Increase of Organic Carbon Accumulation in Deep Soil of Paddy Fields by Long Term Continuous Cropping of Zizania latifolia

doi:10.11924/j.issn.1000-6850.casb2023-0519

Abstract

Abstract:

To understand the changes of organic carbon pool and its components in paddy soils after long-term continuous cropping of Zizania latifolia, six groups of farmlands with the same soil type, varying in Zizania latifolia plantation years of 0 (control), 2-5, 5-10, 10-20, 20-30 and 30-35, were selected, and soil samples of 0-20, 20-40, 40-60 and 60-80 cm layers were collected. Soil organic carbon, different stable forms of organic carbon and microbial biomass carbon were analyzed. The results showed that with the increase of the plantation time of Zizania latifolia, the soil bulk density decreased gradually from the upper layer to the lower layer, the total amount of soil organic carbon, highly active organic carbon, moderately active organic carbon, low active organic carbon, inert organic carbon and microbial biomass carbon in each of soil layers gradually increased, with the most obvious increase in 20-40 and 40-60 cm soil layers. Meanwhile, the proportion of highly active organic carbon in deep soil increased significantly. The storage proportion of total organic carbon and various forms of organic carbon of 20-80 cm soil layers in all of 0-80 cm soil layers also increased gradually, showing the characteristics of organic carbon accumulation in deep soil. The main reasons for the rapid accumulation of organic carbon and the increase of organic carbon activity in the deep soil of farmland planted with Zizania latifolia were the gradual disappearance of the plough pan and the formation of the soft paste layer caused by deep tillage, long-term flooding and frequent human trampling in the field during the production of Zizania latifolia.

Key words: Zizania latifolia field, deep soil, carbon pool, organic carbon components, accumulation, soft paste layer

ZHANG Lijun, ZHANG Mingkui. Increase of Organic Carbon Accumulation in Deep Soil of Paddy Fields by Long Term Continuous Cropping of Zizania latifolia[J]. Chinese Agricultural Science Bulletin, 2024, 40(15): 88-95.

Figures/Tables 7

References 30

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采样深度/ cm	种植年限/a
采样深度/ cm	0	2~5	5~10	10~20	20~30	30~35
0~20	1.13a	1.11a	1.10a	1.09ab	0.99b	0.85c
20~40	1.43a	1.38b	1.26c	1.20cd	1.14d	0.94e
40~60	1.45a	1.44a	1.40ab	1.38bc	1.35c	1.28d
60~80	1.48a	1.49a	1.46ab	1.48a	1.46a	1.42b

采样深度/ cm	种植年限/a
采样深度/ cm	0	2~5	5~10	10~20	20~30	30~35
0~20	1.13a	1.11a	1.10a	1.09ab	0.99b	0.85c
20~40	1.43a	1.38b	1.26c	1.20cd	1.14d	0.94e
40~60	1.45a	1.44a	1.40ab	1.38bc	1.35c	1.28d
60~80	1.48a	1.49a	1.46ab	1.48a	1.46a	1.42b

有机碳组分	采样深度/cm	种植年限/a
有机碳组分	采样深度/cm	0	2~5	5~10	10~20	20~30	30~35
总有机碳	0~20	18.59d	22.12c	23.36c	26.85b	31.52a	30.90a
	20~40	10.17d	9.06d	11.27d	15.10c	22.62b	26.13a
	40~60	5.37c	4.92c	6.95c	10.77b	17.25a	17.83a
	60~80	3.63b	3.31b	3.75b	3.60b	5.52a	6.97a
高活性有机碳	0~20	6.91d	9.65c	10.30bc	11.61b	13.63a	12.66ab
	20~40	1.92d	2.66c	3.20bc	4.41b	7.05a	8.34a
	40~60	0.46e	0.42e	0.91d	2.08c	3.75b	4.53a
	60~80	0.25d	0.21d	0.37c	0.35c	0.70b	1.16a
中活性有机碳	0~20	3.26d	3.01d	3.56cd	4.77bc	6.44b	7.38a
	20~40	2.38cd	1.37d	2.09d	3.52c	5.89b	8.12a
	40~60	1.54d	1.58d	2.00c	3.16b	6.05a	5.79a
	60~80	1.06c	1.04c	1.11c	1.24c	1.95b	2.38a
低活性有机碳	0~20	2.32c	2.50c	2.56c	2.90b	3.52a	3.37a
	20~40	1.62c	1.35d	1.47cd	1.96b	2.89a	2.88a
	40~60	0.98d	0.83d	1.15c	1.72b	2.60a	2.50a
	60~80	0.55bc	0.50bc	0.57bc	0.46c	0.63b	1.04a
惰性有机碳	0~20	6.09b	6.96ab	6.94ab	7.56a	7.93a	7.49a
	20~40	4.26cd	3.67d	4.50c	5.21b	6.80a	6.79a
	40~60	2.40cd	2.09d	2.89c	3.81b	4.85ab	5.01a
	60~80	1.78b	1.55b	1.70b	1.55b	2.24a	2.39a

有机碳组分	采样深度/cm	种植年限/a
有机碳组分	采样深度/cm	0	2~5	5~10	10~20	20~30	30~35
总有机碳	0~20	18.59d	22.12c	23.36c	26.85b	31.52a	30.90a
	20~40	10.17d	9.06d	11.27d	15.10c	22.62b	26.13a
	40~60	5.37c	4.92c	6.95c	10.77b	17.25a	17.83a
	60~80	3.63b	3.31b	3.75b	3.60b	5.52a	6.97a
高活性有机碳	0~20	6.91d	9.65c	10.30bc	11.61b	13.63a	12.66ab
	20~40	1.92d	2.66c	3.20bc	4.41b	7.05a	8.34a
	40~60	0.46e	0.42e	0.91d	2.08c	3.75b	4.53a
	60~80	0.25d	0.21d	0.37c	0.35c	0.70b	1.16a
中活性有机碳	0~20	3.26d	3.01d	3.56cd	4.77bc	6.44b	7.38a
	20~40	2.38cd	1.37d	2.09d	3.52c	5.89b	8.12a
	40~60	1.54d	1.58d	2.00c	3.16b	6.05a	5.79a
	60~80	1.06c	1.04c	1.11c	1.24c	1.95b	2.38a
低活性有机碳	0~20	2.32c	2.50c	2.56c	2.90b	3.52a	3.37a
	20~40	1.62c	1.35d	1.47cd	1.96b	2.89a	2.88a
	40~60	0.98d	0.83d	1.15c	1.72b	2.60a	2.50a
	60~80	0.55bc	0.50bc	0.57bc	0.46c	0.63b	1.04a
惰性有机碳	0~20	6.09b	6.96ab	6.94ab	7.56a	7.93a	7.49a
	20~40	4.26cd	3.67d	4.50c	5.21b	6.80a	6.79a
	40~60	2.40cd	2.09d	2.89c	3.81b	4.85ab	5.01a
	60~80	1.78b	1.55b	1.70b	1.55b	2.24a	2.39a

有机碳组分	采样深度/ cm	种植年限/a
有机碳组分	采样深度/ cm	0	2~5	5~10	10~20	20~30	30~35
高活性有机碳	0~20	37.10b	43.53a	44.03a	43.22a	43.24a	41.03a
	20~40	18.64b	29.35a	28.30a	29.24a	31.17a	31.97a
	40~60	8.48d	8.54d	13.17c	19.31	21.78b	25.45a
	60~80	6.89d	6.67d	9.87c	9.68c	12.70b	16.54a
中活性有机碳	0~20	17.59c	13.56d	15.29cd	17.80c	20.44b	23.80a
	20~40	23.36b	15.17d	18.60c	23.14b	25.97b	30.98a
	40~60	28.83c	32.17b	28.80c	29.38c	35.05a	32.41b
	60~80	29.21b	30.91b	29.69b	34.34a	35.18a	34.21a
低活性有机碳	0~20	12.44a	11.38ab	10.96b	10.77b	11.17ab	10.85b
	20~40	15.90a	14.90ab	13.14ab	13.01b	12.80bc	11.01c
	40~60	18.03a	16.81b	16.50b	15.95bc	15.04bc	14.00c
	60~80	15.03a	15.41a	15.17a	12.81b	11.45b	14.90a
惰性有机碳	0~20	32.87a	31.53a	29.72ab	28.21b	25.15c	24.31c
	20~40	42.10a	40.57ab	39.96b	34.61c	30.06d	26.04e
	40~60	44.66a	42.48ab	41.54b	35.36c	28.12d	28.14d
	60~80	48.87a	47.01a	45.26ab	43.17bc	40.67c	34.34d