Ecological Engineering

Clive G. Jones
Cary Institute of Ecosystem Studies

Ecological engineering combines ecological understanding of the functioning of human-natural coupled systems (earth as it is today!) with engineering – using science, mathematics and experience for solving problems within constraints – to design management practices that are environmentally, socially and economically viable and sustainable.

Ecological engineering has the general strategic goal of maintaining or increasing ecological processes, and hence the tangible and less tangible goods and services they provide to humans, with minimal human intervention and minimal adverse collateral impact. This strategic goal reflects the original definition of ecological engineering by H. T Odum in 1962 as “…. those cases in which the energy supplied by man is small relative to the natural sources, but sufficient to produce large effects in the resulting patterns and processes”. Ecological engineering is accomplished by using the tendencies of ecosystems to self-organize, to resist external forcing, to be resilient (i.e., recover from disturbance), to adapt to change, to be multifunctional, and to be energetically and materially self-sufficient.

An ecological engineering approach can be used:

• to conserve the structure and functioning of ecosystems (e.g., maintaining forest regeneration);
• to restore them (e.g., reintroduce hedgerows and riparian zones into agroecosystems);
• to enhance their functioning (e.g., increase nutrient cycling rates, pollination);
• to substitute natural processes for human activities that depend on fossil-fuels and non-renewable resources (e.g., green roofs for air conditioning; constructed wetlands or forests for water purification instead of filtration plants);
• and as the basis for manufacturing design (e.g., closed industrial cycles, green chemistry, life cycle analysis, artificial ecosystems)

Ecological engineering is therefore a very broad conceptual approach encompassing many specific areas with similar general goals (e.g., habitat restoration, artificial ecosystems, urban and industrial ecological design, sustainable agriculture and forestry, wild land conservation, etc.).

Ecological Engineering Publications

• Jones, C. G.   2008.   Puffins' habits change habitat. Nesting practices erode island, making it unlivable for species. Poughkeepsie Journal   8 June, 6B.
  
  
• Jones, C. G.   2008.   The Army Corps of Engineers vs. muskrat engineers: Nature declared winner. Poughkeepsie Journal   6 July, 6B-7B.
  
  
• Jones, C. G., I. Dajoz, and L. Abbadie.   2008.   Ecological engineering and the sustainable redesign imperative. pp. 138-139In: L. Garnier (ed.). Between Man and Nature: Making the Relationship Last. Réserves de biosphére - Notes techniques 3 - 2008, UNESCO, Paris.  
  
  
• Byers, J. E., K. Cuddington, C. G. Jones, T. S. Talley, A. Hastings, J. G. Lambrinos, J. A. Crooks, and W. G. Wilson.   2006.   Using ecosystem engineers to restore ecological systems. Trends Ecol. Evol.   21(9):493-500.
  
  

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