密植精准调控技术对新疆鲜食糯玉米商品品质的影响

doi:10.16035/j.issn.1001-7283.2026.03.009

作物杂志,2026, 第3期: 64–70 doi: 10.16035/j.issn.1001-7283.2026.03.009

• 第二十八届中国科协年会学术论文专栏（主要粮食作物产能品质提升与高质量发展路径） • 上一篇下一篇

密植精准调控技术对新疆鲜食糯玉米商品品质的影响

吕建晔¹^,²(), 丁万红³, 刘强⁴, 张鹏鹏², 唐勇³, 任红松⁵, 薛军², 明博², 李少昆¹^,²()

¹ 宁夏大学农学院， 750021，宁夏银川
² 中国农业科学院作物科学研究所/农业农村部作物生理生态重点实验室， 100081，北京
³ 新疆维吾尔自治区农业科学院乌鲁木齐综合试验站， 830000，新疆乌鲁木齐
⁴ 伊犁哈萨克自治州农业科学研究所， 835000，新疆伊犁
⁵ 新疆维吾尔自治区农业科学院农业质量标准与检测技术研究所， 830091，新疆乌鲁木齐

收稿日期:2025-12-09 修回日期:2026-01-19 出版日期:2026-06-15 发布日期:2026-06-17
通讯作者: 李少昆，主要从事玉米生态生理及高产高效栽培理论研究，E-mail：lishaokun@caas.cn
作者简介:吕建晔，主要从事玉米高产高效栽培理论研究，E-mail：lvjianye1113@163.com
基金资助:
新疆维吾尔自治区重点研发专项(2023B02041-2)

Effects of Precision Regulation for Dense Planting on Commercial Quality of Fresh Waxy Maize in Xinjiang

Lü Jianye¹^,²(), Ding Wanhong³, Liu Qiang⁴, Zhang Pengpeng², Tang Yong³, Ren Hongsong⁵, Xue Jun², Ming Bo², Li Shaokun¹^,²()

¹ College of Agriculture, Ningxia University, Yinchuan 750021, Ningxia, China
² Institute of Crop Sciences, Chinese Academy of Agricultural Sciences / Key Laboratory of Crop Physiology and Ecology, Ministry of Agriculture and Rural Affairs, Beijing 100081, China
³ Urumqi Comprehensive Experiment Station, Xinjiang Academy of Agricultural Sciences, Urumqi 830000, Xinjiang, China
⁴ Institute of Agricultural Sciences of Ili Kazakh Autonomous Prefecture, Ili 835000, Xinjiang, China
⁵ Institute of Agricultural Quality Standards and Testing Technology, Xinjiang Academy of Agricultural Sciences, Urumqi 830091, Xinjiang, China

Received:2025-12-09 Revised:2026-01-19 Online:2026-06-15 Published:2026-06-17

摘要/Abstract

摘要：

针对我国鲜食糯玉米种植密度低和增密易导致商品率下降的产业瓶颈，于2024-2025年在新疆伊犁河谷灌区开展田间试验。以万糯2000为材料，设置79 500、84 000和88 500株/hm² 3个密度梯度，以及常规水肥（CK）与密植精准调控（T1）2种管理模式，分析其对果穗商品性状、水肥利用效率及经济效益的影响。结果表明，T1处理可显著缓解增密对商品品质的负面效应。与CK处理相比，T1处理合格商品穗数提高了12.85%~16.11%，商品率提升了10.96%~14.01%，空秆率降低了24.82%~31.48%，秃尖长度显著缩短，灌溉水生产力和氮肥偏生产力分别提高了54.42%~73.89%和15.82%~30.42%。经济效益分析显示，T1处理下净收益较CK处理提高了18.19%~25.62%，其中以79 500株/hm²密度结合T1处理的经济效益最优，净收益达2.57万元/hm²。综上，在密植精准调控条件下实施适度密植，可协同提升鲜食糯玉米的商品品质、资源效率与经济效益。

关键词: 鲜食糯玉米, 适度密植, 精准调控, 商品品质, 水肥调控

Abstract:

To address the industry bottlenecks of low planting density and the decline in marketable rate caused by densification of fresh waxy maize in China, field experiments were conducted in the irrigated region of the Ili River Valley, Xinjiang, from 2024 to 2025. Using Wannuo 2000 as the material, three density gradients (79 500, 84 000, and 88 500 plants/ha) and two management modes [conventional water and fertilizer management (CK) and precision regulation in dense planting (T1)] were established to analyze their effects on ear commercial traits, water and fertilizer use efficiency, and economic benefits. The results showed that the T1 treatment significantly alleviated the negative effects of increased density on commercial quality. Compared with the CK, T1 increased the number of qualified commercial ears by 12.85%-16.11%, improved the marketable rate by 10.96%-14.01%, reduced the barren stalk rate by 24.82%-31.48%, and significantly shortened the bald tip length. Irrigation water productivity and nitrogen partial factor productivity increased by 54.42%-73.89% and 15.82%-30.42%, respectively. Economic benefit analysis showed that the net income under the T1 treatment increased by 18.19%-25.62% compared with the CK treatment, among which the combination of 79 500 plants/ha density and T1 treatment achieved the optimal economic benefit, with a net income of 25 700 yuan/ha. In conclusion, implementing moderate densification under precision regulation conditions can synergistically improve the commercial quality, resource efficiency, and economic benefits of fresh waxy maize.

Key words: Fresh waxy maize, Moderate dense planting, Precision regulation, Commercial quality, Water-fertilizer regulation

吕建晔, 丁万红, 刘强, 张鹏鹏, 唐勇, 任红松, 薛军, 明博, 李少昆. 密植精准调控技术对新疆鲜食糯玉米商品品质的影响[J]. 作物杂志, 2026 (3): 64–70

Lü Jianye, Ding Wanhong, Liu Qiang, Zhang Pengpeng, Tang Yong, Ren Hongsong, Xue Jun, Ming Bo, Li Shaokun. Effects of Precision Regulation for Dense Planting on Commercial Quality of Fresh Waxy Maize in Xinjiang[J]. Crops, 2026(3): 64–70

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参考文献 14

[1]	李紫琪, 古艳婷, 郭燕枝, 等. 我国鲜食玉米标准体系及营养标准研究. 食品安全质量检测学报, 2022, 13(18):5964-5973.
[2]	徐丽, 卢柏山, 赵久然. “甜味糯”新型鲜食玉米及其代表品种京科糯768的选育. 植物遗传资源学报, 2023, 24(1):317-324. doi: 10.13430/j.cnki.jpgr.20220726001
[3]	赵久然, 卢柏山, 史亚兴, 等. 我国糯玉米育种及产业发展动态. 玉米科学, 2016, 24(4):67-71.
[4]	Zhang W Q, Fan Y L, Zhang S, et al. Waxy maize yield in response to a novel plant growth regulator and plant density. International Journal of Agriculture and Biology, 2019, 22(2):304-312.
[5]	Wang Z H, Niu S D, Yao X Y, et al. Grain yield and nutrient absorption and utilization of spring-sown waxy maize under different plant densities and fertilization modes. Journal of Integrative Agriculture, 2025, 24(1):1-44.
[6]	Pierik R, de Wit M. Shade avoidance: phytochrome signaling and other aboveground neighbor detection cues. Journal of Experimental Botany, 2014, 65(11):2815-2824. doi: 10.1093/jxb/ert389
[7]	杨国虎, 李新, 王承莲, 等. 种植密度影响玉米产量及部分产量相关性状的研究. 西北农业学报, 2006, 15(5):57-60,64.
[8]	Zuber M S, Kang M S. Corn lodging slowed by sturdier stalks. Crops and Soil Magazine, 1978, 30(5):1-32.
[9]	Wang Y G, Zhang G Q, Li R F, et al. Pathways to increase maize yield in Northwest China: a multi-year, multi-variety analysis. European Journal of Agronomy, 2023, 149:126892. doi: 10.1016/j.eja.2023.126892
[10]	李传哲, 许仙菊, 马洪波, 等. 水肥一体化技术提高水肥利用效率研究进展. 江苏农业学报, 2017, 33(2):469-475.
[11]	Liu G Z, Yang Y S, Guo X X, et al. A global analysis of dry matter accumulation and allocation for maize yield breakthrough from 1.0 to 25.0 Mg ha^-1. Resources,Conservation and Recycling, 2023, 188:106656. doi: 10.1016/j.resconrec.2022.106656
[12]	毛圆圆, 薛军, 翟娟, 等. 水肥一体化条件下密植高产玉米适宜追氮次数研究. 植物营养与肥料学报, 2022, 28(12):2227-2238.
[13]	范虹, 殷文, 胡发龙, 等. 绿洲灌区密植对氮肥减量玉米产量的补偿潜力. 中国农业科学, 2024, 57(9):1709-1721. doi: 10.3864/j.issn.0578-1752.2024.09.007
[14]	翟娟, 薛军, 张园梦, 等. 水肥一体化条件下施氮量对密植春玉米茎秆抗倒伏性状的影响. 玉米科学, 2021, 29(5):137-144.

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年份 Year	有机质 Organic matter (g/kg)	速效氮 Available N (mg/kg)	有效磷 Available P (mg/kg)	速效钾 Available K (mg/kg)	总盐 Total salt (g/kg)	pH
2024	10.83	67.2	24.23	256.6	2.66	7.86
2025	9.95	58.7	29.80	185.0	2.58	8.53

处理 Treatment	施肥时期 Fertilizer application period	肥料施用量 Fertilizer application amount
处理 Treatment	施肥时期 Fertilizer application period	N	P₂O₅	K₂O
CK	基施	45	45	45
	V6	255	45	135
T1	基施	45	45	45
	V6	75	30	45
	V9	45	0	45
	V12	45	15	45
	V12+10 d	60	0	0
	R1	30	0	0

年份 Year	处理 Treatment	种植密度 Planting density	穗重 Ear weight (g)	穗长 Ear length (cm)	穗粗 Ear diameter (cm)	秃尖长度 Bald tip length (cm)
2024	CK	D1	309.33±34.49a	20.07±1.03a	5.22±0.23a	1.68±1.13a
		D2	306.82±33.00a	20.07±1.03a	5.14±0.20a	1.66±0.60a
	T1	D1	331.31±18.43a	20.84±0.83a	5.43±0.12a	0.90±0.83a
		D2	323.59±20.58a	20.76±0.87a	5.36±0.18a	1.13±0.98a
2025	CK	D1	289.69±18.67a	19.55±0.59a	4.95±0.10a	2.00±0.43a
		D2	296.82±9.23a	19.63±0.72a	4.99±0.11a	1.83±0.52a
		D3	288.48±11.07a	19.09±0.99a	4.92±0.11a	1.91±0.81a
	T1	D1	326.58±12.77a	20.79±0.26a	5.20±0.12a	1.35±0.28a
		D2	326.01±11.14a	20.81±0.25a	5.15±0.11a	1.32±0.26a
		D3	318.02±18.19a	20.57±0.56a	5.12±0.08a	1.37±0.31a
Y			ns	ns	ns	ns
D			ns	ns	ns	ns
W			**	**	**	**
Y×D			ns	ns	ns	ns
Y×W			ns	ns	ns	ns
D×W			ns	ns	ns	ns
Y×D×W			ns	ns	ns	ns

年份 Year	处理 Treatment	种植密度 Planting density	总投入（万元/hm²） Total input (×10⁴ yuan/hm²)							总收入（万元/hm²） Total revenue (×10⁴ yuan/hm²)	净收益（万元/hm²） Net income (×10⁴ yuan/hm²)	产投比 Ratio of output to input
年份 Year	处理 Treatment	种植密度 Planting density	X₁	X₂	X₃	X₄	X₅	X₆	总计 Total	总收入（万元/hm²） Total revenue (×10⁴ yuan/hm²)	净收益（万元/hm²） Net income (×10⁴ yuan/hm²)	产投比 Ratio of output to input
2024	CK	D1	0.47	0.30	0.24	－	0.28	0.66	1.94	4.05b	2.11b	2.09ab
		D2	0.47	0.30	0.25	－	0.28	0.66	1.96	4.00b	2.04b	2.04b
	T1	D1	0.37	0.23	0.24	0.30	0.28	0.66	2.07	4.43a	2.36a	2.14a
		D2	0.37	0.23	0.25	0.30	0.28	0.66	2.08	4.36a	2.28a	2.10ab
2025	CK	D1	0.45	0.30	0.24	－	0.28	0.66	1.92	4.15c	2.23c	2.16c
		D2	0.45	0.30	0.25	－	0.28	0.66	1.94	4.00d	2.06d	2.06d
		D3	0.45	0.30	0.27	－	0.28	0.66	1.95	3.98d	2.03d	2.04d
	T1	D1	0.35	0.23	0.24	0.30	0.28	0.66	2.05	4.83a	2.78a	2.36a
		D2	0.35	0.23	0.25	0.30	0.28	0.66	2.06	4.71ab	2.65ab	2.29b
		D3	0.35	0.23	0.27	0.30	0.28	0.66	2.07	4.62b	2.55b	2.23bc

密植精准调控技术对新疆鲜食糯玉米商品品质的影响

Effects of Precision Regulation for Dense Planting on Commercial Quality of Fresh Waxy Maize in Xinjiang

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[1]	刘文广, 严军, 马国成, 等. 草莓/鲜食糯玉米—水稻高产高效栽培模式[J]. 作物杂志, 2009, (6): 79–80
[2]	梁燕听, 莫武平. 鲜食白糯玉米柳糯8号的选育及栽培要点[J]. 作物杂志, 2007, (4): 104–104
[3]	陈惠阳, 赵琛, 兰霞, 等. 氮与磷、钾配施对糯玉米主要品质成分的影响[J]. 作物杂志, 2006, (4): 5–9
[4]	徐勇, 刘金波, 徐福海, 等. 南农紫玉糯1号的选育及配套栽培技术[J]. 作物杂志, 2005, (6): 67–67
[5]	李德新. 高产优质玉米新品种嫩单10的选育[J]. 作物杂志, 2003, (3): 14–14
[6]	刘蔚平. 双季鲜食糯玉米马铃薯三熟高效栽培[J]. 作物杂志, 2003, (3): 27–27
[7]	王同刚, 王凌汉, 付春. 鲜食糯玉米新品种潍黄糯2号[J]. 作物杂志, 2002, (4): 28–28
[8]	张赞飞, 程立巧, 赵一君, 等. 鲜食糯玉米—大白菜—晚稻高效种植模式[J]. 作物杂志, 2001, (3): 15–15
[9]	石德权. 高赖氨酸玉米的育选和利用[J]. 作物杂志, 1985, (2): 9–10