紫云英与双季稻秸秆协同利用影响稻田土壤钾循环与平衡

doi:10.11686/cyxb2020089

摘要/Abstract

摘要：

稻草还田和冬种绿肥是维持稻田地力和化肥替代的重要方式之一。本研究以在湖南酸性红黄泥和碱性紫潮泥两种典型稻田土壤上进行了2年的紫云英-双季稻定位试验为对象，分析紫云英和双季稻秸秆协同利用对稻田土壤K循环的影响。两土壤试验处理一致，包括稻田冬闲（FRR）、冬种紫云英（MvRR）及冬种紫云英与水稻秸秆协同利用（MvRR+St）3个处理。结果表明：与冬闲和冬种紫云英相比，紫云英与水稻秸秆协同利用未影响红黄泥土壤各形态钾的含量，但显著提高紫潮泥土壤速效钾和非交换性钾的含量，其中紫潮泥土壤水溶性钾、非特殊吸附钾及特殊吸附钾的含量较冬种紫云英处理分别提高了134.0%、93.0%、73.4%；两种典型稻田土壤上紫云英与水稻秸秆协同利用显著提高下茬作物紫云英的全K含量及吸K量，且紫云英的吸K量为紫潮泥>红黄泥；两种典型稻田土壤上冬种紫云英与水稻秸秆协同利用均未影响早、晚稻产量及籽粒K积累；在稻田各种植季和周年目前的K投入水平下，两种典型稻田土壤上冬种紫云英与水稻秸秆协同利用处理均存在K盈余（红黄泥K盈余量为401.15 kg·hm^-2、紫潮泥K盈余量为403.42 kg·hm^-2），说明冬种紫云英与水稻秸秆协同利用能减少双季稻生产中的化学钾肥投入量。综上所述，紫云英和双季稻秸秆协同利用有益于稻田土壤的K循环与平衡。

关键词: 紫云英, 水稻秸秆, 协同利用, 红黄泥, 紫潮泥, K循环

Abstract:

Rice straw return and planting green manure in winter are important ways to improve paddy soil fertility and reduce chemical fertilizer input. Chinese milk vetch （Astragalus sinicus） is the most important winter leguminous green manure crop. A typical crop rotation system in Hunan Province is： Chinese milk vetch-early rice-late rice. Many studies have shown that Chinese milk vetch can reduce chemical nitrogen fertilizer input in rice production. If the input of chemical potassium fertilizer in rice production can also be reduced， this will encourage the promotion and use of Chinese milk vetch. Here we report a 2-year field experiment on cultivation of Chinese milk vetch followed by double cropping of rice， in an acidic red yellow soil and an alkaline purple alluvial soil in Hunan， in which the effect of co-utilization of Chinese milk vetch and double cropping rice straw on the soil K cycle and balance were investigated. The experiments had the same treatments in two soil types， including winter fallow-rice-rice without rice straw return （FRR）， Chinese milk vetch-rice-rice without rice straw return （MvRR）， Chinese milk vetch-rice-rice with rice straw return （MvRR+St）. The results indicated： 1） Compared with FRR and MvRR， the content of different soil K forms of the acidic red yellow soil were not influenced in MvRR+St， while the contents of available K and non-exchangeable K of the alkaline purple alluvial soil were significantly increased in MvRR+St. Compared to MvRR， the contents of water-soluble K， non-specifically absorbed K and specifically absorbed K of the alkaline purple alluvial soil in MvRR+St were significantly increased by 134.0%， 93.0% and 73.4%， respectively. 2） Compared with MvRR， the total K content and K uptake of Chinese milk vetch in the acidic red yellow soil in MvRR+St were significantly increased by 68.6% and 91.1%， respectively； the total K content and K uptake of Chinese milk vetch of the alkaline purple alluvial soil in MvRR+St were significantly increased by 56.4% and 81.2%， respectively. Compared with red yellow soil， the K uptake of Chinese milk vetch in alkaline purple alluvial soil was greater than that in acidic red yellow soil under the same treatment. 3） The yield and K uptake of early rice and late rice were not influenced by MvRR+St in the two typical paddy soils. 4） With the current potassium nutrient input in this study， the MvRR+St treatment had a K surplus in the two typical paddy soils （red yellow soil K surplus was 401.15 kg·ha^-1， purple alluvial soil K surplus was 403.42 kg·ha^-1）. This shows that the co-utilization of Chinese milk vetch and rice straw can reduce the input of chemical potassium fertilizer in double cropping rice production. On the whole， the co-utilization of Chinese milk vetch and double cropping rice straw is beneficial to the K cycle and balance of paddy soils.

Key words: Chinese milk vetch, rice straw, co-utilization, red yellow soil, purple alluvial soil, K cycle

张帆, 杨茜. 紫云英与双季稻秸秆协同利用影响稻田土壤钾循环与平衡[J]. 草业学报, 2021, 30(1): 72-80.

Fan ZHANG, Qian YANG. Effects of co-utilization of Chinese milk vetch and rice straw on the potassium cycle and potassium balance in a paddy soil[J]. Acta Prataculturae Sinica, 2021, 30(1): 72-80.

图/表 6

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土壤Soil	处理 Treatments	全钾 Total K (g·kg^-1)	速效钾 Available K (mg·kg^-1)	水溶性钾 Water-soluble K (mg·kg^-1)	非特殊吸附钾 Non-specifically absorbed K (mg·kg^-1)	特殊吸附钾 Specifically absorbed K (mg·kg^-1)	非交换性钾 Non-exchangeable K (mg·kg^-1)	矿物钾 Structural K (g·kg^-1)
红黄泥 Red yellow soil	FRR	11.40±0.44a	49.47±12.89a	5.30±1.73a	9.13±4.67a	35.07±6.52a	142.57±7.29a	11.27±0.42a
	MvRR	11.45±0.23a	76.07±18.76a	8.90±2.04a	18.87±8.80a	48.30±8.34a	149.13±4.59a	11.27±0.23a
	MvRR+St	11.40±0.35a	77.43±28.37a	8.90±3.46a	21.37±12.48a	47.13±12.41a	146.03±4.01a	11.17±0.40a
紫潮泥 Purple alluvial soil	FRR	20.67±0.21b	82.30±4.69b	9.70±1.50b	22.53±2.87b	50.07±1.70b	370.67±10.40b	20.27±0.21b
	MvRR	20.83±0.40b	84.20±4.10b	9.20±1.00b	24.37±0.95b	50.60±2.56b	366.23±3.61b	20.27±0.45b
	MvRR+St	21.73±0.55a	156.30±7.69a	21.53±1.16a	47.03±3.75a	87.73±3.93a	401.87±5.83a	21.27±0.55a

土壤Soil	处理 Treatments	全钾 Total K (g·kg^-1)	速效钾 Available K (mg·kg^-1)	水溶性钾 Water-soluble K (mg·kg^-1)	非特殊吸附钾 Non-specifically absorbed K (mg·kg^-1)	特殊吸附钾 Specifically absorbed K (mg·kg^-1)	非交换性钾 Non-exchangeable K (mg·kg^-1)	矿物钾 Structural K (g·kg^-1)
红黄泥 Red yellow soil	FRR	11.40±0.44a	49.47±12.89a	5.30±1.73a	9.13±4.67a	35.07±6.52a	142.57±7.29a	11.27±0.42a
	MvRR	11.45±0.23a	76.07±18.76a	8.90±2.04a	18.87±8.80a	48.30±8.34a	149.13±4.59a	11.27±0.23a
	MvRR+St	11.40±0.35a	77.43±28.37a	8.90±3.46a	21.37±12.48a	47.13±12.41a	146.03±4.01a	11.17±0.40a
紫潮泥 Purple alluvial soil	FRR	20.67±0.21b	82.30±4.69b	9.70±1.50b	22.53±2.87b	50.07±1.70b	370.67±10.40b	20.27±0.21b
	MvRR	20.83±0.40b	84.20±4.10b	9.20±1.00b	24.37±0.95b	50.60±2.56b	366.23±3.61b	20.27±0.45b
	MvRR+St	21.73±0.55a	156.30±7.69a	21.53±1.16a	47.03±3.75a	87.73±3.93a	401.87±5.83a	21.27±0.55a

土壤 Soil	处理 Treatments	紫云英Chinese milk vetch			早稻Early rice			晚稻Late rice
土壤 Soil	处理 Treatments	生物量 Biomass (kg·hm^-2)	全K Total K (g·kg^-1)	K吸收 K uptake (kg·hm^-2)	产量 Yield (kg·hm^-2)	全K Total K (g·kg^-1)	K积累K accumulation (kg·hm^-2)	产量 Yield (kg·hm^-2)	全K Total K (g·kg^-1)	K积累K accumulation (kg·hm^-2)
红黄泥 Red yellow soil	FRR				5771±1112a	3.37±0.27a	19.48±4.59a	5779±2054a	3.30±0.15ab	19.13±6.45a
	MvRR	6231±291a	14.77±4.64b	92.02±28.63b	5778±1211a	3.30±0.22a	18.96±3.37a	5573±810a	3.27±0.06b	18.21±2.52a
	MvRR+St	7106±1652a	24.90±2.81a	175.80±38.50a	6062±1760a	3.23±0.16a	19.70±4.63a	5559±602a	3.63±0.12a	20.20±2.20a
紫潮泥 Purple alluvial soil	FRR				5997±1253a	3.16±0.15a	18.86±3.29a	6348±1349a	3.10±0.17a	19.53±3.24a
	MvRR	6442±564a	19.77±0.49b	127.27±10.76b	6392±430a	3.17±0.05a	20.34±1.26a	4813±1218a	3.27±0.06a	15.71±3.95a
	MvRR+St	7458±602a	30.93±1.35a	230.65±20.33a	6429±15a	3.18±0.14a	20.44±0.91a	5552±1124a	3.30±0.00a	18.32±3.71a

土壤 Soil	处理 Treatments	紫云英Chinese milk vetch			早稻Early rice			晚稻Late rice
土壤 Soil	处理 Treatments	生物量 Biomass (kg·hm^-2)	全K Total K (g·kg^-1)	K吸收 K uptake (kg·hm^-2)	产量 Yield (kg·hm^-2)	全K Total K (g·kg^-1)	K积累K accumulation (kg·hm^-2)	产量 Yield (kg·hm^-2)	全K Total K (g·kg^-1)	K积累K accumulation (kg·hm^-2)
红黄泥 Red yellow soil	FRR				5771±1112a	3.37±0.27a	19.48±4.59a	5779±2054a	3.30±0.15ab	19.13±6.45a
	MvRR	6231±291a	14.77±4.64b	92.02±28.63b	5778±1211a	3.30±0.22a	18.96±3.37a	5573±810a	3.27±0.06b	18.21±2.52a
	MvRR+St	7106±1652a	24.90±2.81a	175.80±38.50a	6062±1760a	3.23±0.16a	19.70±4.63a	5559±602a	3.63±0.12a	20.20±2.20a
紫潮泥 Purple alluvial soil	FRR				5997±1253a	3.16±0.15a	18.86±3.29a	6348±1349a	3.10±0.17a	19.53±3.24a
	MvRR	6442±564a	19.77±0.49b	127.27±10.76b	6392±430a	3.17±0.05a	20.34±1.26a	4813±1218a	3.27±0.06a	15.71±3.95a
	MvRR+St	7458±602a	30.93±1.35a	230.65±20.33a	6429±15a	3.18±0.14a	20.44±0.91a	5552±1124a	3.30±0.00a	18.32±3.71a

土壤 Soil	处理 Treatments	输入Input			输出 Output	表观平衡 Balance
土壤 Soil	处理 Treatments	前茬晚稻秸秆 Previous late rice straw	紫云英种子 Chinese milk vetch seed	合计 Total	紫云英吸收 Chinese milk vetch uptake	表观平衡 Balance
红黄泥 Red yellow soil	MvRR		0.16	0.16	92.02b	-91.85
红黄泥 Red yellow soil	MvRR+St	216.80	0.16	216.96	175.80a	41.16
紫潮泥 Purple alluvial soil	MvRR		0.16	0.16	127.27b	-127.11
紫潮泥 Purple alluvial soil	MvRR+St	217.94	0.16	218.10	230.65a	-12.55