Abstract is: Katriona Shea is a British-American ecologist. She is currently the endowed Alumni Chair of Biology Science at Eberly College of Science, Pennsylvania State University.
| human | Q5 |
| P2671 | Google Knowledge Graph ID | /g/11c52636mt |
| P1960 | Google Scholar author ID | sXpY0CUAAAAJ |
| P213 | ISNI | 0000000134017028 |
| P496 | ORCID iD | 0000-0002-7607-8248 |
| P3829 | Publons author ID | 2885316 |
| P1053 | ResearcherID | B-7954-2008 |
| P8207 | The Conversation author ID | 143712 |
| P166 | award received | Fellow of the American Association for the Advancement of Science | Q5442484 |
| Fellow of the Ecological Society of America | Q59766793 | ||
| P69 | educated at | University of Oxford | Q34433 |
| P108 | employer | Pennsylvania State University | Q739627 |
| P101 | field of work | ecology | Q7150 |
| P6104 | maintained by WikiProject | WikiProject Invasion Biology | Q56241615 |
| P106 | occupation | biologist | Q864503 |
| P21 | sex or gender | female | Q6581072 |
| Q57656598 | A guide to calculating discrete-time invasion rates from data |
| Q33776615 | A network model for plant-pollinator community assembly |
| Q42029197 | A state-dependent model for the optimal management of an invasive metapopulation |
| Q56434592 | A unifying gravity framework for dispersal |
| Q56482040 | ACTIVE ADAPTIVE MANAGEMENT IN INSECT PEST AND WEED CONTROL: INTERVENTION WITH A PLAN FOR LEARNING |
| Q34379260 | Adaptive management and the value of information: learning via intervention in epidemiology |
| Q94453383 | Advancing an interdisciplinary framework to study seed dispersal ecology |
| Q58241201 | An Adaptive Decision Framework for the Conservation of a Threatened Plant |
| Q97650599 | Anticipating future learning affects current control decisions: A comparison between passive and active adaptive management in an epidemiological setting |
| Q51620225 | Applications of particle image velocimetry for seed release studies. |
| Q57028259 | Are the best dispersers the best colonizers? Seed mass, dispersal and establishment in Carduus thistles |
| Q91680605 | Bee community preference for an invasive thistle associated with higher pollen protein content |
| Q52590950 | Beyond dose: Pulsed antibiotic treatment schedules can maintain individual benefit while reducing resistance. |
| Q58462862 | CONTEXT-DEPENDENT BIOLOGICAL CONTROL OF AN INVASIVE THISTLE |
| Q101565617 | COVID-19 reopening strategies at the county level in the face of uncertainty: Multiple Models for Outbreak Decision Support |
| Q114054795 | Cattle transport network predicts endemic and epidemic foot-and-mouth disease risk on farms in Turkey |
| Q56605503 | Coexistence patterns of two invasive thistle species, Carduus nutans and C. acanthoides, at three spatial scales |
| Q113260382 | Collaborative Hubs: Making the Most of Predictive Epidemic Modeling |
| Q56355732 | Competition between similar invasive species: modeling invasional interference across a landscape |
| Q66679582 | Concurrent assessment of epidemiological and operational uncertainties for optimal outbreak control: Ebola as a case study |
| Q110789441 | Conservation of passively dispersed organisms in the context of habitat degradation and destruction |
| Q33555470 | Correlations in the degeneracy of structurally controllable topologies for networks. |
| Q56434632 | Covariation in abscission force and terminal velocity of windborne sibling seeds alters long-distance dispersal projections |
| Q40643907 | Decision-making for foot-and-mouth disease control: Objectives matter |
| Q93009045 | Disentangling the mechanisms underpinning disturbance-mediated invasion |
| Q60521946 | Dispersal Patterns, Dispersal Mechanisms, and Invasion Wave Speeds for Invasive Thistles |
| Q56774210 | Dispersal and demography contributions to population spread ofCarduus nutansin its native and invaded ranges |
| Q51184968 | Dispersal patterns, dispersal mechanisms, and invasion wave speeds for invasive thistles. |
| Q56447235 | Dispersal under duress: Can stress enhance the performance of a passively dispersed species? |
| Q56776319 | Dispersal, demography and spatial population models for conservation and control management |
| Q112304464 | Disturbance‐mediated invasions are dependent on community resource abundance |
| Q125023229 | Diversity loss from multiple interacting disturbances is regime‐dependent |
| Q24601587 | Diversity-disturbance relationships: frequency and intensity interact |
| Q51186814 | Ecology. How the wood moves. |
| Q64267694 | Employing plant functional groups to advance seed dispersal ecology and conservation |
| Q51729265 | Environmental variability and the initiation of dispersal: turbulence strongly increases seed release. |
| Q30250958 | Essential information: Uncertainty and optimal control of Ebola outbreaks |
| Q57028326 | Establishment and spread of founding populations of an invasive thistle: the role of competition and seed limitation |
| Q60507119 | Global versus local extinction in a network model of plant–pollinator communities |
| Q94548520 | Harnessing multiple models for outbreak management |
| Q57013056 | How can we bring together empiricists and modellers in functional biodiversity research? |
| Q107968127 | How disturbance history alters invasion success: biotic legacies and regime change |
| Q51343696 | How do duration, frequency, and intensity of exogenous CORT elevation affect immune outcomes of stress? |
| Q33851123 | How frequency and intensity shape diversity-disturbance relationships |
| Q33895515 | Importance of individual and environmental variation for invasive species spread: a spatial integral projection model |
| Q56332538 | Individually mark-mass release-resight study elucidates effects of patch characteristics and distance on host patch location by an insect herbivore |
| Q30571688 | Influence of microsite disturbance on the establishment of two congeneric invasive thistles |
| Q31043930 | Integrating multiple disturbance aspects: management of an invasive thistle, Carduus nutans |
| Q56781139 | Integrating the Study of Non-native Plant Invasions across Spatial Scales |
| Q92134080 | Intrinsic and extrinsic drivers of intraspecific variation in seed dispersal are diverse and pervasive |
| Q34386459 | Invasional interference due to similar inter- and intraspecific competition between invaders may affect management |
| Q124863326 | Leveraging federalism for flexible and robust management of social‐ecological systems |
| Q55361389 | Logistical constraints lead to an intermediate optimum in outbreak response vaccination. |
| Q51145980 | Measles outbreak response decision-making under uncertainty: a retrospective analysis. |
| Q60521948 | Measuring plant dispersal: an introduction to field methods and experimental design |
| Q114363239 | Microbes increase thermal sensitivity in the mosquito Aedes aegypti, with the potential to change disease distributions |
| Q125573125 | Misapplied management makes matters worse: Spatially explicit control leverages biotic interactions to slow invasion |
| Q58462888 | Modeling for Management of Invasive Species: Musk Thistle (Carduus nutans) in New Zealand |
| Q92095436 | Modeling infectious epidemics |
| Q106768003 | Modeling of Future COVID-19 Cases, Hospitalizations, and Deaths, by Vaccination Rates and Nonpharmaceutical Intervention Scenarios — United States, April–September 2021 |
| Q21092813 | Modeling the mutualistic interactions between tubeworms and microbial consortia |
| Q60507114 | Motif profile dynamics and transient species in a Boolean model of mutualistic ecological communities |
| Q56785515 | Moving from pattern to process: coexistence mechanisms under intermediate disturbance regimes |
| Q53252811 | Network models. Comment on "Control profiles of complex networks". |
| Q51178685 | Optimal management strategies to control local population growth or population spread may not be the same. |
| Q56783009 | Optimizing dispersal study design by Monte Carlo simulation |
| Q112302136 | Optimizing management of invasions in an uncertain world using dynamic spatial models |
| Q33945198 | Optimizing reproductive phenology in a two-resource world: a dynamic allocation model of plant growth predicts later reproduction in phosphorus-limited plants. |
| Q56447243 | Patterns of introduced species interactions affect multiple aspects of network structure in plant–pollinator communities |
| Q112302139 | Pest management in future climates: Warming reduces physical weed management effectiveness |
| Q34479024 | Plant community associations of two invasive thistles |
| Q33567118 | Plant populations track rather than buffer climate fluctuations |
| Q57028287 | Plant spatial arrangement affects projected invasion speeds of two invasive thistles |
| Q56435483 | Plant-pollinator community network response to species invasion depends on both invader and community characteristics |
| Q104473137 | Political economy of renewable resource federalism |
| Q33758750 | Pollinator Behavior Mediates Negative Interactions between Two Congeneric Invasive Plant Species |
| Q111465234 | Pollinator floral provisioning by a plant invader: quantifying beneficial effects of detrimental species |
| Q57028207 | Post-dispersal seed removal of Carduus nutans and C. acanthoides by insects and small mammals |
| Q110620550 | Prior adaptation, diversity, and introduction frequency mediate the positive relationship between propagule pressure and the initial success of founding populations |
| Q110743478 | Projecting the recovery of a long-lived deep-sea coral species after the Deepwater Horizon oil spill using state-structured models |
| Q36282558 | Quantifying the Value of Perfect Information in Emergency Vaccination Campaigns |
| Q111203507 | Quantitative evolutionary patterns in bipartite networks: Vicariance, phylogenetic tracking or diffuse co‐evolution? |
| Q64970190 | Rapid changes in seed dispersal traits may modify plant responses to global change. |
| Q56636255 | Real-time decision-making during emergency disease outbreaks |
| Q60507118 | Restoration of plant–pollinator interaction networks via species translocation |
| Q35099281 | Roots of the invasive species Carduus nutans L. and C. acanthoides L. produce large amounts of aplotaxene, a possible allelochemical. |
| Q51185267 | Seed release by invasive thistles: the impact of plant and environmental factors. |
| Q56395888 | Seed release in a changing climate: initiation of movement increases spread of an invasive species under simulated climate warming |
| Q57028302 | Shipment and storage effects on the terminal velocity of seeds |
| Q56781168 | Spatial Segregation of Congeneric Invaders in Central Pennsylvania, USA |
| Q37215304 | Supporting crop pollinators with floral resources: network-based phenological matching |
| Q113309015 | Synergistic interventions to control COVID-19: Mass testing and isolation mitigates reliance on distancing |
| Q107967700 | THE INTERMEDIATE DISTURBANCE HYPOTHESIS: PATCH DYNAMICS AND MECHANISMS OF SPECIES COEXISTENCE |
| Q56380382 | Termite cohabitation: the relative effect of biotic and abiotic factors on mound biodiversity |
| Q96136530 | The SEIRS model for infectious disease dynamics |
| Q94574099 | The business of biodiversity |
| Q33940819 | The composite insect trap: an innovative combination trap for biologically diverse sampling. |
| Q129674350 | The increase of an allelopathic and unpalatable plant undermines reindeer pasture quality and current management in the Norwegian tundra |
| Q90446323 | The total dispersal kernel: a review and future directions |
| Q56554386 | Timing of disturbance alters competitive outcomes and mechanisms of coexistence in an annual plant model |
| Q56774037 | To sample or eradicate? A cost minimization model for monitoring and managing an invasive species |
| Q56762169 | Tolerance of two invasive thistles to repeated disturbance |
| Q37243197 | Top-down network analysis characterizes hidden termite-termite interactions. |
| Q36392820 | Topological constraints on network control profiles. |
| Q34419970 | Topology of plant-pollinator networks that are vulnerable to collapse from species extinction. |
| Q98665249 | Uncertainty and the management of epidemics |
| Q46847981 | Unrecognized impact of a biocontrol agent on the spread rate of an invasive thistle |
| Q113816223 | Vote-processing rules for combining control recommendations from multiple models |
| Q92282026 | Warming Increases Pollen Lipid Concentration in an Invasive Thistle, with Minor Effects on the Associated Floral-Visitor Community |
| Q100528932 | Warming and shifting phenology accelerate an invasive plant life cycle |
| Q33955320 | Warming increases the spread of an invasive thistle |
| Q56544456 | Warming leads to divergent responses but similarly improved performance of two invasive thistles |
| Q56747520 | Watch your time step: trapping and tracking dispersal in autocorrelated environments |
| Q57028253 | Water loss from flower heads predicts seed release in two invasive thistles |
| Q111171171 | Weighing the unknowns: Value of Information for biological and operational uncertainty in invasion management |
| Q56779948 | What controls the population dynamics of the invasive thistleCarduus nutansin its native range? |
| Q112431506 | Whole community invasions and the integration of novel ecosystems |
| Q111165569 | Working smarter, not harder: objective-dependent management of an invasive thistle, Carduus nutans |
| Katriona Shea | wikipedia |
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