Effects of Nitrogen Application Rate and Nitrogen Fertilizer Type on Growth and Development of Potato and Nitrogen Utilization

doi:10.11924/j.issn.1000-6850.casb2025-0254

Abstract

Abstract:

To provide a theoretical basis for scientific nitrogen fertilization, increasing yield and economic benefits, and reducing environmental risks, the effects of nitrogen application rate and nitrogen fertilizer type on potato growth, development and nitrogen utilization were studied. Using ‘Xisen 6’ and ‘Chuanyu 62’ as test materials, a randomized block design was employed with five nitrogen application treatments, including a nitrogen-free control (CK), conventional urea nitrogen at 67.5 kg/hm², slow-release urea nitrogen at 67.5 kg/hm², conventional urea nitrogen at 135 kg/hm², and slow-release urea nitrogen at 135 kg/hm². The results showed that the emergence occurred earlier under low nitrogen treatments compared to high nitrogen treatments. At the same growth stage and nitrogen application level, the emergence rate was higher under slow-release nitrogen fertilizer treatments than that of conventional nitrogen fertilizer treatments. With increasing nitrogen application rate, plant height, leaf area index, and chlorophyll content increased for both varieties. However, excessive nitrogen application reduced stem diameter. Agronomic traits were superior under slow-release nitrogen fertilizer treatments compared to conventional nitrogen fertilizer treatments. Plant nitrogen accumulation increased with higher nitrogen application rates. However, nitrogen agronomic efficiency, nitrogen production efficiency, nitrogen uptake efficiency and nitrogen use efficiency (NUE) significantly decreased. At the same nitrogen application level, NUE was better under slow-release nitrogen fertilizer treatments than under conventional nitrogen fertilizer treatments. Within the experimental range, for ‘Xisen 6’, yield increased significantly with increasing nitrogen application. At the same nitrogen level, yields under slow-release nitrogen fertilizer treatments were significantly higher than under conventional nitrogen fertilizer treatments. The highest yield (58000.3 kg/hm²) was achieved with the 135.0 kg/hm² slow-release nitrogen treatment, representing a 16.7% increase compared to the same rate of conventional nitrogen fertilizer. The yield of ‘Chuanyu 62’ increased first and then decreased with the increase of nitrogen application rate, and the differences among treatments were significant. The highest yield was achieved under the treatment of 67.5 kg/hm² of slow-release nitrogen fertilizer, reaching 43294.2 kg/hm², which was significantly higher than that of the control (CK), compared with the conventional nitrogen fertilizer treatment at the same nitrogen application rate, the yield increased by 5.2%. Compared to conventional nitrogen fertilizer treatments, slow-release nitrogen fertilizer treatments also resulted in better marketable tuber rates and harvest indices. Scientific nitrogen application promoted plant growth and optimized dry matter accumulation and partitioning. Slow-release nitrogen fertilizer significantly improved emergence rate, facilitated higher plant nitrogen accumulation, and enhanced nitrogen use efficiency. Under the ecological conditions of this experimental region, applying slow-release nitrogen fertilizer at 135.0 kg/hm² for mid-maturing varieties (such as ‘Xisen 6’) and at 67.5 kg/hm² for mid-late maturing varieties (such as ‘Chuanyu 62’) can achieve higher yields and economic benefits.

Key words: potato, slow-release nitrogen, nitrogen use efficiency, agronomic traits, dry matter accumulation

WANG Kexiu, TANG Mingxia, CHENG Mingjun, HU Jianjun, LI Bing, LIAO Feifei, LI Huapeng, YANG Wenting, GUO Zhan, CUI Kuoshu. Effects of Nitrogen Application Rate and Nitrogen Fertilizer Type on Growth and Development of Potato and Nitrogen Utilization[J]. Chinese Agricultural Science Bulletin, 2026, 42(1): 1-11.

Figures/Tables 8

References 54

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品种	施氮量与氮肥类型/(kg/hm²)	出苗时间/d	出苗率/%
品种	施氮量与氮肥类型/(kg/hm²)	出苗时间/d	播种后69 d	播种后92 d
希森6号	0(CK)	53	95.5±6.43a	98.9±0.79a
	67.5（常规氮）	66	86.4±0.00b	98.4± 0.95a
	67.5（缓释氮）	62	95.5±6.43a	98.9±1.08a
	135.0（常规氮）	71	73.9±1.61c	94.3±1.55b
	135.0（缓释氮）	67	87.5±1.61ab	98.6±0.98a
川芋62	0(CK)	69	79.5±3.21a	98.1±0.68a
	67.5（常规氮）	75	71.6±1.61a	97.5±1.76a
	67.5（缓释氮）	66	87.5±11.25a	97.1±0.93ab
	135.0（常规氮）	69	78.4±8.04a	94.3±3.27b
	135.0（缓释氮）	71	73.9± 1.61a	96.4±2.41ab

品种	施氮量与氮肥类型/(kg/hm²)	出苗时间/d	出苗率/%
品种	施氮量与氮肥类型/(kg/hm²)	出苗时间/d	播种后69 d	播种后92 d
希森6号	0(CK)	53	95.5±6.43a	98.9±0.79a
	67.5（常规氮）	66	86.4±0.00b	98.4± 0.95a
	67.5（缓释氮）	62	95.5±6.43a	98.9±1.08a
	135.0（常规氮）	71	73.9±1.61c	94.3±1.55b
	135.0（缓释氮）	67	87.5±1.61ab	98.6±0.98a
川芋62	0(CK)	69	79.5±3.21a	98.1±0.68a
	67.5（常规氮）	75	71.6±1.61a	97.5±1.76a
	67.5（缓释氮）	66	87.5±11.25a	97.1±0.93ab
	135.0（常规氮）	69	78.4±8.04a	94.3±3.27b
	135.0（缓释氮）	71	73.9± 1.61a	96.4±2.41ab

品种	施氮量与氮肥类型/(kg/hm²)	株高/cm	茎粗/mm	主茎数/(个/株)	叶面积指数(LAI)	叶绿素含量(SPAD)
希森6号	0(CK)	21.4±3.60b	10.5±0.66a	5.8±0.96a	1.0±0.08c	31.0±2.79c
	67.5（常规氮）	26.8±1.39a	10.7±0.95a	5.5±0.58a	1.5±0.35b	38.3±0.73b
	67.5（缓释氮）	26.9±3.45a	11.5±1.48a	5.0±0.00a	1.4±0.23b	37.1±2.87b
	135.0（常规氮）	27.6±1.51a	10.7±0.84a	5.3±0.50a	1.7±0.22ab	39.5±0.77b
	135.0（缓释氮）	27.3±2.74a	10.9±1.04a	5.3±0.50a	1.9±0.42a	43.1±1.47a
川芋62	0(CK)	34.0±4.62c	11.0±1.07a	6.5±1.29a	1.6±0.36c	29.0±1.29c
	67.5（常规氮）	63.9±6.01b	11.4±0.33a	6.3±0.96a	3.4±1.04b	32.1±2.49b
	67.5（缓释氮）	67.4±1.06b	12.1±0.77a	6.5±1.73a	3.9±1.13ab	31.8±0.66b
	135.0（常规氮）	98.4±7.62a	11.5±1.87a	6.0±2.00a	5.4±1.82a	35.9±1.31a
	135.0（缓释氮）	104.2±11.63a	11.0±0.72a	7.0±1.83a	5.2±1.36a	35.5±0.52a

品种	施氮量与氮肥类型/(kg/hm²)	株高/cm	茎粗/mm	主茎数/(个/株)	叶面积指数(LAI)	叶绿素含量(SPAD)
希森6号	0(CK)	21.4±3.60b	10.5±0.66a	5.8±0.96a	1.0±0.08c	31.0±2.79c
	67.5（常规氮）	26.8±1.39a	10.7±0.95a	5.5±0.58a	1.5±0.35b	38.3±0.73b
	67.5（缓释氮）	26.9±3.45a	11.5±1.48a	5.0±0.00a	1.4±0.23b	37.1±2.87b
	135.0（常规氮）	27.6±1.51a	10.7±0.84a	5.3±0.50a	1.7±0.22ab	39.5±0.77b
	135.0（缓释氮）	27.3±2.74a	10.9±1.04a	5.3±0.50a	1.9±0.42a	43.1±1.47a
川芋62	0(CK)	34.0±4.62c	11.0±1.07a	6.5±1.29a	1.6±0.36c	29.0±1.29c
	67.5（常规氮）	63.9±6.01b	11.4±0.33a	6.3±0.96a	3.4±1.04b	32.1±2.49b
	67.5（缓释氮）	67.4±1.06b	12.1±0.77a	6.5±1.73a	3.9±1.13ab	31.8±0.66b
	135.0（常规氮）	98.4±7.62a	11.5±1.87a	6.0±2.00a	5.4±1.82a	35.9±1.31a
	135.0（缓释氮）	104.2±11.63a	11.0±0.72a	7.0±1.83a	5.2±1.36a	35.5±0.52a

品种	施氮量与氮肥类型/(kg/hm²)	分配量/(kg/hm²)		分配比例/%
品种	施氮量与氮肥类型/(kg/hm²)	叶茎	块茎	叶茎	块茎
希森6号	0(CK)	648.9±51.7c	7020.3± 592.1b	8.5±0.6b	91.5±0.6a
	67.5（常规氮）	924.4±11.6b	7084.1±1562.0ab	9.4±1.3ab	90.6±1.3ab
	67.5（缓释氮）	931.8±89.7b	8924.5±981.1ab	9.5±1.6ab	90.5±1.6ab
	135.0（常规氮）	1109.3±139.5ab	8253.0±1067.7ab	12.0±1.9a	88.0±1.9b
	135.0（缓释氮）	1166.0±212.6a	9947.7±1743.9a	10.5±1.4ab	89.5±1.4ab
川芋62	0(CK)	1260.0 ±111.7b	6799.8±679.1a	15.7±1.4b	84.3±1.4a
	67.5（常规氮）	2410.1±516.9b	8079.8±1886.7a	23.3±4.8b	76.7±4.8a
	67.5（缓释氮）	2624.5±534.6b	9557.8±2519.3a	21.8±3.8b	78.2±3.8a
	135.0（常规氮）	4862.8±1954.6ab	6976.2±1340.2a	39.8±6.0a	60.2±6.0b
	135.0（缓释氮）	4707.4±1347.1a	6945.2±1480.8a	40.4±11.6a	59.6±11.6b