Sylvain Pioch

Eco-design of Marine Infrastructures


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just 10 years, that is, an increase of 185% compared to 1970–2000 (Seto et al. 2012), and 3–4.7 million km2 of roads will be created by 2050, an increase of 25% compared to the current annual rate (Meijer et al. 2018).

      Faced with the enormous challenge of a renaturation of culture (Pelt 1977), for a livable future of humankind, it becomes crucial to improve the consideration of biodiversity in territorial planning projects. We will focus here on the potential for nature-friendly planning, trying to integrate its functional needs as a fully-fledged objective in the design of infrastructures.

      The actions taken to allow for the “natural” environment (we will use this term here in relation to the word “ecosystem”) for the operation of maritime works are varied. In the case of ports, these include the control and reduction of discharges, energy, sediment, waste and water management, environmental management plans (compliant since 2013), natural infrastructure master plans – including a natural heritage master plan – and Natura 2000 operators within the port perimeter (e.g. the Grand Port Maritime of Dunkirk).

      In spite of these virtuous impulses, in the field, during the first design phases of a project, the objectives are primarily to propose a structure that meets technical constraints (resistance, durability) with a controlled cost, aligned with socio-economic objectives that meet a functional need: a marina or a commercial port, an offshore wind turbine, a breakwater, an offshore wastewater treatment plant, etc. The environmental question is applied to justificatory and secondary considerations which are dealt with once the technical and socio-economic choices have been made, under regulatory “constraint” (Airoldi et al. 2021).

      This is where the purpose of eco-design, or oekodesign10, takes root, for its objective is to design a project, from sketch or feasibility phases (within the meaning of Act no. 85-704 of July 12, 1985, on public contracting and its relationship with private contracting, known as the MOP Act), according to ecological performance or co-benefit objectives. The aim is not to “wipe the slate clean” for the past but, based on technical engineering knowledge, to introduce biophysical considerations, in connection with the need to protect and develop the natural environment in the project to develop the sea.

      The eco-design of marine infrastructures is the result of recent cultural evolutions, as mentioned above. It is part of the interdisciplinary field of ecological engineering, which includes human sciences (geo-planning, law), engineering sciences (civil engineering, materials science) and natural sciences (biology, ecology). It responds to a major challenge for responsible human societies and biodiversity managers.

      The intimate link between ecology, land use planning and civil engineering is underlined by Van Bohemen (2004) who makes it the key to its diffusion and application. According to Bergen et al. (2001), the design of development projects must integrate the issues of human societies in an ecological approach, for a mutual human–nature benefit, following steps that ratify its application, the first three of which are:

      1 1) design in accordance with ecological principles;

      2 2) design adapted to the environmental specificity of each site;

      3 3) maintaining the functional requirements of the structures, regardless of environmental requirements.