²(W3)3个处理,以传统畦灌灌溉定额4000 m³/hm²为对照(CK),于2017和2018年进行田间试验。结果表明,W1、W2处理与CK之间的玉米籽粒产量差异不显著,W3处理显著高于CK;各处理灌溉水利用效率均显著高于CK。玉米根干重,0~20 cm土层吐丝期2017年浅埋滴灌各处理均显著低于CK,2018年W1处理显著低于CK,W2、W3处理与CK之间的差异不显著,0~20 cm土层完熟期2年均表现为W1处理显著低于CK,W2、W3处理与CK之间的差异不显著;20~40 cm土层吐丝期和完熟期均表现为W1处理显著低于CK,W3、W2处理与CK之间的差异不显著。株、行间根幅10、20 cm土层处处理间差异不显著;30 cm土层处行间根幅W1、W2处理显著低于CK,W3处理与CK之间的差异不显著,株间根幅各处理均显著低于CK。根条数吐丝期10 cm土层处W3处理显著高于CK,W1、W2处理与CK之间的差异不显著,20 cm土层处W2、W3处理显著高于CK,W1处理与CK之间的差异不显著;乳熟期10、20 cm土层处均表现为W3处理显著高于CK,W1、W2处理与CK之间的差异不显著。根系活力各处理均低于CK,处理间随着灌溉定额的增加而增大,随着土层的加深差异逐渐减小;SOD、POD酶活性0~20 cm土层吐丝期和乳熟期处理间差异均不显著,20~40 cm土层吐丝期SOD、POD酶活性W1处理显著低于CK,W2、W3处理与CK之间的差异不显著,乳熟期SOD酶活性表现W1处理显著低于CK,W2、W3处理与CK之间的差异不显著,POD酶活性W1、W2处理显著低于CK,W3处理与CK之间的差异不显著;MDA含量0~20 cm土层吐丝期处理间差异不显著,乳熟期W1处理显著低于CK,W2、W3处理与CK之间的差异不显著,20~40 cm土层吐丝期和乳熟期处理间差异均不显著。浅埋滴灌节水灌溉使玉米根系在土壤表层分布比例增加,适当增加灌溉定额有利于提高玉米根条数和根系酶活性,可为水肥利用效率的提高创造条件。本研究可为玉米浅埋滴灌高产高效栽培提供依据。

关键词: 玉米, 浅埋滴灌, 灌溉定额, 根系特征, 籽粒产量

Abstract:

To study the effects of irrigation quota on the morphological and physiological characteristics of maize root under shallow-buried drip irrigation, field experiments were carried out by using ‘Nonghua 101’ as the experimental variety in 2017 and 2018. The irrigation quota of 1600 m³/hm² (W1), 2000 m³/hm² (W2) and 2400 m³/hm² (W3) were set under shallow-buried drip irrigation by taking 4000 m³/hm² irrigation quota of the traditional border irrigation as a control (CK). The results showed that there was no significant difference among the yield of W1, W2 and CK, and the yield of W3 was significantly higher than that of CK. The irrigation water use efficiency of each treatment was all significantly higher than that of CK. The root dry weight of each treatment under the shallow-buried drip irrigation in 0-20 cm soil layer were all significantly lower than that of CK in silking stage in 2017. The root dry weight of W1 was significantly lower than that of CK in 2018, while there was no significant difference among W2, W3 and CK. In the maturity stage in both 2017 and 2018, the root dry weight of W1 was significantly lower than that of CK, and the difference among W2, W3 and CK was not obvious. The root dry weight of W1 in 20-40 cm soil layer in silking stage and maturity stage were both lower than that of CK, and there was no significant difference among W3, W2 and CK. There was no significant difference among the root width between plants and rows of each treatment in 10 cm and 20 cm soil layer; the root width between rows of W1 and W2 were both significantly lower than that of CK in 30 cm soil layer, while W3 had no significant difference with CK, while the root width between plants of each treatment were all significantly lower than that of CK. In 10 cm soil layer, the root number of W3 was significantly higher than that of CK in silking stage, and there was no significant difference among W1, W2 and CK. In 20 cm soil layer, the root number per plant of W2 and W3 were significantly higher than that of CK, while W1 had no significant difference with CK. In 10 cm and 20 cm soil layer, the root number of W3 was significantly higher than that of CK in milk stage, and there was no significant difference among W1, W2 and CK. The root vitality of the treatments were all lower than that of CK, and the difference increased with the increase of irrigation quota while gradually decreased with the deepening of the soil layer. In 0-20 cm soil layer, the activities of superoxide dismutase (SOD) and peroxidase (POD) of each treatment had no significant difference in both the silking stage and milk stage. The activities of SOD and POD of W1 in 20-40 cm soil layer were lower than those of CK in silking stage, while there was no significant difference among W2, W3 and CK. The activity of SOD of W1 was significantly lower than that of CK in milk stage, while there was no significant difference among W2, W3 and CK, and the activity of POD of W1 and W2 were significantly lower than that of CK, and W3 had no significant difference with that of CK. The content of MDA of W1 was significantly lower than that of CK in 0-20cm soil layer in milk stage, and there was no significant difference among W2, W3 and CK. The content of MDA in 20-40 cm soil layer had no obvious difference among the treatments in both the silking stage and milk stage. The shallow-buried drip irrigation can increase the proportion of root distribution in topsoil, and appropriate increasing irrigation quota is conducive to the improvement of root number and root enzyme activity, which can increase water and fertilizer utilization efficiency. This article can provide a basis for maize high-yield and high-efficiency cultivation under the shallow-buried drip irrigation.

Key words: maize, shallow-buried drip irrigation, irrigation quota, root characteristics, maize kernel yield

中图分类号:

S513

郭子赫, 杨恒山, 赵培军, 张玉芹, 刘晶, 包额尔敦, 张瑞富, 李媛媛, 李丹丹, 秦江. 浅埋滴灌条件下灌溉定额对玉米根系形态特征和生理特性的影响[J]. 中国农学通报, 2022, 38(18): 12-19.

GUO Zihe, YANG Hengshan, ZHAO Peijun, ZHANG Yuqin, LIU Jing, BAO Eerdun, ZHANG Ruifu, LI Yuanyuan, LI Dandan, QIN Jiang. Effects of Irrigation Quota on Morphological and Physiological Characteristics of Maize Root Under Shallow-buried Drip Irrigation[J]. Chinese Agricultural Science Bulletin, 2022, 38(18): 12-19.

图/表 8

参考文献 20

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年份	5月	6月	7月	8月	9月	全年
2017年	37.4	73.0	106.5	162.4	14.1	437.5
2018年	34.0	66.4	96.9	147.7	14.6	397.9
历年平均	30.1	70.7	112.6	86.1	31.8	380.9

年份	5月	6月	7月	8月	9月	全年
2017年	37.4	73.0	106.5	162.4	14.1	437.5
2018年	34.0	66.4	96.9	147.7	14.6	397.9
历年平均	30.1	70.7	112.6	86.1	31.8	380.9

处理	播种—出苗		拔节期—大喇叭口		抽雄—吐丝		吐丝—灌浆		灌浆—成熟
处理	生育阶段灌水量/(m³/hm²)	灌溉频次/次	生育阶段灌水量/(m³/hm²)	灌溉频次/次	生育阶段灌水量/(m³/hm²)	灌溉频次/次	生育阶段灌水量/(m³/hm²)	灌溉频次/次	生育阶段灌水量/(m³/hm²)	灌溉频次/次
W1	550	1	490	2	200	1	300	2	60	1
W2	550	1	670	2	270	1	430	2	80	1
W3	550	1	850	2	350	1	550	2	100	1
CK	1000	1	1000	1	1000	1	1000	1	-	-

处理	播种—出苗		拔节期—大喇叭口		抽雄—吐丝		吐丝—灌浆		灌浆—成熟
处理	生育阶段灌水量/(m³/hm²)	灌溉频次/次	生育阶段灌水量/(m³/hm²)	灌溉频次/次	生育阶段灌水量/(m³/hm²)	灌溉频次/次	生育阶段灌水量/(m³/hm²)	灌溉频次/次	生育阶段灌水量/(m³/hm²)	灌溉频次/次
W1	550	1	490	2	200	1	300	2	60	1
W2	550	1	670	2	270	1	430	2	80	1
W3	550	1	850	2	350	1	550	2	100	1
CK	1000	1	1000	1	1000	1	1000	1	-	-

年份	灌溉定额	有效穗数/穗	穗粒数/粒	千粒重/g	实测产量/(t/hm²)	灌溉水利用效率/(kg/m³)
2017	W1	6.79±0.21a	512.32±15.76a	321.16±11.36b	10.78±0.36c	7.49±0.59a
	W2	6.93±0.35a	506.81±21.33a	344.33±17.18ab	11.79±0.27b	6.55±0.46ab
	W3	6.89±0.16a	529.19±18.76a	351.27±12.62a	12.66±0.41a	5.86±0.31b
	CK	6.53±0.27a	526.83±36.33a	347.86±13.53a	11.29±0.33bc	3.14±0.17c
2018	W1	6.96±0.31a	498.68±12.10b	338.13±17.29b	11.13±0.34c	7.73±0.43a
	W2	6.81±0.18a	516.96±23.41ab	361.66±13.31ab	11.93±0.51bc	6.63±0.36b
	W3	6.86±0.26a	528.68±12.10a	378.13±11.28a	12.81±0.34a	5.93±0.22b
	CK	6.61±0.15a	512.96±13.41ab	362.66±18.39ab	12.03±0.41b	3.34±0.28c

浅埋滴灌条件下灌溉定额对玉米根系形态特征和生理特性的影响

Effects of Irrigation Quota on Morphological and Physiological Characteristics of Maize Root Under Shallow-buried Drip Irrigation

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年份	时期	灌溉定额	根干质量/g					总和
年份	时期	灌溉定额	0~20 cm	20~40 cm	40~60 cm	60~80 cm	80~100 cm	总和
2017年	吐丝期	W1	14.52±0.28c	0.81±0.11b	0.29±0.11a	0.19±0.09a	0.08±0.04a	15.89±0.56b
		W2	16.62±0.72b	0.95±0.45ab	0.37±0.09a	0.24±0.08a	0.14±0.06a	18.32±1.04a
		W3	17.03±0.36b	1.06±0.28ab	0.36±0.13a	0.28±0.07a	0.18±0.03a	18.91±0.61a
		CK	18.09±0.51a	1.17±0.13a	0.41±0.17a	0.29±0.11a	0.17±0.07a	20.13±0.95a
	乳熟期	W1	13.07±0.21c	0.68±0.15b	0.30±0.05a	0.21±0.05a	0.06±0.04a	14.32±0.31c
		W2	13.97±0.32b	0.76±0.23ab	0.33±0.05a	0.22±0.05a	0.12±0.04a	15.40±0.63b
		W3	15.23±1.09ab	0.87±0.16ab	0.39±0.10a	0.26±0.09a	0.15±0.03a	16.90±1.02ab
		CK	15.69±0.89a	0.89±0.06a	0.43±0.10a	0.29±0.09a	0.18±0.03a	17.48±0.98a
	完熟期	W1	9.55±0.47b	0.53±0.06b	0.23±0.03a	0.07±0.03a	-	10.38±0.54b
		W2	10.97±1.03ab	0.62±0.13ab	0.28±0.11a	0.11±0.07a	-	11.98±1.10ab
		W3	11.38±0.44a	0.64±0.12ab	0.32±0.07a	0.11±0.04a	-	12.45±0.62a
		CK	11.85±0.76a	0.71±0.07a	0.28±0.05a	0.17±0.03a	-	13.01±0.81a
2018年	吐丝期	W1	16.64±0.56b	0.87±0.13b	0.44±0.04b	0.21±0.09a	0.19±0.08a	18.35±0.79b
		W2	17.93±0.77ab	0.93±0.09ab	0.56±0.07a	0.29±0.08a	0.17±0.05a	19.88±0.84ab
		W3	18.09±0.45a	1.02±0.11ab	0.61±0.08a	0.36±0.07a	0.22±0.03a	20.30±0.62a
		CK	18.38±0.92a	1.18±0.17a	0.58±0.13a	0.41±0.11a	0.19±0.07a	20.74±1.01a
	乳熟期	W1	14.09±0.91c	0.72±0.13a	0.46±0.08b	0.29±0.08a	0.10±0.03a	16.46±1.04b
		W2	15.64±0.82bc	0.79±0.09a	0.52±0.05b	0.23±0.07a	0.17±0.06a	17.55±0.92b
		W3	16.09±0.91ab	0.77±0.13a	0.56±0.08ab	0.29±0.08a	0.12±0.03a	17.83±0.98ab
		CK	17.64±1.02a	0.83±0.10a	0.65±0.05a	0.33±0.07a	0.18±0.06a	19.63±1.07a
	完熟期	W1	10.73±0.51b	0.52±0.07b	0.27±0.05a	0.13±0.01a	-	11.65±0.61b
		W2	11.70±1.03ab	0.61±0.13ab	0.35±0.11a	0.21±0.07a	-	12.87±1.12ab
		W3	11.99±0.71a	0.67±0.13ab	0.36±0.08a	0.18±0.08a	-	13.20±0.95a
		CK	12.14±0.51a	0.71±0.10a	0.35±0.05a	0.33±0.07a	-	13.53±0.59a

生育时期	酶活性	灌溉定额	0~20 cm	20~40 cm	40~60 cm	60~80 cm	80~100 cm
吐丝期	SOD/(U/g)	W1	144.23±19.12a	118.33±15.68b	112.36±21.23a	99.28±18.36a	118.32±12.53a
		W2	151.22±15.75a	132.23±10.12ab	114.24±6.89a	101.32±20.11a	126.85±9.69a
		W3	148.15±18.22a	140.37±21.33ab	128.36±13.13a	106.28±11.13a	119.12±8.69a
		CK	161.36±21.32a	155.19±16.53a	133.88±10.13a	119.39±9.16a	130.79±13.23a
	POD/(U/g)	W1	67.28±6.39a	54.31±6.63b	56.58±2.55a	46.82±9.23a	44.12±8.07a
		W2	72.13±3.22a	65.56±3.14ab	59.32±9.71a	46.23±11.06a	46.14±5.17a
		W3	75.76±6.18a	68.79±4.28ab	63.51±8.03a	58.18±10.21a	54.36±9.26a
		CK	79.44±7.35a	71.11±9.09a	67.29±10.13a	54.06±2.06a	51.68±8.16a
	MDA/(μmol/g)	W1	7.88±1.31a	7.28±0.16a	6.62±1.01a	5.90±0.36a	5.97±0.12a
		W2	7.34±0.64a	6.82±1.11a	5.76±0.38a	5.51±0.39a	5.38±0.46b
		W3	7.08±0.69a	6.69±0.51a	6.39±0.82a	5.43±0.38a	5.62±0.28a
		CK	6.98±2.01a	6.54±1.03a	6.45±0.37a	5.37±0.64a	5.26±1.01a
乳熟期	SOD/(U/g)	W1	203.90±11.62a	181.76±18.37b	171.76±18.32a	159.84±8.17a	158.54±8.55a
		W2	219.00±23.68a	187.43±11.65ab	168.68±8.65a	161.52±18.69a	153.50±17.11a
		W3	212.81±15.09a	205.32±20.26ab	179.06±19.16a	181.81±26.32a	142.84±8.96a
		CK	220.77±10.96a	218.38±11.17a	186.41±22.53a	145.09±17.13a	167.66±11.36a
	POD/(U/g)	W1	78.83±6.32a	69.12±5.31b	63.33±3.23a	60.85±5.61a	53.16±2.36b
		W2	82.82±7.18a	75.17±4.16b	64.31±1.96a	59.73±7.13a	57.62±1.82a
		W3	86.43±10.93a	80.19±9.10ab	71.62±8.78a	53.51±6.54a	60.74±6.39a
		CK	85.38±9.28a	88.28±6.22a	81.58±6.77a	67.00±1.68a	55.00±5.68a
	MDA/(μmol/g)	W1	9.83±0.83a	8.96±1.03a	7.62±0.91a	7.17±0.19a	6.82±0.55a
		W2	8.31±0.21ab	8.28±0.25a	7.82±0.19a	7.23±0.71a	6.31±0.39a
		W3	8.02±0.22ab	7.63±0.38a	7.22±0.31a	6.82±0.16a	6.33±1.02a
		CK	7.28±1.16b	7.95±0.22a	6.68±0.56a	6.56±0.33a	6.49±0.97a

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