红壤水稻土肥力性状的演变特征

大田条件下 ,通过选点采样分析 ,研究了不同利用年限红壤水稻土的物理、化学和生物学性质的动态变化特征。荒地红壤水耕利用后 ,土壤颗粒组成呈现规律性变化 ,粘粒 (<0 0 0 2mm)含量从荒地红壤的 3 9%下降到 80a稻田土壤的 1 7% ,而粉砂 (0 0 2～ 0 0 0 2mm)含量升高。土壤pH一般增加 0 5～ 1个单位 ;0～ 1 0cm土壤有机碳和全氮含量从荒地红壤的 4 5 8gkg- 1和 0 3 9gkg- 1增加到 3 0a红壤稻田的1 9 6gkg- 1和 1 62gkg- 1,其后 ,即使利用时间长达 80a ,土壤有机碳和全氮含量并没有显著差异 ;土壤全磷含量 ,经 3a水耕利用后可从荒地红壤的 0 5gkg- 1提高到 1 3gkg- 1,表明通过施肥可使红壤磷素快速积累 ;而在水耕利用过程中 ,红壤稻田土壤的钾素含量呈下降趋势 ,经 80a利用的红壤稻田 ,0～ 1 0cm土壤钾素含量仅为荒地红壤的 80 % ;全铁和游离铁的含量也呈下降趋势。随着水耕熟化过程 ,细菌数量和脲酶活性也明显升高。不同利用年限红壤稻田土壤的各项性状指标的变化结果还表明 ,荒地红壤水耕利用后要达到高度熟化的稻田土壤肥力水平 ,需要经过 3 0a的时间     

黄土丘陵区柠条人工林土壤有机碳动态及其影响因子

以黄土丘陵区柠条人工林为研究对象,采用野外调查与室内分析相结合的方法,探讨柠条生长过程中土壤有机碳储量的变化规律。结果表明:1)土壤有机碳主要分布在0～20 cm土层,占0～50 cm土层总储量的49%～63%;2)相对于对照地,柠条林地土壤有机碳储量随柠条生长年限的增加先减小再升高最后趋于稳定,10、26、40、50 a柠条林地土壤总有机碳储量分别为1.555、3.236、2.775、2.444 kg/m2,26 a林地土壤有机碳储量最高,随林龄增大其变化趋于稳定;3)相关性分析结果表明,土壤有机碳质量分数与土壤密度之间呈显著负相关关系,各林地土壤密度随柠条生长年限的增加而减小,说明柠条可以通过改变土壤性质间接增加土壤总有机碳储量,土壤有机碳质量分数与根系生物量、土壤全氮质量分数之间呈极显著正相关关系,说明柠条的根系生长和固氮特性有助于有机碳的积累。     

湘北红壤丘岗稻田土壤有机碳、养分及微生物生物量空间变异

通过对湘北典型红壤丘岗254个稻田耕层样(01～8.cm)进行分析,比较了微地形对稻田土壤有机碳、氮、磷和微生物生物量的影响。结果表明,丘岗底部稻田土壤有机碳、全氮、微生物生物量碳、微生物生物量氮、可溶性氮含量分别比丘岗中下部稻田高14.6%1、3.6%、24.6%、20.4%和95.8%,丘岗中下部稻田土壤Olsen-P含量比丘岗底部稻田高33.3%,差异均达极显著水平(P0.01)。不同部位稻田土壤全磷、微生物生物量磷含量和有效磷库(微生物生物量磷与Olsen-P之和)含量差异不显著。此外,丘岗底部稻田土壤碳磷比、微生物生物量碳磷比和微生物商比丘岗中下部稻田高12.7%,28.5%,8.2%,其差异达显著(P0.05)或极显著(P0.01)水平。但微生物生物量氮/全氮、微生物生物量磷/全磷、土壤碳氮比和微生物生物量碳氮比差异不显著。     

耕作对旱区坡耕地土壤碳素转化及冬小麦产量的影响

利用长期定位试验(1999开始保护性耕作,2004年采样测定),在豫西旱区坡耕地上进行了不同耕作对土壤有机碳、微生物态碳及水分利用效率的影响研究。结果表明:深松覆盖和免耕覆盖处理的耕层有机碳增加较明显,以深松覆盖有机碳含量最高为6.79gkg-1,比传统耕作高13.82%,其次是免耕,较传统高11.58%,而少耕却较传统降低了1.38%,随着土层的加深,土壤有机碳含量降低,0～60cm有机碳平均值,深松和免耕较传统分别增加了14.08%、5.41%,少耕较传统减少1.12%。土壤微生物碳对耕作敏感,其含量免耕>深松>传统>少耕,分别为206.87mgkg-1、138.43mgkg-1、115.42mgkg-1和112.57mgkg-1,较传统增加79.3%、19.9%和-2.5%。土壤有机碳和土壤微生物态碳都有坡下富集现象。少耕、免耕、深松和传统的SMBC/SOC的值分别为1.91%、3.11%、2.04%和1.93%,免耕和深松对培肥地力、改善环境有好的应用前景;同时免耕覆盖与深松覆盖可提高产量,增产分别达10.22%与9.26%;可提高水分利用效率。     

长期施肥对红壤稻田剖面土壤碳氮累积的影响

为了研究长期施肥对红壤稻田剖面土壤碳氮累积的影响,基于中国生态系统研究网络(CERN)桃源农业生态试验站网络监测数据,分析了不施肥(CK)、高量氮磷钾肥(NPK)、减量化肥加秸秆还田优化施肥(OF)对红壤水稻土剖面有机碳、全氮含量及其储量的影响。结果表明:(1)OF处理土壤碳氮含量及其储量随着土层深度的增加呈显著下降趋势(p<0.05)。(2)11 a施肥后,各处理表层(0-20 cm)土壤有机碳含量及碳储量差异显著,且OF>NPK>CK;表层全氮含量及氮储量在NPK与OF处理中无显著差异;40-80 cm土壤氮储量NPK处理显著大于OF处理。(3)各处理0-80 cm土体总有机碳储量差异不显著,NPK处理全氮储量显著大于OF处理。(4)与试验初期相比,各处理在20-40 cm土层,各指标含量增加幅度最大。(5)0-80 cm土体中,有机碳和全氮储量存在极显著正相关关系(y=11.644 x-0.8737,R²=0.9759)。综上所述,红壤稻田土壤有机碳、全氮及碳氮储量对长期不同施肥措施的响应在表层更灵敏;在20-40 cm土层碳氮累积速率最大,并有向深层累积的趋势;OF处理更显著增加表层土壤有机碳氮储量,而NPK处理对深层土壤碳氮储量增加较多。因此,长期高量化肥使用增加了氮素向土壤深处迁移的风险,减量施肥配以秸秆还田措施对保持红壤水稻土碳氮可持续变化更有利。     

开发利用对泥石流滩地土壤肥力特性的影响

龙洞沟泥石流滩地剖面结构和土壤物理结构较差 ,砂石化现象严重 ;土壤微团聚体数量较少 ,粒级间比例不合理 ;土壤养分除全钾极丰富外 ,其它大部分养分都处于缺乏或极缺状态。通过开发利用 ,其表土层结构特性和养分状况得到显著改善 :砾石含量由 63 .0 3～ 70 .78%减少到 3 9.66～ 57.62 % ,粉粒和粘粒含量由 2 6.75～ 3 1.89%增加到 3 0 .54～41.93 % ;有机质由 7.1～ 10 .8gkg- 1提高到 15.8～ 2 6.9gkg- 1;全氮由 1.2 0～ 1.40gkg- 1提高到 1.50～ 1.93gkg- 1;全磷由0 .46～ 0 .57gkg- 1提高到 0 .48～ 0 .79gkg- 1;有效氮由 47.2 2～ 56.67mgkg- 1提高到 79.3 9～ 119.46mgkg- 1;有效磷由 2 .2 1～ 4.69mgkg- 1提高到 5.58mgkg- 1;有效钾由 2 9.84～ 40 .3 6mgkg- 1提高到 51.89～ 89.3 6mgkg- 1。不同利用模式的改良作用不同 ,依次为 :菜园地 >苹果 +蔬菜地 >苹果园地 >苹果 +花椒地 >花椒园地 >荒滩地     

子午岭林区不同植被恢复阶段土壤有机碳变化研究

研究了子午岭林区植被恢复过程中土壤有机碳含量、团聚体有机碳分布以及不同粒级团聚体有机碳对土壤有机碳的贡献率。研究结果表明,0—100 cm剖面上有机碳含量加权平均值随植被恢复年限逐渐升高,坡耕地0—100 cm土层土壤有机碳加权平均值为3.54 g/kg,弃耕地、草地、灌木和乔木阶段分别比坡耕地提高6.8%,36.6%,41.5%和73.6%;0—20 cm土层土壤有机碳含量随植被恢复的提高幅度明显高于20 cm以下土层;0—5和5—10 cm土层土壤各粒级团聚体有机碳含量随植被恢复年限逐渐增加,并有向大粒级（〉2 mm）团聚体中富集的趋势,10—20 cm土层土壤团聚体有机碳含量随植被恢复变化不明显;弃耕地、草地、灌木和乔木阶段0—20 cm土层〉5,5～2和2～1 mm粒级团聚体有机碳贡献率高于坡耕地,说明植被恢复0—20 cm土层土壤增加的有机碳更多地固定在〉1 mm粒级团聚体中。     

垦殖对黄河三角洲盐渍土碳氮分布特征的影响

以黄河三角洲新生盐碱地为例,采用空间替代时间的方法,选取未利用的盐碱地对照(CK)和平均开垦年限分别为小于5 a、10~15 a、20~25 a、30~35 a、50~60 a的小麦/玉米连作土地类型为研究对象,对1 m深土壤碳(有机碳、无机碳、全碳)、氮(全氮、碱解氮)含量进行了分析,研究不同垦殖年限下土壤碳氮水平和垂直分布特征。结果表明:垦殖后,土壤有机碳含量较未垦殖盐碱地均表现为显著提高(p0.05);盐碱地垦殖显著增加了0~40 cm土壤的碳储量,且随垦殖年限增加而增加;40~100 cm土层的有机碳含量无趋势性变化规律;土壤全氮、全碳、无机碳变化与有机碳变化表现出相似规律;垦殖30 a后土壤碳氮养分基本稳定,表层(0~40 cm)含量高于底层(40~100 cm)含量;垦殖年限主要影响0~30 cm土壤碱解氮含量;无机碳作为组成全碳的主要成分,极易受灌溉和地下水的影响。垦殖虽然显著增加土壤有机碳、全氮含量,但垦殖后碳氮比(C/N)呈降低趋势,约30 a后基本稳定,不同垦殖年限C/N平均为9.35,低于全国平均水平,反映出研究区土壤碳氮养分不均衡问题。     

水稻秸秆还田年限对稻麦轮作田土壤碳氮固存的影响

为明确连续秸秆还田对农田土壤碳氮固存的影响,该文于扬州大学试验场展开研究。田间试验布置于2010年,设置秸秆不还田(NR),秸秆还田1a(SR1),秸秆还田2a(SR2),秸秆还田3a(SR3),秸秆还田4a(SR4),秸秆还田5a(SR5),秸秆还田6a(SR6),秸秆还田7a(SR7),秸秆还田8a(SR8)9个处理。于2018年小麦收获后取样,测定分析了土壤容重、有机碳和全氮含量,计算碳氮比、层化率、土壤有机碳和全氮储量(等质量法)。结果表明,随着秸秆还田年限的增加,各土层有机碳和全氮含量逐渐提高,但增幅逐渐减小。0～5 cm土层土壤碳氮比在短期内(≤3 a)随着秸秆还田年限增加而显著提高,但是对其他土层和年限的无显著影响。随着秸秆还田年限增加,表层0～5 cm与其他层次有机碳和碳氮比层化率先增长后下降,全氮层化率则先下降后上升。秸秆还田处理0～20 cm土壤有机碳和全氮储量分别较NR提高6.23%～27.85%和6.04%～25.66%,各土层碳氮储量均随着秸秆还田年限的增加而提高,但是当还田年限6a其增幅明显降低。综上所述,秸秆还田具有良好的碳氮固存效应,但是当秸秆还田年限6a,土壤碳氮固存量的增幅明显降低,可适当减少还田量。     

不同土壤磷的固定特征及磷释放量和释放率的研究

通过加入不同浓度的P(水土比为 2 0∶1 )并利用连续提取法 ,对三种土壤P的固定特征以及磷的释放进行了研究。结果表明 ,红壤对P的固定能力高于潮土 ,而潮土高于水稻土 ,在加入P量为 2 97gkg- 1土壤的条件下 ,三种土壤对P的固定量分别为 2 84gkg- 1、2 5 3gkg- 1和 2 0 8gkg- 1。三种土壤对P的固定率则随着加入P量的增加而降低。在P的释放研究中 ,随着提取次数的增加 ,P的释放量减少 ,并在提取 8次后 ,以后各次P的释放量不发生显著变化。三种土壤中 ,水稻土P的最大释放量 (1 2 4 0 7mgkg- 1)显著高于红壤 (60 46mgkg- 1)和潮土 (1 9 74mgkg- 1) ,水稻土P的总释放量 (1 6次 )也大于红壤和潮土 ,三种土壤P的总释放量分别为 2 0 6 0 2 (1 98gkg- 1土壤P处理 )和 2 71 91mgkg- 1(2 97gkg- 1土壤P处理 )、1 0 0 48和2 60 5 3mgkg- 1、1 1 6 0 6和 1 3 1 91mgkg- 1。三种土壤P的释放率随着提取次数的增加而增加 ,并逐渐达到稳定。水稻土的释放率显著高于红壤和潮土。水稻土和潮土中 ,1 98gkg- 1土壤P处理的土壤P的释放率高于2 97gkg- 1土壤P处理的土壤 ,红壤则相反     

中国亚热带稻田土壤碳氮含量及矿化动态

Dynamics of soil organic matter in a cultivation chronosequence of paddy fields were studied in subtropical China. Mineralization of soil organic matter was determined by measuring CO2 evolution from soil during 20 days of laboratory incubation. In the first 30 years of cultivation, soil organic C and N contents increased rapidly. After 30 years, 0-10 cm soil contained 19.6 g kg^-1 organic C and 1.62 g kg^-1 total N, with the corresponding values of 18.1 g kg^-1 and 1.50 g kg^-1 for 10-20 cm, and then remained stable even after 80 years of rice cultivation. During 20 days incubation the mineralization rates of organic C and N in surface soil （0-10 cm） ranged from 2.2% to 3.3% and from 2.8% to 6.7%, respectively, of organic C and total N contents. Biologically active C size generally increased with increasing soil organic C and N contents. Soil dissolved organic C decreased after cultivation of wasteland to 10 years paddy field and then increased. Soil microbial biomass C increased with number of years under cultivation, while soil microbial biomass N increased during the first 30 years of cultivation and then stabilized. After 30 years of cultivation surface soil （0-10 cm） contained 332.8 mg kg^-1 of microbial biomass C and 23.85 mg kg^-1 of microbial biomass N, which were 111% and 47% higher than those in soil cultivated for 3 years. It was suggested that surface soil with 30 years of rice cultivation in subtropical China would have attained a steady state of organic C content, being about 19 g kg^-1.     

黄土丘陵区人工刺槐林恢复过程中土壤氮素与微生物活性的变化

为了探讨不同生长年限的人工刺槐(Robinnia pseudoacacia)林对土壤中氮素组成与微生物活性的影响及机理,本文采用"时空互代"法进行野外选点调查和采样,对典型黄土丘陵区陕西省安塞纸坊沟小流域不同林龄(10 a、15 a、30 a、38 a)人工刺槐林和撂荒地3个土层(0~10 cm、10~30 cm和30~60 cm)中的全氮、铵态氮、硝态氮、有机氮、微生物生物量碳和磷、基础呼吸及基本理化性质进行了研究。结果表明:人工刺槐林地土壤微生物生物量碳、磷含量和微生物熵都显著高于撂荒地(P<0.05)。随着人工刺槐林生长年限的增加,各层土壤铵态氮、硝态氮和有机氮含量均逐渐增加,其中有机氮的增加最显著;土壤微生物生物量碳、磷含量显著增加;微生物熵显著增大而呼吸熵显著减小;土壤有机碳、速效磷含量总体上显著增加(P<0.05);容重和碳氮比则呈下降趋势。随着土层深度的增加,氮素、有机碳、速效磷和微生物生物量碳、磷含量显著减小(P<0.05);容重和pH显著增加。土壤微生物生物量碳、磷和呼吸熵均与有机氮、全氮、硝态氮显著正相关(P<0.05)。分析发现,刺槐的生长促使土壤中微生物可利用碳增加,提高了碳的利用率,使土壤微生物量碳、磷含量增加;微生物活性的提高反过来促进了土壤氮素含量的提高,土壤中有机氮含量显著增加。与10 a生刺槐林相比,30 a生林地土壤表层的全氮含量明显增加,氮素肥力由7级(0.40 g.kg 1)上升为5级(0.87 g.kg 1)水平。     

Effect of cultivation on microbial carbon and nitrogen in dry tropical forest soil

Summary Fifteen- and forty-year-old cropfields developed from a dry tropical forest were examined for soil organic C and total N and soil microbial C and N. The 15-year-old field had never been manured while the 40-year-old field had been fertilized with farmyard manure every year. The native forest soil was also examined. The results indicated that the native forest soil lost about 57% and 62% organic C and total N, respectively, in the 0–10 cm layer after 15 years of cultivation. The microbial C and N contents of the forest soil were greater than those of the cultivated soils. Application of farmyard manure increased the biomass-C and -N levels in the cultivated soil but the values were still markedly lower than in the forest soil. There was an appreciable seasonal variation in biomass C and N, the values being highest in summer and lowest in the rainy season. During an annual cycle, biomass-C contents varied from 180 to 727 g g^–1 and N from 20 to 80 g g^–1 dry soil, and both were linearly related. Microbial biomass C represented 1.6%–3.6% of total soil organic C and microbial biomass N represented 1.7% 1–4.4% of soil organic N.     

Soil organic C,nutrients, microbial biomass,and grain yield of rice (<Emphasis Type="Italic">Oryza sativa</Emphasis> L.) after 18 years of fertilizer application to an infertile paddy soil

We have studied the influence of long-term fertilization on organic C, nutrients, microbial biomass of soil, and grain yield of rice (Oryza sativa L.) after 18 years of inorganic and organic fertilizer application to an infertile paddy field under subtropical conditions. After 18 years of fertilization, soil organic C and total N contents were 9.56~12.17 and 1.01~1.25 g kg⁻¹, which were 190~269% and 135~191% higher than those of the initial soil, respectively. Organic manure application increased soil organic C, total N, available N, and available P contents by 19.2%, 14.4%, 13.2%, and 78.3% on average compared with organic manure-omitted treatments. Phosphorus fertilizer application increased soil available P content more significantly than organic manure application, and it was an average 385% higher than P-omitted treatments. Soil microbial biomass C, N, and rice yield were 48.9%, 33.2%, and 133% higher in organic manure application treatments and 36.8%, 38.8%, and 239% higher in P fertilizer application treatments than organic manure-omitted or P-omitted treatments, respectively. Incorporation of organic manure-enhanced and P fertilizer-enhanced rice yields by 382% compared with the unfertilized treatment and yield increment index was 123% compared with that observed during 1991–1994, implying that organic manure application combined with P fertilizer was needed to ensure high and sustainable productivity. Rice yield was significantly correlated with all soil chemical properties except available K content, and stepwise regression analysis showed that soil available P content was the limiting factor to rice yield.     

三峡库区不同林龄柑橘土壤酶活性的演变

土壤酶驱动土壤生态系统养分的循环和控制生态系统的功能。本研究以生长年限为10、20年和30年的柑橘林0~20 cm和20~40 cm土层土壤为研究对象,主要探讨了土壤脲酶、转化酶和过氧化氢酶活性随着柑橘林龄的延长和土壤深度的增加的变化规律。结果表明,随着柑橘林龄的延长,0~20 cm土层土壤过氧化氢酶活性10年和20年样地之间无显著性差异,但都显著大于30年的样地;而0~20 cm土层土壤转化酶和脲酶活性逐渐提高,20年时达到最大值,其后又降低。随着土壤深度的增加,过氧化氢酶、转化酶和脲酶活性在3个林龄的柑橘林中都呈现显著的下降趋势。相关性分析的结果表明,土壤转化酶活性、脲酶活性都与土壤有机碳和微生物量碳氮之间都具有显著的正相关性,而过氧化酶氢活性与土壤理化特性及其微生物量之间都无显著的相关性。主成分分析结果进一步显示,土壤转化酶活性、脲酶活性、有机碳和微生物生物量碳氮均在第一主成分中具有较大的载荷,对第一主成分的贡献最大。以上结果表明脲酶和转化酶活性能够做为柑橘土壤质量变化的敏感指标。     

长期不同施肥处理对水稻土有机碳分布变异及其矿化动态的影响

基于持续26 a的太湖地区水稻土长期定位试验,研究了长期施肥对水稻土剖面有机碳分布、有机碳密度和变异幅度、及有机碳矿化动态的影响。结果表明:(1)长期施肥使水稻土表层有机碳含量显著升高,施有机肥和秸秆还田较单施化肥更能促进表层有机碳累积。施化肥处理10~30 cm土层有机碳含量相对稳定,施有机肥处理20~40 cm土层有机碳含量相对稳定;(2)0~25 cm和0~50 cm土层,施有机肥处理的有机碳密度均高于施化肥处理,有机肥+氮+磷处理(MNP)和化肥氮+磷+钾处理(CNPK)的有机碳密度均为最高,秸秆+化肥氮处理(CRN)高于有机肥+秸秆+氮处理(MRN)。各施肥处理0~25 cm和25~50 cm土层有机碳变异幅度均高于对照C0。施有机肥处理的有机碳密度变异幅度均高于施化肥处理。化肥氮+磷处理(CNP)和有机肥+氮+磷+钾处理(MNPK)有机碳密度的变异性最大;(3)各处理土壤有机碳矿化速率在培养第2~4天均达到最大,第3周后达到稳定,有机肥处理的最大矿化速率均高于化肥处理,各处理平均矿化速率为CO255.36~75.46 m l kg-1d-1,稳定矿化速率为CO210~20 m l kg-1d-1。在8周培养期内,施有机肥处理的累积矿化量始终大于施化肥处理,有机肥+秸秆+氮处理(MRN)的累积矿化量最大,各施肥处理土壤的矿化强度和稳定矿化率仍保持稳定。     

沙漠腹地咸水滴灌林地土壤养分、微生物量和酶活性的典型相关关系

鉴于塔里木沙漠公路防护林所处环境条件和管理模式的特殊性及在南疆社会、经济发展中的重要性,试验选择四种不同矿化度(2.58、5.75、8.90、13.99 g L-1)水滴灌的防护林地,采集0~5 cm、5~15cm、15~30 cm、30~50 cm四层土样为研究材料,主要采用典型相关分析法,对防护林地土壤养分因子、微生物量因子和酶活性因子中每两组变量间的相关性进行了分析。结果表明:三组变量土壤养分、微生物量、酶活性中,每两者之间均有显著的典型相关变量存在,而且基本能够代表变量总体相关信息;土壤养分与土壤微生物量的相关性主要由养分中的全氮、速效氮、有机质、全磷含量和土壤微生物量中的放线菌数量、微生物量碳和微生物量磷引起的;土壤养分与土壤酶活性的相关性主要由土壤有机碳、速效钾含量与土壤过氧化氢酶、磷酸酶活性的相关性引起;土壤微生物量与土壤酶活性的相关性主要由土壤微生物量磷、微生物量氮与土壤蔗糖酶、磷酸酶活性的相关性引起;滴灌水矿化度对塔里木沙漠公路防护林地土壤养分和微生物量的效应明显,高矿化度水不利于土壤养分积累和微生物生存。     

Influence of inorganic fertilizers and organic amendments on soil organic matter and soil microbial properties under tropical conditions

 Soil organic matter level, mineralizable C and N, microbial biomass C and dehydrogenase, urease and alkaline phosphatase activities were studied in soils from a field experiment under a pearl millet-wheat cropping sequence receiving inorganic fertilizers and a combination of inorganic fertilizers and organic amendments for the last 11 years. The amounts of soil organic matter and mineralizable C and N increased with the application of inorganic fertilizers. However, there were greater increases of these parameters when farmyard manure, wheat straw or Sesbania bispinosa green manure was applied along with inorganic fertilizers. Microbial biomass C increased from 147 mg kg^–1 soil in unfertilized soil to 423 mg kg^–1 soil in soil amended with wheat straw and inorganic fertilizers. The urease and alkaline phosphatase activities of soils increased significantly with a combination of inorganic fertilizers and organic amendments. The results indicate that soil organic matter level and soil microbial activities, vital for the nutrient turnover and long-term productivity of the soil, are enhanced by use of organic amendments along with inorganic fertilizers. Received: 6 May 1998     

红壤稻田土壤理化及生物学性状的动态变化特征

Rice production plays a crucial role in the food supply of China and a better understanding of the changes in paddy soil fertility and the management effects is of practical importance for increasing rice productivity. In this study, field sampling in a typical red soil region of subtropical China, Jiangxi Province, was used to observe changes in the soil physical, chemical, and biological properties in a cultivation chronosequence of paddy fields. After cultivation, clay (< 0.002 mm) content in the soil, which was 39% in the original uncultivated wasteland, decreased, to 17% in the 80-year paddy field, while silt (0.02--0.002 mm) content increased. Additionally, macroporosity increased and pore shapes became more homogeneous. Soil Ph generally increased. Soil organic C and total N content of the 0-10 cm layer increased from 4.58 and 0.39 g kg-1 to 19.6 and 1.62 g kg-1, respectively in the paddy fields after 30-year cultivation and then remained stable. Soil total P content increased from 0.5 to 1.3 g kg-1 after 3 years of rice cultivation, indicating that application of phosphate fertilizer could accelerate phosphorous accumulation in the soil. Total K content in the 0--10 cm soil layer for the 80-year paddy fields decreased by 28% compared to that of the uncultivated wasteland land. Total Fe and free Fe contents declined with years of cultivation. The bacterial population increased and urease activity noticeably intensified after years of cultivation. In this chronosequence it appeared that it took 30 years to increase soil fertility to a relatively constant value that was seen after 80 years of cultivation.