Effects of Phosphorus on Nitrogen Absorption, Translocation and Utilization in Dryland Flax

doi:10.11924/j.issn.1000-6850.casb2020-0711

Abstract

Abstract:

This field study was conducted to assess the effects of phosphorus on nitrogen absorption, translocation as well as utilization in dryland flax. We set four phosphorus (P₂O₅) levels of 0, 45, 90 and 135 kg/hm², planted two flax varieties (‘Lunxuan 2’ and ‘Dingya 22’) in 2017 and 2018 at Dingxi, and adopted a completely random block group design. The results showed that phosphorus had an influence on nitrogen absorption and translocation of the above ground parts and the physiological utilization efficiency of nitrogen in dryland flax, and the difference between the years was significant. Year, variety and phosphorus interaction showed significant impact on nitrogen absorption in the above ground parts at anthesis and maturity, nitrogen absorption and distribution rate in seeds at maturity, and total nitrogen translocation amount, translocation efficiency, rate of contribution and physiological utilization efficiency of stems, leaves and other parts. The application of phosphorus averagely increased nitrogen absorption in the above ground parts at anthesis and maturity by 76% and 82% respectively, nitrogen absorption and distribution rate in seeds at maturity by 127% and 25% respectively, and nitrogen translocation and translocation efficiency in stems and leaves and other parts by 556%, 102%, 237%, and 16% respectively compared with no application of phosphorus. The physiological utilization efficiency of nitrogen significantly increased with increased phosphorus rate of ‘Lunxuan 2’, however, physiological utilization efficiency of nitrogen of ‘Dingya 22’ showed no difference between 90 kg/hm² and 135 kg/hm². The correlation analysis indicated that the phosphorus application amount had significantly positive correlation with nitrogen absorption translation and utilization in dryland flax.

Key words: phosphorus, flax, nitrogen, absorption, translocation, utilization

CLC Number:

S143.2+2

Xie Yaping, Niu Junyi, Wang Limin, Dang Zhao, Zhao Wei, Li Wenjuan, Qi Yanni, Wang Ping, Li Yue, Zhang Jianping. Effects of Phosphorus on Nitrogen Absorption, Translocation and Utilization in Dryland Flax[J]. Chinese Agricultural Science Bulletin, 2021, 37(25): 17-26.

Figures/Tables 8

References 27

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年份	有机质/(g/kg)	全氮/(g/kg)	碱解氮/(g/kg)	速效磷/(mg/kg)	速效钾/(mg/kg)	pH
2017	10.2	0.98	43.54	11.7	122.5	7.75
2018	11.0	1.01	45.31	12.6	125.2	8.08

年份	有机质/(g/kg)	全氮/(g/kg)	碱解氮/(g/kg)	速效磷/(mg/kg)	速效钾/(mg/kg)	pH
2017	10.2	0.98	43.54	11.7	122.5	7.75
2018	11.0	1.01	45.31	12.6	125.2	8.08

年份	磷	品种	花期			成熟期
年份	磷	品种	茎	叶+花	地上部分	茎	叶+其他部分	籽粒	地上部分
2017	P₀	轮选2号	14.64c	27.95c	42.59d	13.92b	13.46b	18.25d	45.63d
	P₄₅		21.92b	40.68b	62.60c	17.57a	16.72a	34.56c	68.85c
	P₉₀		26.80a	47.10ab	73.90b	21.37a	18.80a	41.14b	81.31b
	P₁₃₅		27.96a	52.87a	80.83a	22.22a	20.15a	45.58a	87.95a
	P₀	定亚22号	13.94c	27.04d	40.98c	12.79b	12.93b	18.84c	44.56c
	P₄₅		21.47b	39.89c	61.36b	17.02a	16.62a	35.24b	68.88b
	P₉₀		25.56a	46.17b	71.73ab	19.99a	17.07a	42.37a	79.43a
	P₁₃₅		27.09a	51.60a	78.69a	20.56a	18.18a	44.15a	82.89a
2018	P₀	轮选2号	11.40c	24.58c	35.98c	11.25c	13.54b	14.27c	39.06c
	P₄₅		19.35b	38.07b	57.42b	17.86b	20.91a	32.59b	71.36b
	P₉₀		23.89a	46.72a	70.61a	21.79a	22.43a	39.39a	83.61ab
	P₁₃₅		24.34a	48.46a	72.80a	21.88a	23.44a	42.15a	87.47a
	P₀	定亚22号	12.31c	24.03c	36.34c	11.77b	13.02b	16.84c	41.63d
	P₄₅		18.51b	36.46b	54.97ab	16.54ab	18.11a	30.31b	64.96c
	P₉₀		22.38a	44.07ab	66.45a	19.51a	19.25a	37.05a	75.81b
	P₁₃₅		23.50a	47.12a	70.62a	20.28a	20.22a	40.48a	80.98a

年份	磷	品种	花期			成熟期
年份	磷	品种	茎	叶+花	地上部分	茎	叶+其他部分	籽粒	地上部分
2017	P₀	轮选2号	14.64c	27.95c	42.59d	13.92b	13.46b	18.25d	45.63d
	P₄₅		21.92b	40.68b	62.60c	17.57a	16.72a	34.56c	68.85c
	P₉₀		26.80a	47.10ab	73.90b	21.37a	18.80a	41.14b	81.31b
	P₁₃₅		27.96a	52.87a	80.83a	22.22a	20.15a	45.58a	87.95a
	P₀	定亚22号	13.94c	27.04d	40.98c	12.79b	12.93b	18.84c	44.56c
	P₄₅		21.47b	39.89c	61.36b	17.02a	16.62a	35.24b	68.88b
	P₉₀		25.56a	46.17b	71.73ab	19.99a	17.07a	42.37a	79.43a
	P₁₃₅		27.09a	51.60a	78.69a	20.56a	18.18a	44.15a	82.89a
2018	P₀	轮选2号	11.40c	24.58c	35.98c	11.25c	13.54b	14.27c	39.06c
	P₄₅		19.35b	38.07b	57.42b	17.86b	20.91a	32.59b	71.36b
	P₉₀		23.89a	46.72a	70.61a	21.79a	22.43a	39.39a	83.61ab
	P₁₃₅		24.34a	48.46a	72.80a	21.88a	23.44a	42.15a	87.47a
	P₀	定亚22号	12.31c	24.03c	36.34c	11.77b	13.02b	16.84c	41.63d
	P₄₅		18.51b	36.46b	54.97ab	16.54ab	18.11a	30.31b	64.96c
	P₉₀		22.38a	44.07ab	66.45a	19.51a	19.25a	37.05a	75.81b
	P₁₃₅		23.50a	47.12a	70.62a	20.28a	20.22a	40.48a	80.98a

年份	磷	品种	茎	叶+其他部分	籽粒
2017	P₀	轮选2号	30.51a	29.50a	40.00b
	P₄₅		25.52b	24.28b	50.20a
	P₉₀		26.28b	23.12b	50.60a
	P₁₃₅		25.26b	22.91b	51.82a
	P₀	定亚22号	28.70a	29.02a	42.28b
	P₄₅		24.71b	24.13b	51.16a
	P₉₀		25.17ab	21.49c	53.34a
	P₁₃₅		24.80b	21.93c	53.26a
2018	P₀	轮选2号	28.80a	34.66a	36.53b
	P₄₅		25.03b	29.30b	45.67a
	P₉₀		26.06ab	26.83c	47.11a
	P₁₃₅		25.01b	26.80c	48.19a
	P₀	定亚22号	28.27a	31.28a	40.45b
	P₄₅		25.46a	27.88b	46.66a
	P₉₀		25.74a	25.39c	48.87a
	P₁₃₅		25.04a	24.97c	49.99a