Relevant bibliographies by topics / Red fox

Academic literature on the topic 'Red fox'

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Published: 4 June 2021
Last updated: 27 July 2024

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Journal articles on the topic "Red fox"

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Richardson, Nick. "The Red Fox." AQ: Australian Quarterly 70, no. 3 (1998): 14. http://dx.doi.org/10.2307/20637733.

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Clarke, Andrea. "Red Fox Catches Gosling." Blue Jay 72, no. 2 (June 25, 2014): 105. http://dx.doi.org/10.29173/bluejay300.

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Połap, Dawid, and Marcin Woźniak. "Red fox optimization algorithm." Expert Systems with Applications 166 (March 2021): 114107. http://dx.doi.org/10.1016/j.eswa.2020.114107.

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Shirley, Mark D. F., Bodil Elmhagen, Peter W. W. Lurz, Steve P. Rushton, and Anders Angerbjörn. "Modelling the spatial population dynamics of arctic foxes: the effects of red foxes and microtine cycles." Canadian Journal of Zoology 87, no. 12 (December 2009): 1170–83. http://dx.doi.org/10.1139/z09-104.

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The Fennoscandian arctic fox ( Vulpes lagopus (L., 1758)) population is critically endangered, possibly because of increased interference competition from red foxes ( Vulpes vulpes (L., 1758)) and fading cycles in microtine rodents, which cause food shortage. It is not known how these factors drive arctic fox population trends. To test their role in arctic fox decline, we developed a spatially explicit and individual-based model that allowed us to simulate fox interactions and food availability in a real landscape. A sensitivity analysis revealed that simulated arctic fox population size and den occupancy were strongly correlated with fecundity and mortality during the microtine crash phase, but also with red fox status. Model simulations suggested that arctic fox population trends depended on microtine cycles and that arctic fox distributions were restricted by red fox presence. We compared the model predictions with field data collected at Vindelfjällen, Sweden. The model recreated the observed arctic fox trend only with the inclusion of arctic fox avoidance of red fox home ranges. The results indicate that avoidance behaviours can affect population trends and hence that relatively small numbers of red foxes can have a strong negative impact on arctic fox population size and distribution.
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NASEER, AMIR, MUHAMMAD BILAL, UMAR NASEER, NAUREEN MUSTAFA, and BUSHRA ALLAH RAKHA. "Population Density, Habitat Characteristics and Preferences of Red Fox (Vulpes vulpes) in Chakwal, Pakistan." Journal of Bioresource Management 7, no. 4 (December 31, 2020): 74–83. http://dx.doi.org/10.35691/jbm.0202.0152.

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The Red fox (Vulpes vulpes) is a least concern carnivore according to the IUCN Red List of Threatened Species (2016). However, in Pakistan Red fox is considered as Near Threatened (NT), due to habitat destruction and depletion of food resources. The objective of the study was to identify habitat preferences and population density of Red fox in District Chakwal, Pakistan. Line transect census method was used to estimate the population density of Red fox through direct sighting and indirect method of burrow counting, presence of footprints and scats. A total of 10 transects were carried out at three potential sites: Devi, Photaki and Chumbisurla Wildlife Sanctuary (CWS) in Chakwal based on preliminary surveys. Habitat preference was estimated by comparing three different study sites by quadrat method and found that CWS area is preferred habitat for Red fox. A total of 24 plant species were recorded in the study areas, among them Cynodon dactylon is major herb found to provide shelter to Red fox in all study sites based on Importance value Index (I.V.I) at CWS (IVI=208.8) followed by Devi (IVI=185.93) and Photaki (IVI=142.33). The maximum population density of Red fox through direct sighting at CWS having 0.26 individuals/km2 compared to Devi and Photaki having 0.16 and 0.13 individuals/km2, respectively. The indirect estimation method revealed that maximum dens were found in CWS area compared to Devi and Photaki, while footprints and scats were found maximum in Devi and Photaki, respectively. It is concluded that Red fox preferred habitat is CWS site. Habitat destruction and conflicts with fox are causing the population of the Red fox to dwindle in Chakwal, Pakistan.
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Harris, Stephen, and J. David Henry. "Red Fox: The Catlike Canine." Journal of Animal Ecology 56, no. 3 (October 1987): 1085. http://dx.doi.org/10.2307/4971.

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Williams, Alison. "Wildlife care: the red fox." Veterinary Nursing Journal 23, no. 1 (January 2008): 24–25. http://dx.doi.org/10.1080/17415349.2008.11013649.

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Colson, K. E., James D. Smith, and Kris J. Hundertmark. "St. Matthew Island colonized through multiple long-distance red fox (Vulpes vulpes) dispersal events." Canadian Journal of Zoology 95, no. 8 (August 2017): 607–9. http://dx.doi.org/10.1139/cjz-2016-0289.

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Expansion of red fox (Vulpes vulpes (L., 1758)) into new arctic habitat and the potential for competition with arctic fox (Vulpes lagopus (L., 1758)) are of considerable conservation concern. Previous work has focused on red fox expanding into contiguous areas with few barriers to dispersal. Here, we examine mitochondrial DNA in red fox on recently colonized St. Matthew Island in the Bering Sea to determine their ultimate origin. Though limited in sample size (n = 7), we found that St. Matthew Island was colonized by North American lineages; surprisingly, despite the >400 km distance to the mainland, we found the island was colonized by at least three mitochondrial matrilines. These results suggest that even extremely isolated places may be colonized by red fox, and that the over-ice or over-ocean dispersal ability of red fox may have been previously underappreciated.
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Kaledin, A. P., A. M. Ostapchuk, O. N. Golubeva, O. V. Poddubnaya, S. V. Beketov, and V. M. Makeeva. "Resources of red fox in the Moscow region." Glavnyj zootehnik (Head of Animal Breeding), no. 10 (September 15, 2023): 34–56. http://dx.doi.org/10.33920/sel-03-2310-04.

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Red fox (Vulpes vulpes L.) is one of the most common predatory mammals of the canid family living on the territory of the Moscow region. The main interest in the study of red fox is caused by the lack of data on the current state of the dynamics of the number of species on the territory of the hunting grounds of this region. The purpose of the research was to study the resources of the red fox grouping and their use on the territory of the Moscow region. It was found that the number of red fox in the Moscow region from 2010 to 2021 tended to decrease and amounted to 4014 individuals in 2021. The average long-term population density of the fox was at the level of 2,7 individuals per 1000 ectares of native land, the biological productivity of hunting grounds for the red fox in 2017–2021 was 1,15 rubles/ha, and the yield of its products in 2016–2019 was 0,82 rubles/ha with the average annual cost of resources 3867,45 thousand rubles in 2010–2021. Fox harvest in 2010–2021 was unstable and amounted to 43-73 % of the post-harvest population, which may be due to the lack of demand for fox skins. According to the results of the research the relationship of the highest fox population density per 1000 hectares of native land in the Solnechnogorsky and the Kashirsky districts with the largest landfi lls of the Moscow region operating on their territories was revealed. A map of the average annual resources of red fox and their placement in the Moscow region in 2010–2021 has been developed, which clearly shows the most promising areas of the Moscow region for the organization of hunting for red fox.
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Reshamwala, Hussain S., Pankaj Raina, Zehidul Hussain, Shaheer Khan, Rodolfo Dirzo, and Bilal Habib. "On the move: spatial ecology and habitat use of red fox in the Trans-Himalayan cold desert." PeerJ 10 (September 15, 2022): e13967. http://dx.doi.org/10.7717/peerj.13967.

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Red fox (Vulpes vulpes) is the most widespread wild carnivore globally, occupying diverse habitats. The species is known for its adaptability to survive in dynamic anthropogenic landscapes. Despite being one of the most extensively studied carnivores, there is a dearth of information on red fox from the Trans-Himalayan region. We studied the home range sizes of red fox using the different estimation methods: minimum convex polygon (MCP), kernel density estimator (KDE), local convex hull (LoCoH) and Brownian-bridge movement model (BBMM). We analysed the daily movement and assessed the habitat selection with respect to topographic factors (ruggedness, elevation and slope), environmental factor (distance to water) and anthropogenic factors (distance to road and human settlements). We captured and GPS-collared six red fox individuals (three males and three females) from Chiktan and one female from Hemis National Park, Ladakh, India. The collars were programmed to record GPS fixes every 15-min. The average BBMM home range estimate (95% contour) was 22.40 ± 12.12 SD km2 (range 3.81–32.93 km2) and the average core area (50% contour) was 1.87 ± 0.86 SD km2 (range 0.55–2.69 km2). The estimated average daily movement of red fox was 17.76 ± 8.45 SD km/d (range 10.91–34.22 km/d). Red fox significantly selected lower elevations with less rugged terrain and were positively associated with water. This is the first study in the Trans-Himalayan landscape which aims to understand the daily movement of red fox at a fine temporal scale. Studying the movement and home range sizes helps understand the daily energetics and nutritional requirements of red fox. Movement information of a species is important for the prioritisation of areas for conservation and can aid in understanding ecosystem functioning and landscape management.
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Dissertations / Theses on the topic "Red fox"

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Molsher, Robyn L. "The ecology of feral cats, Felis catus, in open forest in New South Wales interactions with food resources and foxes /." Connect to this title online, 1999. http://hdl.handle.net/2123/411.

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Reese, Angela. "Addressing food conditioning of Cascade red foxes in Mount Rainier National Park, Washington." Online pdf file accessible through the World Wide Web, 2007. http://archives.evergreen.edu/masterstheses/Accession86-10MES/Reese_A%20MESThesis%202007.pdf.

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Murdoch, James D. "Competition and niche separation between Corsac and Red Foxes in Mongolia." Thesis, University of Oxford, 2008. http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.670063.

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Kasprowicz, Adrienne Egge. "The origin and expansion of the eastern red fox." ScholarWorks@UNO, 2016. http://scholarworks.uno.edu/td/2143.

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When new populations are first identified in a region there are multiple potential sources: introduction of a non-native species, extra-range expansion of a nearby population, or demographic growth of a previously unnoticed species. Red foxes were absent or rare in the mid-eastern portion United States until the late 1800s. Their origins potentially include natural population increase/expansion, translocations from Europe, and, eventually, 20th century fur farming. In this study I attempt to identify the relative impact of native expansion versus human mediated introductions of both colonial era European foxes and early 20th century fur-farm foxes on the establishment of red foxes in the mid-Atlantic region of the United States. I subsequently address the potential impacts of hybridization and nuclear introgression between previously separate sister taxa. Through analysis of mitochondrial DNA, I identified indigenous haplotypes, two European haplotypes, and fur-farm haplotypes; another set of haplotypes were potentially indigenous or native. In addition, I found European Y-chromosome haplotypes. Most European and fur-farm haplotypes were found near the densely human-populated coastal plain and Hudson River lowlands; most red foxes of the Appalachians and Piedmont had native eastern haplotypes. However, nuclear data does not support this division showing low genetic structure despite the broad geographic scale of our study area, attributable both to range expansion and admixture. Admixture has not had the same impact on the nuclear genome as it has in mitochondrial haplotypes leading to mito-nuclear discordance across the region. I also found evidence for differential patterns of expansion related to habitat. Specifically, the Appalachian Mountains acted as a corridor for gene flow from the northern native source into the southern Mid-Atlantic region
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Soulsbury, Carl D. "The costs and benefits of red fox (Vulpes vulpes) dispersal." Thesis, University of Bristol, 2006. http://hdl.handle.net/1983/8d5a7e3a-6c8c-4bd0-94ee-bdca2cabc3fa.

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Devenish-Nelson, Eleanor Sarah. "Sarcoptic mange and the demography of the red fox, Vulpes vulpes." Thesis, Durham University, 2012. http://etheses.dur.ac.uk/6960/.

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Vertebrate species are managed for many reasons, including their role as economically important predators or as carriers of disease. Successful management depends on the ability to predict the outcome of management actions on a species’ population dynamics. However, uncertainty in the models used to make such predictions can arise from multiple sources, including sampling error in vital rates, intraspecific demographic variation and unknown interspecific interactions. The red fox Vulpes vulpes provides a useful model organism for exploring such uncertainty, because management of this important predator and disease host is often ineffective, despite substantial sampling effort. By explicitly accounting for sampling error in survival and fecundity, confidence intervals for population growth rates were derived from published point estimates of red fox demographic data. Uncertainty in population growth rates was found to be high, requiring a quadrupling of sampling effort to halve the confidence intervals. Given the often poor justification for the choice of distribution used to model litter size, the influence of probability distributions on population model outcomes was tested. In this first comprehensive evaluation, estimates of quasi-extinction and disease control probabilities for three Canid species were found to be robust to litter size distribution choice. Demographic analyses of the red fox revealed a medium to fast life history speed and significant survival and fecundity contributions from juveniles to population growth. Intraspecific variation was detected within these spectra of demographic metrics: the first such demonstration for carnivores. Simulated data substitution between fox populations revealed that geographic proximity and similar levels of anthropogenic disturbance did not infer demographic similarity. Considering the sampling effort expended on the red fox, the species appears well-studied; yet, substantial limitations in data collection were identified. Compartment modelling of a sarcoptic mange outbreak in an urban fox population in Bristol, UK, revealed that disease transmission was frequency-dependent, consistent with contact rates being determined by social interactions rather than by population density. Individual-based modelling suggested that indirect transmission, genetic resistance and long-distance recolonisation were required to replicate the observed rapid spread of mange and subsequent population recovery. Thus, this first attempt to model mange dynamics in this canid provided novel insight into previously uncertain epidemiological and behavioural processes in the transmission of sarcoptic mange in the red fox.
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Iossa, Graziella. "The reproductive behaviour of an urban red fox (Vulpes vulpes) population." Thesis, University of Bristol, 2006. http://hdl.handle.net/1983/2d6fe1f1-a84e-400b-99e3-dbb9e92bf750.

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Black, Kathleen Miles. "Red fox ecology and interactions with piping plovers on Fire Island, New York." Diss., Virginia Tech, 2021. http://hdl.handle.net/10919/102663.

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Red foxes (Vulpes vulpes) have been identified as a key predator of the threatened piping plover (Charadrius melodus) along the U.S. Atlantic coast. However, little is known about coastal red fox ecology, making it difficult to create effective red fox management strategies in these settings. Here, we quantify aspects of red fox population, spatial, and dietary ecology and interactions with threatened piping plovers on Fire Island, New York. We conducted remote camera surveys, scat and sign surveys, den monitoring, and GPS tracking of red foxes on the island in 2015–2018. We used these data to estimate red fox occupancy, reproduction, survival, and population density. We used GPS data to investigate red fox space use, habitat selection, and responses to piping plover nest exclosure setup, pre-hatch pipping, and hatching. We used fecal dietary analyses and data from den prey item surveys to quantify the frequency of piping plover predation and to identify major prey items of red foxes on the island. Red fox occupancy remained high even after substantial decreases in abundance, population density, annual reproduction, and seasonal survival following 2 sarcoptic mange outbreaks. Within their home ranges, red foxes selected areas that were closer to vegetation during the daytime and twilight hours, but farther from vegetation at night. We did not find clear evidence that red foxes in our study area keyed in on piping plover nest exclosure setup, pipping, or hatching at the spatial scales considered in our comparisons, although fox penetration of and digging at exclosures was an issue in 2015 at Smith Point County Park. Items from Orders Rodentia (rodents, 43% of scats), Coleoptera (beetles, 38%), and Decapoda (crabs and other crustaceans, 29%) were most frequently found in 293 red fox scats examined. Skates (Family Rajidae, 89% of dens with food items) and Atlantic surf clams (Spisula solidissima, 67%) were found most frequently outside of dens. We did not find any identifiable piping plover remains in red fox scats or outside of dens. Our results suggest that direct interactions between red foxes and piping plovers during our study period and in our study area were less frequent than expected, but concurrent work by collaborators documented that the trap success of red foxes was negatively related to piping plover reproductive output during our study period. Lethal removal of red foxes is unlikely to eliminate them from shorebird nesting areas unless complete eradication of foxes from the island can be achieved. We recommend strategic vegetation management in and around piping plover nesting areas to reduce daytime resting areas and hunting cover for red foxes, and continued use of nest exclosures. We also recommend further investigation into indirect impacts of red foxes on piping plover populations, and into the possibility that anthropogenic food resources could be subsidizing the island's red fox population.
Doctor of Philosophy
Red foxes have been identified as a key predator of the piping plover, a small migratory shorebird that breeds along the U.S. Atlantic coast and is considered 'threatened' (at risk of becoming endangered and eventually disappearing) within the United States. The lack of information about red fox ecology in coastal settings has been a challenge for wildlife biologists tasked with reducing predation on piping plovers. We investigated red fox ecology, behavior, and interactions with piping plovers on Fire Island, New York. We used trail cameras, collected scat (feces), monitored dens, and tracked red foxes on the island with global positioning system (GPS) collars in 2015–2018. We used these data to estimate red fox distribution, litter sizes, survival rates, and population sizes. We used GPS data to estimate red fox territory sizes, describe habitat selection, and investigate responses to piping plover nest exclosure setup, pipping (a period before hatching during which chicks vocalize inside the eggs), and hatching. We dissected red fox scats and recorded prey items found outside of dens to determine what red foxes on the island were eating. The proportion of each study area used by red foxes remained high even after substantial decreases in abundance, population density, annual reproduction, and seasonal survival following 2 parasitic disease (sarcoptic mange) outbreaks. Within their territories, red foxes selected areas that were closer to vegetation during the daytime and twilight hours but farther from vegetation at night. We did not find clear evidence that red foxes in our study area keyed in on piping plover nest exclosure setup, pipping, or hatching, although fox penetration of and digging at exclosures was an issue in some years at a site not included in those comparisons. Rodents, beetles, and crustacean remains were found most frequently in red fox scats. Skates and surf clams were found most frequently outside of dens. We did not find any identifiable piping plover remains in red fox scats or outside of dens. Our results suggest that that direct interactions between red foxes and piping plovers may be less frequent than previously believed, but concurrent work by collaborators documented that the trap success of red foxes was negatively related to piping plover reproductive output during our study period. Lethal removal of red foxes is unlikely to eliminate red foxes from shorebird nesting areas unless all foxes on the island are removed. We recommend strategic vegetation removal in and around piping plover nesting areas to reduce daytime resting spots and hunting cover for red foxes, and continued use of nest exclosures. We also recommend further investigation into indirect impacts of red foxes on piping plover populations, and into the possibility that anthropogenic food resources could be subsidizing the island's red fox population.
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Hofer, Heribert. "Patterns of resource distribution and exploitation by the red fox (Vulpes vulpes) and the Eurasian badger (Meles meles) : a comparative study." Thesis, University of Oxford, 1986. http://ora.ox.ac.uk/objects/uuid:18aae8d6-b540-46bb-87f0-3e0b296db609.

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Thirteen badgers and 20 foxes were radio-tracked in the Wytham Estate, Oxfordshire, between 1981 and 1983. Thirteen badger and 10 fox groups were identified from radio-tracking and bait marking. Badger groups (mean size 1982: 4.45, 1983: 5.82) occupied contiguous territories (size: 22-75 ha) with boundaries marked by latrines. Seasonal variation in marking intensity and choice of marking sites presumably were responses to changing intrusion pressure. Fox groups (mean size: 2.6) occupied stable territories (size: 22- 104 ha) with little overlap. Faeces deposition by foxes facilitated territory marking. Earthworms (Lumbricus terrestris) dominated the diet of badgers (63 % estimated dry weight EDW, faeces), followed by cereals, fruits and other Invertebrates. Diet was highly variable between groups and seasons. For foxes, lagomorphs (20 % EDW) and earthworms (33 % EDW) were the most important prey, followed by scavenge and fruits. Variation in diet between groups and seasons was marked in lagomorphs but not earthworms. Multlvarlate analyses of habitat parameters revealed a low-dimensional 'resource space' that could be divided into conventional habitat categories. Censuses of prey species indicated that resource presence varied consistently between habitat categories. Key habitats occurred at fairly constant proportions in territories of both species) their dispersion partly determined the configuration of territory boundaries. The proportions of specific habitats per territory were correlated with the proportions of certain prey items in diets. space use by individuals was analysed by spatial autocorrelation methods, variation in space use by foxes was attributed to variation in resource dispersion. In contrast, individual badgers were similar in their use of space. Here, small-scale heterogeneity in intensity of use may reflect local earthworm availability, in one studied fox group, males and females differed in range use. Individuals in one studied badger group coordinated their use of space probably to minimize foraging interference. It is suggested that group living in Wytham badgers is a response to defending resources, and a model is proposed to explain how the spatial and social organisation of male and female badgers relate to the characteristics of the resources they require.
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Porteus, Thomas Allen. "Evaluation of restricted-area culling strategies to control local red fox density." Thesis, University of British Columbia, 2015. http://hdl.handle.net/2429/52847.

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Lethal control of red foxes is often implemented on restricted areas where immigration from neighbouring sources is expected to make it difficult to keep local fox density low. The justification of lethal wildlife control should include demonstrating its effectiveness. To this end, population dynamics modelling may help to assess the performance of different control strategies in a range of real-world circumstances. A Bayesian state-space model for within-year fox population dynamics was developed that could be fitted to data on daily culling effort and success obtained from gamekeepers on shooting estates in Britain. The estimation model included parameters for key population processes within the culling area: immigration, cub recruitment and non-culling mortality. A simulation-estimation study showed that given a minimum of three years’ data the estimation of fox density and demographic parameters was reliable. Informative priors for the key model parameters were constructed using empirical data and meta-analysis. Data from 22 estates were modelled on a two-weekly time-step. Most estates achieved some suppression of the fox population relative to estimated carrying capacity, but few maintained consistently low densities. The number of foxes killed was a poor indicator of culling effectiveness, highlighting the need for modelling. Estimated immigration rates onto estates were typically high, indicating rapid replacement of culled foxes. There was unexpectedly high spatial variation among estates in estimated carrying capacity and immigration rate. There was evidence from a limited subset of estates that the variable density of released game birds may explain this. The food requirement of the fox population during the nesting period was assumed to indicate predation pressure on wild birds. Alternative culling strategies to reduce this requirement were evaluated using posterior parameter estimates from some estates. Culling concentrated in spring and summer only was more effective than culling uniformly throughout the year. Autumn-only culling was not an effective strategy for wild birds. Open-loop strategies were most effective as culling effort was used all the time. However, closed-loop strategies, where culling effort was conditional on feedback from simulated field-sign searches, achieved similar effects on food requirements using less effort. This revealed trade-offs between effectiveness, cost and animal welfare.
Science, Faculty of
Zoology, Department of
Graduate
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Books on the topic "Red fox"

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Switzer, Merebeth. Red fox. [S.l.]: Grolier Educational Corp., 1986.

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Switzer, Merebeth. Red fox. [S.l.]: Grolier Educational Corp., 1986.

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Green, Jen. Red fox. Danbury, Conn: Grolier, 2008.

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Wallace, Karen. Red fox. Cambridge, Mass: Candlewick Press, 1994.

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Wallace, Karen. Red fox. London: Walker, 1994.

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Wallace, Karen. Red fox. Cambridge, Mass: Candlewick Press, 1996.

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Wallace, Karen. Red fox. Cambridge, Mass: Candlewick Press, 1996.

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Wallace, Karen. Red fox. Cambridge, Mass: Candlewick Press, 1994.

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Seymour, Gerald. Red fox. London: HarperCollins, 1994.

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Seymour, Gerald. Red fox. London: Harvill, 1991.

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Book chapters on the topic "Red fox"

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Crossley, Émilie. "Red Fox Sociality in Japanese Captive Wildlife Tourism." In Emerging Voices for Animals in Tourism, 126–40. GB: CABI, 2024. http://dx.doi.org/10.1079/9781800625259.0011.

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Hutt, Stephen, Ryan S. Baker, Jaclyn Ocumpaugh, Anabil Munshi, J. M. A. L. Andres, Shamya Karumbaiah, Stefan Slater, et al. "Quick Red Fox: An App Supporting a New Paradigm in Qualitative Research on AIED for STEM." In Artificial Intelligence in STEM Education, 319–32. Boca Raton: CRC Press, 2022. http://dx.doi.org/10.1201/9781003181187-26.

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Kistler, Claudia, Sandra Gloor, Daniel Hegglin, and Fabio Bontadina. "Das Management des Fuchses sollte auf wissenschaftlichen Grundlagen anstatt auf Annahmen basieren." In Evidenzbasiertes Wildtiermanagement, 257–72. Berlin, Heidelberg: Springer Berlin Heidelberg, 2023. http://dx.doi.org/10.1007/978-3-662-65745-4_10.

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ZusammenfassungDer Rotfuchs Vulpes vulpes wird in Europa intensiv bejagt. Als Begründung für die Jagd wird aufgeführt, dass Füchse gefährdete Tierarten sowie Nutztiere erbeuten, Krankheiten auf den Menschen und auf Haustiere übertragen und für Konflikte mit den Menschen im Siedlungsraum sorgen. Allerdings gibt es zunehmend Belege, dass die vorherrschenden Methoden der Fuchsjagd, trotz grossem Aufwand durch die Jägerschaft, weder die Bestände noch die verursachten Schäden wirksam und nachhaltig reduzieren. Die Jagd auf Füchse basiert aktuell nicht auf wissenschaftlichen Grundlagen, denn es fehlen Bestandszahlen sowie klar definierte und messbare Ziele. Hinzu kommt, dass nicht evaluiert wird, wie sich die jagdlichen Eingriffe auf die Fuchsbestände auswirken. Zudem werfen verschiedene Jagdmethoden wie die Baujagd mit Hunden oder der Einsatz von Schrot grundsätzliche ethische und tierschützerische Fragen auf. Daher ist ein neues Managementkonzept für den Fuchs gefordert, das ökologische, ökonomische und ethische Kriterien beinhaltet und neben Abschüssen auch nicht-letale Massnahmen einbezieht. Dies unter anderem auch, weil die wachsenden Fuchsbestände im Siedlungsraum angepasste Lösungen erfordern. Im vorliegenden Kapitel zeigen wir auf, welche Grundlagen für ein evidenzbasiertes Fuchsmanagement notwendig sind.SummaryThe red fox Vulpes vulpes is intensively hunted in Europe. The reason given for the hunting are that foxes prey on endangered species and livestock, transmit zoonoses, transmit diseases to domestic animals, and cause conflicts with humans in urban areas. However, there is increasing evidence that the prevailing hunting methods are unlikely to effectively and sustainably reduce either populations or the damage caused, despite the large investment of time by hunters. The hunting of foxes is generally not based on scientific principles, there is a lack of population figures, clearly defined and measurable objectives, and there is no evaluation how hunting interventions impact fox populations. Furthermore, various hunting methods, such as den hunting with dogs or the use of shotgun pellets, raise profound ethical and animal welfare questions. Therefore, a new management concept for the red fox is required that takes ecological, economic and ethical criteria into account and includes non-lethal measures in addition to culling. Moreover, the growing urban fox populations require adapted solutions. In this chapter, we outline which basics are necessary for an evidence-based fox management.
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LindströM, Erik R. "Diet and Demographics of the Red Fox (vulpes Vulpes) in Relation to Population Density — The Sarcoptic Mange Event in Scandinavia." In Wildlife 2001: Populations, 922–31. Dordrecht: Springer Netherlands, 1992. http://dx.doi.org/10.1007/978-94-011-2868-1_70.

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Bendjoudi, Djamel, Faiza Marniche, Lilia Takdjout, and Manuel Epalanga. "First Report on the Copro-parasitology of Striped Hyena, African Golden Wolf and Red Fox in Chrea National Park, (Algeria)." In Recent Advances in Environmental Science from the Euro-Mediterranean and Surrounding Regions (2nd Edition), 1357–61. Cham: Springer International Publishing, 2021. http://dx.doi.org/10.1007/978-3-030-51210-1_215.

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Henderson, Leysa. "Red." In Model Writing for Ages 7–12, 34–44. Abingdon, Oxon : New York, NY : Routledge, 2018.: Routledge, 2017. http://dx.doi.org/10.4324/9781315144962-6.

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Berger, Ross. "Red Flags." In Storytelling for New Technologies and Platforms, 111–33. Boca Raton: CRC Press, 2022. http://dx.doi.org/10.1201/9781003141594-9.

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Högselius, Per. "Bavaria’s Quest for Energy Independence." In Red Gas, 67–88. New York: Palgrave Macmillan US, 2013. http://dx.doi.org/10.1057/9781137286154_5.

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"Red Fox." In Tracks and Signs of the Animals and Birds of Britain and Europe, 122–27. Princeton University Press, 2013. http://dx.doi.org/10.1515/9781400847921.122.

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"Red Fox." In The Southern Wildlife Watcher, 67–71. University of South Carolina Press, 2020. http://dx.doi.org/10.2307/j.ctvrxk3d7.22.

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Conference papers on the topic "Red fox"

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Wu, Haicheng, Gregory Diamos, Tim Sheard, Molham Aref, Sean Baxter, Michael Garland, and Sudhakar Yalamanchili. "Red Fox." In Annual IEEE/ACM International Symposium. New York, New York, USA: ACM Press, 2014. http://dx.doi.org/10.1145/2581122.2544166.

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Wu, Haicheng, Gregory Diamos, Tim Sheard, Molham Aref, Sean Baxter, Michael Garland, and Sudhakar Yalamanchili. "Red Fox." In CGO '14: 12th Annual IEEE/ACM International Symposium on Code Generation and Optimization. New York, NY, USA: ACM, 2014. http://dx.doi.org/10.1145/2544137.2544166.

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Hahaj-Siembida, Agata, Aneta Nowakiewicz, Monika Greguła-Kania, Aleksandra Trościańczyk, Marcelina Osińska, Klaudia Świca, Anna Tracz, and Przemysław Zięba. "Drug-resistant Staphylococcus pseudintermedius isolated from red fox (Vulpes vulpes)." In 2nd International PhD Student’s Conference at the University of Life Sciences in Lublin, Poland: ENVIRONMENT – PLANT – ANIMAL – PRODUCT. Publishing House of The University of Life Sciences in Lublin, 2023. http://dx.doi.org/10.24326/icdsupl2.a007.

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Balachandar, A., S. Usharani, P. Manju Bala, and P. V. Akshaya. "Energy Efficiency in Wireless Sensor Network using Red Fox Optimization Algorithm." In 2023 Second International Conference on Electronics and Renewable Systems (ICEARS). IEEE, 2023. http://dx.doi.org/10.1109/icears56392.2023.10085283.

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Khabarova, L. S., E. S. Ivanova, N. Ya Poddubnaya, A. V. Andreeva, A. P. Selezneva, and D. M. Feneva. "Mercury in Tissues of Red Fox as Indicator of Environmental Pollution." In Proceedings of the International Symposium “Engineering and Earth Sciences: Applied and Fundamental Research” (ISEES 2018). Paris, France: Atlantis Press, 2018. http://dx.doi.org/10.2991/isees-18.2018.19.

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Ketafa, Fetoh H., and Salah Al-Darraji. "Path Planning for an Autonomous Mobile Robot Using Red Fox Optimization Algorithm." In 2022 International Conference on Data Science and Intelligent Computing (ICDSIC). IEEE, 2022. http://dx.doi.org/10.1109/icdsic56987.2022.10075928.

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Maskeliūnas, Rytis, and Robertas Damaševičius. "Quantum Red Fox Optimisation Algorithm for Supply Chain Forecasting in Timber Industry." In 2024 6th International Conference on Computing and Informatics (ICCI). IEEE, 2024. http://dx.doi.org/10.1109/icci61671.2024.10485104.

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Polap, Dawid, Katarzyna Prokop, and Gautam Srivastava. "Federated Heuristic Optimization Based on Fuzzy Clustering and Red Fox Optimization Algorithm." In 2023 IEEE International Conference on Fuzzy Systems (FUZZ). IEEE, 2023. http://dx.doi.org/10.1109/fuzz52849.2023.10309747.

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"A metapopulation model of Little Red Flying Fox population dynamics across Queensland." In 25th International Congress on Modelling and Simulation. Modelling and Simulation Society of Australia and New Zealand, 2023. http://dx.doi.org/10.36334/modsim.2023.longmuir.

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Itin, G. S., and V. M. Kravchenko. "HELMINTH INFECTION IN THE RED FOX (VULPES VULPES, L., 1758) IN THE NORTH-WEST CAUCASUS." In THEORY AND PRACTICE OF PARASITIC DISEASE CONTROL. VNIIP – FSC VIEV, 2024. http://dx.doi.org/10.31016/978-5-6050437-8-2.2024.25.140-145.

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In the North-West Caucasus, the red fox (Vulpes vulpes) is involved in maintaining natural foci of helminth infections that have medical and veterinary importance. In the region, 160 carcasses of red foxes obtained in 4 landscape and geographical zones were examined by the method of complete helminthological dissections in 2010-2023. The infection prevalence and intensity parameters were determined. The helminth infection rate in the fox was 96.2%. The helminthic cenosis was represented by 30 species of parasitic worms. Out of the found helminths, trematodes were 5 species (16.7%), cestodes, 6 species (20.0%), nematodes, 18 species (60.0%), and acanthocephalans, 1 species (3.0%). The flooded coastal zone found 25 helminth species, the flat zone, 27 species, the foothills, 23 species, and the mountain zone, 19 species. The high infection in foxes was recorded in the region with the following helminths: Alaria alata, Taenia crassiceps, Mesocestoides lineatus, Uncinaria stenocephala, and Toxascaris leonina. The analysis of fox stomach contents showed that the major portion in the diet was rodents, amphibians, reptiles, fish, and insects.
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Reports on the topic "Red fox"

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Olson, Carl. Safety Effectiveness of Red Light Treatments for Red Light Running. Portland State University Library, January 2000. http://dx.doi.org/10.15760/etd.882.

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Stockstill, Richard L. Red River Waterway Revised Outlets for Red River Locks. Hydraulic Model Investigation. Fort Belvoir, VA: Defense Technical Information Center, August 1990. http://dx.doi.org/10.21236/ada227929.

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Kelly, Suzanne Marie, Gerald F. Quinlan, Joel D. Miller, Allen G. Sault, and Paula L. McAllister. ASCI Red for dummies : a recipe book for easy use of the ASCI Red platform. Office of Scientific and Technical Information (OSTI), November 2003. http://dx.doi.org/10.2172/918257.

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Ryburn, James T. Missions and Mobility Configurations for RED HORSE. Fort Belvoir, VA: Defense Technical Information Center, April 1988. http://dx.doi.org/10.21236/ada192526.

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Gatchell, Charles J., Janice K. Wiedenbeck, Elizabeth S. Walker, and Elizabeth S. Walker. 1992 Data Bank for Red Oak Lumber. St. Paul, MN: U.S. Department of Agriculture, Forest Service, North Central Research Station, 1992. http://dx.doi.org/10.2737/ne-rp-669.

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Audsley, Neil, Gonzalo Avila, Claudio Ioratti, Valerie Caron, Chiara Ferracini, Tibor Bukovinszki, Marc Kenis, et al. Red necked longicorn, Aromia bungii (Faldermann). Euphresco, 2023. http://dx.doi.org/10.1079/20240228447.

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The red necked longicorn (RNL), Aromia bungii (Coleoptera: Cerambycidae), originates from eastern Asia and has become an invasive pest in Japan, Germany and Italy. Predominantly attacking stone fruit trees (Prunus spp.), RNL larvae tunnel within the cambium layer, disrupting sap flow and potentially killing the host tree. The pest poses a significant threat to both fruit production and wood production. It is considered a quarantine species in Europe, capable of spreading through wood products and plants for planting. There has been no classical biological control implemented against RNL. However, potential natural enemies include the generalist parasitoids Sclerodermus guani and Sclerodermus harmandi (Hymenoptera: Bethylidae). S. guani has shown a parasitism rate of 43% in laboratory studies and has been used in China for controlling forest pests. Other potential natural enemies include generalist predators and parasitoids, such as Dastarcus helophoroides (Coleoptera: Bothrideridae), which has been used in combination with entomopathogenic nematodes for biological control in China, and species of Braconidae and Ichneumonidae. Despite their potential, the broad host range of these natural enemies raises concerns about non-target effects.
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Camp, William J., and James Lee Tomkins. Architectural requirements for the Red Storm computing system. Office of Scientific and Technical Information (OSTI), October 2003. http://dx.doi.org/10.2172/918236.

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Nordsell, Robert, Dan Bugaris, Thomas Chasapis, Jonathan Melman, Anubhav Jain, and Shyue Ping Ong. Narrow emitting red phosphors for improving pcLED efficacy. Office of Scientific and Technical Information (OSTI), May 2019. http://dx.doi.org/10.2172/1543131.

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Wiedenbeck, Janice K., Charles J. Gatchell, and Elizabeth S. Walker. Data bank for short-length red oak lumber. St. Paul, MN: U.S. Department of Agriculture, Forest Service, North Central Research Station, 1994. http://dx.doi.org/10.2737/ne-rp-695.

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Pfetzing, E., and R. Hoye. Evaluation of Six Options for Obtaining Red Water. Fort Belvoir, VA: Defense Technical Information Center, August 1993. http://dx.doi.org/10.21236/ada467328.

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