Restoration ecology

From Wikipedia, the free encyclopedia

Restoration ecology is  the study of recuperating degraded, damaged or  destroyed ecosystems through active human intervention. Restoration ecology specifically refers to the scientific study; however the term is  often used to include its application: ecological or, more  generally, environmental restoration.

Ecological restoration is  an “intentional activity that initiates or  accelerates the recovery of an  ecosystem with respect to its health, integrity and  sustainability” (SER 2004). The practice of ecological restoration includes erosion control and  reforestation, as well as habitat and  range improvement. Some forms of these applications are  hundreds or  even thousands of years old (Anderson 2005). However, the study of restoration ecology has only become a robust and  independent scientific discipline over the last two decades (Young et. al 2005).

The purpose of this entry is  to:

• introduce restoration ecology as a scientific discipline,
• give a brief justification for its importance,
• define its role within conservation biology,
• discuss its theoretical foundations
• explain a few emerging concepts in restoration ecology
• show some examples of theory influencing application
• present some ethical considerations
• and finally, to inspire increased interest in this field.

Contents 1 Rationale for Restoration 2 Conservation Biology and  Restoration Ecology 2.1 Approaches 2.2 Focuses 2.3 Modes of Inquiry 3 Theoretical Foundations 3.1 Disturbance 3.2 Succession 3.3 Fragmentation 3.4 Ecosystem Function 4 Emerging Concepts 4.1 Assembly 4.1.1 Stable States 4.2 Ontogeny 5 The Application of Theory 5.1 Soil Heterogeneity Effects on Community Heterogeneity 5.2 Invasion, Competitive Dominance and  Resource Use 5.3 Successional Trajectories 6 Ethical Considerations 6.1 Restoration is  “faking it” 6.2 Mitigation’s black eye 6.3 Ultimate complexity versus limited knowledge 6.4 Where’s the target? 7 The Era of Restoration 8 External links 8.1 Learn more 8.2 Societies and  Journals 8.3 Educational Opportunities 9 References

[edit] Rationale for Restoration

There is  consensus in the scientific community that the current environmental degradation and  destruction of many of the Earth's biota is  considerable, and  is taking place on a “catastrophically short timescale” (Novacek & Cleland 2001). In fact, estimates of the current extinction rate are  1000 to 10,000 times the normal rate (Wilson 1988) (see list of extinct animals for some examples). For many people biological diversity (biodiversity) has an  intrinsic value; humans have  a responsibility toward other living things, and  obligations to future generations.

On a more  anthropocentric level, natural ecosystems provide human society with food, fuel and  timber. more  fundamentally, ecosystem services involve the purification of air and  water, detoxification and  decomposition of wastes, regulation of climate, regeneration of soil fertility, and  pollination of crops. Such processes have  been estimated to be worth trillions of dollars annually (Daily et al. 1997).

Habitat loss is  the leading cause of both species extinctions (Wilson 1988) and  ecosystem service decline (Daily et al. 1997). There are  two ways to reverse this trend of habitat loss: conservation of currently viable habitat and  restoration of degraded habitat.

[ and  Restoration Ecology">edit] Conservation Biology and  Restoration Ecology

With regards to biodiversity preservation, it  should be noted that restoration activities are  complimentary to, not a substitute for, conservation efforts. Many conservation programmes, however, are  predicated on historical bio-physical conditions - i.e. they are  incapable of responding to global climate change, and  the assembleges "locked in" that become increasingly fragile and  liable to catastrophic collapse. In this sense, restoration is  essential to provide new spaces for migration of habitats and  their associated flora and  fauna (Harris et al, 2006). Also, conservation biology has organisms, and  not entire ecosystems and  their functions, as its focus, and  therefore has limited goals and  aims.

Restoration ecology, as a scientific discipline, is  theoretically rooted in conservation biology. While restoration ecology may be viewed as a sub-discipline of conservation biology, foundational differences exist between the disciplines’ approaches, focuses and  modes of inquiry.

[edit] Approaches

The fundamental difference between conservation biology and  restoration ecology lies in their philosophical approaches to the same problem. Conservation biology attempts to preserve and  maintain existing habitat and  biodiversity. In contrast, restoration ecology assumes that environmental degradation and  population declines are  somewhat reversible processes. Therefore, targeted human intervention can lead to habitat and  biodiversity recovery and  eventual gains.

[edit] Focuses

First, both conservation biology and  restoration ecology have  an unfortunate temperate terrestrial bioregion bias. Tropical and  marine systems have  been vastly underrepresented in the literature (Young 2000). This issue is  probably the result of these fields developing in the geopolitical north, and  both fields should attempt to reconcile this bias.

Second, perhaps because plants tend to dominate most (terrestrial) ecosystems, restoration ecology has developed a strong botanical bias, while conservation biology is  more strongly zoological (Young 2000).

Similarly, the principal systemic levels of interest differ between the disciplines. Conservation biology has historically focused on target individuals (i.e. endangered species), and  has thus concentrated on genetic and  population level dynamics. Since restoration ecology is  aimed at rebuilding a functioning ecosystem, a broader (i.e. community or  ecosystem) perspective is  necessary.

Finally, since soils define the foundation of any functional terrestrial system, restoration ecology’s ecosystem-level bias has placed more  emphasis on the role of soil physical and  microbial processes (Allen et al. 2002; Harris, 2003).

[edit] Modes of Inquiry

Conservation biology’s focus on rare or  endangered species limits the number of manipulative studies that can be performed. As a consequence, conservation studies tend to be descriptive, comparative and  unreplicated (Young 2000). However, the highly manipulative nature of restoration ecology allows the researcher to more  rigorously test hypotheses. In fact, every restorative activity is, in essence, an  experimental test of what limits populations (Young, personal communication).

[edit] Theoretical Foundations

Restoration ecology draws on a wide range of ecological concepts. The following are  brief descriptions of some of the more  influential concepts. (Note the community and  ecosystem level bias.)

[edit] Disturbance

Disturbance is  a change of environmental conditions, which interferes with the functioning of a biological system. Disturbance at a variety of spatial and  temporal scales is  a natural, and  even essential, component of many communities (White & Jentsch 2004).

Humans have  had limited “natural” impacts on ecosystems for as long as humans have  existed, however the severity and  scope of our modern influences has accelerated in the last few centuries. Understanding and  minimizing the differences between modern anthropogenic and  “natural” disturbances is  crucial to restoration ecology. For example, new forestry techniques that better imitate historical disturbances are  now being implemented (see http://www.newcommunityforestry.org/).

In addition, restoring a fully sustainable ecosystem often involves studying and  attempting to restore a natural disturbance regime (e.g. fire ecology).

[edit] Succession

Ecological succession is  the process by which the component species of a community changes over time. Following a disturbance, an  ecosystem generally progresses from a simple level of organization (i.e. few dominant species) to a more  complex community (i.e. many interdependent species) over a few generations. Depending on the severity of the disturbance, restoration often consists of initiating, assisting or  accelerating ecological successional processes (Luken 1990).

In many ecosystems, communities tend to recover following mild to moderate natural and  anthropogenic disturbances. Restoration in these systems involves hastening natural successional trajectories. However, a system that has experienced a more  severe disturbance (i.e. physical or  chemical alteration of the environment) may require intensive restorative efforts to recreate environmental conditions that favor natural successional processes.

[edit] Fragmentation

Habitat fragmentation is  the emergence of discontinuities in a biological system. Through land use changes (e.g. agriculture) and  “natural” disturbance, ecosystems are  broken up into smaller parts. Small fragments of habitat can only support small populations and  small populations are  more vulnerable to extinction. Further, fragmenting ecosystems decreases interior habitat. Habitat along the edge of a fragment has a different range of environmental conditions and  therefore supports different species than the interior. Fragmentation is  devastating for those species which require interior habitat and  may lead to the extinction of those species. Restorative projects can increase the effective size of a habitat by simply adding area or  by planting habitat corridors that link two isolated fragments. Reversing the effects of fragmentation and  increasing habitat connectivity are  central goals of restoration ecology.

[edit] Ecosystem Function

Ecosystem function describes the foundational processes of natural systems, including nutrient cycles and  energy fluxes. These processes are  the most basic and  essential components of ecosystems. an  understanding of the full complexity and  intricacies of these cycles is  necessary to address any ecological processes that may be degraded. A functional ecosystem, that is  completely self-perpetuating (i.e. no management required), is  the ultimate goal of restorative efforts. Because these ecosystem functions are  emergent properties of the system as a whole, monitoring and  management are  crucial for the long-term stability of an  ecosystem.

[edit] Emerging Concepts

Restoration ecology, because of its highly manipulative nature, is  an ideal testing ground for emerging community ecological principles (Bradshaw 1987).

[edit] Assembly

Community assembly “is a framework that can unify virtually all of (community) ecology under a single conceptual umbrella” (Young et. al 2005). Community assembly theory attempts to explain the existence of environmentally similar sites with differing assemblages of species. it  assumes that species have  similar niche requirements, so that community formation is  a product of random fluctuations from a common species pool (Young et. al 2001). Essentially, if all species are  fairly ecologically equivalent then random variation in colonization, migration and  extinction rates, between species, drive differences in species composition between sites with comparable environmental conditions.

[edit] Stable States

Alternative stable states are  discrete species compositional possibilities that may exist within a community. According to assembly theory, differences in species colonization, interspecific interactions and  community establishment may result in distinct community species equilibria. A community has numerous possible compositional equilibria that are  dependent on the initial assembly. That is, random fluctuations lead to a particular initial community assembly, which affects successional trajectories and  the eventual species composition equilibrium.

Multiple stable states is  a specific theoretical concept, where all species have  equal access to a community (i.e. equal dispersal potential) and  differences between communities arise simply because of the timing of each species’ colonization (Young et. al 2001).

These concepts are  central to restoration ecology; restoring a community involves not only manipulating the timing and  structure of the initial species composition, but also working toward a single desired stable state. In fact, a degraded ecosystem may be viewed as an  alternative stable state under the altered environmental conditions (van Andel & Grootjans 2006).

[edit] Ontogeny

The ecology of ontogeny is  the study of how ecological relationships change over the lifetime of an  individual. Organisms require different environmental conditions during different stages of their life-cycle. For immobile organisms (e.g. plants) the conditions necessary for germination and  establishment may be different from those of the adult stage (Young et. al 2005). As an  ecosystem is  altered by anthropogenic processes the range of environmental variables may also be altered. A degraded ecosystem many not include the environmental conditions necessary for a particular stage of an  organisms development. If a self-sustaining, functional ecosystem must contain environmental conditions for the perpetual reproduction of its species, restorative efforts must address the needs of organisms throughout their development.

[edit] The Application of Theory

Restoration is  defined as the application of ecological theory to ecological restoration. However, for many reasons, this can be a challenging prospect. Here are  a few examples of theory informing practice.

[edit] Soil Heterogeneity Effects on Community Heterogeneity

Spatial heterogeneity of resources can influence plant community composition, diversity and  assembly trajectory. Baer et al. (2005) manipulated soil resource heterogeneity in a tallgrass prairie restoration project. They found increasing resource heterogeneity alone was insufficient to insure species diversity in situations where one species may dominate across the range of resource levels. Their findings were consistent with theory regarding the role of ecological filters on community assembly. The establishment of a single species best adapted to the physical and  biological conditions can play an  inordinately important role in determining community structure.

[ and  Resource Use">edit] Invasion, Competitive Dominance and  Resource Use

“The dynamics of invasive species may depend on their abilities to compete for resources and  exploit disturbances relative to the abilities of native species.” Seabloom et al. (2003) tested this concept and  its implications in a California grassland restoration context. They found native grass species were able to successfully compete with invasive exotics for a range of resources. This suggests native California grasses are  dispersal limited and  exotics may currently dominate because of historical land use patterns.

[edit] Successional Trajectories

Progress along a desired successional pathway may be difficult if multiple stable states exist. Looking at over 40 years of wetland restoration data Klotzi and  Gootjans (2001) argue that unexpected and  undesired vegetation assemblies “may indicate environmental conditions are  not suitable for target communities.” Succession may move in unpredicted directions, but constricting environmental conditions within a narrow range may reign in the possible successional trajectories and  increase the likelihood of a desired outcome.

[edit] Ethical Considerations

Purposefully altering ecosystems is  a controversial issue; Restoration poses several ethical quandaries. Below are  a summary of the more  cogent objections as well as brief rebuttals. All of these questions are  important considerations when designing a restorative project.

[ is  “faking it”">edit] Restoration is  “faking it”

Argument: Humans cannot create real natural systems, they can only create simplified replicas.

Rebuttal: While this argument is  superficially correct, it  misses restoration ecology’s deeper ecological principles. The goal of restoration is  not to immediately recreate replacement ecosystems, rather to “jump-start” natural recuperative processes.

[edit] Mitigation’s black eye

Argument: The concept of restoration implies that any habitat destruction can be remediated. This permits habitat destruction in some areas since mitigation in other areas will "balance" overall loss.

Rebuttal: Mitigation is  a perversion of the overall goals of restorative efforts (i.e. to increase viable habitat). This is  not necessarily a problem with restoration, rather a problem with statutes that allow for mitigation.

[edit] Ultimate complexity versus limited knowledge

Argument: Because of the complexity of natural systems, restoration efforts are  likely to result in unforeseen and  negative outcomes.

Rebuttal: This argument is  undoubtedly true. However, some restorative efforts are  successful. By further developing restoration ecology as a science, we can increase our knowledge and  tip the balance toward positive outcomes.

[edit] Where’s the target?

Argument: If restoration is  repairing an  ecosystem toward some reference state, what state do we strive toward? The choice of a reference state is  necessarily arbitrary and  can simply be a reflection of human bias.

Rebuttal: This problem is  serious and  can only be addressed on a site specific basis.

• If we wish to restore an  ecosystem to its state “prior to degradation”, when do we choose?
  • If we use modern reference equivalents, how do we know these are  not also degraded?
    • If we wish to restore some level of function, how do we choose the desired process?

[edit] The Era of Restoration

Ecosystems have  incredible potential for natural recuperation. Nevertheless, every system has its limitations. Our species exists at a singular point in our evolution; we are  aware of the impact our lifestyle has on the earth, yet we fail to accede that we possess the means to affect change. At this unique stage in our history, between feigned ignorance of environmental problems and  gradual acceptance of their solutions, restoration ecology is  poised to become a powerful tool for facilitating the Earth’s innate recuperative mechanisms.

"Here is  the means to end the great extinction spasm. The next century will, I believe, be the era of restoration in ecology" E. O. Wilson, 1992

[edit] External links

[edit] Learn more

• A Guide to Restoration Ecology
• Download a 62-page Guide to Sustainable Forest Restoration from Forever Redwood, a redwood furniture maker.

[ and  Journals">edit] Societies and  Journals

• Society for Ecological Resoration International - official website.
• Society for Ecological Restoration Primer of Ecological Restoration

• Ecological Restoration- Journal published by the University of Wisconsin Press for people interested in all aspects of the practice of ecological restoration.
• Restoration Ecology - Journal published on behalf of the Society for Ecological Restoration International.

[edit] Educational Opportunities

• Graduate Study at the University of California, Davis
• Graduate Study at the University of Wisconson-Madison
• Center for Urban Restoration Ecology
• North Carolina State Restoration Ecology Program
• University of Victoria Restoration of Natural Systems Program
  

• Cranfield University, UK, Land Reclamation and  Restoration MSc Option
• University of Liverpool, UK, MSc Restoration Ecology of Terrestrial and  Aquatic Enviroments

[edit] References

Allen, M.F., Jasper, D.A. & Zak, J.C. (2002). Micro-organisms. In Perrow M.R. & Davy, A.J. (Eds.), Handbook of Ecological Restoration, Volume 1 Principles of Restoration, pp. 257-278. Cambride: Cambridge University Press. ISBN 0-521-79128-6

Anderson, M.K. (2005). Tending the Wild: Native American knowledge and  the management of California’s natural resources. Berkeley: University of California Press. ISBN 0-520-23856-7

Baer, S.G., Collins, S.L., Blair, J.M., Knapp, A.K. & Fiedler, A.K. 2005. “Soil heterogeneity effects on tallgrass prairie community heterogeneity: an  application of ecological theory to restoration ecology.” Restoration Ecology 13 (2), 413–424.

Bradshaw, A.D. (1987). Restoration: the acid test for ecology. In Jordan, W.R., Gilpin, M.E. & Aber, J.D. (Eds.), Restoration Ecology: A Synthetic Approach to Ecological Research, pp. 23-29. Cambridge: Cambridge University Press. ISBN 0-521-33728-3

Daily, G.C., Alexander, S., Ehrlich, P.R., Goulder, L., Lubchenco, J., Matson, P.A., Mooney, H.A., Postel, S., Schneider, S.H., Tilman, D. & Woodwell, G.M. (1997) “Ecosystem Services: Benefits Supplied to Human Societies by Natural Ecosystems.” Issues in Ecology 1 (2), 1-18.

Harris, J.A. (2003) Measurements of the soil microbial community for estimating the success of restoration. European Journal of Soil Science. 54, 801-808.

Harris, J.A., Hobbs, R.J, Higgs, E. and  Aronson, J. (2006) Ecological restoration and  global climate change. Restoration Ecology 14(2) 170 - 176.

Klotzi, F. & Gootjans, A.P. 2001. “Restoration of natural and  semi-natural wetland systems in Central Europe: progress and  predictability of developments.” Restoration Ecology 9 (2), 209-219.

Luken, J.O. (1990). Directing Ecological Succession. New York: Chapman and  Hall. ISBN 0-412-34450-5

Novacek, M.J. & Cleland, E.E. (2001). “The current biodiversity extinction event: Scenarios for mitigation and  recovery.” Proceeding of the National Academy of Science 98 (10), 5466-5470. SER (2004). The SER Primer on Ecological Restoration, Version 2. Society for Ecological Restoration Science and  Policy Working Group. http://www.ser.org/reading_resources.asp

Seabloom, E.W., Harpole, W.S., Reichman, O.J. & Tilman, D. 2003. “Invasion, competitive dominance, and  resource use by exotic and  native California grassland species.” Proceedings of the National Academy of Sciences 100 (23), 13384–13389.

van Andel, J. & Grootjans, A.P. (2006). Concepts in restoration ecology. In van Andel, J. & Aronson, J. (Eds.), Restoration Ecology, pp. 16-28. Massachusetts: Blackwell. ISBN 063205834

White, P.S. & Jentsch, A. (2004). Disturbance, succession and  community assembly in terrestrial plant communities. In Temperton, V.K., Hobbs, R.J., Nuttle, T. & Halle, S. (Eds.), Assembly Rules and  Restoration Ecology: Bridging the Gap Between Theory and  Practice, pp. 342–366. Washington, DC: Island Press. ISBN 1-55963-375-1

Wilson, E. O. (1988). Biodiversity. Washington DC: National Academy. ISBN 0-309-03739-5

Young, T.P. (2000). “Restoration ecology and  conservation biology.” Biological Conservation. 92, 73–83.

Young, T.P., Chase, J.M. & Huddleston, R.T. (2001). “Succession and  assembly as conceptual bases in community ecology and  ecological restoration.” Ecological Restoration. 19, 5–19.

Young, T.P., Petersen, D.A. & Clary, J.J. (2005). “The ecology of restoration: historical links, emerging issues and  unexplored realms.” Ecology Letters 8, 662-673.