Effects of Topographic Positions and Plantation Time on Soil Properties of Hilly Red Soil Orchards

doi:10.11923/j.issn.2095-4050.cjas2022-0029

Abstract

Abstract:

Taking Hangzhou City of Zhejiang Province as an example, 23 low hilly red soil orchards with different plantation time were selected, and the soil samples at the piedmont, the downhill and the middle and upper slope were collected. The effects of topographic positions (natural factor) and plantation time (human factor) on soil physical, chemical and biological properties of the orchards were evaluated and analyzed. The results showed that the thickness of effective soil layer was mainly controlled by natural factors and less affected by cultivation. The thickness decreased in a sequence of piedmont > downhill > middle and upper slope. Other soil properties were affected by both natural factors and artificial farming. Soil CEC, and the content of soil organic carbon, available phosphorus, available potassium, water stable aggregates and microbial biomass carbon decreased in the order of piedmont > downhill > middle and upper slope, and the soil bulk density increased generally in the order of piedmont < downhill < middle and upper slope. Soil pH was generally higher at the piedmont than that at the downhill and middle and upper slopes. With the increase of the plantation time, soil organic carbon, available phosphorus, available potassium and microbial biomass carbon increased, soil bulk density and water stable aggregates increased first and then decreased, and soil pH decreased continuously. There were great differences in soil properties between the piedmont, the downhill and the middle and upper slope, while the differences in soil properties between the downhill and the middle and upper slope were relatively small. The effect of plantation time on soil properties was more obvious at the piedmont than that at the downhill and the middle and upper slope. Multivariate statistical analysis showed that there was synergy among the changes of soil fertility indexes, and the similarity of the changes could be roughly divided into three groups: group 1 included CEC, organic carbon, microbial biomass carbon, available phosphorus and available potassium, group 2 included pH, bulk density and available calcium, and group 3 included soil thickness and water stable aggregates. The research indicates that the spatial heterogeneity of soil quality in hilly orchards is an objective phenomenon, which is affected by natural and human factors. Therefore, the difference of slope positions and plantation time should be considered in taking management measures.

Key words: topographic position, planting time, orchard, soil properties

ZHENG Mingjie, YU Hongwei, CHEN Zhiliang, ZHANG Mingkui. Effects of Topographic Positions and Plantation Time on Soil Properties of Hilly Red Soil Orchards[J]. Journal of Agriculture, 2023, 13(7): 48-55.

Figures/Tables 8

References 30

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坡位	统计值	土体厚度/cm	pH	CEC/(cmol/kg)	容重/(g/cm³)	>0.25 mm水稳定性团聚体/%
中上坡 (n=23)	范围	32~72	4.76~5.43	6.98~12.65	1.29~1.42	35.64~51.24
中上坡 (n=23)	平均值±标准差	48±11c	5.10±0.18a	9.54±1.44b	1.35±0.04a	44.40±4.16b
下坡 (n=23)	范围	42~96	4.66~5.42	8.69~13.25	1.24~1.42	39.25~58.21
下坡 (n=23)	平均值±标准差	66±14b	5.04±0.24a	10.89±1.18ab	1.34±0.04a	47.64±4.88ab
坡麓 (n=23)	范围	59~132	4.86~5.74	9.25~16.24	1.23~1.38	38.65~62.57
坡麓 (n=23)	平均值±标准差	86±17a	5.24±0.22a	11.89±1.78a	1.30±0.04a	50.04±5.55a

坡位	统计值	土体厚度/cm	pH	CEC/(cmol/kg)	容重/(g/cm³)	>0.25 mm水稳定性团聚体/%
中上坡 (n=23)	范围	32~72	4.76~5.43	6.98~12.65	1.29~1.42	35.64~51.24
中上坡 (n=23)	平均值±标准差	48±11c	5.10±0.18a	9.54±1.44b	1.35±0.04a	44.40±4.16b
下坡 (n=23)	范围	42~96	4.66~5.42	8.69~13.25	1.24~1.42	39.25~58.21
下坡 (n=23)	平均值±标准差	66±14b	5.04±0.24a	10.89±1.18ab	1.34±0.04a	47.64±4.88ab
坡麓 (n=23)	范围	59~132	4.86~5.74	9.25~16.24	1.23~1.38	38.65~62.57
坡麓 (n=23)	平均值±标准差	86±17a	5.24±0.22a	11.89±1.78a	1.30±0.04a	50.04±5.55a

坡位	种植年限/a	土体厚度/cm	pH	CEC/(cmol/kg)	容重/(g/cm³)	水稳定性团聚体/%
中上坡	≤5(n=5)	49±10Ac	5.30±0.11Ab	8.92±1.00Bb	1.34±0.05Aa	40.61±3.26Ba
	6~10(n=7)	53±16Ab	5.12±0.16ABb	8.90±1.15Bb	1.35±0.05Aa	47.17±3.33Ab
	11~15(n=5)	50±6Ac	5.07±0.13Bab	8.92±0.75Bb	1.35±0.04Aab	45.92±4.54ABa
	≥16(n=6)	40±4Ac	4.95±0.16Bab	11.31±1.11Ab	1.34±0.02Aa	43.05±2.85ABb
下坡	≤5(n=5)	66±12Ab	5.26±0.17Ab	10.71±0.86ABab	1.31±0.06Bab	43.53±4.60Ba
	6~10(n=7)	64±18Aab	5.08±0.24ABab	10.33±0.93Bab	1.35±0.04Aa	50.39±3.97Aab
	11~15(n=5)	69±8Ab	4.99±0.22ABb	10.44±0.60Ba	1.35±0.02Aa	49.43±5.78Aa
	≥16(n=6)	66±16Ab	4.86±0.14Bb	12.05±1.38Ab	1.33±0.02ABa	46.39±3.13ABb
坡麓	≤5(n=5)	83±9Aa	5.56±0.12Aa	10.69±1.21Ba	1.27±0.04Bb	45.07±5.68Ba
	6~10(n=7)	82±20Aa	5.25±0.12ABa	11.42±1.20Ba	1.32±0.04Aa	52.23±4.80Aa
	11~15(n=5)	97±21Aa	5.15±0.09ABa	11.18±0.85Ba	1.31±0.04Ab	51.40±7.54ABa
	≥16(n=6)	86±17Aa	5.02±0.12Ba	14.03±1.63Aa	1.28±0.04ABb	50.49±1.80Aa

坡位	种植年限/a	土体厚度/cm	pH	CEC/(cmol/kg)	容重/(g/cm³)	水稳定性团聚体/%
中上坡	≤5(n=5)	49±10Ac	5.30±0.11Ab	8.92±1.00Bb	1.34±0.05Aa	40.61±3.26Ba
	6~10(n=7)	53±16Ab	5.12±0.16ABb	8.90±1.15Bb	1.35±0.05Aa	47.17±3.33Ab
	11~15(n=5)	50±6Ac	5.07±0.13Bab	8.92±0.75Bb	1.35±0.04Aab	45.92±4.54ABa
	≥16(n=6)	40±4Ac	4.95±0.16Bab	11.31±1.11Ab	1.34±0.02Aa	43.05±2.85ABb
下坡	≤5(n=5)	66±12Ab	5.26±0.17Ab	10.71±0.86ABab	1.31±0.06Bab	43.53±4.60Ba
	6~10(n=7)	64±18Aab	5.08±0.24ABab	10.33±0.93Bab	1.35±0.04Aa	50.39±3.97Aab
	11~15(n=5)	69±8Ab	4.99±0.22ABb	10.44±0.60Ba	1.35±0.02Aa	49.43±5.78Aa
	≥16(n=6)	66±16Ab	4.86±0.14Bb	12.05±1.38Ab	1.33±0.02ABa	46.39±3.13ABb
坡麓	≤5(n=5)	83±9Aa	5.56±0.12Aa	10.69±1.21Ba	1.27±0.04Bb	45.07±5.68Ba
	6~10(n=7)	82±20Aa	5.25±0.12ABa	11.42±1.20Ba	1.32±0.04Aa	52.23±4.80Aa
	11~15(n=5)	97±21Aa	5.15±0.09ABa	11.18±0.85Ba	1.31±0.04Ab	51.40±7.54ABa
	≥16(n=6)	86±17Aa	5.02±0.12Ba	14.03±1.63Aa	1.28±0.04ABb	50.49±1.80Aa

坡位	统计值	有机碳/(g/kg)	微生物生物量碳/(mg/kg)	有效磷/(mg/kg)	速效钾/(mg/kg)	有效钙/(mg/kg)
中上坡 (n=23)	范围	3.78~12.14	26.35~114.65	7.26~86.25	52.46~142.54	137~1143
中上坡 (n=23)	平均值±标准差	8.26±2.19b	63.45±27.22b	30.54±19.33b	89.96±20.58b	412.39±272.35a
下坡 (n=23)	范围	4.65~14.65	28.25~154.32	8.65~98.56	68.56~165.23	104~1045
下坡 (n=23)	平均值±标准差	9.27±2.85ab	74.39±35.01b	35.64±23.20b	100.63±24.83ab	386.43±279.67a
坡麓 (n=23)	范围	6.23~21.14	54.32~221.24	13.65~276.25	79.65~187.36	165~1532
坡麓 (n=23)	平均值±标准差	12.96±3.73a	122.80±44.06a	91.77±76.34a	136.18±34.47a	587.61±432.89a