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Small population size

Small population size refers to a condition in which a biological population consists of a limited number of individuals, typically fewer than 100 or even as low as 10–100 in introduced or fragmented contexts, making it particularly susceptible to extinction risks due to amplified stochastic processes and reduced genetic variability.^[1]^[2] This phenomenon often arises from population bottlenecks, where a once-larger group is drastically reduced by events such as habitat destruction, hunting, or disease, or from founder effects, in which a new population is established by a small subset of individuals from the original group, as seen in cases like the Northern elephant seals reduced to about 20 individuals in the late 19th century due to overhunting.^[3]^[2] In population genetics and ecology, small size heightens the impact of genetic drift, the random fluctuation of allele frequencies that leads to a rapid loss of genetic diversity, potentially causing inbreeding depression—a decline in fitness from mating between close relatives—and limiting adaptability to environmental changes.^[3]^[2] For instance, an effective population size (Ne) of 100 may result in the loss of only about 5% of genetic diversity over 10 generations, but at Ne = 2, up to 95% could be lost, underscoring how even modest reductions can trigger long-term vulnerabilities.^[2] Additionally, demographic stochasticity introduces variability in birth, death, and sex ratios, while environmental stochasticity—such as unpredictable weather or catastrophes—can push small groups into an extinction vortex, a feedback loop of declining numbers and fitness.^[2] Ecological models further highlight the Allee effect, a positive density-dependence where per capita growth rates decline at low densities due to factors like mate-finding difficulties, creating an Allee threshold below which extinction becomes inevitable without intervention.^[1] Examples include Speke’s gazelle in captive breeding programs, where inbreeding reduced reproductive success, and African wild dogs, affected by cooperative hunting failures in small packs.^[2] In conservation biology, managing small populations involves strategies like maintaining minimum viable population sizes—often guided by the "50/500 rule" (with subsequent revisions suggesting higher thresholds) for short- and long-term genetic health—and translocation to boost diversity, emphasizing the critical role of habitat connectivity and threat mitigation to prevent irreversible losses.^[2]^[4]

Definition and Measurement

Criteria for Identifying Small Populations

In ecological and biological contexts, a small population is conceptually defined as one with an effective population size (Ne) below thresholds that compromise short-term viability and long-term evolutionary potential. The effective population size, Ne, represents the size of an idealized population that experiences the same rate of genetic drift or inbreeding as the actual population under study, often much smaller than the census population size (Nc), which is simply the total number of individuals counted.^[5] This distinction is crucial because Ne accounts for factors like unequal sex ratios, variance in reproductive success, and overlapping generations, which reduce the genetically effective breeding portion of the population.^[6] A seminal guideline, known as the 50/500 rule, posits that Ne should exceed 50 to avoid immediate risks from inbreeding depression and 500 to maintain sufficient genetic diversity for adaptation over evolutionary timescales.^[7] This rule originated from theoretical considerations of genetic drift and was independently proposed by Franklin and Soulé in their foundational chapters on conservation biology.^[8] Qualitative criteria for identifying small populations extend beyond Ne to include absolute numbers of individuals, often considered small if fewer than 100 mature organisms, as this scale heightens vulnerability to stochastic events.^[9] Such thresholds are contextualized relative to the species' habitat capacity, where a population is deemed small if it occupies a fraction of the available carrying capacity (K), limiting resilience to environmental fluctuations.^[10] These criteria emphasize not just raw counts but the population's capacity to persist without significant loss of fitness, distinguishing small populations from larger ones that buffer against demographic imbalances. The concept of small population size evolved from early 20th-century wildlife management practices, which addressed overhunting and habitat loss through initial regulations like bag limits and refuges, recognizing that populations below sustainable harvest levels faced collapse.^[11] By the mid-20th century, this shifted toward genetic and demographic frameworks in conservation biology, culminating in modern assessments like the IUCN Red List, where small populations are flagged as threatened if mature individuals number under 250 (Endangered) or 50 (Critically Endangered), integrating size with decline rates and fragmentation.^[9] These criteria underpin evaluations of extinction risk, where small size amplifies susceptibility to perturbations.^[12]

Quantitative Indicators and Thresholds

Quantitative indicators for assessing small population size in conservation biology primarily revolve around two key metrics: the census population size (N), which represents the total number of individuals in a population, and the effective population size (Ne), which accounts for the population's genetic and demographic dynamics by estimating the size of an idealized population that would experience the same rate of genetic drift or inbreeding as the actual population.^[5] Census size N is typically estimated through direct counts or sampling methods and serves as a baseline measure of abundance, but it often overestimates the population's evolutionary potential due to factors like unequal sex ratios or reproductive variance.^[13] The effective population size Ne is calculated differently depending on the context, with the inbreeding effective size for dioecious species given by the formula:

N_e = \frac{4 N_m N_f}{N_m + N_f}

where N_m is the number of breeding males and N_f is the number of breeding females; this formula highlights how deviations from equal sex ratios reduce Ne relative to N.^[5] The ratio Ne/N provides a critical indicator of vulnerability, with values below 0.1 signaling severe reductions in genetic effective size due to demographic stochasticity, often placing populations at heightened risk of genetic erosion.^[14] Monitoring these metrics involves established techniques such as capture-mark-recapture (CMR) for estimating census size N, which uses sequential sampling to model population abundance while accounting for detection probabilities.^[15] For Ne, genetic sampling analyzes temporal changes in allele frequencies across generations, enabling indirect estimation through methods like the temporal F-statistics approach.^[16] Demographic modeling software, such as VORTEX, integrates these data into stochastic simulations to project Ne under various scenarios, incorporating vital rates like survival and reproduction to forecast long-term viability. Thresholds for classifying populations as small have evolved since the 1980s, when seminal work proposed the 50/500 rule—suggesting a minimum Ne of 50 to avoid short-term inbreeding depression and 500 for long-term evolutionary potential.^[17] Modern standards, as outlined in IUCN Red List criteria, designate populations with fewer than 50 mature individuals under Criterion D as Critically Endangered, emphasizing immediate conservation needs based on empirical decline rates.^[18] These indicators can signal early entry into an extinction vortex by quantifying when demographic and genetic thresholds are breached.^[19]

Biological and Demographic Effects

Population Dynamics and Extinction Risk

Small populations are particularly susceptible to altered population dynamics due to positive density dependence, known as Allee effects, where per capita growth rates decline at low densities, often leading to negative growth and heightened extinction risk.^[20] In strong Allee effects, populations fall below a critical threshold density, resulting in inevitable decline unless supplemented; a classic component Allee effect arises from mate-finding failure, as seen in lekking species like greater prairie chickens (Tympanuchus cupido), where isolated males fail to attract females, reducing reproductive success and amplifying extinction probabilities in fragmented habitats.^[21] These effects contrast with typical negative density dependence, making recovery from low numbers challenging without intervention. Stochastic processes further exacerbate extinction risks in small populations through demographic and environmental variability. Demographic stochasticity refers to random variations in individual birth and death events, which generate greater relative fluctuations in small groups due to sampling variance, potentially driving populations to zero even under stable average vital rates.^[22] Environmental stochasticity, by contrast, involves unpredictable fluctuations in population-level rates caused by external factors like annual weather variations, which can synchronize declines across years and disproportionately impact small populations by preventing rebound from low points.^[22] Models incorporating these stochasticities, such as birth-death processes, demonstrate that extinction probability rises sharply as population size decreases, with populations below roughly 50–100 individuals often at high risk for many species.^[2] The extinction vortex, conceptualized by Gilpin and Soulé (1986), describes a self-reinforcing feedback loop where declining population size intensifies demographic, environmental, and other risks, accelerating collapse.^[23] As numbers dwindle, stochastic events become more probable, pulling the population into a downward spiral; genetic factors may contribute briefly by reducing fitness, but the core dynamics stem from numerical declines.^[24] Stochastic models approximate this risk with the equation for cumulative extinction probability over time t:

P(\text{[extinction](/page/Extinction)}) \approx 1 - e^{-t / \tau}

where \tau represents the mean time to extinction, derived from diffusion approximations of population trajectories under variance in growth rates.^[22] This framework underscores the urgency of maintaining populations above critical sizes to avert the vortex.

Reproductive and Survival Challenges

In small populations, mating system disruptions often arise from reduced mate availability, leading to delayed reproduction and altered mating behaviors. For instance, in African elephants (Loxodonta africana), poaching has skewed adult sex ratios toward females by selectively removing tusked males, resulting in fewer mature males available for mating and potential Allee effects from mate location difficulties in species with promiscuous or polygynous systems.^[25] Survival rates in small populations decline due to heightened per capita risks from predation and inefficient resource competition. In gray wolves (Canis lupus), small packs struggle with territorial defense against larger rival packs, leading to higher rates of intraspecific mortality as intruders successfully challenge and evict smaller groups, often resulting in the death or dispersal of pack members.^[26] Consequently, small wolf packs experience elevated mortality from inter-pack conflicts, with death by rivals accounting for the majority of natural losses, thereby reducing overall population persistence.^[27] Age structure imbalances, such as skewed sex ratios or disproportionate age classes, frequently emerge from stochastic demographic events in small populations, hindering long-term viability. Such stochastic distortions in age and sex structure underscore the vulnerability of small populations to chance perturbations.

Genetic Consequences

Genetic Drift and Allele Loss

Genetic drift refers to the random fluctuations in allele frequencies within a population due to sampling error during the transmission of alleles from one generation to the next. In small populations, this process is particularly pronounced because the finite number of individuals amplifies chance deviations, leading to greater variance in allele frequency changes. The variance in the change of allele frequency (Δp) per generation is given by Δp = p(1-p)/(2N_e), where p is the initial allele frequency and N_e is the effective population size. Bottleneck and founder effects represent extreme manifestations of genetic drift, where a rapid and severe reduction in effective population size (N_e) occurs, such as during a demographic crash or the establishment of a new population from a small number of colonizers. These events accelerate the fixation or loss of alleles by chance, drastically curtailing genetic variation. For instance, the cheetah (Acinonyx jubatus) experienced a population bottleneck approximately 10,000 years ago, resulting in near-genetic uniformity and average heterozygosity levels of 0.0004–0.014 across loci.^[28]^[29] The primary consequences of genetic drift in small populations include the homogenization of the gene pool through allele fixation or loss, which diminishes overall genetic diversity and erodes the population's adaptive potential to environmental changes. This loss of variation is quantified by the expected decline in heterozygosity over time, expressed as H_t = H_0 \left(1 - \frac{1}{2N_e}\right)^t, where H_t is heterozygosity at generation t, H_0 is initial heterozygosity, and t is the number of generations. Such reductions can interact with inbreeding processes by limiting mate choices and available alleles, further compounding genetic threats.^[30]

Inbreeding Depression and Reduced Diversity

In small populations, mating among close relatives increases the probability that offspring inherit identical copies of deleterious recessive alleles from both parents, leading to elevated homozygosity and the expression of harmful genetic variants. This process, known as inbreeding, quantifies the deviation from random mating through the inbreeding coefficient F, defined as F = 1 - \frac{H_o}{H_e}, where H_o is the observed heterozygosity and H_e is the heterozygosity expected under Hardy-Weinberg equilibrium. As F increases, fitness components such as survival and reproduction decline due to partial dominance effects, where mildly deleterious alleles become more impactful when homozygous.^[31] Inbreeding depression manifests in reduced hybrid vigor (heterosis), where inbred individuals exhibit lower performance compared to outbred counterparts, often through decreased fertility, smaller litter sizes, and impaired immune function. A prominent example is the Florida panther (Puma concolor coryi), where pre-1995 inbreeding in a population of fewer than 30 individuals resulted in widespread congenital abnormalities, poor sperm quality, and elevated juvenile mortality rates, contributing to an overall fitness reduction estimated at 20-50% in key traits like survival to adulthood. Translocation of eight unrelated individuals from Texas in 1995 alleviated these effects, increasing kitten survival and population growth by introducing genetic variation that masked deleterious alleles; a 2025 study confirmed the population had grown to 120-230 individuals by 2023, with heterozygosity increasing nearly threefold and reduced homozygosity without swamping ancestral genotypes.^[32]^[33] Reduced genetic diversity in small populations further exacerbates vulnerability, with metrics like allelic richness—the number of alleles per locus, standardized for sample size—serving as a key indicator of adaptive potential. Lower allelic richness limits the raw material for natural selection, hindering responses to environmental changes such as disease outbreaks or climate shifts. However, in some cases, prolonged inbreeding can lead to purging, where strongly deleterious recessive alleles are selected against and removed from the gene pool, potentially mitigating future depression; for instance, Channel Islands foxes (Urocyon littoralis) show low inbreeding depression despite minimal diversity, attributed to historical purging of lethals that enabled persistence at effective population sizes below 100. This purging effect, while beneficial short-term, does not fully restore adaptability if diversity remains critically low, and recent 2023 analyses indicate ongoing risks from extremely low genetic variation, such as increased vulnerability to novel pathogens.^[34]^[35]

Environmental and Ecological Impacts

Vulnerability to Habitat Changes

Small populations face heightened vulnerability to habitat fragmentation, as the creation of edges in smaller, isolated patches exposes organisms to altered microclimates and increased environmental stress. Edge effects often result in drier, warmer conditions that promote desiccation, particularly affecting amphibians with permeable skin and low mobility, leading to reduced survival and reproduction in fragmented landscapes. For example, in tropical forests, amphibian species distributions are strongly influenced by desiccation resistance in fragmented landscapes.^[36] Similarly, studies in western Ecuador have shown that forest edges become significantly hotter, potentially affecting desiccation-sensitive amphibian species.^[37] Stochastic environmental events, such as volcanic eruptions, floods, or wildfires, pose an existential threat to small populations by potentially eradicating entire groups in a single occurrence. These catastrophes disproportionately impact localized, low-density populations with limited dispersal abilities, amplifying extinction risk through direct mortality and habitat destruction. A prominent case is the 1980 eruption of Mount St. Helens, which devastated small mammal communities in the surrounding area; of the 32 species present, only 14 survived the initial blast, with survivors facing ongoing challenges from ash burial and landscape alteration that hindered recolonization.^[38] Long-term monitoring revealed that pocket gophers and deer mice were among the few resilient species, but overall community recovery was slow due to the initial population bottlenecks.^[39] Reductions in carrying capacity from pollution and land-use changes further compound risks for small populations, as even minor environmental perturbations can push them beyond viability thresholds. In systems with small effective population sizes (Ne), such as coral reef fish assemblages, anthropogenic stressors like urban runoff and wastewater discharge degrade habitat quality, limiting resources and intensifying density-dependent effects. For instance, marine fish populations near densely populated coastal areas exhibit significantly lower Ne and genetic diversity, as land-use intensification reduces reef habitat and amplifies pollution impacts, leading to stalled recovery.^[40] This vulnerability is evident in the Great Barrier Reef, where pollution from agricultural land-use has decreased carrying capacity for herbivorous fish, altering ecosystem dynamics and hindering resilience to additional pressures.^[41]

Interactions with Predators and Competitors

In small populations, interactions with predators often intensify through apparent competition, an indirect negative effect where shared predators subsidized by abundant alternative prey increase pressure on rarer species, leading to overexploitation. This dynamic arises because predators respond numerically and functionally to increases in preferred prey, elevating attack rates on less common victims even if the latter are not directly preferred.^[42] Competitive exclusion poses another threat to small populations, where low densities hinder defense of ecological niches against invaders or aggressive native species, allowing the latter to monopolize resources. In avian communities, small flocks of native birds struggle to maintain positions in mixed-species foraging groups when confronted by aggressive competitors like the noisy miner (Manorina melanocephala), which uses vocal and physical aggression to displace smaller species from food-rich patches in fragmented woodlands.^[43] This exclusion is exacerbated by reduced flock sizes, which lower collective vigilance and territorial assertion, enabling invaders to dominate and push natives toward suboptimal habitats.^[44] Consequently, small bird populations experience restricted access to breeding and feeding sites, intensifying resource scarcity. Trophic cascades are amplified when small keystone populations fail to regulate lower trophic levels, disrupting ecosystem structure and magnifying indirect effects across food webs. Sea otters (Enhydra lutris), as keystone predators, exemplify this: in areas with small populations like San Nicolas Island, otters exert insufficient predation on sea urchins (Strongylocentrotus spp.), allowing urchin densities to persist at intermediate levels that prevent full kelp forest (Macrocystis pyrifera) recovery and weaken overall cascade strength by 20-30%.^[45] In contrast, larger otter populations rapidly deplete urchins, restoring kelp-dominated habitats and biodiversity. This regulatory failure in small groups propagates imbalances, such as urchin barrens that reduce habitat for fish and invertebrates, underscoring how diminished keystone influence destabilizes marine communities. These predatory and competitive pressures contribute to broader demographic survival declines in small populations.

Special Cases and Examples

Island and Isolated Populations

Island biogeography theory, developed by Robert H. MacArthur and Edward O. Wilson in 1967, posits that the number of species on an island reaches a dynamic equilibrium determined by the balance between immigration rates from mainland source pools and extinction rates within the island community.^[46] Small and isolated islands experience lower immigration due to greater distances from continental sources and higher extinction risks owing to limited habitat area and resources, which favors the persistence of endemic species adapted to unique conditions.^[46] The Galápagos finches exemplify this dynamic, where isolation on remote oceanic islands has driven adaptive radiation and the evolution of multiple endemic species from a common ancestor, with small populations enhancing speciation through reduced gene flow.^[47] In isolated island environments, relaxed natural selection pressures—such as reduced predation, competition, and resource scarcity—often lead to evolutionary shifts in body size, manifesting as insular gigantism in small-bodied taxa or dwarfism in larger ones, a pattern known as Foster's rule. For instance, Komodo dragons (Varanus komodoensis) on the Indonesian islands represent insular dwarfism, having evolved to smaller sizes than their larger mainland varanid ancestors (such as Megalania prisca) due to limited resources and isolation in their habitats.^[48]^[49] These size alterations highlight how small population sizes in isolation amplify directional selection and genetic drift, intensifying evolutionary divergence from mainland forms. Human activities exacerbate isolation in island populations, including through habitat fragmentation via deforestation or barriers like dams, and increasingly through climate-driven sea level rise that submerges low-lying areas and restricts dispersal.^[50] Rising seas threaten to isolate remaining populations on atolls and small islands by flooding intertidal zones critical for movement and gene exchange, potentially increasing extinction risks for endemics.^[51] A notable recovery case is the Seychelles warbler (Acrocephalus sechellensis), whose population dwindled to an effective size of approximately 26 individuals on Cousin Island in the 1960s due to human-induced habitat loss, yet rebounded to over 2,500 birds across multiple islands as of 2019 following targeted conservation translocations that restored connectivity.^[52]^[53]

Fragmented Mainland Populations

Fragmented mainland populations arise when continuous continental habitats are divided by human-induced barriers such as urbanization, roads, and agricultural expansion, creating isolated patches that disrupt natural dispersal and lead to small, vulnerable subpopulations. Unlike fully isolated island systems, these fragments may retain some potential for connectivity, but barriers often prevent effective gene flow and recolonization, elevating extinction risks through demographic isolation. This fragmentation transforms once-panmictic populations into metapopulations where local dynamics dominate, often resulting in asynchronous extinctions without external support. In metapopulation dynamics, fragmented mainland habitats frequently exhibit source-sink models, where high-quality "source" patches produce surplus individuals that could colonize "sink" patches with poor reproductive success, but dispersal failure due to barriers prevents this balance. For the California gnatcatcher (Polioptila californica), urban sprawl in southern California has fragmented coastal sage scrub habitats into discrete patches, leading to source-sink imbalances where sink populations experience net emigration without sufficient immigration to offset local declines. A habitat-based metapopulation model demonstrated that under current fragmentation, the probability of regional persistence drops significantly if dispersal rates fall below 1-2% between patches, highlighting how urban development exacerbates small population vulnerabilities. Gene flow barriers like roads and agricultural fields further isolate mainland fragments by reducing migration, causing a breakdown in panmixia and increasing genetic differentiation among subpopulations. In the case of the Florida panther (Puma concolor coryi), extensive road networks and agricultural conversion in southern Florida have subdivided the remaining habitat into isolated cores, limiting natural dispersal and resulting in low gene flow between subpopulations. Long-term monitoring shows that these barriers contribute to effective population sizes around 60 individuals as of 2024, due to disrupted connectivity.^[54]^[55] The absence of rescue effects—immigration that replenishes declining fragments—amplifies extinction risks in peripheral or low-quality mainland patches, as isolated subpopulations cannot recover from stochastic events without external colonists. For the Northern spotted owl (Strix occidentalis caurina), long-term studies across fragmented old-growth forests in the Pacific Northwest reveal higher local extinction risks where dispersal is curtailed by logging-induced barriers, lacking the demographic rescue observed in more connected core areas. Meta-analyses of 25+ years of demographic data indicate population declines of 6-9% annually in some areas.^[56]

Conservation Implications

Population Viability Assessment

Population viability assessment (PVA) is a suite of analytical methods used to evaluate the long-term survival prospects of small populations by estimating the probability of extinction under various scenarios. These assessments typically employ stochastic models that account for demographic variability, environmental fluctuations, and genetic factors to predict outcomes such as quasi-extinction, defined as the population falling below a critical threshold where recovery becomes unlikely.^[57] PVA frameworks often utilize individual-based models (IBMs), which simulate the life histories of individual organisms to integrate demographics, genetics, and environmental influences, allowing for detailed projections of population trajectories. For instance, software like RAMAS Metapop facilitates metapopulation modeling by incorporating spatial structure and outputting quasi-extinction probabilities based on Monte Carlo simulations of stochastic events. These models can briefly reference the incorporation of genetic diversity metrics, such as inbreeding coefficients, to assess cumulative risks over time, and modern approaches increasingly integrate climate change projections and genomic data for improved accuracy.^[58]^[59]^[57] A key parameter in PVA is the minimum viable population (MVP), defined as the smallest population size that ensures a high probability of persistence, often set at 95% survival over 100 years or 99% over 40 generations. For mammals, MVP estimates typically range from 1,000 to 5,000 individuals to maintain viability against stochastic threats, though these vary by species life history and environmental context.^[60] Despite their utility, PVA methods face limitations due to over-reliance on assumptions about parameter values and model structures, which can lead to inaccurate predictions if input data are sparse or unreliable. A meta-analysis of 102 vertebrate populations highlighted this variability, finding median MVP sizes around 4,169 but with wide ranges influenced by factors like generation time and growth rate, underscoring the need for cautious interpretation.^[61]^[60]

Management and Recovery Strategies

Management and recovery strategies for small populations emphasize proactive interventions to counteract genetic, demographic, and environmental risks, often informed by population viability assessments (PVAs) to prioritize actions. These strategies typically involve enhancing genetic diversity, improving connectivity, and bolstering population numbers through targeted conservation efforts. Successful implementation requires collaboration among scientists, policymakers, and local stakeholders to monitor outcomes and adapt approaches dynamically. Translocation and augmentation programs are key tools for genetic rescue, where individuals from larger or related populations are introduced to small, isolated groups to increase genetic diversity and reduce inbreeding. For instance, in 1998, the U.S. Fish and Wildlife Service reintroduced Mexican gray wolves (Canis lupus baileyi) from captive breeding programs and wild sources in Mexico to the American Southwest, leading to the establishment of breeding pairs and gradual population growth from fewer than 20 individuals to a minimum of 286 as of 2025. Such interventions must carefully assess source populations for disease risks and genetic compatibility to avoid unintended negative effects.^[62]^[63] Habitat corridors facilitate natural gene flow and movement between fragmented populations, mitigating isolation by linking suitable habitats and reducing fragmentation's impacts. A prominent example is the network of wildlife overpasses and underpasses in Banff National Park, Canada, constructed since the 1980s, which has enabled grizzly bears and other species to cross the Trans-Canada Highway safely, resulting in increased genetic connectivity and population stability across the region. These structures, often combined with fencing, have been shown to reduce wildlife-vehicle collisions by up to 80% while promoting dispersal. Captive breeding programs provide ex situ conservation for critically small populations, involving controlled breeding in facilities followed by reintroduction to the wild under strict protocols to maintain genetic health. The International Union for Conservation of Nature (IUCN) recommends starting with a minimum of 20-50 founders to capture sufficient genetic diversity, avoiding bottlenecks during propagation. Programs like those for the California condor (Gymnogyps californianus) have successfully reared over 500 individuals since the 1980s, with phased reintroductions into protected habitats leading to a wild free-flying population of more than 300 as of 2025, though ongoing management addresses persistent threats like lead poisoning.^[64]

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We suggest that desiccation proneness is a key trait that may determine amphibian responses to a range of global change drivers, including habitat loss and ...<|separator|>
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The effects of edge influence on the microhabitat, diversity and life ...
Mar 19, 2024 · We hypothesise that the microhabitat will become drier and hotter near the edge, reducing the diversity of amphibians. Further, we hypothesise ...
[42]
How were small mammals affected by the eruption?
Of the 32 species of small mammals thought to be living near Mount St. Helens only 14 were known to have survived. The eruption adversely affected small mammals ...
[43]
Small Mammal Recolonization on the Mount St. Helens Volcano - jstor
ABSTRACT.-In this paper we summarize small mammal studies on Mount St. Helens since its catastrophic eruption in May 1980. Species surviving the initial ...
[44]
Urbanisation Is Associated With Reduced Genetic Diversity in ...
Mar 3, 2025 · We found that genetic diversity and effective population sizes were significantly lower at marine fish sample sites associated with denser human populations.
[45]
Land Use Impacts on Coral Reef Health: A Ridge-to-Reef Perspective
Urban land use affects corals through a number of pathways, including (1) habitat loss from nearshore earthmoving, (2) industrial pollution from factories and ...
[46]
[PDF] Predation, apparent competition, and the structure of prey communities
The introduction of an abundant, alternate food source-the snowshoe hare-may have greatly increased the density of lynx; the arctic hare may have been eaten out ...
[47]
What Drives the 10-year Cycle of Snowshoe Hares? | BioScience
If hare populations are synchronized regionally by predator movements, the fragmentation of hare and lynx habitat in the southern parts of Canada and in the ...
[48]
Navigating fragmented landscapes: Canada lynx brave poor quality ...
We identify a number of linkages for lynx comprised of habitat conditions that differed from high quality core patches identified from our habitat modeling.
[49]
Bird Communities in a Changing World: The Role of Interspecific ...
The Noisy Miner has been referred to as a 'reverse keystone' species as it aggressively excludes almost all small-bodied bird species (<50 g) from its ...Bird Communities In A... · 3. Results · 4. DiscussionMissing: flocks | Show results with:flocks<|separator|>
[50]
competitive exclusion in forest avian mixed-species flocks in a ...
Dec 30, 2017 · This study suggests that competitive interactions mediated by aggressive behaviors of invasive species may have a negative impact on the fitness ...
[51]
Dynamic and context-dependent keystone species effects in kelp ...
Mar 3, 2025 · In nearshore rocky-reef communities, otters can initiate a trophic cascade by reducing the density and grazing effects of sea urchins. In the ...
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https://pmc.ncbi.nlm.nih.gov/articles/PMC4231601/
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The secondary contact phase of allopatric speciation in Darwin's ...
Here, we report the establishment and persistence of a reproductively isolated population of Darwin's finches on the small Galápagos Island of Daphne Major in ...
[54]
Gigantism & Dwarfism on Islands | NOVA - PBS
Nov 1, 2000 · Could the Komodo dragon actually be an island dwarf? Today, human ... dwarfing in surviving species. Nagging Questions. Despite all the ...
[55]
Chapter 4: Sea Level Rise and Implications for Low-Lying Islands ...
This chapter assesses past and future contributions to global, regional and extreme sea level changes, associated risk to low-lying islands, coasts, cities, ...
[56]
Climate Change, Human Impacts, and Coastal Ecosystems in the ...
Oct 7, 2019 · Here we provide a review on interactions between climate change and local human impacts (e.g., interactions between sea level rise and ...
[57]
Museum DNA reveals the demographic history of the endangered ...
The Seychelles warbler, like many bottlenecked species, is characterized by low levels of genetic diversity at neutral and functional genes (Richardson et al.
[58]
Dynamics, Persistence, and Genetic Management of the ...
Jul 23, 2019 · Inbreeding depression, a reduction in fitness ... The explicit consideration of the effects of inbreeding on Florida panther population dynamics ...ABSTRACT · INTRODUCTION · METHODS · DISCUSSION
[59]
Range-wide declines of northern spotted owl populations in the ...
We found that northern spotted owl populations experienced significant declines of 6–9% annually on 6 study areas and 2–5% annually on 5 other study areas.Missing: rescue fragments
[60]
Population Viability Analysis: Origins and Contributions - Nature
Gilpin and Soulé (1986) conceived of population vulnerability analysis as an integrative approach to evaluate the full range of forces impinging on ...Missing: original | Show results with:original
[61]
[PDF] A critical appraisal of population viability analysis
The majority of stud- ies used an individual-based modeling (IBM) framework; unstructured model based on count data was the least commonly used modeling ...
[62]
RAMAS Metapop 6.0
RAMAS Metapop is a tool for population viability analysis, building models for species in multiple patches, and predicting extinction risks.Missing: frameworks | Show results with:frameworks
[63]
Estimates of minimum viable population sizes for vertebrates and ...
We used population viability analysis to estimate MVPs for 102 species. We define a minimum viable population size as one with a 99% probability of persistence ...
[64]
(PDF) The Use and Abuse of Population Viability Analysis
Aug 5, 2025 · Limitations of PVA include the amount of detailed life history data needed for accurate modelling, and studies advise caution to prevent misuse ...