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B. Aukema, K. Raffa (2004)
Does aggregation benefit bark beetles by diluting predation? Links between a group‐colonisation strategy and the absence of emergent multiple predator effectsEcological Entomology, 29
N. Erbilgin, S. Mori, Jianghua Sun, J. Stein, D. Owen, L. Merrill, R. Bolaños, K. Raffa, T. Montiel, D. Wood, N. Gillette (2006)
Response to Host Volatiles by Native and Introduced Populations of Dendroctonus valens (Coleoptera: Curculionidae, Scolytinae) in North America and ChinaJournal of Chemical Ecology, 33
(1998)
Spatial pattern formation in ecological systems: bridging theoretical and empirical approaches. Modeling Spatiotemporal Dynamics in Ecology (ed
J. Skellam (1951)
Random dispersal in theoretical populationsBulletin of Mathematical Biology, 53
B. Aukema, K. Raffa (2005)
Selective manipulation of predators using pheromones: responses to frontalin and ipsdienol pheromone components of bark beetles in the Great Lakes regionAgricultural and Forest Entomology, 7
W. Laidlaw, B. Prenzel, M. Reid, S. Fabris, H. Wieser (2003)
Comparison of the Efficacy of Pheromone-Baited Traps, Pheromone-Baited Trees, and Felled Trees for the Control of Dendroctonus pseudotsugae (Coleoptera: Scolytidae), 32
G. Amman (1984)
Mountain Pine Beetle (Coleoptera: Scolytidae) Mortality in Three Types of InfestationsEnvironmental Entomology, 13
K. Raffa, K. Hobson, S. Lafontaine, B. Aukema (2007)
Can chemical communication be cryptic? Adaptations by herbivores to natural enemies exploiting prey semiochemistryOecologia, 153
R. Ewers, R. Ewers, R. Didham (2006)
Continuous response functions for quantifying the strength of edge effectsJournal of Applied Ecology, 43
B. Bentz, A. Munson (2000)
Spruce Beetle Population Suppression in Northern UtahWestern Journal of Applied Forestry, 15
R. Ewers, R. Didham (2008)
Pervasive impact of large-scale edge effects on a beetle communityProceedings of the National Academy of Sciences, 105
O. Ovaskainen, S. Cornell (2003)
Biased movement at a boundary and conditional occupancy times for diffusion processesJournal of Applied Probability, 40
K. Klepzig, E. Kruger, E. Smalley, K. Raffa (1995)
Effects of biotic and abiotic stress on induced accumulation of terpenes and phenolics in red pines inoculated with bark beetle-vectored fungusJournal of Chemical Ecology, 21
M. Mimura, James Murray (1978)
On a diffusive prey--predator model which exhibits patchiness.Journal of theoretical biology, 75 3
V. Zumr (1992)
Dispersal of the spruce bark beetle Ips typographus (L.) (Col., Scolytidae) in spruce woods 1Journal of Applied Entomology, 114
R. Cantrell, C. Cosner (1999)
Diffusion models for population dynamics incorporating individual behavior at boundaries: applications to refuge design.Theoretical population biology, 55 2
B. Lindgren (1983)
A MULTIPLE FUNNEL TRAP FOR SCOLYTID BEETLES (COLEOPTERA)The Canadian Entomologist, 115
(1986)
Patchiness, dispersal, and species interactions: consequences for communities of herbivorous insects
B. Aukema, Jun Zhu, Jesper Møller, J. Rasmussen, K. Raffa (2010)
Predisposition to bark beetle attack by root herbivores and associated pathogens: Roles in forest decline, gap formation, and persistence of endemic bark beetle populationsForest Ecology and Management, 259
K. Raffa (1991)
Temporal and Spatial Disparities Among Bark Beetles, Predators, and Associates Responding to Synthetic Bark Beetle Pheromones: Ips pini (Coleoptera: Scolytidae) in WisconsinEnvironmental Entomology, 20
Peter Jackson, Dennis Straussfogel, B. Lindgren, Selina Mitchell, B. Murphy (2008)
Radar observation and aerial capture of mountain pine beetle, Dendroctonus ponderosae Hopk. (Coleoptera: Scolytidae) in flight above the forest canopyCanadian Journal of Forest Research, 38
B. Aukema, D. Dahlsten, K. Raffa (2000)
Exploiting Behavioral Disparities Among Predators and Prey to Selectively Remove Pests: Maximizing the Ratio of Bark Beetles to Predators Removed During Semiochemically Based Trap-Out, 29
R. Sokal, F. Rohlf, Freeman, Co. (1969)
Biometry: The Principles and Practice of Statistics in Biological Research
P. Beier, K. Burnham, David Anderson (2001)
Model Selection and Inference: A Practical Information-Theoretic ApproachJournal of Wildlife Management, 65
N. Erbilgin, K. Raffa (2002)
Association of declining red pine stands with reduced populations of bark beetle predators, seasonal increases in root colonizing insects, and incidence of root pathogensForest Ecology and Management, 164
R. Gara, R. Werner, M. Whitmore, E. Holsten (1995)
Arthropod associates of the spruce beetle Dendroctonus rufipennis (Kirby) (Col., Scolytidae) in spruce stands of south‐central and interior AlaskaJournal of Applied Entomology, 119
N. Erbilgin, E. Nordheim, B. Aukema, K. Raffa (2002)
Population Dynamics of Ips pini and Ips grandicollis in Red Pine Plantations in Wisconsin: Within- and Between-Year Associations with Predators, Competitors, and Habitat Quality, 31
J. Cronin, J. Reeve (2005)
Host–parasitoid spatial ecology: a plea for a landscape-level synthesisProceedings of the Royal Society B: Biological Sciences, 272
J. Zabel, T. Tscharntke (1998)
Does fragmentation of Urtica habitats affect phytophagous and predatory insects differentially?Oecologia, 116
B. Aukema, K. Raffa (2004)
Behavior of Adult and Larval Platysoma cylindrica (Coleoptera: Histeridae) and Larval Medetera bistriata (Diptera: Dolichopodidae) During Subcortical Predation of Ips pini (Coleoptera: Scolytidae)Journal of Insect Behavior, 17
B. Aukema, K. Raffa (2002)
Relative effects of exophytic predation, endophytic predation, and intraspecific competition on a subcortical herbivore: consequences to the reproduction of Ips pini and Thanasimus dubiusOecologia, 133
O. Ovaskainen (2004)
HABITAT-SPECIFIC MOVEMENT PARAMETERS ESTIMATED USING MARK–RECAPTURE DATA AND A DIFFUSION MODELEcology, 85
J. Reeve, B. Strom, L. Rieske, Bruce Ayres, A. Costa (2009)
Geographic variation in prey preference in bark beetle predatorsEcological Entomology, 34
J. Cronin, J. Reeve, R. Wilkens, P. Turchin (2000)
The pattern and range of movement of a checkered beetle predator relative to its bark beetle preyOikos, 90
P. Duelli, P. Zahradník, M. Knížek, B. Kalinová (1997)
Migration in spruce bark beetles (Ips typographis L.) and the efficiency of pheromone trapsJournal of Applied Entomology, 121
G. Barton (1975)
The Mathematics of Diffusion 2nd ednPhysics Bulletin, 26
Mimura Mimura, Murray Murray (1978)
On a diffusive predator prey model which exhibits patchiness.Journal of Theoretical Biology, 75
Peter Kareiva (1987)
Habitat fragmentation and the stability of predator–prey interactionsNature, 326
P. Turchin (1998)
Quantitative analysis of movement : measuring and modeling population redistribution in animals and plants
Kung-Sik Chan, H. Tong, R. Boonstra, S. Boutin, C. Krebs, E. Post, M. O’Donoghue, N. Yoccoz, M. Forchhammer, J. Hurrell
Dynamical Role of Predators in Population Cycles of a Forest Insect : An Experimental Test
N. Erbilgin, K. Raffa (2001)
Kairomonal range of generalist predators in specialized habitats: responses to multiple phloeophagous species emitting pheromones vs. host odorsEntomologia Experimentalis et Applicata, 99
K. Klepzig, K. Raffa, E. Smalley (1991)
Association of an insect-fungal complex with red pine decline in WisconsinForest Science, 37
L. Ries, T. Sisk (2004)
A PREDICTIVE MODEL OF EDGE EFFECTSEcology, 85
B. Strom, L. Roton, R. Goyer, J. Meeker (1999)
VISUAL AND SEMIOCHEMICAL DISRUPTION OF HOST FINDING IN THE SOUTHERN PINE BEETLEEcological Applications, 9
H. Comins, M. Hassell, R. May (1992)
The spatial dynamics of host-parasitoid systemsJournal of Animal Ecology, 61
R. Stinner, C. Barfield, and Stimac, L. Dohse (1983)
Dispersal and Movement of Insect PestsAnnual Review of Entomology, 28
S. Wood (1982)
The Bark and Ambrosia Beetles of North and Central America (Coleoptera: Scolytidae), a Taxonomic MonographGreat Basin naturalist memoirs, 6
T. Tscharntke, I. Steffan‐Dewenter, A. Kruess, Carsten Thies (2002)
Characteristics of insect populations on habitat fragments: A mini reviewEcological Research, 17
W. Baker (1972)
Eastern forest insects
K. Ryall, L. Fahrig (2005)
Habitat loss decreases predator/prey ratios in a pine-bark beetle systemOikos, 110
J. Westwater, H. Drickamer (1957)
The Mathematics of Diffusion.Journal of the American Chemical Society, 79
A. Barak, D. McGrevy, G. Tokaya (2018)
Dispersal and Re-Capture of Marked, Overwintering Tomicus Piniperda (Coleoptera: Scolytidae) From Scotch Pine BoltsThe Great Lakes Entomologist
H. Jackson, K. Baum, T. Robert, J. Cronin (2009)
Habitat-Specific Movement and Edge-Mediated Behavior of the Saproxylic Insect Odontotaenius disjunctus (Coleoptera: Passalidae), 38
J. Wiens (1992)
Ecological Flows Across Landscape Boundaries: A Conceptual Overview
Kirsten Haberkern, K. Raffa (2003)
Phloeophagous and Predaceous Insects Responding to Synthetic Pheromones of Bark Beetles Inhabiting White Spruce Stands in the Great Lakes RegionJournal of Chemical Ecology, 29
(1978)
Reducing variation in field tests of behavioral chemicals for the southern pine beetle
J. Reeve, J. Cronin, Kyle Haynes (2008)
Diffusion models for animals in complex landscapes: incorporating heterogeneity among substrates, individuals and edge behaviours.The Journal of animal ecology, 77 5
J. Berisford, S. Cameron (2005)
Effects of Intensive Forest Management Practices on Insect Infestation Levels and Loblolly Pine Growth
R. Werner, E. Holsten (1997)
Dispersal of the spruce beetle, `dendroctonus rufipennis`, and the engraver beetle, `ips perturbatus`, in Alaska. Forest Service research paper
P. Turchin, W. Thoeny (1993)
Quantifying Dispersal of Southern Pine Beetles with Mark-Recapture Experiments and a Diffusion Model.Ecological applications : a publication of the Ecological Society of America, 3 1
A. Costa, J. Reeve (2011)
Olfactory Experience Modifies Semiochemical Responses in a Bark Beetle PredatorJournal of Chemical Ecology, 37
D. Wood (1982)
THE ROLE OF PHEROMONES, KAIROMONES, AND ALLOMONES IN THE HOST SELECTION AND COLONIZATION BEHAVIOR OF BARK BEETLESAnnual Review of Entomology, 27
T. Ricketts (2001)
The Matrix Matters: Effective Isolation in Fragmented LandscapesThe American Naturalist, 158
K. Raffa, A. Berryman (1983)
The role of host plant resistance in the colonization behavior and ecology of bark beetles (Coleoptera: Scolytidae)Ecological Monographs, 53
1 Quantifying dispersal in predator–prey systems can improve our understanding of how these species interact in space and time, as well as their relative distributions across complex landscapes. 2 We measured the dispersal abilities of three forest insects associated with red pine decline: the eastern five spined pine engraver Ips grandicollis (Coleoptera: Curculionidae), its main predator Thanasimus dubius (Coleoptera: Cleridae) and the basal stem and root colonizer Dendroctonus valens (Coleoptera: Curculionidae). We also examined the edge behaviours of these species and the predator Platysoma spp (Coleoptera: Histeridae) between red pine stands (habitat) and clearings (nonhabitat). 3 Thanasimus dubius dispersed 12 times farther than its prey I. grandicollis, with 50% of predators dispersing farther than 1.54 km. This profound difference in dispersal behaviour between prey and predator may contribute to the clumped distribution of I. grandicollis. 4 Most T. dubius and D. valens were confined in the pine forest, thus showing strong edge behaviour. This differed from I. grandicollis and Platysoma spp., which were commonly found in open areas adjacent to red pine plantations. 5 The bark beetle I. grandicollis and one of its main predators, T. dubius, exhibited different patterns of movement within a fragmented landscape. Despite a greater dispersal ability of T. dubius within forests, the spatial distribution of this predator may be restricted by fragmentation of its habitat, and provide an opportunity for partial escape of its prey. 6 The present study contributes to our knowledge of top‐down forces within red pine stands undergoing decline. Differences of dispersal patterns and edge behaviour could contribute to the initiation of new pockets of decline, as well as the connectedness among existing ones.
Agricultural and Forest Entomology – Wiley
Published: Feb 1, 2013
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