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1.
We consider the dynamic simulation model of landscapes proposed by Turner et al. (1993). In this model a landscape, represented by a square grid of 100×100 cells, is exposed to disturbances of a fixed size at random locations at specified time intervals. The affected area recovers through a series of seral stages and achieves a mature stage unless it is affected again by successive disturbances. Two non-dimensional parameters, determining the dynamics of the model, are T, the ratio of the disturbance interval to the time of recovery and S, the ratio of the size of the disturbance to the size of the landscape. The main outcomes of analysis are the means and standard deviations of the areas occupied by different seral stages. We show that these characteristics of the system can be calculated analytically. This facilitates the understanding of the results of the computer experiments, the analysis of the asymptotic behaviour of the system (for example when the disturbances become increasingly small but very frequent, T,S1) and of more complex regimes of external disturbances, e.g., of the combined effects on a landscape from several types of disturbances with different spatial and time scales. 相似文献
2.
Hierarchical relationships between landscape structure and temperature in a managed forest landscape 总被引:10,自引:1,他引:9
Saunders Sari C. Chen Jiquan Crow Thomas R. Brosofske Kimberley D. 《Landscape Ecology》1998,13(6):381-395
Management may influence abiotic environments differently across time and spatial scale, greatly influencing perceptions of fragmentation of the landscape. It is vital to consider a priori the spatial scales that are most relevant to an investigation, and to reflect on the influence that scale may have on conclusions. While the importance of scale in understanding ecological patterns and processes has been widely recognized, few researchers have investigated how the relationships between pattern and process change across spatial and temporal scales. We used wavelet analysis to examine the multiscale structure of surface and soil temperature, measured every 5 m across a 3820 m transect within a national forest in northern Wisconsin. Temperature functioned as an indicator – or end product – of processes associated with energy budget dynamics, such as radiative inputs, evapotranspiration and convective losses across the landscape. We hoped to determine whether functional relationships between landscape structure and temperature could be generalized, by examining patterns and relationships at multiple spatial scales and time periods during the day. The pattern of temperature varied between surface and soil temperature and among daily time periods. Wavelet variances indicated that no single scale dominated the pattern in temperature at any time, though values were highest at finest scales and at midday. Using general linear models, we explained 38% to 60% of the variation in temperature along the transect. Broad categorical variables describing the vegetation patch in which a point was located and the closest vegetation patch of a different type (landscape context) were important in models of both surface and soil temperature across time periods. Variables associated with slope and microtopography were more commonly incorporated into models explaining variation in soil temperature, whereas variables associated with vegetation or ground cover explained more variation in surface temperature. We examined correlations between wavelet transforms of temperature and vegetation (i.e., structural) pattern to determine whether these associations occurred at predictable scales or were consistent across time. Correlations between transforms characteristically had two peaks; one at finer scales of 100 to 150 m and one at broader scales of >300 m. These scales differed among times of day and between surface and soil temperatures. Our results indicate that temperature structure is distinct from vegetation structure and is spatially and temporally dynamic. There did not appear to be any single scale at which it was more relevant to study temperature or this pattern-process relationship, although the strongest relationships between vegetation structure and temperature occurred within a predictable range of scales. Forest managers and conservation biologists must recognize the dynamic relationship between temperature and structure across landscapes and incorporate the landscape elements created by temperature-structure interactions into management decisions. 相似文献
3.
The landscape ecology of large disturbances in the design and management of nature reserves 总被引:7,自引:0,他引:7
William L. Baker 《Landscape Ecology》1992,7(3):181-194
Large disturbances such as fires and floods are landscape processes that may alter the structure of landscapes in nature reserves. Landscape structure may in turn influence the viability of species and the functioning of ecosystems. Past reserve design and management strategies have been focussed on species and ecosystems rather than on landscape-scale processes, such as disturbance.An essential feature of a natural disturbance regime is the variation in disturbance attributes (e.g., size, timing, intensity, spatial location). Although some past reserve management policies have included natural disturbances, perpetuating disturbance variation has not been the explicit goal of either reserve design or management.To design a reserve to perpetuate the natural disturbance process requires consideration of: (1) the size of the reserve in relation to maximum expected disturbance size, (2) the location of the reserve in relation to favored disturbance initiation and export zones and in relation to spatial variation in the disturbance regime, and (3) the feasibility of disturbance control at reserve boundaries, or in reserve buffers.Disturbance management possibilities are constrained by the design of the reserve and the reserve goals. Where a natural disturbance regime is not feasible, then it is important that the managed disturbance regime mimic historical variation in disturbance sizes and other attributes as well as possible. Manipulating structure on the landscape scale to restore landscapes thought to have been altered by historical disturbance control is premature given our understanding of spatial disturbance processes in landscapes. 相似文献
4.
Effects of landscape structure on nest predation in roadsides of a midwestern agroecosystem: a multiscale analysis 总被引:1,自引:1,他引:0
Bergin Timothy M. Best Louis B. Freemark Kathryn E. Koehler Kenneth J. 《Landscape Ecology》2000,15(2):131-143
Nest predation is an important cause of mortality for many bird species, especially in grassland ecosystems where generalist predators have responded positively to human disturbance and landscape fragmentation. Our study evaluated the influence of the composition and configuration of the surrounding landscape on nest predation. Transects consisting of 10 artificial ground nests each were set up in 136 roadsides in six watersheds in south-central Iowa. Nest predation on individual roadside transects ranged from 0 to 100% and averaged 23%. The relationship of landscape structure within spatially-nested landscapes surrounding each roadside transect (within 200, 400, 800, 1200, and 1600 m of the transect line) to nest predation was evaluated by using multiple regression and canonical correlation analyses. The results of this multiscale landscape analysis demonstrated that predation on ground nests was affected by the surrounding landscape mosaic and that nest predators with different-sized home ranges and habitat affinities responded to landscapes in different ways. In general, wooded habitats were associated with greater nest predation, whereas herbaceous habitats (except alfalfa/pasture) either were associated with less nest predation or were not important. Different landscape variables were important at different spatial scales. Whereas some block-cover habitats such as woodland were important at all scales, others such as rowcrops and alfalfa/pasture were important at large scales. Some strip-cover habitats such as gravel roads and paved roads were important at small scales, but others such as wooded roadsides were important at all all scales. Most landscape metrics (e.g., mean patch size and edge density) were important at large scales. Our study demonstrated that the relationships between landscape structure and predator assemblages are complex, thus making efforts to enhance avian productivity in agricultural landscapes a difficult management goal. 相似文献
5.
William L. Baker 《Landscape Ecology》1995,10(3):143-159
The structure of landscapes subject to patch-forming catastrophic disturbances, or disturbance landscapes, is controlled by the characteristics of the disturbance regime, including the distribution of disturbance sizes and intervals, and the rotation time. The primary landscape structure in disturbance landscapes is the structure of the mosaic of disturbance patches, which can be described by indices such as patch size and shape.The purpose of this research was to use a geographical information system-based spatial model (DISPATCH) to simulate the effects of the initial density of patches on the rate of response to alteration of a disturbance regime, the effects of global warming and cooling, and the effects of fragmentation and restoration, on the structure of a generalized temperate-zone forested disturbance landscape over a period of 400 yr.The simulations suggest that landscapes require 1/2 to 2 rotations of a new disturbance regime to adjust to that regime regardless of the size and interval distributions. Thus alterations that shorten rotations, as would be the case if global warming increases fire sizes and decreases fire intervals, produce a more rapid response than do alterations that lengthen rotations, such as cooling and fire suppression. Landscape with long rotations may be in perpetual disequilibrium with their disturbance regimes due to a mismatch between their adjustment rate and the rate of climatic change. Landscapes with similar rotation times may have different structures, because size and interval distributions independently affect landscape structure. The response of disturbance landscapes to changing disturbance regimes is governed by both the number and size of patch births. 相似文献
6.
Short- and long-term patterns of net ecosystem carbon balance (NECB) for small, relatively uniform forest stands have been
examined in detail, but the same is not true for landscapes, especially those with heterogeneous disturbance histories. In
this paper, we explore the effect of two contrasting types of disturbances (i.e., fire and tree harvest) on landscape level
NECB by using an ecosystem process model that explicitly accounts for changes in carbon (C) stores as a function of disturbance
regimes. The latter were defined by the average disturbance interval, the regularity of the disturbance interval (i.e., random,
based on a Poisson frequency distribution, or regular), the amount of C removed by the disturbance (i.e., severity), and the
relative abundance of stands in the landscape with unique disturbance histories. We used the model to create over 300 hypothetical
landscapes, each with a different disturbance regime, by simulating up to 200 unique stand histories and averaging their total
C stores. Mean NECB and its year-to-year variability was computed by calculating the difference in mean total C stores from
one year to the next. Results indicated that landscape C stores were higher for random than for regular disturbance intervals,
and increased as the mean disturbance interval increased and as the disturbance severity decreased. For example, C storage
was reduced by 58% when the fire interval was shortened from 250 years to 100 years. Average landscape NECB was not significantly
different than zero for any of the simulated landscapes. Year-to-year variability in landscape NECB, however, was related
to the landscape disturbance regime; increasing with disturbance severity and frequency, and higher for random versus regular
disturbance intervals. We conclude that landscape C stores of forest systems can be predicted using the concept of disturbance
regimes, a result that may be a useful for adjusting estimates of C storage to broad scales that are solely based on physiological
processes. 相似文献
7.
Environmental,historical, and contextual determinants of vegetation cover: a landscape perspective 总被引:1,自引:1,他引:0
We formulated and tested models of relationships among determinants of vegetation cover in two agroforested landscapes of eastern North America (Haut Saint-Laurent, Quebec, Canada) that differed by the spatial arrangement of their geomorphic features and intensity of agricultural activities. Our landscape model compared the woody plots of each landscape in terms of the relative influence of environmental attributes, land use history (1958 – 1997), and spatial context (i.e., proximity of similar or contrasting land cover). Our vegetation model evaluated the relative contribution of the same sets of variables to the distributions of herbs, trees, and shrubs. Relationships were assessed using partial Mantel tests and path analyses. Significant environmental and contextual differences were found between the vegetation plots of the two landscapes, but disturbance history was similar. Our vegetation model confirms the dominant effect of historical factors on vegetation patterns. Whereas land-use history overrides environmental and contextual control for trees, herbaceous and shrub species are more sensitive to environmental conditions. Context is determinant only for understory species in older, less-disturbed plots. Results are discussed in relevance to vegetation dynamics in a landscape perspective that integrates interactions between environmental and human influences. 相似文献
8.
Víctor Arroyo-Rodríguez Iraida M. González-Perez Adriana Garmendia Mireia Solà Alejandro Estrada 《Landscape Ecology》2013,28(9):1717-1727
Land-use change is forcing many animal populations to inhabit forest patches in which different processes can threaten their survival. Some threatening processes are mainly related to forest patch characteristics, but others depend principally on the landscape spatial context. Thus, the impact of both patch and landscape spatial attributes needs to be assessed to have a better understanding of the habitat spatial attributes that constraint the maintenance of populations in fragmented landscapes. Here, we evaluated the relative effect of three patch-scale (i.e., patch size, shape, and isolation) and five landscape-scale metrics (i.e., forest cover, fragmentation, edge density, mean inter-patch isolation distance, and matrix permeability) on population composition and structure of black howler monkeys (Alouatta pigra) in the Lacandona rainforest, Mexico. We measured the landscape-scale metrics at two spatial scales: within 100 and 500 ha landscapes. Our findings revealed that howler monkeys were more strongly affected by local-scale metrics. Smaller and more isolated forest patches showed a lower number of individuals but at higher densities. Population density also tended to be positively associated to matrices with higher proportion of secondary forests and arboreal crops (i.e. with greater permeability), most probably because these matrices can offer supplementary foods. The immature-to-female ratio also increased with matrix permeability, shape complexity, and edge density; habitat characteristics that can increase landscape connectivity and sources availability. The prevention of habitat loss and isolation, and the increment of matrix permeability are therefore needed for the conservation of this endangered Neotropical mammal. 相似文献
9.
Agricultural soil redistribution and landscape complexity 总被引:2,自引:0,他引:2
A number of hypotheses and conceptual models, particularly those emphasizing nonlinear dynamics and self-organization, postulate increases or decreases in complexity in the evolution of drainage basins, topography, soils, ecosystems, and other earth surface systems. Accordingly, it is important to determine under what circumstances and at what scales either trend might occur. This paper is concerned with changes in soil landscape complexity due to redistribution of sediment by fluvial, aeolian, and tillage processes at historical time scales in an agricultural field system near Grifton, North Carolina. Soil mapping and soil stratigraphic investigations were used to identify and map soil changes associated with erosion and deposition by water, wind, and tillage; reconstruct the pre-agricultural soil pattern; and identify transformations between soil types. The Kolmogorov entropy of the pre- and post- agricultural landscapes was then compared. The soil transformations associated with erosion and deposition created four distinct new soils and made possible new transformations among soil series, increasing the number of soil types from seven to 11 and the number of possible transformations from 14 to 22. However, the entropy and complexity of the soil landscape decreased, with associated increases in information and redundancy. The mass redistributions created a lower-entropy landscape by concentrating particular soils and soil transformations in specific landscape settings. This result is contrary to studies showing a trend toward increasing pedological complexity at comparable spatial scales, but over much longer time scales. These results point to the importance of temporal scale, and to the fact that environmental complexity is influenced by factors other than the number of different landscape units present. 相似文献
10.
David M. Theobald 《Landscape Ecology》2010,25(7):999-1011
Quantifying landscape dynamics is a central goal of landscape ecology, and numerous metrics have been developed to measure
the influence of human activities on natural landscapes. Composite scores that characterize human modifications to landscapes
have gained widespread use. A parsimonious alternative is to estimate the proportion of a cover type (i.e. natural) within
a spatial neighborhood to characterize both compositional and structural aspects of natural landscapes. Here I extend this
approach into a multi-scale, integrated metric and apply it to national datasets on land cover, housing density, road existence,
and highway traffic volume to measure the dynamics of natural landscapes in the conterminous US. Roughly one-third of the
conterminous US (2.6 million km2) in 1992 was classified as human-dominated. By 2001 this expanded by 80,800 km2, and forecasted residential growth by 2030 will potentially lead to an additional loss of up to 92,200 km2. Wetland cover types were particularly affected. The natural landscapes metric developed here provides a simple, robust measure
of landscape dynamics that has a direct physical interpretation related to proportion of natural habitat affected at a location,
represents landscapes as a gradient of conditions rather predicated on patch/matrix definition, and measures the spatial context
of natural areas. 相似文献
11.
Cumulative effects of roads and logging on landscape structure in the San Juan Mountains,Colorado (USA) 总被引:11,自引:0,他引:11
In the southern Rocky Mountains of temperate North America, the effects of Euro-American activities on disturbance regimes and landscape patterns have been less ubiquitous and less straightforward in high-elevation landscapes than in low-elevation landscapes. Despite apparently little change in the natural disturbance regime, there is increasing concern that forest management activities related mainly to timber harvest and to the extensive network of roads constructed to support timber harvest, fire control, and recreation since the late 1800s have altered disturbance regimes and landscape structure. We investigated the magnitude of change in landscape structure resulting from roads and logging since the onset of timber harvest activities in 1950. We found limited evidence for significant impacts in our study area when all lands within the landscape were considered. The relatively minor changes we observed reflected the vast buffering capacity of the large proportion of lands managed for purposes other than timber (e.g., wilderness). Significant changes in landscape structure and fragmentation of mature forest were, however, evident on lands designated as suitable timberlands. Roughly half of the mature coniferous forest was converted to young stands; mean patch size and core area declined by 40% and 25%, respectively, and contrast-weighted edge density increased 2- to 3-fold. Overall, roads had a greater impact on landscape structure than logging in our study area. Indeed, the 3-fold increase in road density between 1950–1993 accounted for most of the changes in landscape configuration associated with mean patch size, edge density, and core area. The extent of area evaluated and the period over which change was evaluated had a large impact on the magnitude of change detected and our conclusions regarding the ecological significance of those changes. Specifically, the cumulative impact on landscape structure was negligible over a 10-year period, but was notable over a 40-year period. In addition, the magnitude of change in landscape structure between 1950–1993 varied as a function of landscape extent. At the scale of the 228000 ha landscape, change in landscape structure was trivial, suggesting that the landscape was capable of fully incorporating the disturbances with minimal impact. However, at intermediate scales of 1000–10000 ha landscapes, change in landscape structure was quite evident, suggesting that there may be an optimal range of scales for detecting changes in landscape structure within the study area. 相似文献
12.
The Hierarchical Patch Dynamics Paradigm provides a conceptual framework for linking pattern, process and scale in ecosystems,
but there have been few attempts to test this theory because most ecological studies focus on only one spatial scale, or are
limited in their temporal scope. Here I use palaeoecological techniques (analysis of fossil pollen and stable carbon isotopes)
to compare vegetation heterogeneity in an east African savanna at three spatial scales, over hundreds of years. The data show
that patterns of vegetation change are different at the three spatial scales of observation, and suggest that different ecological
processes dominate tree abundance at micro, local and landscape scales. Interactions between plants, disturbance (e.g., by
fire and herbivores), climate and soil type may influence tree density at differing spatial and temporal scales. This hierarchical
explanation of savanna vegetation dynamics could inform future biodiversity conservation and management in savannas.
This revised version was published online in July 2006 with corrections to the Cover Date. 相似文献
13.
Abtract Epidemiology models, modified to include landscape pattern, are used to examine the relative importance of landscape geometry
and disturbance dynamics in determining the spatial extent of a disturbance, such as a fire. The models indicate that, except
for very small values for the probability of spread, a disturbance tends to propagate to all susceptible sites that can be
reached. Therefore, spatial pattern, rather than disturbance dynamic, will ordinarily determine the total extent of a single
disturbance event. The models also indicate that a single disturbance will seldom become endemic,i.e., always present on the landscape. However, increasing disturbance frequency can lead to a landscape in which the proportion
of susceptible, disturbed, and recovering sites are relatively constant.
Research supported by Ecological Research Division, Office of Health and Environmental Research, U.S. Department of Energy
under contract No. DE-AC05-840R21400 with Martin Marietta Energy Systems, Inc. Contribution No. 10 to the Sevilleta LTER program.
Environmental Sciences Division Publication No. 3812, ORNL. 相似文献
14.
Detecting hot and cold spots in a seagrass landscape using local indicators of spatial association 总被引:1,自引:0,他引:1
Eelgrass (Zostera marina) is an important feature of coastal ecosystems in Atlantic Canada, providing a suite of valuable ecosystem services. These services, and its sensitivity to stressors, have prompted efforts to characterize the spatial and temporal dynamics of eelgrass landscapes in order to facilitate management and monitoring of coastal ecosystem health. Current methods for broad-scale mapping of eelgrass rely on aerial remote sensing and may not be appropriate in certain types of landscapes, particularly in turbid waters and areas lacking distinct boundaries. This study takes a novel approach to the quantification and analysis of seagrass landscape structure at multiple spatial scales using acoustic data and local spatial statistics. Data from a single-beam acoustic survey in Richibucto, New Brunswick, Canada were analyzed with geostatistical techniques and the Getis-Ord G i * local spatial statistic in order to detect statistically significant zones of high and low cover in an estuarine seagrass bed. Results showed distinct and significant patterns in seagrass cover at multiple spatial scales within a region of apparently continuous spatial cover. Boundaries between areas of high and low cover were also detected. This study demonstrates how acoustic data and local spatial statistics can be used to quantify landscape pattern and to further the application of landscape techniques in the marine environment. 相似文献
15.
Lindsey Gillson 《Landscape Ecology》2005,19(8):883-894
The Hierarchical Patch Dynamics Paradigm provides a conceptual framework for linking pattern, process and scale in ecosystems,
but there have been few attempts to test this theory because most ecological studies focus on only one spatial scale, or are
limited in their temporal scope. Here I use palaeoecological techniques (analysis of fossil pollen and stable carbon isotopes)
to compare vegetation heterogeneity in an east African savanna at three spatial scales, over hundreds of years. The data show
that patterns of vegetation change are different at the three spatial scales of observation, and suggest that different ecological
processes dominate tree abundance at micro, local and landscape scales. Interactions between plants, disturbance (e.g., by
fire and herbivores), climate and soil type may influence tree density at differing spatial and temporal scales. This hierarchical
explanation of savanna vegetation dynamics could inform future biodiversity conservation and management in savannas.
This revised version was published online in July 2006 with corrections to the Cover Date. 相似文献
16.
We developed a spatially-explicit gap dynamics simulation model to evaluate the effects of disturbances at the scale of a landscape for a semiarid grassland in northcentral Colorado, USA. The model simulates the establishment, growth, and death of individual plants on a small plot through time at an annual time step. Long-term successional dynamics on individual plots (single gaps) and on a landscape composed of a grid of plots were evaluated. Landscapes were simulated as either a collection of independent plots or as a collection of interacting plots where processes on one plot were influenced by processes on adjacent plots. Because we were interested in the recovery of the dominant plant species, the perennial grass blue grama (Bouteloua gracilis (H.B.K.) Lag. ex Griffiths) after disturbances, we focused on scale-dependent processes, such as seed dispersal, that are important to the recruitment of individuals of B. gracilis.
The type of simulated landscape was important to the recovery time of B. gracilis after a disturbance. Landscapes composed of independent plots recovered more rapidly following a disturbance than landscapes composed of interacting plots in which the recovery time was dependent on the spatial scale of the disturbance. 相似文献
17.
Noémie Schaller El Ghali Lazrak Philippe Martin Jean-François Mari Christine Aubry Marc Benoît 《Landscape Ecology》2012,27(3):433-446
Landscape spatial organization (LSO) strongly impacts many environmental issues. Modelling agricultural landscapes and describing
meaningful landscape patterns are thus regarded as key-issues for designing sustainable landscapes. Agricultural landscapes
are mostly designed by farmers. Their decisions dealing with crop choices and crop allocation to land can be generic and result
in landscape regularities, which determine LSO. This paper comes within the emerging discipline called “landscape agronomy”,
aiming at studying the organization of farming practices at the landscape scale. We here aim at articulating the farm and
the landscape scales for landscape modelling. To do so, we develop an original approach consisting in the combination of two
methods used separately so far: the identification of explicit farmer decision rules through on-farm surveys methods and the
identification of landscape stochastic regularities through data-mining. We applied this approach to the Niort plain landscape
in France. Results show that generic farmer decision rules dealing with sunflower or maize area and location within landscapes
are consistent with spatiotemporal regularities identified at the landscape scale. It results in a segmentation of the landscape,
based on both its spatial and temporal organization and partly explained by generic farmer decision rules. This consistency
between results points out that the two modelling methods aid one another for land-use modelling at landscape scale and for
understanding the driving forces of its spatial organization. Despite some remaining challenges, our study in landscape agronomy
accounts for both spatial and temporal dimensions of crop allocation: it allows the drawing of new spatial patterns coherent
with land-use dynamics at the landscape scale, which improves the links to the scale of ecological processes and therefore
contributes to landscape ecology. 相似文献
18.
In the last few years, landscape researchers have sought to understand temporal and spatial patterns of landscape changes in order to develop comprehensive models of land cover dynamics. To do so, most studies have used similar methods to quantify structural patterns, usually by comparing various landscape structural indices through time. Whereas the necessity for complementary approaches which might provide insights into landscape dynamics at some finer scale relevant to local managers has been expressed, few studies have proposed alternative methodologies. Moreover, the important relationship between the physical constraints of the landscape and land use dynamics has been seldom emphasized. Here we propose a methodological outline which was applied to the study of a rural landscape of Southern Quebec, Canada, to detect spatial and temporal (1958 to 1993) patterns of land cover changes at field, patch and landscape level. We then relate these patterns to the underlying physical structure of landscape elements using GIS and canonical correspondence analyses. We use the different geomorphological deposit types as stable discriminant factors which may constrain land use.Canonical correspondence analyses showed relations of land use and land use changes to the physical attributes of the landscape elements, whereas spatial analyses revealed very dynamic patterns at finer spatial and temporal scales. They highlighted the fact that not only the physical attributes of the landscape elements but also their spatial configuration were important determinants of land use dynamics in this area. Thus more land use changes occurred at the boundary between geomorphological deposit types than in any other locations. This trend is apparent for specific small-size changes (e.g. forest to crop), but not for the large-size ones (e.g. abandoned land to forest). Although land use changes are triggered by socioeconomic forces in this area, these changes are nevertheless constrained by the underlying physical landscape structure. A thorough comprehension of historical changes will enhance our capability to predict future landscape dynamics and devise more effective landscape management strategies. 相似文献
19.
Michael C. Wimberly 《Landscape Ecology》2006,21(1):35-46
Although landscape ecology emphasizes the effects of spatial pattern on ecological processes, most neutral models of species–habitat relationships have treated habitat as a static constraint. Do the working hypotheses derived from these models extend to real landscapes where disturbances create a shifting mosaic? A spatial landscape simulator incorporating vegetation dynamics and a metapopulation model was used to compare species in static and dynamic landscapes with identical habitat amounts and spatial patterns. The main drivers of vegetation dynamics were stand-replacing disturbances, followed by gradual change from early-successional to old-growth habitats. Species dynamics were based on a simple occupancy model, with dispersal simulated as a random walk. As the proportion of available habitat (p) decreased from 1.0, species occupancy generally declined more rapidly and reached extinction at higher habitat levels in dynamic than in static landscapes. However, habitat occupancy was sometimes actually higher in dynamic landscapes than in static landscapes with similar habitat amounts and patterns. This effect was most pronounced at intermediate amounts of habitat (p = 0.3?0.6) for mobile species that had high colonization rates, but were unable to cross non-habitat patches. Differences between static and dynamic landscapes were contingent upon the initial metapopulation size and the shapes of disturbances and the resulting habitat patterns. Overall, the results demonstrate that dispersal-limited species exhibit more pronounced critical behavior in dynamic landscapes than is predicted by simple neutral models based on static landscapes. Thus, caution should be exercised in extending generalizations derived from static landscape models to disturbance-driven landscape mosaics. 相似文献
20.
Spatial and temporal analysis of landscape patterns 总被引:89,自引:0,他引:89
Monica G. Turner 《Landscape Ecology》1990,4(1):21-30
A variety of ecological questions now require the study of large regions and the understanding of spatial heterogeneity. Methods
for spatial-temporal analyses are becoming increasingly important for ecological studies. A grid cell based spatial analysis
program (SPAN) is described and results of landscape pattern analysis using SPAN are presentedd. Several ecological topics
in which geographic information systems (GIS) can play an important role (landscape pattern analysis, neutral models of pattern
and process, and extrapolation across spatial scales) are reviewed. To study the relationship between observed landscape patterns
and ecological processes, a neutral model approach is recommended. For example, the expected pattern (i.e., neutral model) of the spread of disturbance across a landscape can be generated and then tested using actual landscape data
that are stored in a GIS. Observed spatial or temporal patterns in ecological data may also be influenced by scale. Creating
a spatial data base frequently requires integrating data at different scales. Spatial is shown to influence landscape pattern
analyses, but extrapolation of data across spatial scales may be possible if the grain and extent of the data are specified.
The continued development and testing of new methods for spatial-temporal analysis will contribute to a general understanding
of landscape dynamics. 相似文献