Ecological engineering uses

ecology Ecology () is the study of the relationships between living organisms, including humans, and their physical environment. Ecology considers organisms at the individual, population, community, ecosystem, and biosphere level. Ecology overl ...

and

engineering Engineering is the use of scientific method, scientific principles to design and build machines, structures, and other items, including bridges, tunnels, roads, vehicles, and buildings. The discipline of engineering encompasses a broad rang ...

to predict, design, construct or restore, and manage

ecosystem An ecosystem (or ecological system) consists of all the organisms and the physical environment with which they interact. These biotic and abiotic components are linked together through nutrient cycles and energy flows. Energy enters the syst ...

s that integrate " human society with its

natural environment The natural environment or natural world encompasses all living and non-living things occurring naturally, meaning in this case not artificial. The term is most often applied to the Earth or some parts of Earth. This environment encompasses ...

for the benefit of both".W.J. Mitsch & S.E. Jorgensen (1989), "Introduction to Ecological Engineering", In: W.J. Mitsch and S.E. Jorgensen (Editors), ''Ecological Engineering: An Introduction to Ecotechnology''. John Wiley & Sons, New York, pp. 3-12.

Origins, key concepts, definitions, and applications

Ecological engineering emerged as a new idea in the early 1960s, but its definition has taken several decades to refine, its implementation is still undergoing adjustment, and its broader recognition as a new paradigm is relatively recent. Ecological engineering was introduced by Howard Odum and othersH.T. Odum et al. (1963), ''Experiments with Engineering of Marine Ecosystems'', in: ''Publication of the Institute of Marine Science of the University of Texas'', 9: 374-403. as utilizing natural energy sources as the predominant input to manipulate and control environmental systems. The origins of ecological engineering are in Odum's work with ecological modeling and ecosystem simulation to capture holistic macro-patterns of energy and material flows affecting the efficient use of resources. Mitsch and Jorgensen summarized five basic concepts that differentiate ecological engineering from other approaches to addressing problems to benefit society and nature: 1) it is based on the self-designing capacity of ecosystems; 2) it can be the field (or acid) test of ecological theories; 3) it relies on system approaches; 4) it conserves non-renewable energy sources; and 5) it supports ecosystem and biological conservation. Mitsch and JorgensenW.J. Mitsch and S.E. Jorgensen (1989), "Introduction to Ecological Engineering" In: W.J. Mitsch and S.E. Jorgensen (Editors), ''Ecological Engineering: An Introduction to Ecotechnology''. John Wiley & Sons, New York, pp. 3-12. were the first to define ecological engineering as designing societal services such that they benefit society and nature, and later notedW.J. Mitsch & S.E. Jørgensen (2003), "Ecological engineering: A field whose time has come", in: ''Ecological Engineering'', 20(5): 363-377.W.J. Mitsch and S.E. Jorgensen (2004), "Ecological Engineering and Ecosystem Restoration". John Wiley & Sons, New York the design should be systems based, sustainable, and integrate society with its natural environment. Bergen et al.S.D. Bergen et al. (2001), "Design Principles for Ecological Engineering", in: ''Ecological Engineering'', 18: 201-210. defined ecological engineering as: 1) utilizing ecological science and theory; 2) applying to all types of ecosystems; 3) adapting engineering design methods; and 4) acknowledging a guiding value system. Barrett (1999) offers a more literal definition of the term: "the design, construction, operation and management (that is, engineering) of landscape/aquatic structures and associated plant and animal communities (that is, ecosystems) to benefit humanity and, often, nature." Barrett continues: "other terms with equivalent or similar meanings include ecotechnology and two terms most often used in the erosion control field: soil bioengineering and biotechnical engineering. However, ecological engineering should not be confused with '

biotechnology Biotechnology is the integration of natural sciences and engineering sciences in order to achieve the application of organisms, cells, parts thereof and molecular analogues for products and services. The term ''biotechnology'' was first used b ...

' when describing genetic engineering at the cellular level, or ' bioengineering' meaning construction of artificial body parts." The applications in ecological engineering can be classified into 3 spatial scales: 1) mesocosms (~0.1 to hundreds of meters); 2) ecosystems (~1 to 10s of km); and 3) regional systems (>10s of km). The complexity of the design likely increases with the spatial scale. Applications are increasing in breadth and depth, and likely impacting the field's definition, as more opportunities to design and use ecosystems as interfaces between society and nature are explored. Implementation of ecological engineering has focused on the creation or restoration of ecosystems, from degraded

wetlands A wetland is a distinct ecosystem that is flooded or saturated by water, either permanently (for years or decades) or seasonally (for weeks or months). Flooding results in oxygen-free ( anoxic) processes prevailing, especially in the soils. The ...

to multi-celled tubs and

greenhouse A greenhouse (also called a glasshouse, or, if with sufficient heating, a hothouse) is a structure with walls and roof made chiefly of transparent material, such as glass, in which plants requiring regulated climatic conditions are grown.These ...

s that integrate microbial, fish, and plant services to process human

wastewater Wastewater is water generated after the use of freshwater, raw water, drinking water or saline water in a variety of deliberate applications or processes. Another definition of wastewater is "Used water from any combination of domestic, industri ...

into products such as fertilizers, flowers, and

drinking water Drinking water is water that is used in drink or food preparation; potable water is water that is safe to be used as drinking water. The amount of drinking water required to maintain good health varies, and depends on physical activity level, ...

. Applications of ecological engineering in cities have emerged from collaboration with other fields such as

landscape architecture Landscape architecture is the design of outdoor areas, landmarks, and structures to achieve environmental, social-behavioural, or aesthetic outcomes. It involves the systematic design and general engineering of various structures for constructio ...

urban planning Urban planning, also known as town planning, city planning, regional planning, or rural planning, is a technical and political process that is focused on the development and design of land use and the built environment, including air, water ...

, and urban horticulture, to address human health and biodiversity, as targeted by the UN Sustainable Development Goals, with holistic projects such as stormwater management. Applications of ecological engineering in rural landscapes have included wetland treatment and community

reforestation Reforestation (occasionally, reafforestation) is the natural or intentional restocking of existing forests and woodlands ( forestation) that have been depleted, usually through deforestation, but also after clearcutting. Management A debat ...

through

traditional ecological knowledge Traditional ecological knowledge (TEK) describes indigenous and other traditional knowledge of local resources. As a field of study in Northern American anthropology, TEK refers to "a cumulative body of knowledge, belief, and practice, evolving by ...

Permaculture Permaculture is an approach to land management and settlement design that adopts arrangements observed in flourishing natural ecosystems. It includes a set of design principles derived using whole-systems thinking. It applies these principle ...

is an example of broader applications that have emerged as distinct disciplines from ecological engineering, where

David Holmgren David Holmgren (born 1955) is an Australian environmental designer, ecological educator and writer. He is best known as one of the co-originators of the permaculture concept with Bill Mollison. Early life Holmgren was born in Fremantle, Wester ...

cites the influence of Howard Odum in development of permaculture.

Design guidelines, functional classes, and design principles

Ecological engineering design will combine

systems ecology Systems ecology is an interdisciplinary field of ecology, a subset of Earth system science, that takes a holism, holistic approach to the study of ecological systems, especially ecosystems. Systems ecology can be seen as an application of general ...

with the process of engineering design. Engineering design typically involves problem formulation (goal), problem analysis (constraints), alternative solutions search, decision among alternatives, and specification of a complete solution. A temporal design framework is provided by Matlock et al.,M.D. Matlock and others (2001), "Ecological Engineering: A Rationale for Standardized Curriculum and Professional Certification in the United States", in: ''Ecological Engineering'', 17: 403-409. stating the design solutions are considered in ecological time. In selecting between alternatives, the design should incorporate ecological economics in design evaluation and acknowledge a guiding value system which promotes biological conservation, benefiting society and nature. Ecological engineering utilizes

with engineering design to obtain a holistic view of the interactions within and between society and nature. Ecosystem simulation with Energy Systems Language (also known as energy circuit language or energese) by Howard Odum is one illustration of this systems ecology approach. This holistic model development and simulation defines the system of interest, identifies the system's boundary, and diagrams how energy and material moves into, within, and out of, a system in order to identify how to use renewable resources through ecosystem processes and increase sustainability. The system it describes is a collection (i.e., group) of components (i.e., parts), connected by some type of interaction or interrelationship, that collectively responds to some stimulus or demand and fulfills some specific purpose or function. By understanding systems ecology the ecological engineer can more efficiently design with ecosystem components and processes within the design, utilize renewable energy and resources, and increase sustainability. Mitsch and Jorgensen identified five Functional Classes for ecological engineering designs: # Ecosystem utilized to reduce/solve pollution problem. Example: phytoremediation, wastewater wetland, and bioretention of stormwater to filter excess nutrients and metals pollution # Ecosystem imitated or copied to address resource problem. Example: forest restoration, replacement wetlands, and installing street side rain gardens to extend canopy cover to optimize residential and urban cooling # Ecosystem recovered after disturbance. Example: mine land restoration, lake restoration, and channel aquatic restoration with mature riparian corridors # Ecosystem modified in ecologically sound way. Example: selective timber harvest, biomanipulation, and introduction of predator fish to reduce planktivorous fish, increase zooplankton, consume algae or phytoplankton, and clarify the water. # Ecosystems used for benefit without destroying balance. Example: sustainable agro-ecosystems, multispecies aquaculture, and introducing agroforestry plots into residential property to generate primary production at multiple vertical levels. Mitsch and Jorgensen identified 19 Design Principles for ecological engineering, yet not all are expected to contribute to any single design: # Ecosystem structure & function are determined by forcing functions of the system; # Energy inputs to the ecosystems and available storage of the ecosystem is limited; # Ecosystems are open and dissipative systems (not thermodynamic balance of energy, matter, entropy, but spontaneous appearance of complex, chaotic structure); # Attention to a limited number of governing/controlling factors is most strategic in preventing pollution or restoring ecosystems; # Ecosystem have some homeostatic capability that results in smoothing out and depressing the effects of strongly variable inputs; # Match recycling pathways to the rates of ecosystems and reduce pollution effects; # Design for pulsing systems wherever possible; # Ecosystems are self-designing systems; # Processes of ecosystems have characteristic time and space scales that should be accounted for in environmental management; # Biodiversity should be championed to maintain an ecosystem's self design capacity; # Ecotones, transition zones, are as important for ecosystems as membranes for cells; # Coupling between ecosystems should be utilized wherever possible; # The components of an ecosystem are interconnected, interrelated, and form a network; consider direct as well as indirect efforts of ecosystem development; # An ecosystem has a history of development; # Ecosystems and species are most vulnerable at their geographical edges; # Ecosystems are hierarchical systems and are parts of a larger landscape; # Physical and biological processes are interactive, it is important to know both physical and biological interactions and to interpret them properly; # Eco-technology requires a holistic approach that integrates all interacting parts and processes as far as possible; # Information in ecosystems is stored in structures. Mitsch and Jorgensen identified the following considerations prior implementing an ecological engineering design: * Create conceptual model of determine the parts of nature connected to the project; * Implement a computer model to simulate the impacts and uncertainty of the project; * Optimize the project to reduce uncertainty and increase beneficial impacts.

Academic curriculum (colleges)

An academic curriculum has been proposed for ecological engineering, and institutions around the world are starting programs. Key elements of this curriculum are:

environmental engineering Environmental engineering is a professional engineering discipline that encompasses broad scientific topics like chemistry, biology, ecology, geology, hydraulics, hydrology, microbiology, and mathematics to create solutions that will protect and ...

;

; restoration ecology; ecological modeling; quantitative ecology; economics of ecological engineering, and technical electives. Complementing this set of courses are prerequisites courses in physical, biological, and chemical subject areas, and integrated design experiences. According to Matlock et al., the design should identify constraints, characterize solutions in ecological time, and incorporate ecological economics in design evaluation. Economics of ecological engineering has been demonstrated using energy principles for a wetland., and using nutrient valuation for a dairy farm C. Pizarro and others, ''An Economic Assessment of Algal Turf Scrubber Technology for Treatment of Dairy Manure Effluent. Ecological Engineering, 26(12): 321-327.

Literature

* Howard T. Odum (1963), "Man and Ecosystem" Proceedings, Lockwood Conference on the Suburban Forest and Ecology, in: ''Bulletin Connecticut Agric. Station''. * * W.J. Mitsch (1993), ''Ecological engineering—"a cooperative role with the planetary life–support systems''. ''

Environmental Science & Technology ''Environmental Science & Technology'' is a biweekly peer-reviewed scientific journal published since 1967 by the American Chemical Society. It covers research in environmental science and environmental technology, including environmental policy. ...

'' 27:438-445. * * * * H.D. van Bohemen (2004)
''Ecological Engineering and Civil Engineering works''
Doctoral thesis TU Delft, The Netherlands. *

References

External links

Webtext, Ecological Engineering Group, 2007.
Ecological Engineering Student Society
Website, EESS, Oregon State University, 2011.
Ecological Engineering
webtext by Howard T.Odum Center for Wetlands at the University of Florida, 2007.

Organizations

American Ecological Engineering Society
homepage.
Ecological Engineering Student Society
Website, EESS, Oregon State University, 2011.
American Society of Professional Wetland Engineers
homepage, wiki.
Ecological Engineering Group
homepage.
International Ecological Engineering Society
homepage.

Scientific journals

Ecological Engineering
since 1992, with a general description of the field.
Landscape and Ecological Engineering
since 2005.
Journal of Ecological Engineering Design
Officially launched in 2021, this journal offers a diamond open access format (free to the reader, free to the authors). This is the official journal of the American Ecological Engineering Society with production support from the University of Vermont Libraries. {{DEFAULTSORT:Ecological Engineering Ecological restoration Environmental terminology Environmental engineering Environmental social science Engineering disciplines Climate change policy