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CHAPTER 5
Principles and Practices
of Ecological Restoration
Introduction
Restoration as a general term means returning
some degraded portion of landscape to an improved
and more natural preexisting condition. It
means reestablishing a healthy ecosystem which
Aldo Leopold (1949) defined as “the capacity of
the land for self-renewal.” John Berger (1990),
author of Restoring the Earth, called restoration
“an effort to imitate nature in all its artistry and
complexity by taking a degraded system and making
it more diverse and productive.”It can involve
the reestablishment of an ecosystem, the control of
air pollution, the prevention of acid rain, or the
protection of habitat for animals where they nest,
rest, and spend the winter. Restoration can mean
making something grow on bare soil or on damaged,
inverted soils (e.g., mine spoil). Restoration
also means replanting a forest in a field. Sometimes
it is the practice of an art (things work for reasons
not known) and sometimes it is science (things
work and we know why). Because this book deals
broadly with the restoration of landscapes and
managed lands, we decided to use the term ecological
restoration to mean returning a specific area to
its predisturbance condition, including both functional
and structural characteristics. In reality, some
of the projects and goals outlined in this book are
habitat creations. The uncertainty about the extent
and composition of the original community may
make habitat creation both practical and necessary
for overall ecological restoration. In the limited
areas available for golf course construction, for
example, restoration of a hydrologically altered
wetland may not be possible, but creation of a fully
functioning marsh or swamp may be possible and
desirable.
What is the difference between ecological restoration
and natural landscaping? To some extent, restoration
encompasses all plantings designed to improve
a site. Natural landscaping can be considered a
form of restoration. For the purposes of this book,
ecological restoration is distinquished from natural
landscaping. If the goal is to restore a native plant
community and a complement of native species from
that community has been used in a planting scheme,
then it is ecological restoration. Natural landscaping is
the planting of a group of native species to meet some
specific aesthetic, management, or design goals. There
is generally a difference of intent and scale between
these two actions. Ecological restoration is large and
allows a community to evolve and natural succession
to occur. Natural landscaping is conducted on a
smaller scale and tends to remain at a particular
managed level or state.
The natural world without human intervention
is the cumulative, dynamic response to millions of
years of reacting to itself and the physical world
around it. Humans do not understand all of the
intricacies of ecosystems. We channelize a stream
to drain a wetland and, in the simplicity of our
desires and understanding, destroy what the wetland
is to the stream—a source of water in summer,
a filter of chemicals and sediment, a refuge for
young fish, and a sponge to soak up and hold heavy
rains. Destroying the results of millions of years of
nature’s work is infinitely easier than restoring it.
Ecological restoration is the art and science of
recreating viable natural or ecological communities.
It goes beyond just doing plantings for the
purpose of stabilizing areas that are eroding. It goes
beyond the idea of landscaping with native plants.
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It is an attempt to recreate nature. Nature, of course,
is a lot of things. It is weather and climate, soils,
water, slope, aspect, and altitude. It is also a squirrel
that buries an acorn and a bird that eats a seed.
Nature is mushrooms, lichens, wildflowers, and
trees. To restore a truly natural system is beyond the
capacity and knowledge of humans. We can, however,
bring together the basic components and
characteristic plants and animals of an area (Table
5.1). Nature is assisted and directed by ecological
restoration. Natural processes will take over and
other components of the natural system will naturally
invade the restored system. Of course, some
systems are so devastated and the sources of plants
and animals available for reinvasion are so remote
that nearly everything must be provided by the
restorationist.
Don Falk (1990) of the Center for Plant Conservation
says in ecological restoration we seek not to
“preserve” a static entity but to protect and nurture
its capacity for change. “Restoration thus uses the
past not as a goal but as a reference point for the
future. If we seek to recreate the temperate forests,
tallgrass savannas, or desert communities of centuries
past, it is not to turn back the evolutionary clock
Habitat Characteristic Habitat Elements No. of
Species
1. Forest Cover 0–9 Years Old Forage, open areas, 49
high stem densities, dense cover
2. Old Growth–Forest Cover Large diameter, mast, snags, dens, 270
>100 Years Old logs, layered vegetation
3. Oak and Oak–Pine Forest Mast, cavity trees, and snags 80
>50 Years Old
4. Pole and Sawtimber with CrownForest cover with closed canopies 41
Closure over 80%
5. Sawtimber with 20–30% Sawtimber with moderate to open 61
Ground Cover understory
6. Oak forest >50 Years Old Sawtimber with moderate to dense 74
With a Dense Understory understory
7. Open and Semi-Open Forage, dense cover, some mast, 200
(nonforested) Habitats cavities
8. Permanent Water Sources Water for drinking, breeding, ——
feeding, roosting sites
9./10. Den Trees/Snags Cavities for nesting, roosting, song 155
and observation perches, feeding, shelter,
and eventually fallen woody material
Table 5.1. Representative habitat characteristics identified for the MarkTwainNational Forest (Putnam 1988).
but to set it ticking again.”
John Cairns (1988b) questions whether restoration
of ecological communities to their original
condition may be practical or possible. He offers
the following observations:
n Information about the original system may
be inadequate. For example, there is no
adequate description of the preindustrial Ohio
River that includes a detailed species inventory,
along with detailed descriptions of the
spatial relationships, trophic dynamics, and
functional attributes of the system.
n An adequate source of species for
recolonization may not be available because
of the uniqueness of the damaged community
or because the remaining communities
of this type would be damaged by removing
organisms for recolonization elsewhere.
n It may be impossible to put a halt to some of the
factors causing the damage. The notorious
example is acid rain, which may originate
many miles away in a political jurisdiction
over which the restorationist has no influence.
n The original ecosystem may have developed
as a result of a sequence of meteorological
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events that are unlikely to be repeated and
may be difficult or impossible to reproduce.
n The sheer complexity of duplicating the
sequencing of species introductions is overwhelming.
To recreate the original community,
it is not only necessary that species
colonize at the appropriate time, but also that
some decolonize (disappear) at the appropriate
time.
The restoration efforts envisioned by this book
can be considered only partial restorations of natural
communities, designed to set the “evolutionary
clock ticking again.” A repertoire of target ecological
communities is compiled as Appendix A. They
represent over 200 different dominant communities
found in 30 natural regions of the continental
United States (see Chapter 6). These communities
can be targets for more restoration research as well
as starting points for initiating restoration efforts.
The species lists will, we hope, encourage nurseries
to propagate these plant materials for restoring
these basic ecological communities.
The type of restoration program undertaken
depends upon the goals for a site or landscape.
Goals can include aesthetics, reestablishment of
natural conditions, maintenance of a diversity of
plant and animal species, protection of the local
gene pool of particular species, reduction of grounds
maintenance costs and environmental impacts, and
creation of representative local ecosystems.
Often more than one goal is possible for any
given restoration project. While all the reasons
listed above are significant, goals may be quite
limited. For instance, restoration to increase the
carrying capacity for a given plant or animal is a
specific desired outcome. However, in the process
of restoring a specific habitat for a species, habitat
for other species will also result. A number of spinoff
benefits may result from any restoration project,
but the reported success or failure of the effort is
almost entirely based on a single criterion. A more
comprehensive, idealized goal would be to emulate
a healthy, ecologically robust, natural, self-regulating
system that is integrated with the ecological
landscape in which it is situated (Cairns 1991).
The focus of this handbook will be restoring
presettlement, predisturbance, and/or natural conditions.
Presettlement conditions are defined as
conditions encountered by the first European settlers
to describe the North American landscape.
Although early historical accounts of the first Europeans
are sketchy, we have a general idea of the
broad vegetation types present during the 1700s
and 1800s. Native Americans had inhabited North
America for centuries and through the pattern and
timing of harvests, as well as through the burning,
pruning, weeding, and planting of some sites, certain
mixtures and frequencies of plants and animals
were favored (for examples, see Boyd 1986;
Whitney 1994; Anderson 1993, 1996). Native
American land uses sustained native landscapes
rather than severely altering or degrading them.
The mutual existence of large herds of bison and
Native Americans contrasted with the rapid decline
in bison herds as European settlers moved
westward supports this idea. In fact, our understanding
of indigenous methods and practices may
lead to improved restoration methods and approaches
to restoration.
Predisturbance is the approximate condition of
the site prior to a major land degradation event.
Sometimes neither presettlement nor predisturbance
conditions are possible as a restoration goal. Information
regarding species composition and structure
may be lacking or the climate or another
important physical parameter may not exert the
same influence as it did in presettlement or
predisturbance times. The behavior of an ecological
system depends to some degree upon its unique
past, specific spatial setting, and current influences
(Pickett and Parker 1994). All ecosystems are the
product of climatological and biogeochemical sequences
that probably are unique (Cairns 1991).
This is why restoration projects must be very sitespecific
and flexible in terms of preferred goals.
Restoration to predisturbance condition may
not even be as appropriate as restoration to a
present natural condition. The difference between
predisturbance and natural conditions is that predisturbance
is a past condition, whether it is a few
years or a few decades. Predisturbance condition is
our best estimation of how an area appeared before
a human disturbance occurred. Natural condition
may be indistinguishable from predisturbance condition,
especially when one considers our lack of
detailed accounts of many ecological communities.
The difference in these conditions is that the
natural condition is based on a present day existing
model system (such as an adjacent intact natural
area) while predisturbance (as well as presettlement)
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conditions are based on conceived previous or
historic accounts. Species in ecosystems are influenced
by both short- and long-term events, and the
inability to recreate a special sequence may mean
that attempts to restore to presettlement or
predisturbance conditions are unlikely to succeed
because of this fact alone (Cairns 1989). That is
exactly why restoration of natural conditions representative
of an existing local ecosystem (comparable
undisturbed system) is often more realistic.
As Dan Willard (quoted in Primack et al. [1995])
stated, “restore to a system that will work, not
necessarily the system that you wish would work.”
Some other types of restoration include rehabilitation
of selected attributes (e.g., forested) as well as
creation of an alternative ecosystem (Magnuson et
al. 1980).
Pickett and Parker (1994) stated that one of the
“pitfalls” of restoration ecology is “the assumption
that there is one reference state or system that can
inform restoration.” To assume that there is only
one ecologically legitimate or ideal system for a site
is a trap. However, Aronson et al. (1995) argue that
for the purposes of project design and evaluation, it
is desirable to establish at the outset some standard
of comparison and evaluation, even if it is arbitrary
and imperfect. Aronson et al. (1993a, 1993b) call
this the “ecosystem of reference.” This standard is
followed (in the broad sense) in the present handbook
by the use of Ecological Restoration Types
and Dominant Ecological Communities. A standard
of comparison and evaluation allows the
restorationist to track progress and to determine
success or evaluate the need to select another ecosystem
type for restoration on a particular site. The
creation of habitats in places they may never have
occupied is an approach with great potential for
sites that are so degraded that restoration to even a
semblance of the original habitat type is impractical.
This approach is valuable for landfilled sites,
surface mined areas, contaminated sites, or regionally
rare communities.
Matsui (1996) described an interesting project
from 20th-century Japan in which the goal was to
create a majestic, tranquil forest and landscape that
would be able to regenerate and survive almost
forever, not for economic reasons, but because this
was to be a holy place. Although the plan for the
project (Meji Shrine) was modeled to some extent
on natural forests of the area, no attempt was made
to create a natural ecosystem in the modern sense.
Instead, they assembled species from various areas
that they felt would grow well on the site. The
primary goal was for the forest to last forever with
little or no maintenance. While modeling a restoration
project after a natural community is typically
how restoration projects are planned, value (ecological
and cultural) also exists in creating habitats
for other purposes.
The best manner in which restoration projects
should be designed and evaluated is often not
clearly defined (Cairns 1989, Simberloff 1990,
Sprugel 1991). Many ecological and societal reasons
influence the choice of certain reference states,
including aesthetics, commodity production, ecosystem
services, and species protection, among
others (Pickett and Parker 1994). Aronson et al.
(1995) asked the question, “If no reference or
‘control’ is selected, how can the project be evaluated?”
For the purposes of this handbook, ecological
restoration means recreating both functional
and structural characteristics of a damaged ecosystem.
While this book concentrates mostly on vegetation,
discussions of other important considerations
also are presented.
A full-scale model need not exist; all else
failing, at least a few square feet or tens of square
feet may usually be found as a vestige of former
vegetation, and this can serve as a micro-model,
reference, and inspiration all at the same time
(Aronson et al. 1995). No criteria or guidelines that
provide ecological predictive capability are found
in the professional literature (Cairns 1989). Some
efforts will be so far from expectation that the
project should be terminated and a fresh start made
using a new design. Even an ecologically unsuccessful
project may appear successful to laymen
because a devegetated area has been revegetated or
because they may not understand the management
effort required to sustain the ecosystem (ibid.). All
restoration projects should have an explicit statement
of the product to be ultimately produced and
the condition at intermediate stages toward the
eventual goal. Each restoration project should have
several alternative standby plans so that if Plan A
fails, Plan B can be implemented. Communicating
that the outcome is uncertain is extremely important.
Incorporating an alternative course of action
into the restoration plan is equally important. In any
restoration project, the goals and the consequences
of meeting those goals must be part of the planning
process (Cairns 1991).
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We now prefer to think in terms of many
equally possible ecosystem trajectories and of guiding
or piloting the ecosystem under study in one
direction or another (Aronson et al. 1995). Luken
(1990) used the phrase “directing ecological succession”
in order to manage for a particular successional
stage.
Ecological Restoration
Planning
Many steps are required to conduct a successful
restoration project. The most important component
for success is understanding that restoration takes
time. Actually, restoration, like other aspects of
looking after the earth, is an eternal vigil. As part of
that vigil, planting trees is an act of hope and
optimism. If one plants small trees and waits for a
canopy to plant understory shrubs, many years will
pass. Even a restored prairie of grasses and forbs
will take years before it resembles a natural community.
The level of maintenance required to look
after a forest while it is developing is, however,
relatively low compared to the meticulous, incessant
care of a golf green or a lawn. The long-term
maintenance of a restored natural ecosystem is
negligible.
The Natural Resources Management Staff of
the McHenryCounty (Illinois) Conservation District
(1996) have broken the process of natural
community restoration into three distinct phases:
structural, functional, and compositional. During
the structural phase a community's original structure
is recreated, as invasive brush, fencelines,
roadways, buildings, and other human modifications
to the site are removed. The functional phase
involves the reintroduction of ecological factors
such as fire, grazing, and hydrological processes
that shaped the site's ecological communities prior
to Euro-American settlement. Finally, in the compositional
phase, plant and animal species are
reintroduced and exotic species removed in order to
restore the community as closely as possible to its
historic composition. Planning a restoration project
in phases such as these improves the success rate.
Jackson et al. (1995) stated that while every