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Environmental Management

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02.01.2017

Managing for No Net Loss of Ecological Services: An Approach for Quantifying Loss of Coastal Wetlands due to Sea Level Rise

verfasst von: Jennifer Kassakian, Ann Jones, Jeremy Martinich, Daniel Hudgens

Erschienen in: Environmental Management | Ausgabe 5/2017

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Abstract

Sea level rise has the potential to substantially alter the extent and nature of coastal wetlands and the critical ecological services they provide. In making choices about how to respond to rising sea level, planners are challenged with weighing easily quantified risks (e.g., loss of property value due to inundation) against those that are more difficult to quantify (e.g., loss of primary production or carbon sequestration services provided by wetlands due to inundation). Our goal was to develop a cost-effective, appropriately-scaled, model-based approach that allows planners to predict, under various sea level rise and response scenarios, the economic cost of wetland loss—with the estimates proxied by the costs of future restoration required to maintain the existing level of wetland habitat services. Our approach applies the Sea Level Affecting Marshes Model to predict changes in wetland habitats over the next century, and then applies Habitat Equivalency Analysis to predict the cost of restoration projects required to maintain ecological services at their present, pre-sea level rise level. We demonstrate the application of this approach in the Delaware Bay estuary and in the Indian River Lagoon (Florida), and discuss how this approach can support future coastal decision-making.

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The analyses conducted in this paper were completed in collaboration with two National Estuary Programs (NEP) in the U.S., the Partnership for the Delaware Estuary and the Indian River Lagoon NEP (Florida). This work was funded by the U.S. Environmental Protection Agency’s Climate Ready Estuaries program, a partnership between EPA and the NEPs on coastal adaptation to climate change.

Initial development of SLAMM occurred in the 1980s (Park et al. 1986). Warren Pinnacle Consulting continues model development through contracts with EPA and various non-profit and other groups. Documentation on SLAMM is available from http://www.warrenpinnacle.com/prof/SLAMM/index.html ^.

The model provides a set of accelerated sea level rise scenarios for the user, either IPCC (2000) scenarios or Titus and Narayanan (1995), or the user may elect a specific increase by 2100 (e.g., 0.5 m).

In this context, the term “injury” is used to describe a measurable adverse change in the chemical or physical quality or the viability of the natural resource.

The National Oceanic and Atmospheric Administration (NOAA), U.S. Fish and Wildlife Service (FWS), and other natural resource Trustees use HEA for damage determination resulting from injuries to natural resources, as described under the Oil Pollution Act (OPA) and the Comprehensive Environmental Response, Compensation, and Liability Act (CERCLA). NOAA websites provide detailed descriptions of this method and guidance on its implementation (see http://www.darrp.noaa.gov/library/pdf/heaoverv.pdf and http://www.csc.noaa.gov/coastal/economics/habitatequ.htm).

NOAA provides four basic requirements necessary for appropriate implementation of HEA: (a) the primary services lost are biological (as opposed to human-use services); (b) there exists a means of quantifying the level of lost services due to the injury and the level of services gained by the compensatory restoration; (c) an estimate of recovery rates is available (i.e., natural recovery if applicable and restoration recovery); (d) suitable restoration sites exist (e.g., same habitat type as injured area, close by, likely to succeed). (Source: http://www.csc.noaa.gov/coastal/economics/habitatequ.htm).

The ecological service level is generally reported as the percentage of services provided, relative to a fully-functioning habitat (“baseline”). This service level may be a qualitative estimate (“best professional judgment”) of the overall habitat quality or may be based on a more quantitative evaluation of particular metrics (e.g., primary productivity or contaminant levels).

For further information on Habitat Equivalency Analysis, see, for example, NOAA (2006) or Unsworth and Bishop (1994).

We can contrast this methodology with more direct economic evaluations of ecological services, as might be provided by natural capital valuation (see, for example, http://www.naturalcapitalproject.org).

The ability of this type of compensatory restoration to achieve no net loss of ecosystem services is the underlying premise to the well-established requirement for compensatory mitigation under the Clean Water Act Section 404(b)(1) guidelines (40 CFR § 230.91–230.98).

We acknowledge that a goal of restoration may be to achieve a level of service above the baseline level, however, in this analysis it is assumed that the objective is to maintain the original level of benefits.

Due to the large size of these spatial data sets and internal processing limits of the model, we divide the watersheds into 27 subsites and excise data significantly inland from the shore (areas that had limited wetland information). We then rejoin the subsites for the watershed-level analysis and mapping.

Data sets include: “2007 Impervious Surface Data” published in 2008 by the State of Delaware, Office of Management and Budget; “Impervious surface area for Southeast Pennsylvania, 2000,” published in 2003 by Penn State University, Dept. of Meteorology; and Land Use/Land Cover data published in 2002 by the New Jersey Department of Planning, Office of Information Resources Management, Bureau of Geographic Information Systems.

For more information on tidal and vertical datums, see http://vdatum.noaa.gov/docs/datumtutorial.html.

Local expertise was provided primarily by members of the Partnership for the Delaware Estuary’s Climate Workgroup.

The primary productivity services provided by the beach and dry land habitats omitted from the analysis are small in comparison to those offered by tidal wetland and open water habitats, and thus are unlikely to have a substantial impact on the results. Because the benefits of these habitats are excluded from our calculation of the initial level of ecological services, but the benefits provided by the habitats to which they convert are included in the calculation of the final level of ecological services, the analysis may underestimate the amount of restoration required to achieve no net loss of services.

Maximum service for restoration projects is generally not equal to 100% for HEA. Based on literature reviews of restored habitats, created habitat is generally less productive, less diverse, and less robust than “natural” habitats over the time scale of relevance (e.g., Moreno-Mateos et al. 2012; Meli et al. 2014).

While primary productivity indicates a slight increase in wetland DSAYs due to inundation, the available land for marsh migration is limited relative to the overall impacts (e.g., roughly one percent of the change in regularly flooded marsh, Table 2) and the area was not brought forward in the analysis.

NASA developed these scenarios as part of an effort to examine climate change effects and adaptation strategies for all NASA facilities.

SLAMM is available for download at http://www.warrenpinnacle.com/prof/SLAMM/ while a HEA can be constructed in any spreadsheet application.

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Titel: Managing for No Net Loss of Ecological Services: An Approach for Quantifying Loss of Coastal Wetlands due to Sea Level Rise
verfasst von: Jennifer Kassakian
Ann Jones
Jeremy Martinich
Daniel Hudgens
Publikationsdatum: 02.01.2017
Verlag: Springer US
Erschienen in: Environmental Management / Ausgabe 5/2017
Print ISSN: 0364-152X
Elektronische ISSN: 1432-1009
DOI: https://doi.org/10.1007/s00267-016-0813-0

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