Phosphorus uptake and utilization characteristics of conventional japonica rice on major paddy soils in northern Zhejiang of China

doi:10.3969/j.issn.1004-1524.20250301

Acta Agriculturae Zhejiangensis ›› 2026, Vol. 38 ›› Issue (3): 417-427.DOI: 10.3969/j.issn.1004-1524.20250301

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Phosphorus uptake and utilization characteristics of conventional japonica rice on major paddy soils in northern Zhejiang of China

WU Yong¹(), XU Zaimeng², LU Chenni², ZHU Yuxiang¹, ZHU Riqing³, SUN Da⁴, SHI Yanping⁵, CHEN Gui²^,^*()

^1. Tongxiang Institute of Agricultural Sciences, Jiaxing Academy of Agricultural Sciences, Tongxiang 314024, Zhejiang, China
^2. Jiaxing Academy of Agricultural Sciences, Jiaxing 314016, Zhejiang, China
^3. Agricultural Technology Extension Station of Xiuzhou District, Jiaxing City, Jiaxing 314001, Zhejiang, China
^4. Agricultural and Fishery Technology Extension Station of Nanhu District, Jiaxing City, Jiaxing 314051, Zhejiang, China
^5. Soil, Fertilizer, Plant Protection and Rural Energy Station of Jiaxing City, Jiaxing 314050, Zhejiang, China

Received:2025-04-14 Online:2026-03-25 Published:2026-04-17
Contact: CHEN Gui

Abstract

Abstract:

This study investigated the interactive effects of paddy soil types and rice varieties on rice yield and phosphorus (P) uptake/utilization characteristics, as well as the key factors influencing these parameters, using four main paddy soil types in northern Zhejiang (blue-purple paddy soil, yellow-mottled paddy soil, powdery paddy soil, and bluish silty-clay paddy soil) and five major conventional japonica rice varieties (Zhejing99, Xiushui14, Xiushui121, Jia67, and Zhehexiang No. 2) as research materials. The results showed that: (1) Significant (p<0.05) differences were observed in yield, aboveground dry matter accumulation at maturity (DA-M), aboveground P accumulation at tillering stage (PA-T), aboveground P accumulation at heading stage (PA-H), aboveground P accumulation at maturity (PA-M), P uptake efficiency (PupE), P physiological use efficiency for biomass (PE-bio), P physiological use efficiency for grains (PE-grain), P translocation amount from leaves (PtrA-L), P translocation amount from stem (PtrA-S), P translocation efficiency from leaves (PtrE-L), and P translocation efficiency from stem (PtrE-S) among rice varieties across different paddy soil types. (2) Rice yield and PupE were significantly affected by both variety and paddy soil type. PE-bio and PE-grain were only significantly influenced by variety. PtrA-L, PtrA-S, and PtrE-S were significantly affected by variety, paddy soil type, and their interaction. PtrE-L was significantly influenced by paddy soil type and its interaction with variety. (3) PupE was positively correlated with yield, DA-M and PA-M at p<0.01 level. PE-bio was positively correlated with PtrE-S at p<0.05 level. PE-grain was positively correlated with PtrE-S at p<0.01 level. In conclusion, selecting rice varieties based on local soil conditions is essential to improve rice yield and P uptake/utilization efficiency.

Key words: conventional japonica rice, paddy soil, phosphorus uptake efficiency, phsphorus physiological use efficiency, phosphorus translocation efficiency

CLC Number:

WU Yong, XU Zaimeng, LU Chenni, ZHU Yuxiang, ZHU Riqing, SUN Da, SHI Yanping, CHEN Gui. Phosphorus uptake and utilization characteristics of conventional japonica rice on major paddy soils in northern Zhejiang of China[J]. Acta Agriculturae Zhejiangensis, 2026, 38(3): 417-427.

Figures/Tables 12

References 31

[1]	吕真真, 刘秀梅, 侯红乾, 等. 长期不同施肥对红壤性水稻土磷素及水稻磷营养的影响[J]. 植物营养与肥料学报, 2019, 25(8): 1316-1324.
	LÜ Z Z, LIU X M, HOU H Q, et al. Effects of long-term fertilizations on soil phosphorus and its supply to rice in red paddy soil[J]. Journal of Plant Nutrition and Fertilizers, 2019, 25(8): 1316-1324.
[2]	白虓宇, 李秀芳, 李传飞, 等. 磷高效水稻材料的根系形态结构特征[J]. 植物营养与肥料学报, 2024, 30(5): 1032-1042.
	BAI X Y, LI X F, LI C F, et al. The root morphological and structural characteristics of phosphorus-efficient rice materials[J]. Journal of Plant Nutrition and Fertilizers, 2024, 30(5): 1032-1042.
[3]	李丹, 楼玲, 章明奎, 等. 杭州湾蔬菜地土壤的磷素积累特点及其淋失临界值[J]. 浙江农业学报, 2025, 37(2): 447-455.
	LI D, LOU L, ZHANG M K, et al. Characteristics of phosphorus accumulation and critical value of phosphorus leaching in vegetable soils of Hangzhou Bay, China[J]. Acta Agriculturae Zhejiangensis, 2025, 37(2): 447-455.
[4]	汪玉, 赵旭, 王磊, 等. 太湖流域稻麦轮作农田磷素累积现状及其环境风险与控制对策[J]. 农业环境科学学报, 2014, 33(5): 829-835.
	WANG Y, ZHAO X, WANG L, et al. Accumulation, environmental risk and control of phosphorus in rice/wheat rotation farmland in Taihu Lake watershed[J]. Journal of Agro-Environment Science, 2014, 33(5): 829-835.
[5]	鲁晨妮, 陈菊根, 程旺大, 等. 嘉兴市长期秸秆还田水稻产量和土壤肥力的调查[J]. 浙江农业科学, 2021, 62(7): 1285-1287.
	LU C N, CHEN J G, CHENG W D, et al. Investigation of rice yield and soil fertility in long-term straw returning field in Jiaxing[J]. Journal of Zhejiang Agricultural Sciences, 2021, 62(7): 1285-1287.
[6]	李秀芳. 磷高效利用水稻材料筛选及磷利用特征研究[D]. 雅安: 四川农业大学, 2023.
	LI X F. Screening of high efficient phosphorus utilization rice materials and study on phosphorus utilization characteristics[D]. Ya’an: Sichuan Agricultural University, 2023.
[7]	王秋菊, 常本超, 孙兵, 等. 不同类型土壤对水稻产量及养分吸收特性的影响[J]. 作物杂志, 2015(3): 116-121.
	WANG Q J, CHANG B C, SUN B, et al. Effects of different soil types on yield and nutrient absorption characters of rice[J]. Crops, 2015(3): 116-121.
[8]	于天一, 逄焕成, 唐海明, 等. 不同母质发育的土壤对双季稻产量及养分吸收特性的影响[J]. 作物学报, 2013, 39(5): 896-904.
	YU T Y, PANG H C, TANG H M, et al. Effects of paddy soils from different parent materials on yield and nutrient uptake characteristics of double-cropping rice[J]. Acta Agronomica Sinica, 2013, 39(5): 896-904.
[9]	王箫璇, 张敏, 张鑫尧, 等. 不同磷肥对砂姜黑土和红壤磷库转化及冬小麦磷素吸收利用的影响[J]. 中国农业科学, 2023, 56(6): 1113-1126.
	WANG X X, ZHANG M, ZHANG X Y, et al. Effects of different varieties of phosphate fertilizer application on soil phosphorus transformation and phosphorus uptake and utilization of winter wheat[J]. Scientia Agricultura Sinica, 2023, 56(6): 1113-1126.
[10]	王月星, 王岳钧. 浙江省水稻生产现状与发展对策[J]. 浙江农业科学, 2019, 60(2): 177-179.
	WANG Y X, WANG Y J. Production situation and development countermeasures of rice in Zhejiang Province[J]. Journal of Zhejiang Agricultural Sciences, 2019, 60(2): 177-179.
[11]	魏孝孚, 吕仁焕, 严学芝, 等. 浙江土种志[M]. 杭州: 浙江科学技术出版社, 1993.
[12]	吴嘉平, 荆长伟, 支俊俊. 浙江省县市土壤图集[M]. 长沙: 湖南地图出版社, 2012.
[13]	鲁如坤. 土壤农业化学分析方法[M]. 北京: 中国农业科技出版社, 1999.
[14]	MOLL R H, KAMPRATH E J, JACKSON W A. Analysis and interpretation of factors which contribute to efficiency of nitrogen utilization[J]. Agronomy Journal, 1982, 74(3): 562-564.
[15]	都江雪, 柳开楼, 黄晶, 等. 中国稻田土壤有效磷时空演变特征及其对磷平衡的响应[J]. 土壤学报, 2021, 58(2): 476-486.
	DU J X, LIU K L, HUANG J, et al. Spatio-temporal evolution characteristics of soil available phosphorus and its response to phosphorus balance in paddy soil in China[J]. Acta Pedologica Sinica, 2021, 58(2): 476-486.
[16]	徐月梅, 彭诗燕, 孙志伟, 等. 不同耐低磷水稻品种的内源激素水平差异及其与产量和磷利用率的关系[J]. 中国水稻科学, 2025, 39(2): 231-244.
	XU Y M, PENG S Y, SUN Z W, et al. Differences in endogenous hormone levels and their relationship with yield and phosphorus use efficiency in rice varieties with various tolerance to low phosphorus stress[J]. Chinese Journal of Rice Science, 2025, 39(2): 231-244.
[17]	孙博, 吴振洋, 秦裕波, 等. 吉林省半干旱地区滴灌玉米的磷肥用量研究[J]. 中国土壤与肥料, 2025(2): 174-182.
	SUN B, WU Z Y, QIN Y B, et al. Study on the amount of phosphate fertilizer under mulched drip irrigation in semi-arid area[J]. Soil and Fertilizer Sciences in China, 2025(2): 174-182.
[18]	邓亚萍. 水稻耐低磷的机理与栽培调控技术[D]. 扬州: 扬州大学, 2022.
	DENG Y P. Mechanism in tolerance to low phosphorus and cultivation regulation techniques of rice[D]. Yangzhou: Yangzhou University, 2022.
[19]	张建恒, 李宾兴, 王斌, 等. 不同磷效率小麦品种光合碳同化和物质生产特性研究[J]. 中国农业科学, 2006, 39(11): 2200-2207.
	ZHANG J H, LI B X, WANG B, et al. Studies on the characteristics of photosynthesis and dry matter production in wheat varieties with different P efficiency[J]. Scientia Agricultura Sinica, 2006, 39(11): 2200-2207.
[20]	李莉, 张锡洲, 李廷轩, 等. 高产磷高效水稻磷素吸收利用特征[J]. 应用生态学报, 2014, 25(7): 1963-1970.
	LI L, ZHANG X Z, LI T X, et al. Characteristics of phosphorus uptake and use efficiency of rice with high yield and high phosphorus use efficiency[J]. Chinese Journal of Applied Ecology, 2014, 25(7): 1963-1970.
[21]	林文雄, 石秋梅, 郭玉春, 等. 水稻磷效率差异的生理生化特性[J]. 应用与环境生物学报, 2003, 9(6): 578-583.
	LIN W X, SHI Q M, GUO Y C, et al. Physio-biochemical characters of P-efficient differences in rice (Oryza sativa L.)[J]. Chinese Journal of Applied and Environmental Biology, 2003, 9(6): 578-583.
[22]	李莉, 张锡洲, 李廷轩, 等. 不同产量类型水稻基因型干物质积累与磷素吸收利用[J]. 植物营养与肥料学报, 2014, 20(3): 588-597.
	LI L, ZHANG X Z, LI T X, et al. Genotype differences in dry matter accumulation and phosphorus absorption and use efficiency in rice[J]. Journal of Plant Nutrition and Fertilizer, 2014, 20(3): 588-597.
[23]	刘星, 邓仕文, 陈英龙, 等. 水稻氮磷高效吸收与利用的特征及机制研究进展[J]. 江苏农业科学, 2024, 52(5): 1-11.
	LIU X, DENG S W, CHEN Y L, et al. Research progress on characteristics and mechanisms of efficient absorption and utilization of nitrogen and phosphorus in rice[J]. Jiangsu Agricultural Sciences, 2024, 52(5): 1-11.
[24]	李永夫, 罗安程, 王为木, 等. 不同供磷水平下水稻磷素吸收利用和产量的基因型差异[J]. 土壤通报, 2005, 36(3): 365-370.
	LI Y F, LUO A C, WANG W M, et al. Genotypic variation of rice in yield, phosphorus uptake and utilization at different phosphous supply[J]. Chinese Journal of Soil Science, 2005, 36(3): 365-370.
[25]	吴照辉, 贺立源, 左雪冬, 等. 低磷胁迫下不同基因型水稻阶段性磷营养特征[J]. 中国水稻科学, 2008, 22(1): 71-76.
	WU Z H, HE L Y, ZUO X D, et al. Characteristics of phosphorus nutrition of different rice genotypes under low-P stress at different growth stages[J]. Chinese Journal of Rice Science, 2008, 22(1): 71-76.
[26]	陈贵, 张红梅, 沈亚强, 等. 嘉兴地区不同基因型水稻的氮利用效率研究[J]. 浙江农业学报, 2015, 27(11): 1965-1970.
	CHEN G, ZHANG H M, SHEN Y Q, et al. Characteristics of N utilization efficiency in different rice genotypes in Jiaxing area[J]. Acta Agriculturae Zhejiangensis, 2015, 27(11): 1965-1970.
[27]	杨建峰, 贺立源, 左雪冬, 等. 不同pH低磷土壤上水稻磷营养特性研究[J]. 植物营养与肥料学报, 2009, 15(1): 62-68.
	YANG J F, HE L Y, ZUO X D, et al. Phosphorous nutritional characteristics of rice in P-deficient soils with different pH values[J]. Plant Nutrition and Fertilizer Science, 2009, 15(1): 62-68.
[28]	夏瑶, 娄运生, 杨超光, 等. 几种水稻土对磷的吸附与解吸特性研究[J]. 中国农业科学, 2002, 35(11): 1369-1374.
	XIA Y, LOU Y S, YANG C G, et al. Characteristics of phosphate adsorption and desorption in paddy soils[J]. Scientia Agricultura Sinica, 2002, 35(11): 1369-1374.
[29]	王晓洁, 卑其成, 刘钢, 等. 不同类型水稻土微生物群落结构特征及其影响因素[J]. 土壤学报, 2021, 58(3): 767-776.
	WANG X J, BEI Q C, LIU G, et al. Microbial abundance and community composition in different types of paddy soils in China and their affecting factors[J]. Acta Pedologica Sinica, 2021, 58(3): 767-776.
[30]	王蕾, 邓兰生, 涂攀峰, 等. 聚磷酸铵水解因素研究进展及在肥料中的应用[J]. 磷肥与复肥, 2015, 30(4): 25-27.
	WANG L, DENG L S, TU P F, et al. Research progresses of hydrolysis factors of ammonium polyphosphate and its application in fertilizer[J]. Phosphate & Compound Fertilizer, 2015, 30(4): 25-27.
[31]	魏晓璠, 徐博, 刘悦, 等. 不同水分管理条件下硫素对稻田土壤磷素有效性的影响研究[J]. 安徽农业大学学报, 2024, 51(4): 690-696.
	WEI X F, XU B, LIU Y, et al. Effects of sulfur on the effectiveness of soil phosphorus under different water management conditions[J]. Journal of Anhui Agricultural University, 2024, 51(4): 690-696.

水稻土类型 Paddy soil type	c_TN/ (g·kg^-1)	c_AN/ (mg·kg^-1)	c_AP/ (mg·kg^-1)	c_AK/ (mg·kg^-1)	c_OM/ (g·kg^-1)	pH值 pH value
青紫泥田Blue-purple paddy soil	1.74	143.0	7.80	69.3	28.1	6.35
黄斑田Yellow-mottled paddy soil	2.05	169.0	15.2	72.7	33.3	6.97
小粉田Powdery paddy soil	1.19	89.7	4.94	56.7	20.0	6.62
青粉泥田Bluish silty-clay paddy soil	1.52	117.0	17.8	94.4	24.7	7.59

水稻土类型 Paddy soil type	c_TN/ (g·kg^-1)	c_AN/ (mg·kg^-1)	c_AP/ (mg·kg^-1)	c_AK/ (mg·kg^-1)	c_OM/ (g·kg^-1)	pH值 pH value
青紫泥田Blue-purple paddy soil	1.74	143.0	7.80	69.3	28.1	6.35
黄斑田Yellow-mottled paddy soil	2.05	169.0	15.2	72.7	33.3	6.97
小粉田Powdery paddy soil	1.19	89.7	4.94	56.7	20.0	6.62
青粉泥田Bluish silty-clay paddy soil	1.52	117.0	17.8	94.4	24.7	7.59

水稻土类型 Paddy soil type	各品种的产量Yield of different rice varieties
水稻土类型 Paddy soil type	浙粳99 Zhejing99	秀水14 Xiushui14	秀水121 Xiushui121	嘉67 Jia67	浙禾香2号 Zhehexiang No.2
青紫泥田Blue-purple paddy soil	10.80 aA	10.00 abcAB	9.47 cAB	9.67 bcB	10.40 abB
黄斑田Yellow-mottled paddy soil	10.10 aA	9.21 abB	8.18 bC	9.01 abB	9.21 abC
小粉田Powdery paddy soil	10.80 aA	11.00 aA	9.97 bA	10.90 aA	11.40 aA
青粉泥田Bluish silty-clay paddy soil	9.90 aA	9.00 aB	8.88 aB	9.57 aB	9.98 aBC

水稻土类型 Paddy soil type	各品种的产量Yield of different rice varieties
水稻土类型 Paddy soil type	浙粳99 Zhejing99	秀水14 Xiushui14	秀水121 Xiushui121	嘉67 Jia67	浙禾香2号 Zhehexiang No.2
青紫泥田Blue-purple paddy soil	10.80 aA	10.00 abcAB	9.47 cAB	9.67 bcB	10.40 abB
黄斑田Yellow-mottled paddy soil	10.10 aA	9.21 abB	8.18 bC	9.01 abB	9.21 abC
小粉田Powdery paddy soil	10.80 aA	11.00 aA	9.97 bA	10.90 aA	11.40 aA
青粉泥田Bluish silty-clay paddy soil	9.90 aA	9.00 aB	8.88 aB	9.57 aB	9.98 aBC

水稻土类型 Paddy soil type	各品种的干物质积累量Dry matter accumulation of different rice varieties
水稻土类型 Paddy soil type	浙粳99 Zhejing99	秀水14 Xiushui14	秀水121 Xiushui121	嘉67 Jia67	浙禾香2号 Zhehexiang No.2
青紫泥田Blue-purple paddy soil	19.8 aA	18.9 abAB	17.2 bAB	18.4 abA	20.1 aA
黄斑田Yellow-mottled paddy soil	20.0 abA	17.9 bcB	17.0 cB	19.2 abA	20.3 aA
小粉田Powdery paddy soil	19.1 bcA	20.9 abA	18.6 cA	18.8 bcA	21.6 aA
青粉泥田Bluish silty-clay paddy soil	16.2 bB	16.1 bB	16.8 bB	17.7 abA	19.5 aA

Phosphorus uptake and utilization characteristics of conventional japonica rice on major paddy soils in northern Zhejiang of China

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生育期 Growth stage	水稻土类型 Paddy soil type	各品种的磷积累量Phosphorus accumulation of different rice varieties
生育期 Growth stage	水稻土类型 Paddy soil type	浙粳99 Zhejing99	秀水14 Xiushui14	秀水121 Xiushui121	嘉67 Jia67	浙禾香2号 Zhehexiang No.2
分蘖期 Tillering stage	青紫泥田Blue-purple paddy soil	13.3 aA	13.9 aAB	12.2 aB	10.9 aAB	11.5 aB
	黄斑田Yellow-mottled paddy soil	11.8 abAB	12.9 abB	11.6 abB	10.5 bAB	14.8 aA
	小粉田Powdery paddy soil	8.8 abB	8.3 bC	7.4 bC	10.0 aB	8.2 bC
	青粉泥田Bluish silty-clay paddy soil	13.8 aA	15.5 aA	16.5 aA	13.8 aA	12.8 aB
齐穗期 Heading stage	青紫泥田Blue-purple paddy soil	34.3 aAB	30.8 aB	33.4 aA	37.1 aAB	31.4 aA
	黄斑田Yellow-mottled paddy soil	29.6 aB	26.9 aB	32.2 aA	29.2 aBC	32.3 aA
	小粉田Powdery paddy soil	29.7 abB	24.9 bcB	21.9 cB	23.3 cC	31.2 aA
	青粉泥田Bluish silty-clay paddy soil	36.5 aA	40.9 aA	36.2 aA	43.0 aA	38.4 aA
成熟期 Maturity	青紫泥田Blue-purple paddy soil	43.4 aA	34.6 bA	38.1 abA	33.0 bA	37.9 abA
	黄斑田Yellow-mottled paddy soil	38.7 aAB	34.0 aA	34.9 aA	34.7 aA	40.5 aA
	小粉田Powdery paddy soil	34.2 abB	34.8 abA	36.2 abA	33.4 bA	43.8 aA
	青粉泥田Bluish silty-clay paddy soil	31.0 bB	30.6 bA	35.1 bA	33.9 bA	41.2 aA

指标 Index	DA-M	PA-T	PA-H	PA-M	PupE	PE-bio	PE-grain	PtrA-L	PtrE-L	PtrA-S	PtrE-S
Y	0.670^**	-0.474^**	-0.194	0.396^**	0.633^**	0.131	-0.109	0.340^**	0.126	0.420^**	0.335^**
DA-M	—	-0.427^**	-0.210	0.591^**	0.685^**	0.176	-0.271^*	0.747^**	-0.115	0.580^**	-0.069
PA-T	—	—	0.470^**	-0.144	-0.538^**	-0.226	0.007	0.244	-0.017	-0.298^*	-0.204
PA-H	—	—	—	0.086	-0.319^*	-0.325^*	-0.202	0.011	0.051	-0.343^**	-0.304^*
PA-M	—	—	—	—	0.789^**	-0.683^**	-0.844^**	0.415^**	-0.177	0.277^*	-0.274^*
PupE	—	—	—	—	—	-0.326^*	-0.572^**	0.404^**	-0.096	0.462^**	0.016
PE-bio	—	—	—	—	—	—	0.795^**	0.146	0.106	0.202	0.302^*
PE-grain	—	—	—	—	—	—	—	0.141	0.117	-0.011	0.356^**
PtrA-L	—	—	—	—	—	—	—	—	0.048	0.241	-0.316^*
PtrE-L	—	—	—	—	—	—	—	—	—	-0.009	0.326^*
PtrA-S	—	—	—	—	—	—	—	—	—	—	0.574^**

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[2]	LYU Hao\\|hao1，2， LIU Yu\\|xue1，2， YANG Sheng\\|mao1，2，*， ZOU Ping1， LIU Guang\\|rong3， XU Chang\\|xu3. Classification comparison and improvement techniques of cold waterlogged paddy in Southern District， China [J]. , 2015, 27(5): 822-.
[3]	TU Wen\\|wen1，SONG Zhao\\|liang1，WANG Xu\\|dong1， YE Zheng\\|qian1， LI Zi\\|min2，SUN Ying1. Effects of mixing fertilization of silicon and phosphorus on fractionation and availability of phosphorus in a paddy soil [J]. , 2014, 26(6): 1596-.
[4]	JI Xiaojiang;CHEN Yi;WU Chunyan;LI Chaoying;LI Yan;TANG Xu*. Current status and evolution trends of soil nutrients in the paddy soils in Zhejiang Province [J]. , 2014, 26(3): 0-775778.
[5]	ZHAI Li-xin;JI Chang-ying*;DING Qi-shuo;IRSHAD Ali. Viscoelastic computation for creep test of paddy soil [J]. , 2010, 22(4): 0-514.
[6]	BIAN Wu—ying;DONG Yue—yong;ZHOU Jiang—ming . Variation characteristics of nutrient status of four soil genus in Zhejiang Province [J]. , 2009, 21(4): 0-357.