共查询到20条相似文献,搜索用时 31 毫秒
1.
Influence of soil compaction on carbon and nitrogen mineralization of soil organic matter and crop residues 总被引:18,自引:0,他引:18
We studied the influence of soil compaction in a loamy sand soil on C and N mineralization and nitrification of soil organic
matter and added crop residues. Samples of unamended soil, and soil amended with leek residues, at six bulk densities ranging
from 1.2 to 1.6 Mg m–3 and 75% field capacity, were incubated. In the unamended soil, bulk density within the range studied did not influence any
measure of microbial activity significantly. A small (but insignificant) decrease in nitrification rate at the highest bulk
density was the only evidence for possible effects of compaction on microbial activity. In the amended soil the amounts of
mineralized N at the end of the incubation were equal at all bulk densities, but first-order N mineralization rates tended
to increase with increasing compaction, although the increase was not significant. Nitrification in the amended soils was
more affected by compaction, and NO3
–-N contents after 3 weeks of incubation at bulk densities of 1.5 and 1.6 Mg m–3 were significantly lower (by about 8% and 16% of total added N, respectively), than those of the less compacted treatments.
The C mineralization rate was strongly depressed at a bulk density of 1.6 Mg m–3, compared with the other treatments. The depression of C mineralization in compacted soils can lead to higher organic matter
accumulation. Since N mineralization was not affected by compaction (within the range used here) the accumulated organic matter
would have had higher C : N ratios than in the uncompacted soils, and hence would have been of a lower quality. In general,
increasing soil compaction in this soil, starting at a bulk density of 1.5 Mg m–3, will affect some microbially driven processes.
Received: 10 June 1999 相似文献
2.
Simple methods for the measurement of nitrogen (N) availability are needed to assess the effect of low-input, organically
based land management systems on the N supply of tropical soils. Our objectives were to determine the effect of contrasting
land-use systems (LUS) on soil N availability and to identify measures of N availability that correlated with maize (Zea mays L.) grain yield. The LUS at the two sites in Kenya involved growth of a maize crop following 17 months of either: (1) Sesbania sesban (L.) Merr. tree growth (sesbania fallow), (2) natural regrowth of vegetation without cultivation (natural fallow), (3) three
crops of unfertilized maize (maize monoculture), or (4) bare uncultivated soil (bare fallow). Soil was collected before the
post-fallow maize crop was sown. The LUS had no effect on total soil N or amount of N in the heavy fraction soil organic matter
(SOM) (>150 μm, >1.37 Mg m–3). Sesbania and natural fallows, as compared to maize monoculture, increased the N in light fraction SOM (>150 μm, <1.13Mgm–3), N in intermediate fraction SOM (>150 μm, 1.13 to 1.37 Mg m–3), ammonium-N and aerobic N mineralization at a depth of 0–15 cm. Maize yields were highest following the sesbania fallow.
Nitrate-N, inorganic-N (ammonium plus nitrate) and anaerobic N mineralization correlated with maize grain yield at both sites.
The relationship between maize yield and pre-season nitrate-N improved when the depth of soil sampling was increased to 1 m
at one site (an Alfisol), but did not improve at the site with anion adsorption in the subsoil (an Oxisol). The sesbania fallow
was more effective than the natural fallow in increasing available soil N. Maize yield was better related to pre-season nitrate
than N in size-density fractions of SOM.
Received: 5 May 1997 相似文献
3.
F. Ponder Jr Fumin Li Diann Jordan Edwin C. Berry 《Biology and Fertility of Soils》2000,32(2):166-172
The influence of compaction on Diplocardia ornata (Smith) burrowing and casting activities, soil aggregation, and nutrient changes in a forest soil were investigated using
pot microcosms. Treatments included two levels each of compaction, organic matter, and earthworms. Both burrowing and casting
activities were more abundant in uncompacted soil than in compacted soil. Bulk density decreased in microcosms of compacted
soil containing D. ornata from 1.76 g cm–3 to 1.49 g cm–3 over the study period. The overall percent of aggregates in the same size classes in compacted soil was less than the percent
of aggregates in uncompacted soil. The mean percent of aggregates in earthworm casts for size classes 0.25–1.00 mm was higher
for compacted soil than for uncompacted soil. The reverse was true for aggregates in class sizes 2.00–4.00 mm. Soil compaction
also affected soil microbial biomass carbon and soil inorganic N concentrations. These results indicate that the burrowing
and casting activities of earthworms in compacted forest soils, as in soils of agricultural and pastured lands, can help ameliorate
disturbed soils by improving aggregation, reducing bulk density, and increasing nutrient availability.
Received: 1 September 1999 相似文献
4.
A study was conducted to determine mineralization rates in the field and in different soil layers under three grassland managements
(viz. a reseeded sward, a permanent sward with a conventional N management, and a long-term grass sward with 0 N (0-N) input).
Potential mineralization rates of soil particles (sand, silt and clay) and macro-organic matter fractions of different sizes
(i.e. 0.2–0.5, 0.5–2.0 and >2 mm) were also determined in the laboratory. In the reseeded plots, net mineralization was unchanged
down to 40 cm depth. In the undisturbed conventional-N swards, mineralization rates were substantially higher in the top layer
(0–10 cm) than in the deeper layers. In plots which had received no fertilizer N, mineralization was consistently low in all
the layers. There was more macro-organic matter (MOM) in the 0-N plots (equivalent to 23 g kg–1 soil for 0–40 cm) than in the two fertilized plots (i.e. conventional-N and reseeded) which contained similar amounts (ca. 15 g kg–1 soil). C and N contents of separated soil particles did not differ amongst the treatments, but there were large differences
with depth. Potential mineralization in the bulk soil was greatest in the 0–10 cm layers and gradually decreased with depth
in all the treatments. Separated sand particles had negligible rates of potential mineralization and the clay component had
the highest rates in the subsurface layers (10–40 cm). MOMs had high potential rate of mineralization in the surface layer
and decreased with soil depth, but there was no clear pattern in the differences between different size fractions.
Received: 17 November 1997 相似文献
5.
Populations of soil-dwelling mites were monitored in monoculture plots of four agroforestry tree species, Gliricidia sepium, Leucaena leucocephala, Dactyladenia barteri and Treculia africana, and compared to those in grass and secondary forest plots in the dry season (December 1993 to January 1994) and in the wet
season (April to June 1994) in southwest Nigeria. Mite populations were very low in all plots during the dry season (500–3000 m–2), compared to those during the wet season (10 000–30 000 m–2). The highest mite population was observed in Gliricidia plots (3 044 m–2) for the dry season and Leucaena plots (30 240 m–2) for the wet season. Mite genera that were dominant in all the experimental plots were Annectacarus, Haplozetes, Machadobelba, Scheloribates and members of the Galumnidae, Dermanyssidae and Parasitidae. The community structure of mites was similar in the soil for
Treculia and Gliricidia plots and for Leucaena and Dactyladenia plots. There were more taxonomic groups of mites under Leucaena than in the other agroforestry plots. Based on the density, diversity and complexity of the mite communities, Leucaena was considered to be better than other agroforestry species in encouraging the growth of mite populations.
Received: 28 April 1998 相似文献
6.
Effect of solid waste compost on microbiological and physical properties of a burnt forest soil in field experiments 总被引:2,自引:0,他引:2
C. Guerrero I. Gómez J. Mataix Solera R. Moral J. Mataix Beneyto M. T. Hernández 《Biology and Fertility of Soils》2000,32(5):410-414
The restoration of soil microbial activities is a basic step in the reclamation of burnt soils. For this reason, the ability
of municipal solid waste compost to accelerate the re-establishment of bacterial and fungal populations, as well as to re-establish
physical properties in a burnt soil, was evaluated in a field experiment. Four treatments were performed by adding different
doses of compost (0, 0.5, 1 and 2 kg compost m–2 soil) to a burnt Calcic Rodoxeralf soil, and the changes in microbial populations, salt content, aggregate stability and
bulk density were evaluated for 1 year. Initially, the addition of compost had a negative effect on soil microbial populations,
but 3 months after compost addition, the number of viable fungal propagules increased in all the amended soils. This positive
effect lasted until the end of the experiment. From 30 days onwards, all the amended soils showed a greater total number of
bacterial cell forming units than the unamended burnt soil. Organic amendment increased the percentage of 2- to 4-mm aggregates,
although the effect on the stability of the 0.2- to 2-mm aggregates and on bulk density was less noticeable.
Received: 24 November 1999 相似文献
7.
We investigated whether, under a temperate climate and in a maize crop, earthworm casts could contribute to soil erosion
and further favour the exportation of phosphorus by runoff waters. Recording of casts was made in compacted (wheel-tracks)
and non-compacted inter-rows, for a 2-month period in spring. To assess the rainfall impact on cast evolution, half of the
observation sites were protected against rain splash by a nylon mesh placed above the soil surface. The water runoff was collected
and analysed for sediment contents and phosphorus concentration. The mean annual production of surface casts was calculated
to be 34 kg (dry weight) year–1 kg–1 earthworm (fresh weight). Synchronization between cast erosion and rainfall events was shown under natural conditions (unprotected
sites). The erosion rate was 4 times greater over rainy periods than dry ones, reaching 80% of cast numbers. It appeared that
not the runoff effect but the splash effect, due to the kinetics of the drops, disrupted casts. Newly formed casts disappeared
first, with the erosion rate decreasing twofold for casts more than 10 days old. Cast erosion and runoff, as well as worm
casting activity, were greater under compacted sites than under non-compacted sites, indicating an influence of earthworms
on soil erosion from compacted soils. The total phosphorus content was similar in casts and uningested soil (0.80 mg phosphorus
g–1). Potential phosphorus losses from cast erosion was calculated to reach 25–49 mg phosphorus m–2 per rainfall event depending on soil compaction. The amounts of particulate phosphorus recovered in water runoff after each
rainfall event varied from 1 mg to 11 mg phosphorus. These results are compared and discussed.
Received: 20 October 1998 相似文献
8.
Transformations and recovery of residue and fertilizer nitrogen-15 in a sandy Lixisol of West Africa
The fate of 15N-labeled plant residues from different cover-cropping systems and labeled inorganic N fertilizer in the organic, soil mineral,
microbial biomass and soil organic matter (SOM) particle-size fractions was investigated in a sandy Lixisol. Plant residues
were from mucuna (legume), lablab (legume), imperata (grass), maize (cereal) and mixtures of mucuna or lablab with imperata
or maize, applied as a surface mulch. Inorganic N fertilizer was applied as 15N-(NH4)2SO4 at two rates (21 and 42 mg N kg–1 soil). Total N release from mucuna or lablab residues was 2–3 times higher than from the other residues, whereas imperata
immobilized N throughout the study period. In contrast, 15N was mineralized from all the plant residues irrespective of the mineralization–immobilization pattern observed for total
N. After 168 days, 69% of soil mineral N in mucuna- or lablab-mulched soils was derived from the added residues, representing
4–8% of residue N, whereas 9–30% of inorganic N was derived from imperata, maize and the mixed residues. At the end of the
study, 4–19% of microbial biomass N was derived from the added residue/fertilizer-N, accounting for 1–3% of added residue-N.
Averaged across treatments, particulate SOM fractions accounted for less than 1% of the total soil by weight but contained
20% of total soil C and 8% of soil N. Soils amended with mucuna or lablab incorporated more N in the 250–2000 μm SOM pool,
whereas soil amended with imperata or the mixed residues incorporated similar proportions of labeled N in the 250–2000 μm
and 53–250 μm fractions. In contrast, in soils receiving the maize or inorganic fertilizer-N treatments, higher proportions
of labeled N were incorporated into the 53–250 μm than the 250–2000 μm fractions. The relationship between these differences
in residue/fertilizer-N partitioning into different SOM particle-size fractions and soil productivity is discussed.
Received: 12 March 1999 相似文献
9.
Soil structure and organic carbon relationships following 10 years of wheat straw management in no-till 总被引:6,自引:1,他引:6
Crop residue retention is important for sequestering soil organic carbon (SOC), controlling soil erosion, and improving soil quality. Magnitude of residue management impacts on soil structural properties and SOC sequestration is, however, site specific. This study assessed long-term (10 year) impacts of three levels (0, 8, and 16 Mg ha−1 on a dry matter basis) of wheat (Triticum aestivum L.) straw applied annually on SOC concentration and physical properties of the bulk soil and individual 5- to 8-mm aggregates for the 0- to 50-cm soil depth under no-till (NT) on a Crosby silt loam (fine, mixed, active, mesic Aeric Epiaqualfs) in central Ohio. This study also quantified relationships between soil properties and straw-induced changes in SOC concentration. Changes in soil properties due to straw mulching were mostly confined to the upper 5 cm of the soil. Mulching increased SOC concentration, but it did not significantly change cone index (CI) and shear strength (SHEAR). Within the upper 0–5-cm soil depth, mulching decreased bulk density (ρb) by 40–50%, aggregate density (ρagg) by 30–40%, and particle density (ρs) by 10–15%, and increased tensile strength (TS) of aggregates by up to 14 times as compared to unmulched soil. At the same depth, soil with mulch retained >30% more water than soil without mulch from 0 to −1500 kPa potentials. The SOC amount was 16.0 Mg ha−1 under no straw, 25.3 Mg ha−1 under 8 Mg ha−1 straw, and 33.5 Mg ha−1 under 16 Mg ha−1 straw in the 0- to 10-cm depth. Below 10 cm, differences in SOC pool between mulched and unmulched soil were not significant. Overall, SOC from 0- to 50-cm depth was 82.5 Mg ha−1 for unmulched soil, 94.1 Mg ha−1 for 8 Mg ha−1 mulch, and 104.9 Mg ha−1 for 16 Mg ha−1. About 33% of C added with straw over the 10-year period was sequestered in soil. This means that 2/3 of the wheat straw applied was not converted to SOC and most probably was lost as emissions of CO2 and CH4. The annual rate of total C accrual was 1.2 Mg ha−1 in soil mulched with 8 Mg ha−1 and 2.2 Mg ha−1 in soil mulched with 16 Mg ha−1 of straw in the 0- to 50-cm depth. The percentage of macroaggregates (>5-mm) was six times higher under 8 Mg ha−1 of straw and 12 times higher under 16 Mg ha−1 compared to unmulched treatments. Macroaggregates contained greater SOC than microaggregates in mulched soil. The SOC concentration explained the variability in aggregate properties by as much as 96%. Overall, long-term straw mulching increased SOC concentration and improved near-surface aggregate properties. 相似文献
10.
11.
G. Sparling L. A. Schipper G. W. Yeates J. Aislabie M. Vojvodic-Vukovic J. Ryburn H. J. Di A. E. Hewitt 《Biology and Fertility of Soils》2008,44(4):633-640
The chemical, physical and biological conditions of a New Zealand Gley Soil was examined on matched sites under long-term
permanent pasture or used to grow blackcurrants (Ribes nigrum) for 2, 8, 10 or 20 years. The chemical and physical conditions of topsoils (0–10 cm) were assessed by soil pH, Olsen P,
total C, total N, mineralisable N, cation exchange, bulk density, porosity and moisture release characteristics. The biological
conditions were assessed from the microbial biomass, soil respiration, catabolic evenness and numbers and diversity of the
soil nematode populations. The ability of the soil populations to degrade the triazine herbicide simazine was tested. The
particle size distribution confirmed all the sites were very well matched, within 2%, in terms of percentage clay, silt and
sand contents, which were 36.5–40.5% clay and 59.5–62.5% silt. Compared with the soil under pasture, that under horticultural
use for 2, 8, 10 and 20 years had lower total C and N, lower mineralisable N, lower cation exchange and lower porosity but
higher bulk density and particle density. The differences were greater the longer the plots had been under blackcurrant production.
Olsen P content was greatest (58 μg P cm−3) under the 20-year blackcurrant plots. Changes in biological characteristics were greater than in physical or chemical characteristics.
Microbial biomass was 1.73 mg C cm−3 under pasture and decreased to 0.87 mg C cm−3 after 20 years of blackcurrants. Total nematode populations deceased from 3.89 million m−2 under pasture to 0.36 million m−2 after 2 years of blackcurrant production and to 108 000 m−2 after 20 years. There were similar proportional decreases in bacterial-feeding, fungal-feeding, plant-feeding and omnivore
nematodes; however, there was comparatively little change in nematode diversity (Shannon–Weiner) or in microbial catabolic
diversity or soil respiration. Despite the decreased microbial biomass, the microbial community under blackcurrant production
had enhanced capacity to degrade simazine, as compared with the pasture soil. That capacity to degrade simazine was similar
in soils that had grown blackcurrants for 2, 8, 10 or 20 years. Yield of blackcurrants had been maintained in the longer-term
sites, despite the marked changes in soil chemical, physical and biological conditions. 相似文献
12.
Long-term experiments on different crop management systems provide essential information about turnover of soil organic matter
and changes in microbial properties over a period of time. A long-term field site trial, which was established in 1967 near
Vienna, Austria, to document the fate of 14C-labelled manure (straw and farmyard) under different crop management systems (crop rotation, spring wheat and bare fallow),
was investigated. Soil samples were taken in 1997 and separated into size fractions (>250 μm, 250–63 μm, 63–2 μm, 2–0.1 μm
and <0.1 μm) after aggregate dispersion using low-energy sonication. Organic C, total N and 14C content were measured in the bulk soil and the size fractions and microbial properties were analysed in the bulk soil. Additionally,
C mineralization in bulk soil samples was monitored at 20 °C over a period of 28 days, and subsequently 14C-CO2 content was analysed. The distribution of organic C and N within the size fractions was similar between crop rotation and
spring wheat; the highest amounts of organic C and N were found in the clay-sized fraction. The amounts of C and N were significantly
smaller in the bare fallow, which was depleted of organic matter in the coarse-sized fractions. 14C distribution differed significantly from unlabelled C distribution, labelled C was accumulated in the silt-sized fraction,
indicating weak humification of the applied manure C. The highest rate of C mineralization was measured in the crop rotation
and spring wheat, whereas the emission rate of the bare fallow was about 40% lower. The higher 14C:C ratio of the bulk soil in comparison to the emitted CO2 indicated that labelled C compounds still remained mineralizable after a period of 30 years. Microbial properties showed
a great difference between crop management systems and bare fallow, particularly regarding urease and xylanase activity.
Received: 31 May 1999 相似文献
13.
Nitrous oxide emission from wetland rice soil as affected by the application of controlled-availability fertilizers and mid-season aeration 总被引:5,自引:0,他引:5
N2O emission from a wetland rice soil as affected by the application of three controlled-availability fertilizers (CAFs) and
urea was investigated through a pot experiment. N2O fluxes from the N fertilized paddy soil averaged 44.8–69.3 μg N m–2 h–1 during the rice growing season, accounting for 0.28–0.51% of the applied N. The emission primarily occurred during the mid-season
aeration (MSA) and the subsequent re-flooding period. Fluxes were highly correlated with the NO3
– and N2O concentrations in the soil water. As there were relatively large amounts of NH4
+-N present in the soil of the CAF treatments at the beginning of MSA, leading to large amounts of NO3
–-N during the MSA and the subsequent re-flooding period, the tested CAFs were not effective in reducing N2O emission from this paddy soil. The potential of applied CAFs to reduce N2O emissions from paddy soil is discussed.
Received: 25 May 1999 相似文献
14.
Carbon and nitrogen dynamics in ageing earthworm casts in grasslands of the eastern plains of Colombia 总被引:5,自引:0,他引:5
The effects of a large species of anecic earthworm, Martiodrilus carimaguensis Jiménez and Moreno, on soil C and N dynamics were investigated in a native savanna and a man-made pasture of the eastern
plains of Colombia. We compared, across time (11 months), the total C, total N, NH+
4 and NO–
3 contents in the earthworm casts, the underlying soil and the adjacent soil. Additional sampling of root biomass and macrofauna
was performed. In the two management systems, the total C and N contents were higher in casts (4.33–7.50%) than in the bulk
soil (2.81–4.08%), showing that the earthworms selected food substrates with high organic contents. In general, C contents
significantly increased during cast ageing (+100%), possibly because of CO2 fixation processes, dead root accumulation and/or macrofaunal activities in casts. In fresh casts, NH+
4 levels were very high (294.20–233.98 μg g–1 dry cast) when compared to the soil (26.96–73.95 μg g–1 dry soil), due to the intense mineralisation processes that occurred during the transit of soil and organic matter through
the earthworm gut. During the first week of cast ageing, NH+
4 levels sharply decreased, while NH–
3 levels showed successive peaks in the casts, the underlying soil and the adjacent soil. These results suggested the rapid
production of NO–
3 by nitrification processes in the fresh casts, followed by diffusion to the nearby soil, first vertically, then horizontally.
After 2 weeks of cast ageing, NH+
4 and NO–
3 levels only showed slight variations, likely because of organic matter protection in stable dry casts. The root biomass was
higher (1.6–4.7 times) below the old earthworm casts. The ecological significance of these results is discussed.
Received: 22 October 1998 相似文献
15.
Larionova A. A. Yermolayev A. M. Blagodatsky S. A. Rozanova L. N. Yevdokimov I. V. Orlinsky D. B. 《Biology and Fertility of Soils》1998,27(3):251-257
Soil respiration was measured by closed chamber and gradient methods in soils under forest, sown meadow and crops. Annual
total soil respiration determined with the closed chamber method ranged from 180 to 642 g CO2-C m–2 year–1 and from 145 to 382 g CO2-C m–2 year–1 determined with the CO2 profile method. Soil respiration increased in the order: cropland<sown meadow<forest. The C balance calculated as the difference
between net primary production (sink) and respiration of heterotrophs (source) suggested an equilibrium between the input
and output of C in the cropland, and sequestration of 135 and 387 g CO2-C m–2 year–1 in the forest and meadow, respectively.
Received: 1 December 1997 相似文献
16.
A field experiment was conducted during 2003–2005 and 2004–2006 at the Indian Institute of Sugarcane Research, Lucknow, India
to study the effect of Trichoderma viride inoculation in ratoon sugarcane with three trash management practices, i.e. trash mulching, trash burning and trash removal.
Trichoderma inoculation with trash mulch increased soil organic carbon and phosphorus (P) content by 5.08 Mg ha−1 and 11.7 kg ha−1 over their initial contents of 15.75 Mg ha−1 and 12.5 kg ha−1, respectively. Soil compaction evaluated as bulk density in 0- to 15-cm soil layer, increased from 1.48 Mg m−3 at ratoon initiation (in April) to 1.53 Mg m−3 at harvest (in December) due to trash burning and from 1.42 Mg m−3 at ratoon initiation (in April) to 1.48 Mg m−3 at harvest (in December) due to trash mulching. The soil basal respiration was the highest during tillering phase and then
decreased gradually, thereafter with the advancement of crop growth. On an average, at all the stages of crop growth, Trichoderma inoculation increased the soil basal respiration over no inoculation. Soil microbial biomass increased in all plots except
in the plots of trash burning/removal without Trichoderma inoculation. The maximum increase (40 mg C kg−1 soil) in soil microbial biomass C, however, was observed in the plots of trash mulch with Trichoderma inoculation treatment which also recorded the highest uptake of nutrient and cane yield. On an average, Trichoderma inoculation with trash mulch increased N, P and K uptake by 15.9, 4.68 and 23.6 kg ha−1, respectively, over uninoculated condition. The cane yield was increased by 12.8 Mg ha−1 with trash mulch + Trichoderma over trash removal without Trichoderma. Upon degradation, trash mulch served as a source of energy for enhanced multiplication of soil bacteria and fungi and provided
suitable niche for plant–microbe interaction. 相似文献
17.
Ecological pre-release risk assessment of two genetically engineered, bioluminescent Rhizobium meliloti strains in soil column model systems 总被引:2,自引:0,他引:2
In order to identify potential ecological risks associated with the environmental release of two Rhizobium meliloti strains, genetically engineered with the firefly-derived luciferase gene (luc), a pre-release greenhouse investigation was conducted. The upper 4 cm of soil columns (30 cm diameter; 65 cm depth), which
were filled according to the horizons of an agricultural field (loamy sand), were inoculated with seeds of Medicago sativa (alfalfa) and R. meliloti cells at approximately 5×106 cells·g–1 soil. Four treatments were tested: inoculation with a non-engineered wild type strain (2011), strain L33 (luc
+), strain L1(luc
+, recA–) and non-inoculated controls. The fate of the engineered strains was followed by two methods: (1) selective cultivation and
subsequent detection of bioluminescent colonies and (2) PCR detection of the luc gene in DNA, directly extracted from soil. Strain R. meliloti L33 declined to 9.0×104 cfu·g–1 soil within 24 weeks and to 2.8×103 cfu·g–1 soil within 85 weeks in the upper 25 cm of the soil columns. Decline rates for R. meliloti L1 were not significantly different. Vertical distribution analysis of the recombinant cells after 37 weeks revealed that
in three of four columns tested, the majority of cells (>98%) remained above 10 cm soil depth and no recombinant cells occurred
below 20 cm depth. However, in one column all horizons below 20 cm were colonized with 2.2×104 to 6.8×104 cfu g–1 soil. Ecological monitoring parameters included organic substance, total nitrogen, ammonium and nitrate, microbial biomass,
culturable bacteria on four different growth media and the immediate utilization of 95 carbon sources (BiologGN) by soil-extracted
microbial consortia. None of the parameters was specifically affected by the genetically engineered cells.
Received: 6 December 1996 相似文献
18.
V. Acosta-Martínez Z. Reicher M. Bischoff R. F. Turco 《Biology and Fertility of Soils》1999,29(1):55-61
The influence of tree leaf amendment and N fertilization on soil quality in turfgrass environments was evaluated. Our objective
was to assess changes in soil quality after additions of leaf materials and N fertilization by monitoring soil chemical and
physical parameters, microbial biomass and soil enzymes. Established perennial ryegrass (Lolium perenne) plots were amended annually with maple (Acer spp.) leaves at three different rates (0, 2240, and 4480 kg ha–1 year–1) and treated with three nitrogen rates (0, 63, and 126 kg N ha–1 year–1). Tree leaf mulching did not significantly affect water infiltration or bulk density. However, trends in the data suggest
increased infiltration with increasing leaf application rate. Tree leaf mulching increased total soil C and N at 0–1.3 cm
depth but not at 1.3–9.0 cm. Extracted microbial phospholipid, an indicator of microbial biomass size, ranged from 28 to 68
nmol phospholipid g–1 soil at the 1.3–9.0 cm depth. The activity of β-glucosidase estimated on samples from 0–1.3 cm and 1.3–9.0 cm depths, and
dehydrogenase activity estimated on samples from 1.3–9.0 cm were significantly increased by leaf mulching and N fertilizer
application. Changes in microbial community composition, as indicated by phospholipid fatty acid methyl ester analysis, appear
to be due to seasonal variations and did not reflect changes due to N or leaf amendment treatments. There were no negative
effects of tree leaf mulching into turfgrass and early data suggest this practice will improve soil chemical, physical, and
biological structure.
Received: 10 December 1997 相似文献
19.
Changing role of cultivated land in the global carbon cycle 总被引:3,自引:0,他引:3
The carbon balance is ill defined for agricultural lands so that their role in global C balance cannot be accurately estimated.
Changes in agriculture in the last 50 years have resulted in a general increase in grain yields, total net annual production
(TNAP), and C input to the soil. Amounts of C returned annually with crop residues on Sanborn Field, one of the oldest experimental
fields in the United States, increased after 1950, and this was accompanied by C accumulation in soils. Under wheat monocrop
(with mineral fertilizer), C accumulated at a rate of 50 g m–2 year–1. A 3-year rotation (corn/wheat/clover) with manure and nitrogen applications sequestered 150 g m–2 year–1 of C. Total C balance for the wheat and corn production area in the United States, approximated on the basis of these rates,
indicates that at least 32 Tg C was sequestered annually during the last 40–50 years.
Received: 1 December 1997 相似文献
20.
Soil-released carbon dioxide from microbial biomass carbon in the cultivated soils of karst areas of southwest China 总被引:1,自引:0,他引:1
Soil microbial biomass and the emission of CO2 from the soil surface were measured in yellow soils (Ultisols) of the karst areas of southwest China. The soils are relatively
weathered, leached and impoverished, and have a low input of plant residues. The measurements were made for a 1-year period
and show a reciprocal relationship between microbial biomass and surface CO2 efflux. The highest (42.6±2.8 mg CO2-C m–2 h–1) and lowest (15.6±0.6 mg CO2-C m–2 h–1) CO2 effluxes are found in the summer and winter, respectively. The cumulative CO2 efflux is 0.24 kg CO2-C m–2 year–1. There is also a marked seasonal variation in the amount of soil microbial biomass carbon, but with the highest (644±71 μg
C g–1 soil) and lowest (270±24 μg C g–1 soil) values occurring in the winter and summer, respectively. The cumulative loss of soil microbial biomass carbon in the
top 10 cm of the soil was 608 μg C g–1 year–1 soil over 17 sampling times. The mean residence time of microbial biomass is estimated at 105 days, suggesting that the carbon
in soil microbial biomass may act as a source of the CO2 released from soils.
Received: 13 July 1999 相似文献