不同质地土壤对花生根系生长、分布和产量的影响

doi:10.3724/SP.J.1258.2013.00071

摘要/Abstract

摘要：

为了探究土壤类型与花生(Arachis hypogaea)根系生长及产量之间的关系, 采用箱栽的方法, 研究了不同质地土壤(砂土、壤土、黏土)对花生根系生长、分布和产量的影响。砂土和壤土中花生根系干物质重各时期均显著高于黏土中, 但生育后期黏土中花生根系干物质重比壤土和砂土下降相对较慢。从不同类型土壤质地根系分布及根系活力来看, 黏土根系主要分布在上层土壤, 但上层土壤根系活力后期下降慢; 砂土有利于花生根系向深层土壤生长, 但上层土壤根系活力后期下降快; 而壤土对花生根系生长和活力时空分布的影响介于黏土和砂土之间。砂土有利于花生荚果的膨大, 且花生荚果干物质积累早而快, 但后期荚果干物质重积累少; 壤土的花生荚果干物质积累中后期多, 黏土则在整个生育期均不利于花生荚果干物质积累。最终荚果产量、籽仁产量和有效果数均表现为壤土最大、砂土次之、黏土最小。研究表明通气性和保肥保水能力居中的壤土更适合花生的根系生长发育及产量的形成。

关键词: 生长, 花生, 根系, 土壤质地, 产量

Abstract:

Aims This paper explores soil types to suit the development of root system and improve the yield of peanut (Arachis hypogaea).
Methods We used the method of box-planted cultivation to study the effects of different soil textures, i.e., sandy, loam and clay soils, on the development and distribution of root system and yield of peanut.
Important findings Root dry matter weight of peanut in sandy and loam soils was higher significantly than in clay soil; however, in the later growth stage, the decrease of root dry matter weight of peanut in clay soil is relative slow compared with peanut in loam and sandy soil. In clay soil, the root system of peanut was mainly distributed in the shallow soil layer, but the decrease of root activity in the upper layers was much slower in the late growth period. Sandy soil was helpful for the root system of peanut to grow to the deeper soil layer, but the decrease of root activity in the surface layers was faster in the later growth period. The effects of loam soil on the spatial and temporal distribution of the development and activity of peanut roots were between sandy and clay soil. Sandy soil favored enlargement of the peanut pod, and the dry matter accumulation of peanut pod in sandy soil was earlier and faster, but the dry matter accumulation in the later growth period was less in sandy soil. In loam soil, the dry matter accumulation of peanut pod was mainly concentrated in middle and later periods, while clay soil was not suitable for the dry matter accumulation of peanut pod in the entire growth period. The pod yield, kernel yield and available pod number were largest in loam soil, second in sandy soil and lowest in clay soil. Results suggested that loam soil, with mid-levels of aeration and water and fertilizer conservation among the three soil textures, was most suitable for the growth and yield of peanut.

Key words: growth, peanut, root system, soil texture, yield

贾立华,赵长星,王月福,王铭伦. 不同质地土壤对花生根系生长、分布和产量的影响. 植物生态学报, 2013, 37(7): 684-690. DOI: 10.3724/SP.J.1258.2013.00071

JIA Li-Hua,ZHAO Chang-Xing,WANG Yue-Fu,WANG Ming-Lun. Effects of different soil textures on the growth and distribution of root system and yield in peanut. Chinese Journal of Plant Ecology, 2013, 37(7): 684-690. DOI: 10.3724/SP.J.1258.2013.00071

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链接本文: https://www.plant-ecology.com/CN/10.3724/SP.J.1258.2013.00071

https://www.plant-ecology.com/CN/Y2013/V37/I7/684

图/表 7

参考文献 13

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土壤质地 Soil texture	土壤颗粒组成 Composition of soil particles (%)			pH	有机质 Organic matter (%)	碱解氮 Available nitrogen (mg·kg^-1)	速效磷 Available phosphorus (mg·kg^-1)	速效钾 Available potassium (mg·kg^-1)
土壤质地 Soil texture	<0.001 mm	0.05-0.01 mm	0.05-1.0 mm	pH	有机质 Organic matter (%)	碱解氮 Available nitrogen (mg·kg^-1)	速效磷 Available phosphorus (mg·kg^-1)	速效钾 Available potassium (mg·kg^-1)
砂土 Sandy soil	9	26	65	6.01	7.59	55.10	8.67	50.05
壤土 Loam soil	19	58	23	6.11	13.26	66.76	10.11	77.00
黏土 Clay soil	45	46	9	5.93	19.73	91.45	9.65	89.20

土壤质地 Soil texture	土壤颗粒组成 Composition of soil particles (%)			pH	有机质 Organic matter (%)	碱解氮 Available nitrogen (mg·kg^-1)	速效磷 Available phosphorus (mg·kg^-1)	速效钾 Available potassium (mg·kg^-1)
土壤质地 Soil texture	<0.001 mm	0.05-0.01 mm	0.05-1.0 mm	pH	有机质 Organic matter (%)	碱解氮 Available nitrogen (mg·kg^-1)	速效磷 Available phosphorus (mg·kg^-1)	速效钾 Available potassium (mg·kg^-1)
砂土 Sandy soil	9	26	65	6.01	7.59	55.10	8.67	50.05
壤土 Loam soil	19	58	23	6.11	13.26	66.76	10.11	77.00
黏土 Clay soil	45	46	9	5.93	19.73	91.45	9.65	89.20

年度 Year	土壤质地 Soil texture	有效果数 Valid pods (No.·plant^-1)	荚果产量 Pod yield (g·plant^-1)	生物产量 Biological yield (g·plant^-1)	出仁率 Shelling percentage (%)	籽仁产量 Seed yield (g·plant^-1)
2011	黏土 Clay soil	10.30^Bb	24.97^Bb	50.79^Bb	67.44^Aa	16.84^Cc
	壤土 Loam soil	13.25^Aa	32.30^Aa	55.85^Aa	61.42^Bb	19.84^Aa
	砂土 Sandy soil	12.67^Aa	30.46^Aa	53.72^Aa	59.03^Cc	17.98^Bb
2012	黏土 Clay soil	18.50^Bb	43.33^Cc	79.28^Cc	62.07^Aa	26.89^Bb
	壤土 Loam soil	23.50^Aa	50.68^Aa	95.87^Aa	60.49^Bb	30.66^Aa
	砂土 Sandy soil	22.50^Aa	46.25^Bb	87.54^Bb	58.99^Cc	27.28^Bb

年度 Year	土壤质地 Soil texture	有效果数 Valid pods (No.·plant^-1)	荚果产量 Pod yield (g·plant^-1)	生物产量 Biological yield (g·plant^-1)	出仁率 Shelling percentage (%)	籽仁产量 Seed yield (g·plant^-1)
2011	黏土 Clay soil	10.30^Bb	24.97^Bb	50.79^Bb	67.44^Aa	16.84^Cc
	壤土 Loam soil	13.25^Aa	32.30^Aa	55.85^Aa	61.42^Bb	19.84^Aa
	砂土 Sandy soil	12.67^Aa	30.46^Aa	53.72^Aa	59.03^Cc	17.98^Bb
2012	黏土 Clay soil	18.50^Bb	43.33^Cc	79.28^Cc	62.07^Aa	26.89^Bb
	壤土 Loam soil	23.50^Aa	50.68^Aa	95.87^Aa	60.49^Bb	30.66^Aa
	砂土 Sandy soil	22.50^Aa	46.25^Bb	87.54^Bb	58.99^Cc	27.28^Bb

年份 Year	土壤质地 Soil texture	开花后天数 Days after flowering (d)
年份 Year	土壤质地 Soil texture	17	27	37	47	57	70
2011	黏土 Clay soil	12.5^Bb	26.0^Bb	28.0^Bb	55.0^Cc	85.0^Bb	95.0^Bb
	壤土 Loam soil	22.5^Aa	60.0^Aa	67.5^Aa	75.0^Bb	112.5^Aa	115.7^Aa
	砂土 Sandy soil	23.0^Aa	55.0^Aa	75.0^Aa	105.0^Aa	115.0^Aa	117.5^Aa
2012	黏土 Clay soil	4.5^Bb	40.3^Cc	85.0^Cc	95.0^Cc	109.5^Cc	120.0^Bb
	壤土 Loam soil	17.0^Aa	53.8^Bb	102.5^Bb	115.0^Bb	129.9^Bb	145.0^Aa
	砂土 Sandy soil	21.0^Aa	64.6^Aa	122.5^Aa	132.5^Aa	135.0^Aa	152.5^Aa