scholarly article | Q13442814 |
P50 | author | Anke Jentsch | Q21253894 |
P2093 | author name string | Peter White | |
P2860 | cites work | Contribution to the Energetics of Evolution | Q22066205 |
Natural Selection as a Physical Principle | Q22066221 | ||
Global change and terrestrial plant community dynamics | Q28079266 | ||
Functional traits, convergent evolution, and periodic tables of niches | Q28601193 | ||
Disturbance interactions can impact resilience mechanisms of forests | Q29031992 | ||
Microclimate moderates plant responses to macroclimate warming | Q30685482 | ||
Scaling metabolism from organisms to ecosystems | Q30800599 | ||
Plant succession as an integrator of contrasting ecological time scales | Q30840198 | ||
Does climate directly influence NPP globally? | Q31002188 | ||
Biodiversity increases the resistance of ecosystem productivity to climate extremes | Q31004939 | ||
The global spectrum of plant form and function | Q31033775 | ||
What can we learn from resource pulses? | Q33331922 | ||
Theoretical perspectives on resource pulses | Q33331926 | ||
Novel ecosystems: implications for conservation and restoration | Q33493771 | ||
The intermediate disturbance hypothesis should be abandoned | Q34299860 | ||
A functional approach reveals community responses to disturbances | Q34472931 | ||
On the processes generating latitudinal richness gradients: identifying diagnostic patterns and predictions | Q34608904 | ||
Diversity in tropical rain forests and coral reefs | Q34684821 | ||
Biodiversity and Resilience of Ecosystem Functions | Q35799488 | ||
Ecology: Biodiversity and productivity entwined | Q35892494 | ||
Constancy in Functional Space across a Species Richness Anomaly. | Q35973944 | ||
Navigating the complexity of ecological stability | Q36081290 | ||
Disturbance-driven changes in the variability of ecological patterns and processes | Q37142142 | ||
Cross-scale interactions, nonlinearities, and forecasting catastrophic events | Q37585360 | ||
A succession of theories: purging redundancy from disturbance theory | Q38271857 | ||
Forest disturbances under climate change | Q38634649 | ||
What do you mean, 'resilient'? | Q39279131 | ||
Defining and quantifying the resilience of responses to disturbance: a conceptual and modelling approach from soil science | Q39292709 | ||
Predicting Chronic Climate-Driven Disturbances and Their Mitigation | Q46260007 | ||
Biodiversity and species competition regulate the resilience of microbial biofilm community. | Q46304554 | ||
The ecology of resource pulses | Q46636588 | ||
Thermodynamic constraints on the utility of ecological stoichiometry for explaining global biogeochemical patterns | Q46686436 | ||
Defining and defending Connell's intermediate disturbance hypothesis: a response to Fox. | Q46931590 | ||
A framework for quantifying the relationship between intensity and severity of impact of disturbance across types of events and species. | Q48239693 | ||
Toward a unifying theory of biodiversity | Q50077813 | ||
What makes a terrestrial ecosystem resilient? | Q51150139 | ||
Towards a Comparable Quantification of Resilience. | Q51151311 | ||
Interactions between predation and disturbances shape prey communities. | Q51152974 | ||
Do simple models lead to generality in ecology? | Q51165636 | ||
Rules of thumb for judging ecological theories. | Q51189323 | ||
Comparing resource pulses in aquatic and terrestrial ecosystems. | Q51688801 | ||
Invasion of a Legume Ecosystem Engineer in a Cold Biome Alters Plant Biodiversity. | Q55336288 | ||
Toward a metabolic theory of ecology | Q55879845 | ||
The interactive effects of press/pulse intensity and duration on regime shifts at multiple scales | Q56333169 | ||
Ecosystem engineer unleashed: Prosopis juliflora threatening ecosystem services? | Q56441835 | ||
A Framework to Assess Biogeochemical Response to Ecosystem Disturbance Using Nutrient Partitioning Ratios | Q56557316 | ||
On Theory in Ecology | Q56568183 | ||
Novel ecosystems: theoretical and management aspects of the new ecological world order | Q56781936 | ||
Multiple facets of biodiversity drive the diversity–stability relationship | Q56879739 | ||
Isolation predicts compositional change after discrete disturbances in a global meta-study | Q56933740 | ||
Minireviews: Neighborhood Effects, Disturbance Severity, and Community Stability in Forests | Q56966413 | ||
REVIEW: Predictive ecology in a changing world | Q57051490 | ||
Understanding ecosystem retrogression | Q57055994 | ||
Reconciling plant strategy theories of Grime and Tilman | Q57187540 | ||
On the Importance of First Principles in Ecological Theory Development | Q57205183 | ||
Changing disturbance regimes, ecological memory, and forest resilience | Q57430758 | ||
Cross-system comparisons elucidate disturbance complexities and generalities | Q58110935 | ||
Recovery from disturbance requires resynchronization of ecosystem nutrient cycles | Q58240750 | ||
Functional trait and phylogenetic tests of community assembly across spatial scales in an Amazonian forest | Q60146419 | ||
Global trait–environment relationships of plant communities | Q60228272 | ||
Global trait-environment relationships of plant communities | Q64121010 | ||
Pulsed resources and community dynamics of consumers in terrestrial ecosystems | Q73765468 | ||
Ecosystem growth and development | Q80967064 | ||
P433 | issue | 7 | |
P6104 | maintained by WikiProject | WikiProject Ecology | Q10818384 |
P304 | page(s) | e02734 | |
P577 | publication date | 2019-05-20 | |
P1433 | published in | Ecology | Q1013420 |
P1476 | title | A theory of pulse dynamics and disturbance in ecology | |
P478 | volume | 100 |