长期不同施肥下塿土有机碳和全氮在团聚体中的分布

【目的】研究小麦/玉米轮作体系不同施肥方式下土壤有机碳(SOC)和全氮(TN)在(?)土不同水稳性团聚体中的分布特征,以期深入理解不同施肥方式对土壤碳、氮固持的机制。【方法】采集(?)土21年长期肥料定位试验不同施肥处理0-10 cm和10-20 cm土层土样,分析其水稳性团聚体(2 mm、2~1 mm、1~0.5 mm、0.5~0.25 mm以及0.25 mm)有机碳和全氮的分布特征。试验设不施肥(CK),化肥氮磷钾配施(N、NP、NK、PK、NPK)和秸秆还田配施氮磷钾(SNPK)以及两个水平有机肥与氮磷钾配施(M1NPK、M2NPK)9个处理。【结果】长期施肥0-10 cm土层土壤团聚体SOC和TN含量明显高于10-20 cm,平均增幅20%以上。2~1 mm或1~0.5mm团聚体中SOC和TN的含量最高,0.25 mm团聚体最低。长期不施磷肥处理的土壤团聚体SOC和TN含量均与CK相似。NP、NPK以及SNPK处理,0-10 cm土层SOC较CK分别增加16%~43%、9%~40%和22%~47%;TN增幅分别为28%~48%、39%~61%和39%~91%。10 20 cm土层,NP、NPK以及SNPK处理2mm、2~1 mm、1~0.5 mm土壤团聚体SOC较CK增幅分别为35%~49%、17%~40%和45%~46%,TN增幅分别为44%~47%、39%~54%和54%~64%。长期有机肥与氮磷钾配施处理(M1NPK、M2NPK),0-10 cm土层的团聚体SOC平均较CK分别增加68%~122%和61%~163%,TN平均分别增加84%~133%和97%~175%;10-20 cm土层,SOC较CK平均增幅分别为20%~61%和39%~118%,TN增幅平均分别为43%~86%和107%~136%。SOC和TN主要储存于0.25 mm团聚体中(40%)2~1 mm团聚体储存最少(10%)。长期不施氮或不施磷对SOC和TN在团聚体中的储存比例基本没有影响。长期NP、NPK以及M1NPK、M2NPK均降低了各土层SOC和TN在2 mm或2~1 mm的储存比例增加了在1~0.25 mm团聚体储存比例。2 mm或2~1 mm团聚体的C/N比值高于微团聚体(0.25 mm),而与CK相比,长期施肥降低了土壤团聚体的C/N比值。【结论】关中地区(?)土长期偏施化肥对有机碳和全氮在团聚体的含量及分布没有显著影响而长期氮磷或氮磷钾化肥配合、氮磷钾与有机物配合均明显增加土壤团聚体的有机碳及全氮含量,特别是长期氮磷钾配合有机肥能显著增加土壤1~0.25 mm团聚体对土壤有机碳和全氮的固存比例,提高土壤有机碳和全氮储量减少温室气体的排放。     

玉米秸秆源有机物料对黑土养分有效性与酶活性的提升效应

  【目的】  研究以玉米秸秆为主要原料制备的不同类型有机物料对东北黑土土壤肥力和玉米产量的影响,为黑土地保护和秸秆资源高效利用提供理论依据。  【方法】  田间定位试验连续进行了5年。试验设不施肥对照 (CK)、单施化肥 (NPK)、化肥配施秸秆 (NPK+ST)、化肥配施生物炭 (NPK+BR) 以及化肥配施堆肥 (NPK+CP) 5个处理,各有机物料每年均为等碳量投入 (C 3200 kg/hm2)。5年后,采集耕层 (0—20 cm) 和亚耕层 (20—40 cm) 土壤样品,测定土壤有机碳 (SOC)、活性有机碳 (LOC)、速效养分与酶活性,并结合年际间玉米产量变化进行综合评价。  【结果】  与NPK相比,NPK+BR处理显著增加了耕层及亚耕层SOC含量,增幅分别为28.2%和11.2%;NPK+CP和NPK+ST处理增加了耕层SOC含量,增幅分别为15.5%和7.6%,对亚耕层SOC含量影响不显著;配施有机物料处理显著增加了0—40 cm土层LOC含量,且NPK+CP和NPK+ST处理LOC含量在0—20 cm土层显著高于NPK+BR,增幅分别为13.2%和8.7%,各种有机物料处理LOC含量在20—40 cm土层差异不显著;3个配施有机物料处理均显著增加了0—20 cm土层有效磷含量,仅NPK+CP和NPK+BR处理显著提高了20—40 cm土层有效磷含量;配施有机物料处理对0—40 cm土层土壤速效氮和速效钾含量影响均不显著,但配施堆肥处理0—20 cm土层土壤速效氮含量显著高于配施秸秆和生物炭处理。配施有机物料处理比NPK处理显著增加了0—40 cm土层土壤纤维素酶、蔗糖酶和磷酸酶活性。NPK+ST和NPK+BR处理比NPK+CP处理更利于提高耕层纤维素酶活性,NPK+ST处理耕层蔗糖酶活性显著高于NPK+BR和NPK+CP处理;配施有机物料处理亚耕层土壤纤维素酶和蔗糖酶活性差异不显著。NPK+ST和NPK+CP处理较NPK+BR处理显著提高了0—40 cm土层土壤磷酸酶活性。不同处理玉米产量在年际间波动变化,配施有机物料处理玉米产量高于NPK处理,NPK+CP和NPK+ST处理对玉米产量的提升在第一年即有明显效果,而NPK+BR处理对玉米产量的积极效果在4年后才表现出来。各处理平均玉米产量的高低表现为NPK+CP > NPK+ST > NPK+BR > NPK > CK。  【结论】  化肥配施生物炭对0—40 cm土层土壤有机碳的积累作用最突出,而配施秸秆和堆肥更利于提升土壤活性有机碳的含量。配施堆肥0—20 cm土层土壤速效氮含量显著高于配施秸秆和生物炭处理,三者0—20 cm土层土壤有效磷含量无显著差异,但配施堆肥和生物炭20—40 cm土层有效磷含量显著高于配施秸秆处理。配施秸秆或生物炭增强了0—40 cm土层土壤纤维素酶活性,而蔗糖酶和磷酸酶活性以配施秸秆和堆肥处理为最高。随着土壤肥力的提高,配施有机物料处理促进了玉米产量的提升,以配施堆肥处理对玉米平均产量的增加幅度最高。因此,对于基础肥力较高的黑土而言,生物炭还田可实现黑土有机碳的快速提升,而堆肥和秸秆直接还田对玉米产量的促进作用更为明显。     

不同培肥处理对土壤溶解性有机碳含量及特性的影响

以黄土高原南部地区的长期肥料定位试验为研究对象,通过室内测定及培养试验研究了不施肥(CK)、撂荒(FA)、施氮磷钾肥(NPK)、氮磷钾配施有机肥(MNPK)和氮磷钾配施秸秆(SNPK)培肥处理土壤中溶解性有机碳(DOC)的含量、结构特性及其降解特性。结果表明,在0～20 cm耕层土壤中,不同培肥处理土壤中DOC的含量变化范围在4.65～8.94 mg kg-1之间,平均为6.42 mg kg-1,各培肥处理间差异明显,其大小顺序为MNPKSNPKNPKFACK。由DOC溶液的UV280吸收值和腐殖化指数(HIXem)可以得出,不同培肥处理土壤中溶解性有机物中结构相对复杂的芳香化合物所占的比例明显不同,其大小顺序为SNPKMNPKFANPKCK。经过7d的生物降解培养,不同培肥处理土壤DOC溶液的降解率变化范围在19.3%～48.5%之间,平均为28.6%,其大小顺序为CKFANPKSNPKMNPK。随着培养的进行,DOC溶液中结构较为复杂的溶解性有机物的比例上升。     

秸秆和生物炭还田对棕壤团聚体分布及有机碳含量的影响

  【目的】  比较长期秸秆和生物炭还田后土壤团聚体的变化与差异，旨在探索棕壤适宜的改良方法。  【方法】  在辽宁沈阳棕壤上连续进行了6年的田间定位微区试验，种植制度为玉米连作，试验共设6个处理:不施肥 (CK)、单施氮磷钾 (NPK)、单施生物炭 (B)、生物炭与氮磷钾配施 (BNPK)、单施秸秆 (S)、秸秆与氮磷钾配施 (SNPK)。在玉米收获后，采集0—20和20—40 cm两土层土壤样品，采用Yoder湿筛法进行了团聚体分级和测定。  【结果】  与NPK相比，BNPK和SNPK处理显著提高了0—20和20—40 cm土层 > 1 mm、1～0.5 mm和 0.25～0.5 mm粒级团聚体含量占比，降低了0.25～0.053 mm粒级团聚体含量占比，SNPK处理提高大团聚体含量占比的效果显著高于BNPK。与NPK处理相比，BNPK和SNPK处理显著增加了团聚体平均重量直径 (MWD)、几何平均直径 (GMD) 和0.25 mm粒级团聚体含量 (R_0.25)，即增加了团聚体的稳定性，SNPK处理的团聚体MWD和GMD值又显著高于BNPK，R_0.25值两处理间无显著差异 (0—20 cm土层)。随团聚体粒级减小，不同粒级团聚体有机碳含量随之减少，以 > 1 mm粒级团聚体有机碳含量最高。与CK相比，各施肥处理均增加了各粒级团聚体有机碳含量，BNPK处理对0—20 cm土层0.25～0.053 mm粒级团聚体有机碳含量影响最显著，有机碳含量增加了44.57%。  【结论】  长期秸秆和生物炭还田能够改变土壤团聚体的分布，有利于大团聚体的形成和土壤结构改善，可提高土壤团聚体有机碳含量和团聚体稳定性，增加作物产量；秸秆直接还田提高团聚体稳定性的效果优于生物炭还田，生物炭还田提高团聚体有机碳的效果方面优于秸秆直接还田。     

长期有机培肥提高红壤性水稻土生物学特性及水稻产量的微生物学机制

  【目的】  依托位于江西红壤研究所的有机肥长期定位试验，探究长期施用紫云英、猪粪和秸秆还田对土壤微生物量、酶活性和产量的影响，阐明土壤微生物学特性对土壤肥力的生物指示功能，揭示影响作物产量和微生物学特性的关键环境因子。  【方法】  长期定位试验始于1981年，选取的6个处理分别为:CK (不施肥)、NPK (单施化肥)、M1 (早稻施绿肥)、M2 (早稻加倍施绿肥)、M3 (早稻施绿肥+晚稻施猪粪) 和M4 (早稻施绿肥+晚稻秸秆还田)，此外，有机处理 (M1、M2、M3和M4) 在施用有机物料的基础上，每季还补充一定量化肥（N 69 kg/hm2、P₂O₅ 30 kg/hm2、K₂O 67.5 kg/hm2）。于每季收获后测定水稻产量。2018 年早稻收获后，采集耕层 (0—20 cm)土壤，测定土壤化学指标、微生物量碳氮、脲酶及其他参与土壤碳、氮、磷和硫循环的胞外酶活性。  【结果】  1) 2009—2018年间，长期施肥处理明显提高了水稻产量，其中M3处理的产量最高，其次为M2处理，二者均明显高于NPK处理；2) 土壤微生物量及酶活性均以有机处理 (M1、M2、M3和M4) 较高，其中M3处理土壤微生物量碳含量及各类土壤酶活性最高，M2处理土壤微生物量氮含量最高。有机处理较CK和NPK处理提高了土壤微生物熵。此外，微生物量碳氮和土壤酶活性与有机碳、全氮间存在显著或极显著相关关系；3) 有机碳与土壤微生物量 (0.895)、碳循环相关酶活性 (0.903)、氮循环相关酶活性 (0.854) 及水稻产量 (0.827) 呈显著正影响 (P < 0.05)；土壤pH与土壤碳循环相关酶活性 (0.378) 和氮循环相关酶活性 (0.365) 呈显著正影响 (P < 0.05)，对水稻产量 (0.211) 也表现为正影响，但不显著 (P > 0.05)。相较于pH，土壤有机碳含量在提高水稻产量、改善土壤微生物学特性上发挥了更为重要的作用。  【结论】  土壤微生物量碳氮和参与土壤碳、氮、磷和硫循环的胞外酶活性均可作为土壤微生物学指标表征土壤肥力的变化。土壤有机碳含量是提高作物产量、调控土壤微生物量和酶活性的关键因子。在供试条件下，长期实行早稻施绿肥+晚稻施猪粪的有机培肥，是提高土壤微生物量及酶活性并提高水稻产量的最佳选择。     

Long-term effects of mineral and organic fertilization on soil organic matter fractions and sorghum yield under Sudano-Sahelian conditions

Abstract. Knowledge of changes in soil organic matter (SOM) fractions resulting from agricultural practice is important for decision‐making at farm level because of the contrasting effects of different SOM fractions on soils. A long‐term trial sited under Sudano‐Sahelian conditions was used to assess the effect of organic and inorganic fertilization on SOM fractions and sorghum performance. Sorghum straw and kraal manure were applied annually at 10 t ha^?1, with and without urea at 60 kg N ha^?1. The other treatments included fallowing, a control (no fertilization), and inorganic fertilization only (urea, 60 kg N ha^?1). Fallowing gave significantly larger soil organic carbon and nitrogen (N) levels than any other treatment. Total soil SOM and N concentrations increased in the following order: urea only < straw < control < straw+urea < manure with or without urea < fallow. Farming had an adverse effect on SOM and N status; however, this mostly affected the fraction of SOM >0.053 mm (particulate organic matter, POM). The POM concentrations in the control, straw and urea‐only treatments were about one‐half of the POM concentrations in the fallow treatment. POM concentrations increased in the following order: urea only < control < straw with or without urea < manure with or without urea < fallow. The fraction of SOM <0.053 mm (fine organic matter, FOM) was greater than POM in all plots except in fallow and manure+urea plots. Total N concentration followed the same trend as SOM, but cultivation led to a decline in both POM‐N and FOM‐N. Crop yield was greatest in the manure plots and lowest in the straw, control and urea‐only plots. Results indicate that under Sudano‐Sahelian conditions, SOM, POM and FOM fractions and crop performance were better maintained using organic materials with a low C/N ratio (manure) than with organic material with a high C/N ratio (straw). Urea improved the effect of straw on crop yield and SOM concentration.     

Long-term manure amendments enhance neutral sugar accumulation in bulk soil and particulate organic matter in a Mollisol

Manure application generally increases soil organic matter (SOM) and particulate organic matter (POM) content in soil. Free and occluded POM (fPOM and oPOM) can be quantified by combining density and ultrasonic dispersion approaches, but it remains unclear which fraction of POM is more responsive to manure application, and whether manure treated soils have a more pronounced effect on POM content than unmanured soils (no or chemical fertilizer treated soils). Because neutral sugars in POM can be attributed to either plant- or microbial-derived compounds, we analyzed the pattern and ratio of different neutral sugars to clarify effects of different fertilizations on quality of POM in a study over two decades. Soil samples (0–20 cm) were collected from six fertilization treatments in a 25-year long fertilization experiment including no fertilizer (CK), low manure (M1), high manure (M2), chemical nitrogen, phosphorus and potassium fertilizers (NPK), and combined manure and chemical fertilizers (M1NPK, M2NPK). Our results showed that manure application generally led to higher organic carbon concentrations in bulk soil (M2NPK > M2 > M1NPK > M1 > CK > NPK), fPOM (M2NPK > M2 > M1 > M1NPK > NPK > CK) and oPOM (M1 > M2 > M1NPK > M2NPK > NPK > CK), respectively. As compared with unmanured treatments, manure amendments induced 48, 21 and 107% greater increases on average in neutral sugar concentrations in bulk soil, fPOM and oPOM, respectively. More plant-derived organic compounds were enriched in fPOM than oPOM and bulk soil, and the enrichment was more pronounced in manure treated soils than the unmanured soils. This study suggests that long-term use of manure enhanced microbial routing of specific monosaccharides into different POM fractions. Clearly, manure amendments improved labile SOM content and SOM quality in the Mollisol thus maintaining soil productivity over decades.     

长期施肥对红壤性水稻土颗粒有机质和矿物结合态有机质含量与化学组成的影响

以江西红壤地区双季稻田肥料定位试验为依托,研究了不施肥(CK)、单施化肥(NPK)及3种不同比例有机无机肥配施(LM、MM、HM)对红壤性水稻土全土、颗粒有机质(POM)和矿物结合态有机质(MinOM)组分碳、氮含量及其化学结构的影响。结果表明:施肥处理全土、POM和MinOM组分中有机碳、全氮含量均显著高于CK处理(P<0.05);与CK处理相比,施肥提高了POM组分质量分布,其中中、高量有机肥配施(MM、HM)分别显著提高POM组分质量分数15.7%和25.1%;施肥处理POM有机碳对土壤有机碳贡献率显著增加13.4%~42.6%;施肥处理未显著影响全土和MinOM组分碳氮比,但显著降低了POM组分碳氮比,降低量为16.8%~25.0%。与NPK处理相比,有机无机配施处理显著提高POM-C/MinOM-C值27.7%~70.2%,提高了土壤有机质活性。红外光谱分析显示,施肥处理较CK处理分别提高全土烷基碳和芳香碳相对含量5.4%~33.2%和0~12.2%;而施肥处理提高了POM烷基碳含量并降低了其芳香碳含量,但几乎不影响POM羧基碳含量,其中MM、HM处理POM烷基碳含量分别较CK处理显著提高12.4%和40.6%;除NPK处理降低了MinOM烷基碳含量外,施肥均提高了MinOM烷基碳和羧基碳含量并降低了其芳香碳含量,其中NPK处理较CK处理显著提高MinOM羧基碳含量70.8%。研究结果说明施肥能提高供试土壤全土及各土壤组分有机碳、全氮含量,与单施化肥相比,有机无机配施更有利于提高土壤POM数量及其结构活性,改善稻田土壤质量。     

长期施肥对土黑碳积累的影响

通过长期定位试验,探讨了20年不施肥（CK）、 单施化肥（NPK）、 秸秆和化肥配施（SNPK）、 常量有机肥和化肥配施（M1NPK）以及高量有机肥和化肥配施（M2NPK）5个施肥处理对土中黑碳含量及积累的影响。结果表明: 与CK处理相比,NKP处理对黑碳含量和积累没有明显影响; 有机肥和化肥配施（M1NPK、 M2NPK）对耕层（020 cm）土壤黑碳含量的影响较大,与CK处理相比,在土壤表层（05 cm）,M1NPK、 M2NPK分别提高了黑碳含量的108%和134%, 510 cm土层中黑碳含量增幅最高,分别提高164%和176%,在整个土层,M1NPK、 M2NPK处理分别增加了1.51和1.55倍; 秸秆和化肥配施（SNPK）下表层黑碳含量也有所增加,但增加幅度相对施用有机肥来说明明显较小。施肥对黑碳含量的影响主要发生在土壤表层,深层土壤黑碳受施肥影响较小。     

长期施肥对浙江稻田土壤团聚体及其有机碳分布的影响

以浙江省稻田长期定位试验站为依托,研究长期不同施肥措施对土壤团聚体及其有机碳分布的影响。研究结果表明,与不施肥对照(CK)相比,栏肥与化肥配施(NPKOM)、单施栏肥(OM)、秸秆与化肥配施(NPKRS)和单施秸秆(RS)处理均显著提高了2 mm和2~0.25 mm水稳定性大团聚体的含量和团聚体平均重量直径(p0.05),强化了团聚体对土壤有机碳的物理保护作用。此外,长期有机无机配施(NPKOM和NPKRS)处理显著提高了各个粒级团聚体中有机碳含量,并且显著增加水稳定性大团聚体有机碳的贡献率,而长期单施化肥和单施秸秆处理并未有效增加土壤总有机碳含量。不同施肥处理下,2~0.25 mm粒级团聚体有机碳占土壤总有机碳的34.2%~48.6%,是土壤有机碳的主要载体。利用傅立叶变换红外光谱(FT-IR)技术对2~0.25 mm和0.053 mm团聚体进行结构表征,发现长期单施有机肥或者有机无机配施下芳香族C较CK提高29.9%~45.2%,较NPK处理提高22.3%~36.6%,提高了土壤有机碳的芳构化。在有机碳积累方面,施用有机肥,尤其是栏肥与化肥配施,同时强化了团聚体对有机碳的物理保护以及促进了化学抗性有机碳组分的积累,是加强稻田土壤有机碳库积累的合理施肥模式。     

等氮条件下长期有机无机配施对春玉米的氮素吸收利用和土壤无机氮的影响

【目的】研究等氮量投入条件下,长期使用不同有机物料替代无机肥的适宜比例对玉米氮养分累积、运移和氮肥利用效率和产量的影响,可以为吉林黑土区春玉米高效施肥,维持并提高土壤肥力提供理论依据。【方法】以国家(公主岭)黑土肥力与肥料效益长期定位试验为研究平台,玉米品种郑单958为供试作物,设5个不同处理,即:不施肥(CK)、氮肥(N)、氮磷钾化肥(NPK)、粪肥+NPK(MNPK)、秸秆还田+NPK(SNPK)。在玉米苗期、拔节期、大喇叭口期、抽丝期、灌浆期和成熟期采集地上部植株样品,分析玉米植株不同部位的氮含量和累积量以及运移比例,计算氮肥利用效率。【结果】在玉米各生育时期,MNPK处理氮素累积量均高于NPK和SNPK处理;拔节期至大喇叭口期氮素累积量为19.67~86.44 kg/hm2,其中MNPK氮素累积量达到86.44 kg/hm2,为氮素累积量增加最多、吸收速率最快的时期;在成熟期,MNPK、NPK、SNPK、N和CK处理植株氮素总累积量分别达到286.2、276.2、249.4、151.7和63.6 kg/hm2,SNPK处理氮素累积量略低于NPK处理,MNPK显著高于NPK和SNPK(P0.05)。MNPK、SNPK、NPK和N处理中,叶和茎鞘总氮素转移量分别为99.0、79.7、87.2和41.8 kg/hm2,总的转移氮素对籽粒的贡献率分别为51.0%、47.7%、47.2%和43.4%,以MNPK处理的总氮素转移量和转移氮素对籽粒贡献率最高,与其他处理差异显著。在各处理中,MNPK、NPK和SNPK三个处理的氮肥偏生产力(PFP)均大于60kg/kg,以MNPK最高,达到65.4 kg/kg。与化肥NPK处理比较,SNPK氮素偏生产力和收获指数差异不显著。MNPK处理土壤无机氮的含量在玉米整个生育期一直高于化肥NPK处理,并在玉米大喇叭口期达到最高,达到60.83 mg/kg,并与其他处理差异显著。【结论】长期有机无机配合施用,不仅能有效调节氮素积累和转运,还能提高氮肥利用效率。在适宜氮用量为165 kg/hm2时,以农家肥氮替代70%,或秸秆氮替代30%化肥氮素,既减少化肥氮投入,又增加了土壤供氮能力,因此,有机肥氮替代部分化肥氮是吉林省黑土区春玉米氮素管理的有效途径之一。     

生物炭及秸秆长期施用对紫色土坡耕地土壤团聚体有机碳的影响

依托紫色土坡耕地长期施肥试验观测平台,研究生物炭、秸秆对紫色土坡耕地团聚体有机碳分布的影响。长期施肥试验处理包括不施肥(CK)、无机氮磷钾肥(NPK)、秸秆还田(RSD)、生物炭与无机氮磷钾配施(BCNPK)、秸秆与无机氮磷钾配施(RSDNPK)。利用湿筛法,进行土壤团聚体粒径分组,随后测定各粒径团聚体含量及其有机碳含量,并计算团聚体平均质量直径(MWD)和几何平均直径(GMD)。结果表明,RSD、RSDNPK和BCNPK处理的表层SOC含量比CK处理增加43.1%～90.5%,SOC储量提高65.1%～74.3%,其中RSDNPK处理、BCNPK处理较NPK处理SOC显著增加25.2%～33.1%(P0.05), SOC储量显著提高23.2%～30.0%(P0.05)。团聚体MWD和GMD均为RSD处理RSDNPK处理BCNPK处理NPK处理CK处理; RSD处理0.25～2 mm的团聚体含量高达45.5%,较CK处理提高57.7%;秸秆和生物炭配施处理(RSDNPK处理和BCNPK处理)0.25～2mm的团聚体含量为41.3%～45.7%,而0.053mm粒径团聚体含量却降低54.1%～55.4%。NPK处理、RSD处理与CK处理的增长趋势相似,呈随团聚体粒径减小,团聚体有机碳含量先增大后减小,继而再增大的趋势;而RSDNPK、BCNPK处理则呈随粒径减小团聚体有机碳含量增加的趋势。生物炭和秸秆的施用能显著提升土壤有机碳含量,增强土壤结构稳定性,但生物碳的施用对提升土壤有机碳含量效果优于秸秆的施用,秸秆的施用对稳定土壤结构效果更优,因此生物炭和秸秆的施用可作为紫色土耕地土壤肥力维持和提升的有效管理措施。     

长期施肥下新疆灰漠土有机碳及作物产量演变

为明确长期不同施肥下新疆灰漠土有机碳和作物产量演变特征,依托始于1990年的灰漠土肥力长期定位监测试验,选择对照(CK,不施肥)、施氮磷肥(NP)、氮磷钾平衡施肥(NPK)、氮磷钾配合常量有机肥(NPKM)、氮磷钾配合高量有机肥(h NPKM,有机肥施用量为NPKM的2倍)、氮磷钾配合秸秆还田(NPKS)6个处理,分析不同处理下土壤有机碳和小麦、玉米产量演变特征,探讨碳投入及有机碳与作物产量的关系。结果表明:1)长期耗竭种植(CK)、连续施用NP或NPK肥,灰漠土有机碳含量持续下降,年均下降速率分别为0.094 g·kg~(-1)、0.043 g·kg~(-1)和0.053 g·kg~(-1),表明施化肥(NP、NPK)不能维持土壤有机碳含量,不利于土壤肥力的保持。NPKM和h NPKM处理,土壤有机碳显著增加,年均增加0.360 g·kg~(-1)和0.575 g·kg~(-1),增施有机肥是快速提高灰漠土肥力的重要措施。秸秆还田处理(NKPS),土壤有机碳年均增幅0.006 g·kg~(-1),与NPK处理对比,秸秆还田虽没有大幅度提高土壤有机碳,但维持了土壤肥力。2)较CK,长期化肥有机肥配施(NPKM、h NPKM)显著增加了作物产量(P0.05)。与NP和NPK比较,长期化肥有机肥配施显著提高了小麦产量(P0.05),但玉米产量与施化肥处理差异不显著(P0.05),玉米产量以平衡施肥(NPK)的增幅最高,达到220 kg·hm~(-2)·a~(-1)。小麦的产量变异系数(29.1%~43.9%)高于玉米产量变异(19.0%~32.7%)。化肥配合秸秆还田(NPKS)处理的小麦增产幅度与高量施用有机肥(h NPKM)处理接近,喻示了秸秆还田对作物增产的作用不可忽视。3)碳投入与土壤有机碳和小麦、玉米产量有显著线性正相关(P0.05)。基于以上分析,在干旱区灰漠土增加土壤碳投入(有机肥或秸秆)仍然是最基本的土壤培肥措施。     

不同施肥模式对南方黄泥田耕层有机碳固存及生产力的影响

【目的】探讨南方丘陵黄泥田不同施肥对耕层土壤有机碳固存及生产力的影响,促进区域农田固碳减排和作物高产。【方法】基于32年的长期定位试验,研究不施肥(CK)、单施化肥(NPK)、化肥+牛粪(NPKM)、化肥+全部稻草还田(NPKS)处理下,历年水稻产量、代表性年份耕层土壤有机碳含量及固碳速率的变化。【结果】NPK、NPKM、NPKS处理下水稻历年平均产量分别较CK高67.1%、88.1%和84.2%,差异显著,且NPKM、NPKS处理与NPK处理间亦具有显著差异。NPK、NPKM与NPKS处理耕层土壤有机碳历年平均含量比CK高8.9%~36.8%其中NPKM最高且亦显著高于NPKS与NPK处理。与初始土壤相比各处理有机碳含量增加1.84~5.26g/kg。以每10年为评价周期,NPKM、NPKS处理的固碳速率与CK及NPK差异均显著,其中双季稻年份NPKM与NPKS处理固碳速率分别是CK的2.38倍和1.98倍,是NPK处理的1.59倍与1.32倍但NPK处理与CK间差异不显著。稻田系统年均有机碳输入与有机碳固存间存在极显著幂函数关系,施肥土壤有机碳含量变化与籽粒产量变化间亦呈极显著正相关。【结论】南方黄泥田化肥配施有机肥或配合秸秆还田较单施化肥稳步提升水稻产量。长期不施肥土壤有机碳仍可维持低幅度增长,随着土壤有机碳含量升高,固碳效率逐步降低。化肥配施有机肥或配合秸秆还田较单施化肥明显提高了土壤的固碳速率二者均是提高黄泥田生产力与固碳能力的双赢措施。     

长期不同施肥和土地利用方式对塿土耕层碳储量的影响

利用土20年长期肥料定位试验研究了不同土地利用方式和施肥对土壤有机碳和无机碳储量变化的影响。试验包括休闲（Fallow, FL）、 撂荒（Setaside, SL）、 不施肥（CK）、 单施氮（N）、 氮钾（NK）、 磷钾（PK）、 氮磷（NP）、 氮磷钾（NPK）、 氮磷钾配合秸秆还田（SNPK）、 氮磷钾配合低量有机肥（M1NPK）和氮磷钾配合高量有机肥（M2NPK）11个处理。结果表明,CK和 FL 处理等质量耕层土壤有机碳储量仍维持在试验前水平,NP和 SL 处理显著提高了耕层土壤有机碳储量,年均增加分别达到 347 kg/hm2 和518 kg/hm2, 此4个处理等质量耕层土壤无机碳储量均较试验开始前（Initial soil, IniS）显著下降,尤其是NP处理显著低于其它3个处理。与IniS和CK相比,除NK处理外的所有施肥处理均显著地提高了等质量耕层土壤有机碳储量,其大小顺序为 M2NPKM1NPKSNPKNPKNPPKN,最大年均增加量为M2NPK 944 kg/hm2,最小为N 127 kg/hm2。施肥处理除PK和M2NPK处理外,其它处理等质量耕层土壤无机碳储量均较试验前明显降低,可能是由于土壤酸化所致。PK和M2NPK处理无机碳储量能够维持不下降,表明土壤无机碳和有机碳在适合条件下可能有某种关系。试验结果还显示,长期试验20年除M1NPK和M2NPK处理外,其它处理耕层土壤容重均明显高于试验开始前,表明等质量土壤碳储量与等深度碳储量相比可以更好地反映土壤碳的变化。     

长期施肥对红壤旱地土壤活性有机碳和酶活性的影响

以江西进贤长期肥料定位试验为平台,研究了红壤旱地不同施肥措施对土壤微生物生物量、活性有机C、C库管理指数以及土壤酶活性的影响。研究结果表明:与不施肥和单施化肥土壤相比,施有机肥处理土壤的pH、CEC、有机C、全N、全P、无机N、速效P、速效K及土壤微生物生物量均显著增加,土壤活性有机C和C库管理指数也较试前土壤和其他处理土壤明显提高,此外,土壤的转化酶、脱氢酶、脲酶和酸性磷酸酶活性也较其他处理显著增加。土壤微生物生物量、活性有机C以及4种土壤酶活性之间的相关关系显著,且它们均与土壤有机C、全N、全P、无机N、速效P等土壤养分呈显著正相关。因此,红壤旱地通过长期施用有机肥或与无机肥配施,不仅能显著提高土壤有机质的数量和质量,而且能增加土壤微生物生物量和酶活性,从而显著提高土壤肥力和土壤持续生产力。     

Long-term impacts of manure, straw, and fertilizer on amino sugars in a silty clay loam soil under temperate conditions

There is increasing evidence that microorganisms participate in soil C sequestration and stabilization in the form of resistant microbial residues. The type of fertilizers influences microbial activity and community composition; however, little is known about its effect on the microbial residues and their relative contribution to soil C storage. The aim of this study was to investigate the long-term impact (21 years) of different fertilizer treatments (chemical fertilizer, crop straw, and organic manure) on microbial residues in a silty clay loam soil (Udolls, USDA Soil Taxonomy). Amino sugars were used to indicate the presence and origin of microbial residues. The five treatments were: CK, unfertilized control; NPK, chemical fertilizer NPK; NPKS₁, NPK plus crop straw; NPKS₂, NPK plus double amounts of straw; and NPKM, NPK plus pig manure. Long-term application of inorganic fertilizers and organic amendments increased the total amino sugar concentrations (4.4–8.4 %) as compared with the control; and this effect was more evident in the plots that continuously received pig manure (P?<?0.05). The increase in total amino sugar stock was less pronounced in the straw-treated plots than the NPKM. These results indicate that the accumulation of soil amino sugars is largely influenced by the type of organic fertilizers entering the soil. Individual amino sugar enrichment in soil organic carbon was differentially influenced by the various fertilizer treatments, with a preferential accumulation of bacterial-derived amino sugars compared with fungal-derived glucosamine in manured soil.     

Nitrous oxide emission,global warming potential,and denitrifier abundances as affected by long-term fertilization on Mollisols of Northeastern China

ABSTRACT

A long-term field experiment was performed to assess the effects of fertilization regimes on greenhouse gas emissions, soil properties, soil denitrifies, and maize (Zea mays) grain yield on Mollisols of Northeastern China. Chemical nitrogen (N), phosphorus (P), and potassium (K) fertilizers plus pig manure (MNPK) treatment significantly increased soil N₂O emissions by 29.9–226.4% and global warming potential (GWP) by 29.8–230.7% compared to unfertilized control (CK), chemical N fertilizer only (N), chemical N, P, and K fertilizers (NPK) and chemical N, P, and K fertilizers plus corn straw (SNPK) treatments. However, the MNPK treatment yielded similar greenhouse gas intensity (GHGI) as compared with other treatments, mainly due to higher maize grain yield. There were also higher gene copy numbers of nirK, nirS, and nosZ in topsoil (0–20 cm depth) under MNPK treatment. Automatic linear modeling analysis indicated that main factors influencing soil N₂O emissions were soil organic carbon (SOC), NO₃^? content, and nirK gene abundance. Although the application of chemical fertilizers plus organic manure increases N₂O emissions due to higher N and C availability and nirK gene activity in the soil, this is still a promising fertilizer management due to its notable enhancement of maize grain yield and SOC content.     

Effect of long-term organic and mineral fertilizer on physical properties in root zone of a clayey Ultisol

To explore the effects of long-term organic and mineral fertilization practices on the physical properties in Ultisol of south China, a study was conducted since 1998 to investigate the effects of a control (CK), application of chemical fertilizers (NPK), application of organic manure (OM), and NPK fertilizer plus straw returning (NPK + straw). Results showed that OM significantly increased soil water retention capacity at all tensions but with larger increment in low tension at depths of 0–10 cm and 10–20 cm (p < 0.05) when compared with the CK. On the contrary, NPK and NPK + straw led to a decrease in soil water retention capacity under chemical treatments. In the field both in wet and dry periods, soil water content was significantly higher in OM than in NPK + straw and NPK (p < 0.05) since soil hydraulic conductivity (saturated and unsaturated) are lower in OM than in other treatments (p < 0.05). OM was also found to have the lowest soil bulk density and penetration resistance of the four treatments. A high negative correlation was observed between the soil organic carbon and the bulk density and the penetration resistance (p < 0.01). In this way, the application of OM improved the clayey soil physical properties.     

Effects of combined organic manure and mineral fertilization on soil aggregation and aggregate-associated organic carbon in two agricultural soils

Abstract

The effect of organic manure and inorganic fertilizer on soil aggregate size distribution and stability, and associated carbon (C) within aggregates varies greatly in previous studies because of the differences in soil conditions, cropping systems, and management practices. This study was conducted as two field fertilization experiments, with different cropping systems, under a subtropical climate in China. The two field experiment sites were located in Jinhua (established in April 2011) in the Jinqu basin in Zhejiang province and Jintan (established in October 2010) in the low-middle Yangtze River plain in Jiangsu province. Both experiments consisted of four treatments, including unfertilized (CK), mineral fertilizer nitrogen (N)–phosphorus (P)–potassium (K) (NPK), NPK plus straw (NPK?+?SR), and NPK plus cattle manure (NPK?+?FYM) or half NPK plus cattle manure (1/2NPK?+?FYM). Water stable aggregate size classes (>5, 2–5, 1–2, 0.5–1, 0.25–0.5, and <0.25?mm) and associated soil organic C (SOC) at 0–15?cm depth were measured. The mean weight diameter (MWD), geometric mean diameter (GMD), and water stable aggregates (WSA)?>?0.25?mm were also determined. The results showed that aggregate-size distribution varied with soil types. Combined application of NPK and organic matter (straw residue or cattle manure), unlike the CK and NPK treatments, significantly increased the WSA >0.25?mm, MWD, and GMD, while obviously reducing the proportion of <0.25?mm aggregates. However, no differences in WSA >0.25?mm, MWD, GMD, and associated C were observed between CK and NPK at both sites. The addition of FYM to the NPK treatment yielded the highest SOC contents in bulk soil, and showed significantly higher associations of C within all size aggregates at both sites. In contrast, NPK?+?SR significantly increased SOC within aggregate classes (2–5?mm, 0.5–1?mm, 0.25–0.5?mm, and <0.25?mm) at Jinhua and (>5?mm and 1–2?mm) at Jintan compared to the CK and NPK treatments. Overall, the combined application of FYM and mineral NPK was the best sustainable management practice for the improvement of aggregate stability and SOC sequestration.