添加石灰和秸秆对塿土有机碳固持的影响

doi:10.3864/j.issn.0578-1752.2020.20.010

摘要/Abstract

摘要：

【目的】研究作物秸秆与石灰配施对土壤CO₂排放、土壤有机碳（SOC）固持、土壤无机碳（SIC）转化的影响机制,以及SOC固持对初始SOC含量的响应。【方法】--采用室内恒温培养试验及稳定同位素技术（¹³C）,选用经16年不同碳氮水平管理,且长期进行冬小麦-夏休闲种植的2个供试土壤样品:S₀N₀土壤（不进行秸秆还田+不施用氮肥）和S₁N₁土壤（高量秸秆还田+高量施用氮肥:240 kg·hm^-2）,将S₀N₀土壤和S₁N₁土壤分别在添加秸秆（12 g·kg^-1）或不添加秸秆以及添加石灰（3 g·kg^-1）或不添加石灰的情况下于25℃黑暗条件中培养120 d。【结果】未添加秸秆和石灰时,S₁N₁土壤的CO₂累积释放量比S₀N₀土壤高出42.9%;添加等量秸秆不仅提高了S₀N₀土壤和S₁N₁土壤的CO₂累积释放量（81.6%,70.4%）,而且S₀N₀土壤CO₂累积释放量的增加幅度高于S₁N₁土壤,这说明秸秆的添加对初始SOC含量低的土壤即S₀N₀土壤的原SOC矿化影响更大。但是无论添加秸秆与否,石灰的加入使S₀N₀土壤和S₁N₁土壤的CO₂累积释放量分别降低了428.11和528.52 mg·kg^-1。与空白土壤相比,添加秸秆使S₀N₀土壤和S₁N₁土壤的SOC含量分别提高了2.95和3.19 g·kg^-1;但是与单独添加秸秆相比,同时添加秸秆和石灰使S₁N₁土壤的SOC显著降低了1.36 g·kg^-1,而对S₀N₀土壤的SOC含量没有影响。利用¹³C稳定同位素技术发现,添加秸秆能促使新形成SOC;其中,S₀N₀土壤中新形成的SOC含量比S₁N₁土壤高出0.77 g·kg^-1;然而与单独添加秸秆相比,同时添加石灰和秸秆后新形成的SOC与其相差无几,说明石灰的加入对秸秆的腐解不会造成影响。在S₀N₀土壤和S₁N₁土壤中,添加秸秆使SOC净固持量分别提高了3 066.3和2 480.53 mg·kg^-1;同时添加石灰和秸秆对S₀N₀土壤的SOC净固持量无显著影响,但是S₁N₁土壤的SOC净固持量则呈现下降的趋势。石灰的加入使S₀N₀土壤和S₁N₁土壤的CO₂释放量分别降低了469和529 mg·kg^-1,同时使SIC含量分别提高了443和566 mg·kg^-1。【结论】初始SOC含量低的土壤具有更高的固碳潜力;添加钙源能够与土壤CO₂通过化学反应生成无机碳—碳酸钙的方式从另一个角度达到土壤固碳减排的目标。

关键词: 土壤碳, 土壤呼吸, 添加秸秆, 施用石灰, 同位素技术

Abstract:

【Objective】Soil organic carbon (SOC) sequestration is crucial for improving soil fertility and agricultural production sustainability. The soil inorganic carbon (SIC) is closely related to SOC with regarding with inter-transformation, which has also great effect on carbon sequestration. Crop straw return has been recognized as one of the most important organic amendment improving soil organic carbon sequestration in farmland. Meanwhile, the addition of lime also contributes greatly to increasing SIC, thereby affecting the SOC sequestration. However, the mechanism of simultaneous incorporation of crop straw and lime affecting on the CO₂ emission, SOC and SIC dynamics are not well understood, and how the SOC sequestration responds to the initial level of SOC is not clear, particularly after straw return. 【Method】 The incubation experiment and stable isotope technique (¹³C) were used in the study. The two tested soils were collected from a field with continuously cropping of winter wheat for 16 years, which was subjected to differential crop residue and nitrogen managements over long-term, including (1) S₀N₀ soil (no straw return+ nitrogen fertilizer application: 0); (2) S₁N₁ soil (high amount of straw return+ nitrogen fertilizer application: 240 kg·hm^-2). And then the two soils were both incubated with or without addition of straw and lime for 120 days under 25℃. 【Result】 The study showed that the soil cumulative CO₂ emission was observed 42.9% higher in S₁N₁ soils than that in S₀N₀ soils, when without straw and lime addition. In both soils, the straw addition alone increased the soil cumulative CO₂ emission by averages of 81.6% and 70.4%, respectively, compared with straw absence. Meanwhile, the increase of the cumulative CO₂ emission in S₀N₀ soils was higher than in S₁N₁ soils. This showed that straw addition had a greater impact on the native OC mineralization in soil with low initial SOC. Lime addition decreased soil cumulative CO₂ emission in both soils whether straw addition or not. Straw addition increased the SOC by 2.95 g·kg^-1 and 3.19 g·kg^-1 in S₀N₀ soils and S₁N₁ soils, respectively, while reduced the SOC by 1.36 g·kg^-1 in S₁N₁ soils and did not affect the SOC in S₀N₀ soils when combining with lime addition. Using¹³C stable isotope technology, the newly formed organic carbon (OC) in the two soils both significantly increased after straw addition, therein which increased 25.8% in S₀N₀ soils when compared with S₁N₁ soils. However, the conjoint addition of lime and straw did not modify the newly formed SOC when compared with the addition of straw alone, which showed that the lime addition had no effect on the decomposition process of straw in the soil. Over all, straw addition alone increased the SOC net sequestration by 3 066.3 mg?kg^-1and 2 480.53 mg?kg^-1 in S₀N₀ soils and S₁N₁ soils, respectively. The conjoint addition of lime and straw had no significant effect on the SOC net sequestration in S₀N₀ soils, but there was a decreasing trend on the SOC net sequestration in S₁N₁ soils. Lime addition reduced the cumulative CO₂ emission by 469 mg?kg^-1 and 529 mg?kg^-1 in S₀N₀ soils and S₁N₁ soils, respectively, which approximately equaled to the increases in SIC (by 443 mg?kg^-1 and 566 mg?kg^-1, respectively).【Conclusion】 In conclusion, the soil with low initial SOC content had higher potential in SOC sequestration. Lime addition might be an effective method to affect soil carbon sequestration and reduce soil CO₂ emission through chemical reactions.

Key words: soil carbon, soil respiration, straw return, lime, isotope technology

曹彬彬,朱熠辉,姜禹含,师江澜,田霄鸿. 添加石灰和秸秆对塿土有机碳固持的影响[J]. 中国农业科学, 2020, 53(20): 4215-4225.

CAO BinBin,ZHU YiHui,JIANG YuHan,SHI JiangLan,TIAN XiaoHong. Effects of Lime and Straw Addition on SOC Sequestration in Tier Soil[J]. Scientia Agricultura Sinica, 2020, 53(20): 4215-4225.

0
/ / 推荐

导出引用管理器 EndNote|Reference Manager|ProCite|BibTeX|RefWorks

链接本文: https://www.chinaagrisci.com/CN/10.3864/j.issn.0578-1752.2020.20.010

https://www.chinaagrisci.com/CN/Y2020/V53/I20/4215

图/表 8

表1

图1

表2

表3

图2

表4

图3

图4

参考文献 40

[1]	LEHMANN J, KLEBER M. The contentious nature of soil organic matter.Nature, 2015(528):60-68.
[2]	LAL R. Soil carbon sequestration impacts on global climate change and food security. Science, 2004,304(5677):1623-1627. doi: 10.1126/science.1097396 pmid: 15192216
[3]	CHEN C R, XU Z H, MATHERS N J. Soil carbon pools in adjacent natural and plantation forests of subtropical Australia. Soil Science Society of America Journal, 2004,68(1):282-291.
[4]	HUSSAIN S, SHARMA V, ARYA V M, SHARMA K R, CH S. Total organic and inorganic carbon in soils under different land use/land cover systems in the foothill Himalayas. Catena, 2019,182:104.
[5]	BATJES N H. Soil carbon stocks of Jordan and projected changes upon improved management of croplands. Geoderma, 2006,132(3-4):361-371.
[6]	AN H, WU X Z, ZHANG Y R, TANG Z S. Effects of land-use change on soil inorganic carbon: A meta-analysis. Geoderma, 2019,353:273-282.
[7]	霍丽丽, 赵立欣, 孟海波, 姚宗路. 中国农作物秸秆综合利用潜力研究. 农业工程学报, 2019,35(13):218-224.
	HUO L L, ZHAO L X, MENG H B, YAO Z L. Study on straw multi-use potential in China. Transactions of the Chinese Society of Agricultural Engineering, 2019,35(13):218-224.(in Chinese)
[8]	ZHANG J, HU K, LI K, ZHENG C, LI B. Simulating the effects of long-term discontinuous and continuous fertilization with straw return on crop yields and soil organic carbon dynamics using the DNDC model. Soil & Tillage Research, 2017,165:302-314.
[9]	SILVEIRA M L, LIU K, SOLLENBERGER L E, FOLLETT R F, VENDRAMINI J M B. Short-term effects of grazing intensity matter accumulation in cultivated and native grass soils. Soil Science Society of America Journal, 2013,62:1367-1377.
[10]	HE Y T, ZHANG W J, XU M G, TONG X G, SUN F X, WANG J Z, HUANG S M, ZHU P, HE X H. Long-term combined chemical and manure fertilizations increase soil organic carbon and total nitrogen in aggregate fractions at three typical cropland soils in China. Science of the Total Environment, 2015,532(1):635-644.
[11]	KUZYAKOV Y. Priming effects: interactions between living and dead organic matter. Soil Biology and Biochemistry, 2010,42(9):1363-1371.
[12]	LI S, LI Y B, LI X S, TIAN X H, ZHAO A Q, WANG S J, WANG S X, SHI J L. Effect of straw management on carbon sequestration and grain production in a maize-wheat cropping system in Anthrosol of the Guanzhong Plain. Soil & Tillage Research, 2016,157(303):43-51.
[13]	FONTAINE S, MARIOTTI A, ABBADIE L. The priming effect of organic matter: a question of microbial competition? Soil Biology and Biochemistry, 2003,35:837-843.
[14]	EDWARDS K R, PICEK T, ČÍŽKOVÁ H, ZEMANOVÁ K M, STARÁ A. Nutrient addition effects on carbon fluxes in wet grasslands with either organic or mineral soil. Wetlands, 2015,35:55-68.
[15]	KIRKBY C A, RICHARDSON A E, WADE L J, PASSIOURA J B, BATTEN G D, BLANCHARD C, KIRKEGAARD J A. Nutrient availability limits carbon sequestration in arable soils. Soil Biology and Biochemistry, 2014,68:402-409.
[16]	陈宗定, 许春雪, 安子怡, 王亚平, 孙德忠, 王苏明. 土壤碳赋存形态及分析方法研究进展. 岩矿测试, 2019,38(2):104-115.
	CHEN Z D, XU C X, AN Z Y, WANG Y P, SUN D Z, WANG S M. Research Progress on Fraction and Analysis Methods of Soil Carbon. Rock and Mineral Analysis, 2019,38(2):104-115. (in Chinese)
[17]	PARADELO R, VIRTO I, CHENU C. Net effect of liming on soil organic carbon stocks: a review. Agriculture, Ecosystems and Environment, 2015,202(1):98-107.
[18]	AYE N S, SALE P W G, TANG C. The impact of long-term liming on soil organic carbon and aggregate stability in low-input acid soils. Biology &Fertility of Soils, 2016,52:697-709.
[19]	何翠翠, 王立刚, 王迎春, 张文, 杨晓辉. 长期施肥下黑土活性有机质和碳库管理指数研究. 土壤学报, 2015(1):194-202.
	HE C C, WANG L G, WANG Y C, ZHANG W, YANG X H. Effect of long-term fertilization on labile organic matter in and carbon pool management index of black soil.Acta Pedologica Sinica, 2015(1):194-202. (in Chinese)
[20]	姜振辉, 师江澜, 贾舟, 丁婷婷, 田霄鸿. 秸秆还田配施中微量元素对农田土壤有机碳固持的影响. 应用生态学报, 2016,27(4):1196-1202.
	JIANG Z H, SHI J L, JIA Z, DING T T, TIAN X H. Effects of straw returning combined with medium and microelements application on soil organic carbon sequestration in cropland. Chinese Journal of Applied Ecology, 2016,27(4):1196-1202. (in Chinese)
[21]	WU L, ZHANG W J, WEI W J, HE Z L, KUZYAKOV Y, BOL R, HU R G. Soil organic matter priming and carbon balance after straw addition is regulated by long-term fertilization. Soil Biology and Biochemistry, 2019,135:383-391.
[22]	张蕊, 赵钰, 何红波, 张旭东. 基于稳定碳同位素技术研究大气CO₂浓度升高对植物-土壤系统碳循环的影响. 应用生态学报, 2017,28(7):2379-2388.
	ZHANG R, ZHAO Y, HE H B, ZHANG X D. Investigation on effects of elevated atmospheric CO₂ concentration on plant-soil system carbon cycling: Based on stable isotopic technique. Chinese Journal of Applied Ecology, 2017,28(7):2379-2388. (in Chinese)
[23]	寇太记, 朱建国, 谢祖彬, 刘钢, 曾青. 大气CO₂浓度升高和氮肥水平对麦田土壤有机碳更新的影响. 土壤学报, 2009,46(3):459-465.
	KOU T J, ZHU J G, XIE Z B, LIU G, ZENG Q. Effect of elevated atmospheric pCO₂ and nitrogen level on replacement rate of soil organic carbon in winter wheat field. Acta Pedologica Sinica, 2009,46(3):459-465. (in Chinese)
[24]	SINGH B P, COWIE A L. Long-term influence of biochar on native organic carbon mineralization in a low-carbon clayey soil. Scientific Reports, 2014,4(3687):1-9.
[25]	鲍士旦. 土壤农化分析. 北京: 中国农业出版社, 2000.
	BAO S D. Soil and Agricultural Chemistry Analysis. Beijing: China Agriculture Press, 2000. (in Chinese)
[26]	CHIANG P N, WANG M K, CHIU C Y, KING H B, HWONG J L. Change in the grassland-forest boundary at Ta-Ta-China long term ecological research (LTER) site detected by stable isotope ratio of soil organic matter. Chemosphere. 2004; 54:217-224. pmid: 14559272
[27]	李顺姬, 邱莉萍, 张兴昌. 黄土高原土壤有机碳矿化及其与土壤理化性质的关系. 生态学报, 2010,30(5):1217-1226.
	LI S J, QIU L P, ZHANG X C. Mineralization of soil organic carbon and its relations with soil physical and chemical properties on the Loess Plateau. Acta Ecologica Sinica, 2010,30(5):1217-1226. (in Chinese)
[28]	SCHMATZ R, RECOUS S, AITA C, TAHIR M M, SCHU A L, CHAVES B, GIACOMINI S J. Crop residue quality and soil type influence the priming effect but not the fate of crop residue C. Plant and Soil, 2017,414:229-245.
[29]	KUZYAKOV Y, FRIEDEL J K, STAHR K. Review of mechanisms and quantification of priming effects. Soil Biology and Biochemistry, 2000,32(11):1485-1498.
[30]	CHEN R, SENBAYRAM M, BLAGODATSKY S, MYACHINA O, DITTERT K, LIN X G, BLAGODATSKAYA E, KUZYAKOV Y. Soil C and N availability determine the priming effect: microbial N mining and stoichiometric decomposition theories. Global Change Biology, 2014,20(7):2356-2367. pmid: 24273056
[31]	FALCHINI L, NAUMOVA N, KUIKMAN P J, BLOEM J, NANNIPIERI P. CO₂ evolution and denaturing gradient gel electrophoresis profiles of bacterial communities in soil following addition of low molecular weight substrates to simulate root exudation. Soil Science Society of America Journal, 2003,35(6):775-782.
[32]	戚瑞敏, 赵秉强, 李娟, 林治安, 李燕婷, 杨相东, 李志杰. 添加牛粪对长期不同施肥潮土有机碳矿化的影响及激发效应. 农业工程学报, 2016,32(2):118-127.
	QI R M, ZHAO B Q, LI J, LIN Z A, LI Z T, YANG X D, LI Z J. Effects of cattle manure addition on soil organic carbon mineralization and priming effects under long-term fertilization regimes. Transactions of the Chinese Society of Agricultural Engineering, 2016,32(2):118-127. (in Chinese)
[33]	SHAHBAZ M, KUZYAKOV Y, SANAULLAH M, HEITKAMP F, ZELENEV V, KUMAR A, BLAGODATSKAYA E. Microbial decomposition of soil organic matter is mediated by quality and quantity of crop residues: mechanisms and thresholds. Biology and Fertility of Soils, 2017,53:287-301.
[34]	CRAINE J M, MORROW C, FIERER N O. Microbial nitrogen limitation increases decomposition. Ecology, 2007,88:2105-2113. doi: 10.1890/06-1847.1 pmid: 17824441
[35]	KOWALENKO C G, IHNAT M. Residual effects of combinations of limestone, zinc and manganese applications on soil and plant nutrients under mild and wet climatic conditions. Canadian Journal of Soil Science, 2013,93(1):113-125.
[36]	ZHAO H L, ZHANG H J, ABDUL G, LIU J F, CHEN Y L, CHU S J, TIAN X H. Enhancing organic and inorganic carbon sequestration in calcareous soil by the combination of wheat straw and wood ash and/or lime. PLoS ONE, 2018,13(10):e0205361. doi: 10.1371/journal.pone.0205361 pmid: 30304053
[37]	SHAHBAZ M, KUMAR A, KUZYAKOV Y, BÖRJESSON G, BLAGODATSKAYA E. Priming effects induced by glucose and decaying plant residues on SOM decomposition: A three-source, ¹³C/¹⁴C partitioning study. Soil Biology and Biochemistry, 2018,121:138-146.
[38]	STEWART C E, PAUSTIAN K, CONANT R T, PLANTE A F, SIX J. Soil carbon saturation: Evaluation and corroboration by long-term incubations. Soil Biology and Biochemistry, 2008,40(7):1741-1750.
[39]	KAISER M, ELLERBROCK R H, WULF M, DULTZ S, HIERATH C, SOMMER M. The influence of mineral characteristics on organic matter content, composition, and stability of top soils under long-term arable and forest land use. Journal of Geophysical Research: Biogeosciences, 2015,117:1-16.
[40]	LIM S S, CHOI W J. Changes in microbial biomass, CH₄ and CO₂, emissions, and soil carbon content by fly ash co-applied with organic inputs with contrasting substrate quality under changing water regimes. Soil Biology and Biochemistry, 2014,68(1):494-502.

土样 Soil	pH	SOC (g?kg^-1)	TN (g?kg^-1)	DOC (mg?kg^-1)	MBC (mg?kg^-1)	CaCO₃ (g?kg^-1)	NO₃^--N (mg?kg^-1)	NH₄⁺-N (mg?kg^-1)	δ¹³C (‰)
S₀N₀	8.21a	7.98b	0.77b	7.49b	177.8b	68.6a	6.86b	0.45b	-24.514
S₁N₁	7.99b	12.61a	1.05a	195.7a	447.0a	65.5b	28.59a	1.38a	-25.132

	时间 Time	时间×土壤 Time×soil fertility	时间×秸秆 Time× straw	时间×石灰 Time× lime	时间×土壤×秸秆 Time×soil fertility×straw	时间×土壤×石灰 Time×soil fertility×lime	时间×秸秆×石灰 Time×straw ×lime	时间×土壤×秸秆×石灰 Time×soil fertility×straw×lime
	P	P	P	P	P	P	P	P
CO₂累积释放量 Cumulative CO₂ emission	<0.001	<0.001	<0.001	<0.001	<0.001	<0.001	<0.001	<0.001

处理 Treatment		CO₂释放量 CO₂ emission (mg?kg^-1)	增加量 Increase amount (mg?kg^-1)	SOC (mg?kg^-1)	增加量 Increase amount (mg?kg^-1)	SIC (mg?kg^-1)	增加量 Increase amount (mg?kg^-1)
S₀N₀	M₀	600b	-	7280b	-	8380a	-
S₀N₀	M₁	3564a	2964	10480a	3200	8390a	10
S₁N₁	M₀	1193b	-	12440b	-	7823a	-
S₁N₁	M₁	4027a	2833	14435a	1995	7783a	-40
S₀N₀	L₀	2316a	-	8825a	-	8160b	-
S₀N₀	L₁	1847b	-469	8940a	115	8610a	443
S₁N₁	L₀	2912a	-	13575a	-	7520b	-
S₁N₁	L₁	2383b	-529	13300b	-275	8086a	566

处理 Treatment			丰度值 δ¹³C ¹³C abundance (‰)	土壤有机碳 (C_total) Final SOC (g?kg^-1)	源自秸秆碳比例(f_new) New OC proportion (%)	源自秸秆碳 New OC (g?kg^-1)	源自原土壤碳比例(f_native) Native SOC proportion (%)	源自土壤有机碳 Native SOC (g?kg^-1)
S₀N₀	L₀	M₀	-23.54	7.35e	0	0	100	7.35b
		M₁	-21.61	10.30d	28.9	2.98a	71.1	7.32b
	L₁	M₀	-23.52	7.22e	0	0	100	7.22b
		M₁	-21.49	10.66d	32.4	3.45a	67.6	7.21b
S₁N₁	L₀	M₀	-25.28	12.48c	0	0	100	12.48a
		M₁	-23.48	14.67a	15.1	2.21b	84.9	12.46a
	L₁	M₀	-25.42	12.40c	0	0	100	12.40a
		M₁	-23.46	14.20b	15.2	2.15b	84.8	12.04a