Ecoengineering with Ecohydrology: Successes and failures in estuarine restoration

Michael Elliott,Lucas Mander,Krysia Mazik,Charles Simenstad,Fiona Valesini,Alan Whitfield,Eric Wolanski

doi:10.1016/j.ecss.2016.04.003

Abstract

Ecological Engineering (or Ecoengineering) is increasingly used in estuaries to re-create and restore ecosystems degraded by human activities, including reduced water flow or land poldered for agricultural use. Here we focus on ecosystem recolonization by the biota and their functioning and we separate Type A Ecoengineering where the physico-chemical structure is modified on the basis that ecological structure and functioning will then follow, and Type B Ecoengineering where the biota are engineered directly such as through restocking or replanting. Modifying the physical system to create and restore natural processes and habitats relies on successfully applying Ecohydrology, where suitable physical conditions, especially hydrography and sedimentology, are created to recover estuarine ecology by natural or human-mediated colonisation of primary producers and consumers, or habitat creation. This successional process then allows wading birds and fish to reoccupy the rehabilitated areas, thus restoring the natural food web and recreating nursery areas for aquatic biota. We describe Ecohydrology principles applied during Ecoengineering restoration projects in Europe, Australia, Asia, South Africa and North America. These show some successful and sustainable approaches but also others that were less than successful and not sustainable despite the best of intentions (and which may even have harmed the ecology). Some schemes may be ‘good for the ecologists’, as conservationists consider it successful that at least some habitat was created, albeit in the short-term, but arguably did little for the overall ecology of the area in space or time. We indicate the trade-offs between the short- and long-term value of restored and created ecosystems, the success at developing natural structure and functioning in disturbed estuaries, the role of this in estuarine and wetland management, and the costs and benefits of Ecoengineering to the socio-ecological system. These global case studies provide important lessons for both the science and management of estuaries, including that successful estuarine restoration is a complex and often difficult process, and that Ecoengineering with Ecohydrology aims to control and/or simulate natural ecosystem processes.

Highlights

Background and DefinitionsEnvironmental management aims to fulfil the ‘big idea’, i.e. ‘to protect and enhance the natural structure and functioning of the ecosystem while at the same time ensuring the processes which deliver ecosystem services from which we obtain societal goods and benefits’ (Elliott, 2014)
We focus on ecosystem recolonization by the biota and their functioning and we separate Type A Ecoengineering where the physico-chemical structure is modified on the basis that ecological structure and functioning will follow, and Type B Ecoengineering where the biota are engineered directly such as through restocking or replanting
This review emphasises Type A Ecoengineering initiatives which lead to the recolonization of biota and their food web relationships but, because of space restrictions, gives less attention to Type B ones involving the active introductions of organisms

Summary

Introduction

Background and DefinitionsEnvironmental management aims to fulfil the ‘big idea’, i.e. ‘to protect and enhance the natural structure and functioning of the ecosystem while at the same time ensuring the processes which deliver ecosystem services from which we obtain societal goods and benefits’ (Elliott, 2014). The remaining principles are that the design parameters and features should (3) be kept simple in order to deliver the functioning required but with the simplest design; (4) use energy inside the system or, if coming from outside work with nature, such as existing flow conditions, and lastly (5) aid the natural system and help achieve social goals and have an ethical dimension; this may involve ‘over-engineering’ the design in order to further protect human safety and property These principles aim to produce at least a ‘win-win’ for economy and ecology or even ‘triple wins’ by including human safety

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Conclusion