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。     

长期不同比例有机肥-化肥配施下红壤性水稻土氮素矿化特征

土壤有机氮的矿化是土壤氮素肥力的重要指标之一,也是影响作物产量至关重要的因素。以33年长期定位试验为依托,对红壤性双季稻田土壤氮累积、矿化动力学特征等进行系统研究。定位试验始于1984年,选取其中5个施肥处理:不施肥(CK),施氮磷钾肥(NPK),施50%化肥+50%有机肥(50F+50M),施30%化肥+70%有机肥(30F+70M),施70%化肥+30%有机肥(70F+30M),于2017年早稻种植前采集耕层(0～20 cm)土壤样品,采用淹水密闭间歇淋洗法,对土壤氮矿化量和速率进行测定,并采用一级动力学方程拟合土壤氮矿化势(N_0)、矿化速率常数(k)等。结果表明,长期施肥显著提高土壤有机碳、全氮、碱解氮含量,以有机无机肥配施提升效果最为显著,且随有机肥投入量增加而递增,30F+70M处理较NPK处理显著提高铵态氮、硝态氮及总矿质氮含量,分别提高了47.0%、64.6%和49.7%。连续施肥33年后,施肥显著提高了土壤净矿化速率和土壤矿化氮释放量,排序为30F+70M50F+50M70F+30MNPKCK,配施有机肥较施化肥处理显著提高了土壤矿化氮累积释放量和土壤氮素矿化率,分别是化肥处理的2.70和1.41倍。长期施肥均显著提高了土壤氮素矿化势(N_0),提高幅度为65.9%～196.0%,配施30%有机肥(70F+30M)较施化肥处理(NPK)可显著增加水稻土氮素矿化势,降低氮矿化速率常数。土壤有机质、全氮、碱解氮及铵态氮含量显著影响N_0、N_0/N、累积矿化量及矿化率,土壤氮矿化速率常数(k)与C/N呈现极显著负相关。长期化学氮肥与低比例有机肥配施,使水稻土供氮缓慢而持久,在水稻的生长发育过程中能够不断地补充氮素。     

长期施肥对棕壤铁形态及其有效性的影响

【目的】利用沈阳农业大学棕壤肥料长期定位试验,研究不同施肥处理对耕层土壤酸碱度（pH）、氧化还原电位（Eh）和有机质的影响,探讨不同施肥条件下土壤游离态氧化铁、无定形氧化铁、亚铁总量和有效铁含量的变化以及与pH、Eh和有机质的关系。 【方法】本文选取试验处理为CK（不施肥）、N（氮肥）、NP（氮磷肥配施）、NPK（氮磷钾肥配施）、M（有机肥）、MN（有机肥与氮肥配施）、MNP（有机肥与氮磷肥配施）、MNPK（有机肥与氮磷钾肥配施）。在2014年大豆收获期,采集了不同施肥处理0-20 cm耕层土壤样品,分析了土壤pH、Eh、有机质含量以及游离态氧化铁、无定形氧化铁、亚铁和有效铁含量。 【结果】与1979年原始土壤相比,所有处理土壤pH显著降低了0.6~1.4个单位。不施肥处理土壤有机质下降了11.5%,化肥处理有机质略有下降,而有机肥处理有机质含量显著增加。所有处理有效铁含量显著增加,化肥有机肥配施增加幅度更大;与2014年不施肥处理相比,施用氮肥处理土壤pH最低,而氮肥配施磷、钾和有机肥中的一种或几种pH又有所上升,其中配施有机肥效果最明显;施用化肥处理土壤Eh增加,而施用有机肥处理Eh则下降。施用化肥土壤游离态氧化铁和有效铁含量增加,亚铁含量下降,而施用有机肥土壤游离态氧化铁降低,亚铁总量及有效铁含量增加。 【结论】经过长期耕作和施肥,土壤pH显著下降,有效铁含量显著增加。长期不施肥土壤有机质显著下降。施用氮肥土壤酸化趋势明显,磷、钾和有机肥配施能够缓解氮肥引起的酸化现象。施用有机肥显著降低土壤氧化还原电位,有利于氧化态铁向还原态铁转化,更有利于增加土壤有效性铁的含量。     

黄土高原黑垆土施肥的作物累积产量及土壤肥力贡献

施肥的作物产量和土壤肥力贡献是评价施肥是否科学的关键参数,为了给黄土高原黑垆土区施肥及农业可持续发展提供科学的决策依据,通过设置在黄土高原黑垆上的长期定位试验系统研究了不同施肥的作物产量和土壤肥力贡献。试验设不施肥(CK)、单施氮肥(N)、氮磷配施(NP)、秸秆与氮磷配施(SNP)、单施有机肥(M)和有机肥与氮磷配施(MNP)6个处理。结果表明,所有处理玉米和小麦累积产量与种植年限显著正相关。MNP、SNP、NP、M4处理玉米年均产量分别为8 856、7 089、7 226、7 043 kg·hm~(-2),小麦年均产量分别为4 916、3 747、4 132、3868kg·hm~(-2),均显著高于对照(CK)。SNP、M和MNP处理玉米和小麦产量与NP处理相近或高于NP处理。氮肥、磷肥的作物累积产量贡献量与种植年限分别呈二次凹函数和凸函数关系。氮磷配施(NP)、秸秆还田的作物累积产量贡献量则与种植年限显著正相关,其年均玉米产量贡献量分别为3408、2191kg·hm~(-2),小麦产量贡献量分别为429、206kg·hm~(-2)。长期施用有机肥及秸秆还田可显著增加土壤有机质和全氮含量。长期施磷肥土壤有效磷含量显著增加,而长期施用有机肥土壤有效磷和速效钾含量均显著增加。总体而言,黄土高原黑垆土区长期平衡施用化肥、施用有机肥、秸秆与化肥配合施用及有机肥与化肥配合施用均可增加作物产量,提升土壤肥力质量,适宜化肥施用量为N 90kg·hm~(-2)、P_2O_5 75 kg·hm~(-2),秸秆还田可隔年施磷。     

长期不同施肥对土壤和玉米锌含量的影响

利用棕壤肥料长期定位试验,研究不同施肥处理对耕层土壤pH值、有机质、不同形态Zn和玉米茎秆、籽粒中Zn含量的影响,揭示长期施肥条件下,Zn在土壤-植物系统中的迁移规律及其影响因素。试验开始于1979年,采用玉米-玉米-大豆轮作体系,试验处理为:N1P、N1PK、N1、N2、CK、M1N1P、M1N1PK、M1N1、M1N2、M1、M2N1P、M2N1PK、M2N1、M2N2、M2,其中CK为不施肥处理,N1和N2施氮量分别为120和180kg/hm2,M1和M2施有机肥量分别为13.5和27 t/hm2。在2015年玉米收获期,采集了不同施肥处理0~20 cm耕层土壤样品,分析了土壤pH值、有机质,测定了土壤不同形态Zn和玉米籽粒、茎秆中Zn含量。与1979年原始土壤相比,绝大多数处理土壤pH值都显著降低,化肥处理降低1~2个单位,有机肥和化肥配施降低0.5~0.8个单位,单独施用有机肥pH值有所增加。不施肥处理土壤有机质、全量Zn和有效态Zn均下降,施用化肥绝大多数处理土壤有机质、全量和有效态Zn含量基本保持不变;施用有机肥处理,土壤有机质、全量和有效态Zn含量均显著增加。施用有机肥也显著增加有机结合态和交换态Zn含量。玉米籽粒和茎秆中Zn含量也表现为不施肥处理最低,施用化肥或有机肥配施化肥处理显著增加。pH值与土壤有效锌之间没有显著负相关关系,土壤有机质与有效态Zn、全Zn、籽粒以及茎秆Zn之间均呈现显著性正相关关系。经过长期耕作和施肥,土壤pH值显著下降,施用氮肥是引起土壤pH值下降的主要原因。长期不施肥土壤和植物中Zn含量下降,而施用有机肥显著增加土壤和植物中Zn含量。施用有机肥主要是通过增加土壤有机质含量,从而提高有机结合态和可交换态Zn的储量来为土壤和植物提供更多的Zn。pH值降低对土壤锌的活化作用不显著。     

长期施肥对黑土活性有机质的影响

通过测定长期定位施肥处理条件下,不同土层土壤各活性有机质的含量,探讨不同施肥处理对活性有机质的影响.主要有4个处理:不施肥(CK)、单施化肥(NPK)、单施有机肥(M)、有机肥-化肥配施(MNPK).土壤活性有机质用KMnO4氧化法测定,采用3种浓度KMnO4(33,167,333 mmol/L)将土壤活性有机质分为高活性有机质(HAOM)、中活性有机质(MAOM)和活性有机质(AOM).试验结果表明,长期施用有机肥或化肥均能提高土壤活性有机质的含量,尤其有机肥-化肥配施和单施有机肥对土壤活性有机质积累的作用大于单施化肥和无肥处理.施肥所增加的土壤活性有机质,主要是在0-20 cm土层,尤其在单施有机肥和有机肥-化肥配施处理上表现明显.施肥与否、施肥种类和不同土层对土壤中的总有机质和活性有机质均有明显影响.3种活性有机质含量之间都显著或极显著相关,高活性有机质与中活性有机质、高活性有机质与活性有机质、中活性有机质与活性有机质的相关系数分别为0.819*,0.812*和1.000**.可见,三种活性有机质之间,以活性有机质和中活性有机质的关系最为密切.     

长期不同培肥措施下玉米产量稳定性及棕壤氮素累积分布特征

  【目的】  研究长期不同培肥措施下玉米产量的稳定性、可持续性和土壤矿质氮累积分布、微生物量氮含量特征,为制定合理的施肥措施和保证东北棕壤地区农业的可持续绿色发展提供理论依据。  【方法】  棕壤肥料长期定位试验始于1979年。选取其中的12个处理:不施肥对照(CK)、单施氮肥(N)、氮磷肥配施(NP)、氮磷钾肥配施(NPK)、低量有机肥(M1)及其与化肥配施(M1N、M1NP和M1NPK)、高量有机肥(M2)及其与化肥配施(M2N、M2NP和M2NPK),分析长期施肥下玉米产量的变化,并于2018年在玉米收获期采集植株和土壤样品,阐明玉米地上部吸氮量变化,0—100 cm土层土壤矿质氮分布、累积及微生物量氮含量的差异。  【结果】  长期不同施肥下玉米产量呈波动变化,且在1979—1998年内玉米产量变化趋势较平稳,1999—2018年内变幅较大。M1NPK、M2NPK处理玉米平均产量最高,在试验前20年较NPK处理分别提高了10.3%、11.7%,后20年分别提高了17.1%、19.4%。随着试验年限增加,玉米产量的稳定性和可持续性增加,有机肥配施化肥各处理高于单施化肥处理,在试验前20年和后20年玉米产量的可持续性指数(SYI)介于0.43～0.58和0.50～0.67,低量有机肥配施处理高于高量有机肥配施处理。配施有机肥各处理肥料贡献率高于单施化肥处理,且试验后20年M1NPK处理肥料贡献率最高,达54%。施肥40年后(2018年)玉米地上部吸氮量以M1NPK处理最高(302 kg/hm2),与M2NPK处理差异不显著。配施低量有机肥玉米收获期80—100 cm土层土壤矿质氮含量较低,M1NPK处理 0—100 cm土层土壤矿质氮贮量为127 kg/hm2,显著低于M1N和M1NP处理。而高量有机肥配施各处理0—100 cm土层土壤矿质氮贮量较化肥试区和低量有机肥试区分别增加了324.5%和172.9%,增加了氮素损失风险。此外,长期配施有机肥处理0—40 cm土层土壤微生物量氮含量增加,但低量和高量有机肥试区各处理间差异不显著。  【结论】  长期不同培肥措施会影响玉米产量的稳定性和可持续性,改变土壤氮素分布和累积,进而影响玉米氮素吸收。低量有机肥(13.5 t/hm2)配施氮磷钾化肥可促进玉米生长和氮素吸收,降低0—100 cm土层土壤矿质氮贮量,降低氮素损失风险,增加微生物量氮含量,较高的微生物量氮又可作为有机氮库来增加土壤供氮并固持易损失的矿质氮和肥料氮,以保证玉米的高产稳产和环境友好。     

长期不同施肥模式下砂姜黑土的固碳效应分析

以安徽淮北32 a的定位试验为平台,运用土壤等质量方法对土壤耕层的固碳效应进行了研究。结果表明,较不施肥和单施化肥,施用有机肥显著降低了表层土壤容重。长期施用有机肥和单施化肥均对提高土壤有机质和活性有机质含量有显著作用,但以高量有机肥和化肥配施的效果最明显。土壤碳库管理指数以有机肥和化肥配施的效果显著,而长期单施化肥降低了土壤碳库管理指数,表明化肥长期施用下土壤肥力下降。0~20 cm土层的有机碳储量有机肥化肥配施的最高,其次为单施有机肥、单施化肥,不施肥最低。有机肥有助于提高土壤质量,且有机肥和化学氮肥分别以高于N262.5 kg hm-2 a-1配施的效果最佳。     

长期不同施肥处理水稻土溶解性有机质组分含量及其特性研究

基于长期定位试验研究不同施肥处理下土壤溶解性有机质量(DOM)组分含量及其特性。研究表明:不同量化肥施用土壤DOC含量没有显著增加,而施用化肥,配施秸秆能显著增加耕层土壤DOC含量,配施猪粪能显著提高耕层和犁底层土壤DOC含量。施化肥以及化肥有机肥配施均能显著提高土壤各层DON含量,除耕层C2外。施化肥后土壤无机态氮含量增加,DON比例下降,化肥配施猪粪后土壤DON含量和比例显著增加。施用C1+M处理土壤DOP含量均显著高于其他处理,并促进磷向下层迁移,而其他施肥处理之间差异不明显。耕层土壤DP含量显著高于犁底层和渗育层,C1+M、C2+S、C3均能显著提高土壤DP含量,且向深层迁移明显。施化肥以及化肥有机肥配施均能显著提高土壤DS含量,化肥有机肥配施处理增幅尤为显著。施化肥以及化肥有机肥配施均能提高土壤UV280,而化肥有机肥配施显著有利于土壤DOM芳香性结构更具复杂化与稳定性,特别是C1+M。DOM组分间显著相关性分析表明土壤DOM各组分之间是密切相关,相互联系的。     

长期定位施肥对土壤腐殖质含量的影响

以潮土、旱地红壤和红壤性水稻土为研究对象 ,探讨了长期施肥对土壤腐殖质含量的影响。结果表明 ,长期施用 NPK化肥、有机肥或有机无机肥配施均能提高潮土、旱地红壤和红壤性水稻土耕层的有机质、腐殖质和活性腐殖质含量 ,其中胡敏酸、富里酸也相应地增加 ,但以有机无机肥配施的效果最好。施有机肥或有机无机肥配施还能提高土壤腐殖质的胡 /富比值。施肥对土壤有机质的影响不仅局限于土壤耕层 (0～ 2 0 m) ,而且影响耕层以下层次 ,但以 0～ 6 0 cm土层的效果显著 ,且以潮土的效果明显     

Response of soil organic matter fractions and composition of microbial community to long-term organic and mineral fertilization

The effects of organic and mineral fertilization on four soil organic matter (SOM) fractions (non-protected, physically protected, chemically protected, and biochemically protected) and microbial community composition were investigated by sampling soil of a 35-year-long fertilization experiment. The SOM fractions were investigated by combined physical and chemical approaches, while microbial community composition was determined by phospholipid fatty acid analysis (PLFA). Organic C (SOC) was primarily distributed within the microaggregate-protected particulate organic matter (iPOM) and the hydrolysable and non-hydrolysable silt-sized (H-Silt, NH-Silt) fractions, which accounted for 11.6–16.9, 23.4–28.9, and 25.4–30.6% of the total SOC content, respectively. The contributions of these “slow” fractions (iPOM, H-Silt, NH-Silt) to the increased SOC were 178–293, 118–209, and 85–109% higher after long-term sole manure or manure in combination with inorganic N fertilization compared with unfertilized soil (control). The combination of manure and mineral fertilizers increased the coarse and fine non-protected C (cPOM and fPOM) contents much more (34.1–60.7%) than did manure alone. PLFAs, bacteria, G (+) bacteria, and actinomycete abundances were the highest in soil with manure, followed by soil treated with manure combined with mineral N. The addition of inorganic and organic fertilization both altered the microbial community composition compared with the control. All SOM fractions contributed to 81.1% of the variance of the PLFAs-related microbial community composition by direct and indirect effects. The change in coarse unprotected particulate organic matter (cPOM) was the major factor affecting soil microbial community composition (p < 0.001). Our study indicates that physical, chemical, and biochemical protection mechanisms are important in maintaining high SOC level after the addition of manure. A close linkage between soil microbial community composition and cPOM suggests that C availability is an important factor for influencing microbial composition after long-term inorganic and organic fertilization.     

The role of iron oxides in the preservation of soil organic matter under long-term fertilization

Purpose

The aim of this paper is to enlighten the role of highly reactive iron (Fe) minerals in soil organic carbon (SOC) preservation in soil aggregates.

Materials and methods

The effects of four long-term (37-year) fertilization regimes (NPK, chemical fertilization; NPKM, chemical fertilization + cattle manure; M, cattle manure; CK, non-fertilization control) on organic carbon (OC) stability, soil iron fractions in bulk soil, and soil aggregates were studied to characterize the capacity and mechanism of Fe minerals to preserve SOM in soil.

Results and discussion

Long-term fertilization significantly altered the Fe fractions in soil and soil aggregates. The two applications with manure (NPKM and M) increased the non-crystalline Fe content, while the chemical fertilizer (NPK) increased the crystalline Fe content. Besides, long-term fertilization with manure greatly increased the content of SOC and soil total nitrogen (STN). The non-crystalline Fe was positively correlated with the SOC content in both soil and soil aggregates. Meanwhile, the long-term fertilization treatments greatly changed the mass distribution and OC content of soil aggregates.

Conclusions

Long-term manure fertilization promoted the formation of non-crystalline Fe fractions, which bounds to SOC to form soil macro-aggregates. Thus, the formation of SOC-Fe association in soil and soil aggregates plays a crucial role in SOC preservation.

     

不同施肥措施对小麦－玉米轮作中作物产量和土壤肥力的影响

A 15-year field experiment was carried out in Henan Province, China, to study the effects of different fertilization practices on yield of a wheat-maize rotation. Fertilizers tested contained N alone (N), N plus P (NP) or plus P and K (NPK), all with or without manure (M). Different long-term fertilization practices affected the yields under the rotation system of wheat and maize differently and the effects on yields was in a general trend of MNPK＞MNP＞MN＞NPK＞NP＞M＞N＞the control. The average contribution rate of soil fertility to the highest yield was 37.9%, and the rest 62.1% came from fertilizer applications. The yield effects of the chemical fertilizers were in the order of N＞P＞K and were increased by application of manure.Balanced fertilization with multielement chemical fertilizers and manure can be effective in maintaining growth in agricultural production. Combined application of chemical fertilizer and organic manure also increased the content of soil organic matter.     

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.     

长期施用有机肥增加黄壤稻田土壤微生物量碳氮

【目的】微生物量碳、氮是土壤中易于利用的养分库及有机物分解和矿化的动力,与土壤养分循环密切相关,其变化可反映土壤耕作制度和土壤肥力的变化。本研究旨在揭示长期施肥对贵州黄壤稻田土壤微生物生物量碳 (SMBC) 和土壤微生物生物量氮 (SMBN) 的影响,并探讨其合理培肥模式。【方法】以贵州黄壤肥力与肥效长期定位监测基地为依托,采用氯仿熏蒸—K₂SO₄提取法,重点研究不同施肥条件下土壤微生物生物量碳氮的变化及其与全量有机碳氮的关系。试验处理包括不施肥 (CK)、单施化肥 (NPK)、单施有机肥 (M)、低量有机无机肥配施 (0.5MNPK) 和高量有机无机肥配施 (MNPK)。【结果】长期不同施肥处理下,SMBC的变化范围在423.87～695.04 mg/kg之间,SMBN的变化范围在44.36～91.65 mg/kg之间。施用化肥 (NPK) 和施用有机肥及两者配施 (M、0.5MNPK和MNPK) 能增加SMBC和SMBN含量,其中MNPK处理较CK处理SMBC含量增幅最高,达64.0%,显著高于NPK和0.5MNPK处理,但与M处理差异不明显;M处理较CK处理SMBN含量增幅最高,达106.6%,显著高于NPK和0.5MNPK处理,但与MNPK处理差异不明显;长期单施化肥 (NPK) 仅对SMBN含量有显著提高作用 (44.1%),对SMBC作用不明显。SOC、TN和微生物熵 (qMB) 的变化与SMBC一致,均表现为MNPK处理最高,其次为M和0.5MNPK处理,NPK处理最低;所有施肥处理下的SMBC/SMBN无显著性差异且均低于CK处理。【结论】土壤微生物碳、氮量和微生物熵的显著提高均与土壤有机质和全氮的含量变化呈正相关,单施有机肥和高量有机无机肥配施是提高土壤微生物生物量的有效途径。     

Variation of intra‐aggregate organic carbon affects aggregate formation and stability during organic manure fertilization in a fluvo‐aquic soil

The aggregate formation and stability are controlled by the dynamics of soil organic matters (SOM), but how it is related to SOM chemical composition within different‐sized aggregates is largely unknown during manure fertilization. In this study, the variations of intra‐aggregate organic carbon (OC), including intra‐particulate organic matter (iPOM) and mineral‐associated organic matter, were quantitatively and qualitatively analysed, and then, their effects on aggregate formation and stability were assessed under four treatments: control (CK), mineral fertilizer (NPK), reduced manure (30%M) and manure fertilizers (M). Manure application (M) significantly increased macroaggregate proportion, mean weight diameter (MWD), and OC contents within different‐sized aggregates compared to CK, NPK, and 30%M. The OC accumulation of macroaggregate in M was attributed to OC content increase in silt plus clay subfraction rather than iPOM with more labile organic groups; oppositely, in microaggregate it was located in the relatively stable fine iPOM. The macroaggregate formation and stability were controlled by the fine iPOM within macroaggregates, whose abundant polysaccharide‐C and aliphatic‐C after manure fertilization advanced the microbial growth except for Gram‐positive bacteria, which further promoted macroaggregate formation and stability. The free silt plus clay fraction also affected macroaggregate formation and stability, and its polysaccharide‐C derived from microorganisms or decomposing SOM was positively associated with MWD and macroaggregate proportion. Because polysaccharide‐C can be easily associated with mineral particles, further improving micro‐ or macroaggregation. We conclude that continuous manure fertilization could increase labile SOM accumulation within aggregates and then facilitate microbial growth, which collectively are responsible for aggregate formation and stabilization.     

西湖平原区连续13年定位施肥对麦、稻产量及土壤肥力的影响

以浙江省水网平原水稻主产区土壤为对象,通过定位试验,研究了连续13年的不同施肥处理对麦稻产量、土壤养分状况和物理性状的影响。结果表明,化肥配施有机肥可显著提高麦、稻产量; 不同施肥处理的长期定位试验土壤有机质含量和全氮均呈上升趋势,增幅依次为: 栏肥+NPK秸秆+NPKNPK秸秆栏肥CK处理; 土壤碱解氮和速效磷也呈增加趋势,以栏肥+NPK处理的增幅最为明显。土壤物理性状的分析表明,长期施肥均能明显增加土壤水稳性团粒含量和土壤孔隙度。经土壤养分平衡分析,栏肥+NPK、秸秆+NPK和NPK处理的氮和磷呈现盈余,秸秆和CK处理氮和磷亏缺; 栏肥+NPK和秸秆+NPK处理钾基本平衡,NPK、秸秆、栏肥和CK处理钾严重亏缺。长期定位试验进一步证明有机肥与氮、磷、钾化肥长期配合施用可实现当地农作物持续稳产,农田施肥管理要注意适当减少氮、磷投入,增加钾肥施用量,保持农田土壤养分平衡。     

Functional analysis of soil organic matter as affected by long-term manurial treatment

The composition of soil organic matter (SOM) is influenced by land use and fertilization. We studied changes in the SOM in a long-term field experiment on a sandy Podzoluvisol. The control plot and four combinations of manurial treatments of the experiment were selected: one with mineral fertilizer only and three combinations of organic manure with mineral fertilizer: cattle manure + NPK, cattle manure + PK and straw + NPK. The SOM was extracted by sodium pyrophosphate solution (pH = 10) and hot water (100°C). The extracts were analysed by Fourier-Transform Infrared (FT-IR) spectroscopy and gel permeation chromatography (GPC). The FT-IR spectra from sodium pyrophosphate extracts indicate that composition of SOM is indeed influenced by different fertilization. The C=O band at 1710 cm^–1 in the samples of the plots fertilized with cattle manure has the highest absorption intensity, whereas the material from the plot fertilized with straw + NPK has the least intense. The GPC analyses of the extracts showed that adding cattle manure + NPK increased the molecular size of SOM in comparison with the control plot. The analysis of hot-water extracts with FT-IR showed no significant differences in functional groups, but GPC chromatograms distinguished features in molecular size distribution. Fertilization with cattle manure increased the molecular size of the SOM in comparison with the control, but the differences in content of carboxylic groups and molecular weight were detected in sodium pyrophosphate extracts only.     

有机–无机肥配施比例对双季稻田土壤质量的影响

【目的】利用江西省稻田土壤质量演变定位监测试验为平台,系统分析长期不同施肥措施下土壤质量状况,明确提升红壤性双季稻田土壤质量的优化施肥措施。 【方法】长期定位试验设置 8 个处理,分别为不施肥处理 (CK),施磷钾肥处理 (PK),施氮磷肥处理 (NP),施氮钾肥处理 (NK),施氮磷钾肥处理 (NPK),施 70% 化肥 + 30% 有机肥处理 (70F + 30M),施 50% 化肥 + 50% 有机肥处理 (50F + 50M),施 30% 化肥 + 70% 有机肥处理 (30F + 70M),于 2012 年晚稻收获后测定 2 个土壤物理性质指标 (容重和总孔隙度)、7 个基础化学性质指标 (有机质、全氮、全磷、碱解氮、有效磷、速效钾和 pH 值) 及 3 个生物学性质指标 (细菌、真菌和放线菌数量),分析长期不同施肥对各土壤性质的影响,并运用主成分分析对各处理土壤质量进行综合评分,最后将综合得分进行聚类分析,以评价长期不同施肥措施对红壤性双季稻田土壤质量的影响。 【结果】经 28 年连续不同施肥处理后,各土壤性质在处理间均产生显著差异,但各土壤性质在处理间的变化趋势并不完全一致。化肥配施有机肥处理较化肥处理土壤容重降低 12.7%～20.6%,土壤孔隙度增加 2.3%～17.4%,有机质增加 22.5%～41.8%,全氮和碱解氮分别提高 9.8%～20.9% 和 11.1%～30.3%,全磷和有效磷分别提高 11.1%～71.7% 和 1.31～1.75 倍,pH 值提高 0.19～0.48 个单位;主成分分析方法将原 12 个土壤性质指标降维、提取出 2 个主成分,反映了原信息量的 87.4%,有机质、容重、真菌、全氮、有效磷、放线菌、总孔隙度、细菌、全磷和碱解氮在第一主成分上有较高载荷值,pH 值和速效钾在第二主成分上有较高载荷;各施肥处理下土壤质量综合水平高低排序为:30%F + 70M > 50F + 50M > 70F + 30M > NPK > NP > NK > PK > CK;聚类分析方法将长期不同施肥制度下稻田土壤质量划分为一级 (30F + 70M),二级 (50F + 50M、70F + 30M),三级 (NPK、NP),四级 (NK、PK、CK) 4 个等级。 【结论】与单施化肥相比,有机无机配施可有效增加土壤养分含量,改善土壤物理性质,缓解土壤酸化,提高土壤微生物数量,是提高红壤性双季稻田土壤质量的有效施肥措施。     

长期施肥对棕壤氨氧化细菌和古菌丰度的影响

【目的】氨氧化是氮转化过程的限速步骤,其由氨氧化微生物所驱动。本研究旨在探明 37 年玉米–大豆轮作施肥条件下影响棕壤氨氧化微生物丰度的主要影响因子及变化规律。【方法】以沈阳农业大学棕壤肥料长期定位试验耕层土壤 (0—20 cm) 为材料,选取其中 9 个施肥处理进行取样分析:不施肥 (CK)、低量氮肥 (N₁)、高量氮肥 (N₂)、氮磷肥 (N₁P)、氮磷钾肥 (N₁PK)、高量有机肥 (M₂)、高量有机肥 + 低量氮肥 (M₂N₁)、高量有机肥 + 氮磷肥 (M₂N₁P)、高量有机肥 + 氮磷钾肥 (M₂N₁PK)。采用实时荧光定量 PCR 技术测定其氨氧化微生物丰度,通过对土壤基本化学性质和氨氧化微生物丰度的冗余分析找出影响氨氧化微生物丰度的主要因素。【结果】施用有机肥处理的土壤 pH、有机质、全氮、碱解氮、速效钾、速效磷、铵态氮、硝态氮含量明显高于不施肥和单施化肥处理。各施肥处理土壤有机质、全氮、碱解氮、速效钾、速效磷的含量总体呈现有机肥处理 > 化肥处理 > CK;与不施肥处理 (CK) 相比,单施化肥处理显著降低了土壤 pH 值,施用有机肥处理显著提高了土壤 pH 值,其中 N₂ 处理的土壤 pH 最低,M₂ 处理的土壤 pH 最高。不同施肥处理氨氧化细菌 (AOB) 的丰度为 0.94 × 106～5.77 × 106 copies/g 干土,氨氧化古菌 (AOA) 的丰度为 3.56 × 106～1.22 × 107 copies/g 干土;施用有机肥处理 AOB 和 AOA 丰度显著高于不施肥和单施化肥处理,其中 M₂ 处理的 AOB 和 AOA 丰度最高,单施氮肥处理的 AOB 和 AOA 丰度最低。冗余分析 (RDA) 表明,影响棕壤 AOB 和 AOA 丰度的主要环境因子有土壤 pH、有机质、全氮、碱解氮、速效磷、速效钾,且与 AOB 和 AOA 丰度呈正相关关系。【结论】长期轮作施肥显著改变了棕壤的化学性质,从而对氨氧化微生物的丰度产生了显著影响。长期施用有机肥显著提高了土壤养分含量及 AOB 和 AOA 的丰度,对维持土壤氨氧化微生物的数量起到十分重要的作用;同时试验结果也为今后通过改变土壤 pH、有机质、全氮、碱解氮、速效磷、速效钾等性质对 AOB 和 AOA 进行调节提供了依据。