耕作方式对连作高粱产量及土壤水分与有机碳含量的影响

doi:10.7668/hbnxb.20193492

摘要/Abstract

摘要：

为缓解连作障碍,改善土壤,保证高粱原粮生产量和农业可持续发展。2019-2020年,在山西农业大学高粱研究所东白试验基地开展高粱连作长期定位试验,研究休闲期传统耕作、免耕、秋旋耕、秋深松、秋深耕、春深耕等不同耕作方式对连作高粱土壤水分、有机碳及产量的影响,旨在寻求连作高粱产量提升的适宜耕作方式和时间,及其蓄水保墒固碳增产机理,为高粱的稳定生产提供栽培技术及理论依据。结果表明,休闲期耕作可增加连作高粱各生育时期0~20 cm土壤有机质含量,增加颗粒有机碳、轻组有机碳、重组有机碳、易氧化有机碳和可溶性有机碳含量;增加播前0~100 cm土壤蓄水量0.72~46.52 mm和各生育时期0~100 cm土壤蓄水量,且播前水分可延续用至拔节期,中后期由于降水多仍有效果;可增加产量4.75%~23.67%,增加生育期水分利用效率19.09~29.19 kg/(hm²·mm),尤其秋深耕耕作方式增加更明显。相关分析表明,连作高粱产量与土壤水分、有机质含量显著正相关;底墒较高时,产量与生长前期土壤水分关系更密切;底墒较低、中后期降水较多时产量与中后期土壤水分关系更密切。总之,连作高粱在休闲期秋深耕,利于增加有机碳含量,利于蓄水保墒,且水分延用至拔节期,从而提高产量和水分利用效率。

关键词: 连作高粱, 耕作, 土壤有机碳, 土壤水分, 产量

Abstract:

In order to alleviate continuous cropping obstacles and improve soil, to ensure sorghum raw grain production and sustainable agricultural development. The long-term located experiment of continuous cropping sorghum was carried out in Dongbai base of Sorghum Research Institute of Shanxi Agricultural University from 2019 to 2020 to study the effects of tillage methods(traditional tillage,no tillage,rotary in autumn,subsoiling in autumn,deep ploughing in autumn,deep ploughing in spring)in fallow period on soil moisture,organic carbon content and yield of continuous cropping sorghum,aiming to find the suitable tillage method and time for increasing the yield of continuous cropping sorghum,and the mechanism of water conservation,carbon sequestration and yield increase so as to provide cultivation techniques and theoretical basis for the stable production of sorghum.The results showed that tillage in fallow period increased the soil organic matter in 0-20 cm soil layer in each growth period of sorghum,and increased the content of particulate organic carbon,light fraction organic carbon,heavy fraction organic carbon,readily oxidized organic carbon and dissolved organic carbon, and also increased soil water storage in 0-100 cm soil layer by 0.72-46.52 mm before sowing and soil water storage of 0-100 cm soil layer at each growth period, furthermore, the soil water before sowing continued to be used until jointing stage and it still was very effective even though much precipitation in the middle and late stages.Meanwhile,tillage in fallow period increased the yield by 4.75%-23.67% and the water use efficiency in the growth period by 19.09-29.19 kg/(ha·mm),especially the increased effect of deep ploughing in autumn was more significant.The correlation analysis showed that the yield of continuous cropping sorghum was significantly positively correlated with soil moisture and organic matter content,and the yield was more closely related to the soil moisture in the early growth stage if the base soil moisture level was higher and more closely related to the soil moisture in the middle and late stages if the base soil moisture level was lower and the precipitation in the middle and late stages was more.In short,deep ploughing in autumn of continuous cropping sorghum during fallow period was beneficial to increase the organic carbon content and promote the soil moisture conservation so that the moisture continued to be used at jointing stage,thereby increased yield and water use efficiency.

Key words: Continuous cropping sorghum, Tillage, Soil organic carbon, Soil water, Yield

李光, 史丽娟, 崔旭东, 赵雪峰, 白文斌. 耕作方式对连作高粱产量及土壤水分与有机碳含量的影响[J]. 华北农学报, 2023, 38(2): 170-178. doi: 10.7668/hbnxb.20193492.

LI Guang, SHI Lijuan, CUI Xudong, ZHAO Xuefeng, BAI Wenbin. Effect of Tillage Methods on Yield and Soil Water and Organic Carbon Content of Continuous Cropping Sorghum[J]. Acta Agriculturae Boreali-Sinica, 2023, 38(2): 170-178. doi: 10.7668/hbnxb.20193492.

http://www.hbnxb.net/CN/Y2023/V38/I2/170

图/表 7

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耕作方式 Tillage method	具体方法 Specific method
传统耕作CK	高粱收获后前茬不作处理,次年春季(2019年3月1日、2020年3月3日)焚烧秸秆
免耕NT	高粱收获后至播种前不搅动土壤(秸秆不还田),次年直接播种
秋旋耕AT	高粱收获后秸秆粉碎还田,立刻旋耕(深度15 cm)
秋深松ASS	高粱收获后秸秆粉碎还田,立刻深松(深度35 cm)
秋深耕ADT	高粱收获后秸秆粉碎还田,当年秋季(2019年10月18日、2020年10月20日)深耕(深度25 cm)
春深耕SDT	高粱收获后秸秆粉碎还田,次年春季(2019年3月1日、2020年3月3日)深耕(深度25 cm)

耕作方式 Tillage method	具体方法 Specific method
传统耕作CK	高粱收获后前茬不作处理,次年春季(2019年3月1日、2020年3月3日)焚烧秸秆
免耕NT	高粱收获后至播种前不搅动土壤(秸秆不还田),次年直接播种
秋旋耕AT	高粱收获后秸秆粉碎还田,立刻旋耕(深度15 cm)
秋深松ASS	高粱收获后秸秆粉碎还田,立刻深松(深度35 cm)
秋深耕ADT	高粱收获后秸秆粉碎还田,当年秋季(2019年10月18日、2020年10月20日)深耕(深度25 cm)
春深耕SDT	高粱收获后秸秆粉碎还田,次年春季(2019年3月1日、2020年3月3日)深耕(深度25 cm)

年份 Year	耕作方式 Tillage method	初期 Initial stage (IS)	苗期 Emergence stage (ES)	拔节期 Jointing stage (JS)	抽穗期 Heading stage (HS)	成熟期 Mature stage (MS)
2019	传统耕作	8.01±0.12a	8.04±0.15c	8.25±0.13c	8.55±0.13d	8.69±0.16d
	免耕	8.69±0.25a	9.00±0.16b	9.53±0.10b	9.90±0.12c	9.96±0.14c
	秋旋耕	9.02±0.11a	9.16±0.24b	9.54±0.27b	9.93±0.21c	10.21±0.14b
	秋深松	9.12±0.15a	9.20±0.06ab	10.83±0.08ab	10.88±0.08b	10.98±0.13b
	秋深耕	9.08±0.18a	10.00±0.08a	11.53±0.14a	11.58±0.07a	12.03±0.12a
	春深耕	9.11±0.12a	9.13±0.11b	9.62±0.09b	9.91±0.07c	10.01±0.25b
2020	传统耕作	8.63±0.27d	8.85±0.25d	9.65±0.12c	10.24±0.08c	10.32±0.15c
	免耕	9.66±0.05c	10.11±0.12c	10.26±0.24bc	10.34±0.13c	10.47±0.11c
	秋旋耕	10.02±0.04c	10.14±0.12c	10.32±0.15b	10.89±0.12b	10.99±0.27b
	秋深松	10.93±0.16b	10.96±0.15b	11.02±0.10b	11.22±0.14b	11.48±0.12b
	秋深耕	11.67±0.08a	11.69±0.14a	11.75±0.11a	11.89±0.16a	12.05±0.12a
	春深耕	9.94±0.12c	10.14±0.07c	10.30±0.13bc	10.56±0.14bc	10.56±0.10bc

年份 Year	耕作方式 Tillage method	初期 Initial stage (IS)	苗期 Emergence stage (ES)	拔节期 Jointing stage (JS)	抽穗期 Heading stage (HS)	成熟期 Mature stage (MS)
2019	传统耕作	8.01±0.12a	8.04±0.15c	8.25±0.13c	8.55±0.13d	8.69±0.16d
	免耕	8.69±0.25a	9.00±0.16b	9.53±0.10b	9.90±0.12c	9.96±0.14c
	秋旋耕	9.02±0.11a	9.16±0.24b	9.54±0.27b	9.93±0.21c	10.21±0.14b
	秋深松	9.12±0.15a	9.20±0.06ab	10.83±0.08ab	10.88±0.08b	10.98±0.13b
	秋深耕	9.08±0.18a	10.00±0.08a	11.53±0.14a	11.58±0.07a	12.03±0.12a
	春深耕	9.11±0.12a	9.13±0.11b	9.62±0.09b	9.91±0.07c	10.01±0.25b
2020	传统耕作	8.63±0.27d	8.85±0.25d	9.65±0.12c	10.24±0.08c	10.32±0.15c
	免耕	9.66±0.05c	10.11±0.12c	10.26±0.24bc	10.34±0.13c	10.47±0.11c
	秋旋耕	10.02±0.04c	10.14±0.12c	10.32±0.15b	10.89±0.12b	10.99±0.27b
	秋深松	10.93±0.16b	10.96±0.15b	11.02±0.10b	11.22±0.14b	11.48±0.12b
	秋深耕	11.67±0.08a	11.69±0.14a	11.75±0.11a	11.89±0.16a	12.05±0.12a
	春深耕	9.94±0.12c	10.14±0.07c	10.30±0.13bc	10.56±0.14bc	10.56±0.10bc

年份 Year	耕作方式 Tillage method	播前 SS	苗期 ES	拔节期 JS	抽穗期 HS	成熟期 MS
2019	传统耕作	208.36±23.47c	196.62±18.83d	159.72±14.24d	145.87±10.04b	136.32±8.82b
	免耕	235.41±24.31b	224.81±16.32c	182.66±12.53c	142.43±15.10b	125.45±10.65c
	秋旋耕	253.45±27.64b	247.45±23.55b	230.89±15.37b	156.76±12.45a	136.39±15.71b
	秋深松	279.62±21.47a	271.27±13.96a	257.65±22.85a	159.04±18.52a	142.20±19.38a
	秋深耕	281.36±25.38a	277.24±10.52a	262.48±23.24a	159.48±16.11a	148.79±10.33a
	春深耕	278.39±26.12a	272.09±23.37a	253.45±19.27a	146.35±9.38b	139.20±7.69bc
2020	传统耕作	166.58±17.87b	129.60±11.48d	153.60±15.57e	229.13±23.85c	305.84±25.78c
	免耕	173.12±19.23b	168.11±17.46c	170.25±18.86d	229.65±18.56c	305.63±21.37c
	秋旋耕	216.37±25.25a	210.67±15.92a	183.49±25.45c	234.71±8.78b	313.11±14.07bc
	秋深松	219.64±18.44a	214.68±23.33a	203.52±23.04b	237.33±24.53b	320.97±19.54b
	秋深耕	216.92±13.36a	218.43±20.80a	213.24±20.83a	258.69±16.45a	345.71±28.62a
	春深耕	173.84±17.43b	180.94±16.54b	162.99±13.07d	249.67±12.84a	320.03±23.44b

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