2 Climate variability - change in average, variation, and/or extreme values.

Slides:

Advertisements

Similar presentations

Ecological resilience for ecologists

Advertisements

Immigrant Integration as a Complex Adaptive Social Systems Agnes Meinhard, PhD.

May 9, subgroup 1. Forest ecosystems functioning and dynamics Giuseppe Scarascia-Mugnozza Jean-Marc Guehl Frits Mohren.

What is Close-to-Nature Silviculture in a Changing World? Kevin L. O’Hara University of California - Berkeley.

Disturbance Ecology Top 5 Questions, Answers, and Future Directions Lindsay Berk December 9, 2005.

General questions: are there barriers for cross-breeding in the oceans? Implications for evolutionary study (e.g., species stability), ecology (e.g., local.

Funded By NATO Oyster reefs are complex ecological systems because they:

(Mt/Ag/EnSc/EnSt 404/504 - Global Change) Ecosystems (from IPCC WG-2, Chapters 4,9-16) Ecosystems Primary Source: IPCC WG-2 Chapter 4 - Ecosystems, their.

1 Managing for Complexity Dave Coates, B.C. Forest Service, Smithers, BC Future Forest Ecosystem Initiative Seminar May 19, 2009.

Ecological Resilience An active learning module about ecosystem change.

Introduction to Vegetation Classification and the Biogeoclimatic Ecosystem Classification System FRST 211: Forest Classification and Silvics.

Interrelationships among climate, geology, soil, vegetation, and animals.

Complexity, Emergence, and Chaos: Geog 220: Geosimulation Lisa Murawski 1/31/05 Application to Regional Industrial Systems.

Evaluation Methods Workshop ? Definitions: an introduction Evaluation Methods Workshop Sponsored by the Community Based Collaboratives Research Consortium.

1 / x Complex Adaptive systems GRS Introduction Arnold Bregt.

Systems Dynamics and Equilibrium

Biotic and Abiotic Factors in Ecosystems

Studying Geography The Big Idea

How do forest ecosystems respond to environmental change?

Ecosystem Stability: Components and Models.

Systems and Models What is a system? What is a model? Feedback Mechanisms Transfer vs. Transform Laws of Thermodynamics.

Translation to the New TCO Panel Beverly Law Prof. Global Change Forest Science Science Chair, AmeriFlux Network Oregon State University.

Innovation and Transformation in Agricultural Systems Mike Jones Swedish Biodiversity Centre IUCN Resilience Task Force Resilience Alliance Connector.

Chapter 1 – A Geographer’s World

Managing Tree Species Diversity for Forest Resilience and Adaptability Andy MacKinnon - Research Ecologist -Coast Area Provincial Ecologists Nanaimo BC.

Interrelationships among climate, geology, soil, vegetation, and animals.

Modeling Complex Dynamic Systems with StarLogo in the Supercomputing Challenge

LEARNING FOR A NONLINEAR WORLD: Cultivating a Prospective Mind 21 ST Century Learning Leadership Forum October Banff, Alberta Thomas Homer-Dixon.

1 William P. Cunningham University of Minnesota Mary Ann Cunningham Vassar College Copyright © The McGraw-Hill Companies, Inc. Permission required for.

Complexity in Fisheries Ecosystems David Schneider Ocean Sciences Centre, Memorial University St. John’s, Canada ENVS 6202 – 26 Sept 2007.

Interpreting Ecological Sites for Grazing Management.

Sustainability Freshman Inquiry Jan. 13, 2010 Jeff Fletcher.

Landscape Ecology: Conclusions and Future Directions.

Population Dynamics Introduction

Systems. Environmental Systems and Societies Interrelationships among climate, geology, soil, vegetation, and animals.

Welcome Grant from National Science Foundation: Fire, Atmospheric pCO 2, and Climate as Alternative Primary Controls of C 4 -Grass Abundance: The Late-Quaternary.

Lesson Objectives All of you should be able to: Identify the parts of any given system. Most of you will be able to: Describe all elements of any given.

1 William P. Cunningham University of Minnesota Mary Ann Cunningham Vassar College Chapter 02 Lecture Outline Copyright © McGraw-Hill Education. All rights.

Neural Networks and Machine Learning Applications CSC 563 Prof. Mohamed Batouche Computer Science Department CCIS – King Saud University Riyadh, Saudi.

1. Synthesis Activities on Hydrosphere and Biosphere Interactions Praveen Kumar Department of Civil and Environmental Engineering University of Illinois.

Biocomplexity Teacher Workshop May 31 – June 2, 2008 University of Puerto Rico.

What do terms like biosphere, ecosystem, population, and ecology make you think of? Work with 3-4 partners and quickly sketch a concept map. SBI4U RHSA.

Lifelong Learning = Resilient Communities Reflecting on the theme for the 2012 Adult Learning Australia Conference Dr Roslyn Foskey Adjunct Lecturer in.

TRANSFORMING AUSTRALIA TO REMAIN RESILIENT. food waterenergy climate change antibiotic resistance, new diseases economic shocks refugees, war, terrorism.

Chapter 3: The Big Picture: Systems of Change. Systems A system is a set of components or parts that function together to act as a whole. –E.g. Body,

Boreal forest resilience Some initial thoughts BNZ LTER meeting, March 2009 Terry Chapin & Jill Johnstone.

An Introduction to Systems

Chapter 4 Motor Control Theories Concept: Theories about how we control coordinated movement differ in terms of the roles of central and environmental.

AUTOMATIC CONTROL THEORY II Slovak University of Technology Faculty of Material Science and Technology in Trnava.

Emergence of Landscape Ecology Equilibrium View Constant species composition Disturbance & succession = subordinate factors Ecosystems self-contained Internal.

MODELS PURPOSE: Predict the future, test outcomes of various scenarios, identify the important components or variables, and understand how the parts interact.

Ecology --- primary definition The scientific study of how organisms interact with the natural world.

Climate Sensitivity Succession Regime Shifts Integration Current Proposal: The Dynamics of Change Next Proposal (due in < 4 years!!) Human Dimensions K-12.

13.1 Ecologists Study Relationships KEY CONCEPT Ecology is the study of the relationships among organisms and their environment.

© D. M. Steketee, SUSTAINABILITY=An aspiration for A SYSTEM CONDITION.

Space Is the Final Frontier in Ecology

CARBON, WATER, LAND USE & CLIMATE

Cycles of the Earth & Biogeochemical Cycles

TRANSFORMING AUSTRALIA TO REMAIN RESILIENT

Chapter 02 Lecture Outline

Nature-inspired Robustness Rüdiger W. Brause

The Basics of Complex Adaptive Systems Theory

Chapter 02 Lecture Outline

7 Environmental Systems and Ecosystem Ecology Part A

Coupled Human - Environment Systems

Principles of Science and Systems

Chapter 02 Lecture Outline

Emergent Properties of Coupled Systems

Forest health and global change

Presentation transcript:

2 Climate variability - change in average, variation, and/or extreme values

New Reality Seastedt et al. 2008, Frontiers in Ecology, Novel ecosystems will be increasingly common

Time Ecosystem characteristics C Management objective A Complexity management objective B Silvicultural interventions Modified from Puettmann et al. Management objective “Complexity” management approach

This can be achieved by viewing and managing ecosystems as complex adaptive systems

The most important ideas about ecosystems come from Complex Systems Science: Much of the order/pattern we see in the world comes, not from top down control, but from local-level (bottom-up) interactions among system components. (self-organization) Examples: Examples: grass roots social movements, viral YouTube, ant colonies, microbial networks

 A system with many parts  The parts interact (inter- dependent, feedbacks)  Emergence or synergy  The whole is greater than the sum of the parts (interactions give rise to emergent properties).  Bottom-up self-organization  Adaptive, Evolving  System memory  Fuzzy, open boundaries

Feedbacks are the key to self-organization of terrestrial ecosystems Ehrenfeld et al. (2005)

 Unpredictable: because interactions non-linear  Contagion: easy spread due to interconnection  Modularity: some parts more intra-connected than inter-connected (e.g., above- and belowground foodwebs)  Redundancy  Resilient

Forest ecosystems: cross- scale interactions and emergence of self- organization Forest structure is emergent property

Neural networks underpin the brain as a complex adaptive system  Feedback loops, cross scales  Non-linear, sometimes chaotic  Indeterminate, unpredictable  Self-organization  Emergent properties  System memory  Non-equilibrium, open to outside  Fuzzy boundaries  Adaptive “use it or lose it” “mindful practice” “neurons that wire together, fire together”

EQUILIBRIUM PERSPECTIVE  The future is the basically the same as the past  Most systems return to a stable state  Time is reversible COMPLEXITY PERSPECTIVE  The future is never the same as the past  Systems continue to evolve  Time is like an arrow -not reversible

Climate essentially stable at time scales relevant to ecosystem management After disturbance, ecosystems follow a predictable trajectory back to a climax state Zonal soils and zonal plant communities best reflect the regional climate Climate variable over short and long time scales relevant to ecosystem management Disturbance and recovery are ongoing processes; Both ecosystems and soils change over time Equilibrium vs. Non-Equilibrium Perspective of System Dynamics Equilibrium PerspectiveComplexity Perspective

Essentially one pathway to stability Disturbance seen as an aberration Time succession disturbance