不同肥力红壤水稻土根际团聚体组成和碳氮分布动态

研究水稻种植期间表层土壤团聚体数量及其有机碳、全氮含量的变化,对揭示人为耕作的影响、认知土壤肥力的演变规律具有重要意义。选择两种不同肥力的红壤性水稻土进行田间根袋试验,分别于水稻插秧前、分蘖期、孕穗期和成熟期采样,分析了水稻生长过程中根际和非根际土壤团聚体组成、稳定性以及有机碳、全氮分布的动态变化。结果表明,低肥力土壤团聚体以0.25 mm大团聚体为主(56.2%~64.0%),0.25~1 mm粒级团聚体含量最高;除1~2 mm粒级外,水稻生育期内根际土壤各粒级团聚体含量均有显著变化;取样时期、根际作用与取样时期的交互效应对0.25~1 mm和0.053~0.25 mm粒级含量有显著影响。高肥力土壤中以0.25 mm微团聚体为主(59.8%~72.0%),0.053~0.25 mm粒级团聚体比例最高,取样时期显著影响0.25 mm大团聚体含量,根际作用与取样时期的交互效应对2 mm粒级含量有极显著影响。与非根际相比,根际土壤大团聚体的破坏率较低,平均重量直径(MWD)较高,种植水稻有助于提高根际土壤的稳定性。两种肥力土壤团聚体中有机碳和全氮含量均表现为1~2 mm粒级最高,0.053~0.25 mm粒级最低,大团聚体中显著高于微团聚体。根际土壤中,水稻成熟期各粒级团聚体有机碳含量与插秧前无显著差异,而分蘖期和孕穗期有明显波动;水稻的生长降低了大团聚体中的全氮含量,对高肥力土壤的影响更为显著。总体而言,低肥力土壤中,根际作用主要影响团聚体组成和稳定性,取样时期影响团聚体碳氮含量;高肥力土壤中,团聚体组成和碳氮分布受根际作用和取样时期的共同影响。     

控制排水条件下淹水稻田田面及地下水氮浓度变化

为了在减少农田面源污染,提高氮肥的利用效率。该文通过蒸渗测坑进行淹水稻田不同渗漏强度控制试验,研究了稻田施肥后NH4+-N、NO3--N浓度变化及各生育阶段不同渗漏强度稻田水NH4+-N、NO3--N浓度变化。结果表明：施分蘖肥后,地表水及地下水NH4+-N浓度急剧升高而后回落,均在施肥后第5天出现峰值,分别为17.75和10.34?mg/L;地表水NO3--N浓度短暂升高后便回落,在施肥后第2天出现峰值,但地下水NO3--N浓度急剧上升而后回落,在施肥后第5天出现峰值（3.25?mg/L）,6?d上升了249.4%。稻田补水会扰动土壤,促进土壤表层吸附的NH4+-N的释放及硝化进程,使地表水中NH4+-N和NO3--N浓度升高,随着淹水时间的延长,NH4+-N和NO3--N浓度会随之降低。不同渗漏强度（2和4?mm/d）对稻田水氮素变化有一定影响,但各处理之间差异不显著。因此,施肥后应该避免排水,应避免雨后和灌水后立即进行地表排水。     

水稻生育期内红壤稻田氨氧化微生物数量和硝化势的变化

利用荧光定量PCR(Real-timePCR)技术,通过特异引物检测amoA基因拷贝数分析了水稻不同生育期红壤稻田土壤中氨氧化细菌(Ammonia oxidizing bacteria,AOB)和氨氧化古菌(Ammonia oxidizing archaea,AOA)的数量变化,并测定了土壤潜在硝化势。结果显示:红壤稻田土壤中AOA数量显著高于AOB,二者比例在1.6～120.7之间;红壤稻田根层土中AOA数量显著高于表土,随水稻生长根层和表土中AOA数量均逐渐增加,且根层土中增加幅度更大;在水稻生长前期表土中AOB数量较多,孕穗期后根层土中AOB数量显著增加且高于表土。水稻生长期内土壤潜在硝化势也具有逐渐增加趋势,且根层土潜在硝化势增加幅度更大。根层土中潜在硝化势与AOB和AOA数量均呈显著正相关,而表土中潜在硝化势只与AOA数量存在显著正相关。研究表明,红壤稻田土壤中AOA数量更为丰富,且与硝化作用的关联程度更为密切,证实了氨氧化微生物在红壤稻田土壤微生物组成及其生态系统功能中的重要性。     

玉米?水稻轮作和水稻连作土壤根际和非根际氮含量及酶活性

【目的】以水稻连作为对照,研究玉米?水稻水旱轮作模式对稻田作物根际和非根际土壤氮素含量及酶活性的影响,为稻田系统玉米?水稻轮作对土壤氮素转化与稻田土壤质量的影响提供科学依据。【方法】利用根际袋盆栽试验进行水稻连作与玉米?水稻轮作,在玉米喇叭口期、抽穗期及成熟期,水稻分蘖期、孕穗期及成熟期分别采取根际与非根际土样,测定土壤铵态氮、硝态氮、全氮含量与脲酶、硝酸还原酶活性变化。【结果】两种种植模式及作物生育期对土壤氮素含量和酶活性均有显著影响。不同种植模式下土壤酶活性变化趋势基本相同。与水稻连作相比,玉米?水稻轮作土壤铵态氮减少了24.7%;土壤硝态氮含量增加了153.4%,主要表现在第一季。与水稻连作相比,玉米?水稻轮作条件下两季作物成熟期土壤全氮含量降低,土壤脲酶活性整体提高24.3%,土壤硝酸还原酶活性整体降低34.6%。水旱轮作对各个指标的影响可持续到第二季。根际土壤铵态氮含量及脲酶活性整体低于非根际土壤,玉米根际土壤硝态氮含量低于非根际,水稻根际土壤硝态氮含量高于非根际土壤,根际土壤硝酸还原酶活性高于非根际土壤。【结论】在本试验中,轮作在第一季对土壤氮素及酶活性的影响可持续至第二季。与水稻连作相比,玉米?水稻轮作可以提高作物根际与非根际土壤的脲酶活性及硝态氮含量,有利于氮素有效性的提高。     

肥力水平对水稻苗期生长及氮素吸收同化的影响

通过盆栽试验研究了不同肥力水平红壤水稻土种植条件下,水稻苗期生长及其N素吸收同化的差异.结果表明,在高肥力土壤中水稻的苗期生物量均显著高于低肥力土壤,主要表现为根生物量的差异,而且高肥力显著增加了水稻根数,但对水稻根冠比无显著影响.高土壤肥力对水稻N素吸收有显著促进作用,在一定程度上提高了水稻N素利用率,但并无显著影响.与低肥力红壤水稻土相比,水稻在高肥条件下叶片和根硝酸还原酶活性(NRA)和谷氨酰胺合成酶活性(GSA)均显著提高,显著促进水稻对N素的吸收同化.因此,适当提高和改善红壤水稻土肥力对红壤区水稻生长及N素营养具有重要意义.     

不同土壤的还原状况对铁镉形态转化和水稻吸收的影响

采用土壤-蛭石联合培养,以填充蛭石的网袋模拟根际,置于红壤、水稻土、盐土中后淹水栽培水稻13 d.试验结果表明,水稻栽培期问,红壤、水稻土、盐土pH变化范围分别为6.05 ～6.78、6.47 ～7.33、6.42 ～7.44;有机质处理下,除红壤根际pH明显升高外,其余土壤根际和非根际pH均有所下降.各土壤对照根际Eh保持在233 ～ 385 mV;有机质处理使根际Eh下降,同时也导致除盐土外的非根际Eh上升.土壤还原溶解Fe与蛭石吸附Fe的90％以上均米自铁锰氧化物结合态铁(Oxide-Fe)组分,与溶液Eh、pe+ pH均有显著相关性,表明两表面同为Fe的氧化还原反应,但方向相反.水稻根表Fe膜的形成与根际氧化还原状况有关,在对照根际(高Eh)环境下,根表Fe含量随pH升高而降低,在有机质处理根际(低Eh)环境下则随pH升高而升高;在红壤中,根表Fe膜阻碍Fe的吸收,在水稻土和盐土中,根表Fe膜促进Fe吸收.根表Cd含量与根内Cd、地上部Cd有显著正相关;在红壤中,根表Fe膜阻碍了水稻Cd的吸附和吸收;水稻土和盐土中,根表Fe膜促进了水稻Cd的吸附和吸收.     

不同水肥管理模式对太湖地区稻田土壤氮素渗漏淋溶的影响

针对当前我国水稻生产中日益严重的水资源短缺及稻田土壤氮素渗漏淋溶引发的面源污染问题,本研究通过设置2种灌溉方式及4个施氮水平的双因子交互试验,探讨了不同水肥处理对稻田土壤氮素渗漏淋溶的影响.结果表明,稻田20 cm处渗漏水中NH+4-N浓度与施氮量呈正相关关系,减少氮肥施用量,可降低2％～35％的NH+4-N浓度,而80 cm处NH+4-N浓度与施氮量无相关关系;稻田20 cm、80 cm处渗漏水中NO3-N浓度均与施氮量呈正相关关系;控制灌溉显著提高了稻田80 cm处渗漏水中NO-3-N浓度,增幅达31％,但由于其水分渗漏量少,NO3-N淋溶量较常规灌溉仍降低16％～ 49％; NO3-N是稻田中氮素渗漏淋溶的主要形式,占氮素渗漏淋溶总量的77％～92％;减氮施肥条件下,NO3-N渗漏淋溶量降低14％～56％.控灌减氮措施可很好地协调产量效益与水体环境效益,是适宜太湖地区的环境友好型水肥管理模式.     

两种硝化抑制剂在不同土壤中的效果比较

采用室内培养试验,比较了两种硝化抑制剂3,4-二甲基吡唑磷酸盐(DMPP)和双氰胺(DCD)在4种典型农田土壤(水稻土、潮土、黑土、红壤)中的抑制效果。结果表明,在培养期内土壤pH和NH4+-N呈先上升后下降的趋势,NO3--N和表观硝化率呈逐渐上升的趋势。与单施尿素处理(U)相比,添加硝化抑制剂显著增加了土壤NH4+-N含量,降低了NO3--N含量,表观硝化率表现为UU+DMPPU+DCD。在水稻土和潮土中,单施尿素处理的硝化过程到第14天时基本完成,添加硝化抑制剂使硝化过程延长了至少28天。在黑土和红壤中,尤其是在红壤中,硝化过程相对缓慢,施用抑制剂虽然降低了土壤的表观硝化率,但降低的程度低于水稻土和潮土。总之,在推荐用量下10%DCD的硝化抑制效果优于1%DMPP,且这两种抑制剂在不同土壤中的抑制效果不同。     

脲酶/硝化抑制剂双控下红壤性水稻土氮素变化特征

以红壤性水稻土为对象,设置大田试验处理:不施肥(CK)、单施氮肥(U)、氮肥配施0. 5%脲酶抑制剂N-丁基硫代磷酰三胺(NBPT)与1%硝化抑制剂3,4-二甲基吡唑磷酸盐(DMPP)(U+N/D)、氮肥配施1%NBPT与2%DMPP [U+2 (N/D)],研究4种施肥组合下双季稻土壤脲酶、土壤NH+4-N、田面水NH+4-N和NO-3-N的变化特征。结果表明,与CK和U处理相比,各施肥处理在施肥后第1～15 d,土壤脲酶活性、土壤NH+4-N、田面水NH+4-N含量增加,田面水NO-3-N含量无显著变化。与U+2 (N/D)处理相比,早稻中U+N/D处理的脲酶活性显著增加了0. 03～0. 70 mg·g-1,土壤NH+4-N含量显著增加了19. 11～61. 44 mg·kg-1,田面水NH+4-N含量显著增加了34. 48～40. 70 mg·L-1。相关分析表明,土壤NH+4-N与土壤脲酶、田面水NH+4-N均呈显著负相关,田面水NH+4-N与土壤脲酶、田面水NO-3-N均呈显著正相关(P 0. 05)。综上,与其他处理相比,U+N/D处理是在短期内有效提高土壤脲酶活性、土壤NH+4-N和田面水NH+4-N含量的最优处理,合理配施尿素及0. 5%脲酶抑制剂NBPT和1%硝化抑制剂DMPP能够显著提高NH+4-N供水稻吸收,减少氮素损失。     

不同光照条件下莴笋生长期间三种紫色土中氮素的变化

运用盆栽试验方法,研究了不同光照条件下,莴笋生长期间三种紫色土中氮素含量的变化,结果表明:三种土壤中氮素含量的变化因处理光照的强弱而有所不同,光照增强时,土壤中NH4+-N含量下降速度较快,光照较弱时则下降速度相对较慢;NO3--N含量的变化亦因光照强度的不同而有差异,但其同时也决定于土壤中NH4+-N的含量;三种紫色土相互比较,NH4+-N和NO3--N含量的变幅受光照强度影响的大小与土壤本身的肥力状况有关,其中肥力较低的石骨子土所受的影响相对较小,沙土所受的影响则稍大,肥力较高的大眼泥土所受的影响则最大;土壤中碱解氮含量的变化亦在一定程度上受土壤本身肥力状况的影响.     

不同氮效率水稻品种增硝营养下根系生长的响应特征

试验采用两室分根盒和溶液培养方法,研究了在增硝营养下不同氮效率水稻品种根系生长的响应特征。结果表明,在本试验条件下,与全铵培养下的根系相比,氮高效水稻品种南光在铵硝混合培养下的根系干重和氮积累量显著增加,增幅达33%和41%;同时其根系表面积、根系体积和侧根数增幅均达到显著水平,但根系长度却无明显增加。氮低效水稻品种Elio在铵硝混合培养下的根系生长差异均不显著。这表明氮高效水稻品种南光的根系生长对增硝营养的响应度强,进而促进了根系对氮素的吸收利用。从本试验的结果可推论,水稻对增硝营养的强响应度可能是水稻氮素高效吸收利用的生理机制之一。     

水培和土培条件下氮素供应对燕麦生长和磷素吸收的影响

Plants show different growth responses to N sources supplied with either NH₄⁺ or NO₃^-. The uptake of different N sources also affects the rhizosphere pH and therefore the bioavailability of soil phosphorus, particularly in alkaline soils. The plant growth, P uptake, and P availability in the rhizosphere of oat (Avena nuda L.) grown in hydroponics and in soil culture were investigated under supply with sole NH₄⁺-N, sole NO₃^--N, or a combination. Sole NO₃^--fed oat plants accumulated more biomass than sole NH₄⁺-fed ones. The highest biomass accumulation was observed when N was suppliedw ith both NH₄⁺-N and NO₃^--N. Growth of the plant root increased with the proportion of NO₃^- in the cultural medium. Better root growth and higher root/shoot ratio were consistently observed in NO₃^--fed plants. However, root vigor was the highest when N was supplied with NO₃^-+NH₄⁺. NH₄⁺ supply reduced the rhizosphere pH but did not affect P uptake by plants grown in soils with CaHPO₄ added as P source. No P deficiency was observed, and plant P concentrations were generally above 2 g kg^-1. P uptake was increased when N was supplied partly or solely as NO₃^--N, similarly as biomass accumulation. The results suggested that oat was an NO₃^--preferring plant, and NO₃^--N was essential for plant growth and the maintenance of root absorption capacity. N supply with NH₄⁺-N did not improve P nutrition, which was most likely due to the absence of P deficiency.     

Growth and Phosphorus Uptake of Oat (Arena nuda L.) as Affected by Mineral Nitrogen Forms Supplied in Hydroponics and Soil Culture

Plants show different growth responses to N sources supplied with either NH4+ or NO3-.The uptake of different N sources also affects the rhizosphere pH and therefore the bioavailability of soil phosphorus,particularly in alkaline soils.The plant growth,P uptake,and P availability in the rhizosphere of oat (Arena nuda L.) grown in hydroponics and in soil culture were investigated under supply with sole NH4+-N,sole NO3--N,or a combination.Sole NO3-fed oat plants accumulated more biomass than sole NH4+-fed ones.The highest biomass accumulation was observed when N was supplied with both NH4+-N and NO3--N.Growth of the plant root increased with the proportion of NO3-in the cultural medium.Better root growth and higher root/shoot ratio were consistently observed in NO3--fed plants.However,root vigor was the highest when N was supplied with NO3-+NH4+.NH4+ supply reduced the rhizosphere pH but did not affect P uptake by plants grown in soils with CaHPO4 added as P source.No P deficiency was observed,and plant P concentrations were generally above 2 g kg-1.P uptake was increased when N was supplied partly or solely as NO3--N,similarly as biomass accumulation.The results suggested that oat was an NO3-prcferring plant,and NO3--N was essential for plant growth and the maintenance of root absorption capacity.N supply with NH4+-N did not improve P nutrition,which was most likely due to the absence of P deficiency.     

复合污染土壤中水稻根际元素特性及效应研究

【目的】以广东大宝山重金属复合污染农田为生长介质,通过研究水稻不同部位生长量、 金属含量、 对金属的富集系数,及其与根际、 非根际土金属含量、 形态变化的相关关系,探讨根际效应可能对水稻体内金属积累转运以及生物量的影响。【方法】选取了广东大宝山稻田重金属复合污染(As、 Pb、 Fe、 Cu、 Zn)土壤及当地常见的20个水稻品种进行根际袋试验,即将根际袋内的土视为根际土,根际袋外的土视为非根际土,将供试水稻品种种植于根际袋土壤中60天后收获,测定水稻各部位的生长量、 不同金属的含量,根际土和非根际土中各金属有效态的含量。【结果】Fe、 Cu、 Pb、 Zn、 As在根部的富集系数均大于其在茎叶的富集系数,各金属在茎叶和根部的富集能力排序分别为Zn Cu As ≈ Pb ≈ Fe和Fe Zn As Cu Pb。根际土和非根际土中各种金属有效态含量均为Fe Cu Pb Zn As。研究还发现,有效态Fe、 Cu和Zn浓度对整株干重的影响显著,作用强弱顺序为Cu Zn Fe,对水稻生长影响作用显著的三种有效态金属Fe、 Cu和Zn均为植物生长所必需的元素。供试土壤中有效态Cu浓度对水稻的生长所起的作用最强。根际土有效态Fe浓度对根系Fe的积累作用效果显著,有效态As浓度显著抑制了根系Fe的积累,且有效态As浓度的作用强于有效态Fe。【结论】根际土中有效态Fe对株高、 根干重、 茎叶干重和整株干重均起着抑制作用,有效态Cu对水稻生长起到了促进作用。根际土有效态As和非根际土有效态Zn对根部Fe的积累起到了抑制作用,根际土有效态Fe和非根际土有效态Cu则起到了促进作用。非根际土有效态Fe和有效态Zn对水稻根长的增加均起到了促进作用。     

水稻根际中铁的形态转化

本文以熟化红壤性水稻土、淀浆白土、红壤和赤红壤为样品,研究了植稻后根际中铁的形态转化.结果表明,两种水稻土根际中无定形氧化铁、游离氧化铁、络合态铁、土壤中氧化铁的活化度及两种红壤上根际中的络合态铁均低于非根际土;而两种红壤上其余各项在根际内外分布趋势均与水稻土相反.用穆斯堡尔谱仪分析表明,所有根际土与非根际土相比,四极矩分裂增大,内磁场下降,说明根际中氧化铁被活化.同时,水稻土上根际中Fe²⁺增多,赤红壤中根际出现新矿物磁赤铁矿.根际中铁被活化,可能会影响根际中重金属等污染物的吸附和解吸特性、植物的铁素营养及对其它养分的吸收.     

Interaction of silicon,iron, and manganese in rice (oryza sativa L.) rhizosphere at low ph in relation to rice growth

Rice (Oryza Sativa L.) nutrition is influenced by the interactions of (Iron) Fe, (Manganese) Mn, and (Silicon) Si in the rhizosphere. A greenhouse experiment was carried out with rice grown in four low‐pH soils (a granitic lateritic red earth, a paddy soil from the red earth, a basaltic latosol, and a paddy soil from the latosol). Rice was grown in pots with the roots confined in rhizobags and the rhizosphere soil and nonrhizosphere soil were analyzed separately for active Si, Fe, and Mn by Tamm's solution. Silicon and Mn concentrations were lower in the rhizosphere soil indicating a depletion which was higher for the basaltic soils and for the paddy soils. Iron concentrations were higher in the rhizosphere soil indicating an accumulation that was higher for granitic soils and for the upland soils. Plant growth response was due mostly to Mn with the basaltic soils supplying toxic amounts and the granitic soils being deficient. Iron accumulation in the rhizosphere caused lower plant uptake of Si, phosphorus (P), and calcium (Ca) and higher Fe and aluminum (Al) absorption leading to the conclusion that Fe deposition on plant roots and in rhizosphere may block the uptake of other nutrients.     

Contribution of nitrification happened in rhizospheric soil growing with different rice cultivars to N nutrition

A rhizobox with three compartments and soil slicing followed by quick freezing were used to study the spatiotemporal variations of nitrification of rhizospheric soil of Yangdao 6 (Indica) and Nongken 57 (Japonica). The results obtained revealed that ammonium () was the main N form in flooded paddy soil. A concentration gradient for was observed with the lowest concentration nearer to the root zone and the concentrations increased with increasing distance from the root zone. No concentration gradient was observed for nitrate (). The nitrification activities of both rice cultivars increased with the development of the incubation time. The nitrification activities were maximal in rhizospheric soil, followed by those in bulk soil and in the root zone. In the rhizosphere, nitrification activities decreased with increasing distance from the root zone. The maximal nitrification activity measured at 44, 51, and 58 days after sowing of Yangdao 6 and Nongken 57 rice cultivars was at a distance of 6 and 2 mm away from the root zone, respectively, and they were 0.88 and 0.73 mg kg⁻¹ h⁻¹, respectively. In this experiment, the nitrification activities were significantly and positively correlated with the ammonia-oxidizing bacteria (AOB) abundance (r=0.86, p<0.01). The nitrification activity, concentration, AOB abundance, dry matter and N accumulation and leaf reductase activity associated with Indica were always higher than those with Japonica. Therefore, nitrification in rhizosphere had more important significance for N nutrition, especially for the Indica rice cultivars.