Introduction

A common goal of ecological restoration is to establish habitat that is self-sustaining and resembles natural conditions in both structure and function (Thayer et al. 2003; Turner and Streever 2002). While restoration practitioners have made significant advances toward replicating the structure of natural habitats, key questions remain about how to re-establish and sustain key ecological functions over time. These questions include the following: (1) to what extent do mature restoration projects function similarly to natural habitats?; (2) what is the rate of development for specific ecological functions?; (3) what additional data are needed to reduce uncertainty in the rates of development of ecological functions?; (4) what restoration actions might increase the rates of development for desired functions?; and (5) are there synergies between different types of restoration projects that enhance restoration outcomes?

Many early coastal restoration projects focused on manipulating physical conditions and establishing habitat structure. Less effort was given to addressing whether restoration interventions resulted in similar ecological functions as natural habitats. Some ecological functions can take years to decades to develop or may never fully reach the level of natural reference habitats (McGlathery et al. 2012; Moreno-Mateos et al. 2012; Zedler and Callaway 1999). The restoration trajectory or the rate of development of ecological structure and functions and the time required for restored habitats to resemble to natural habitats, can have important implications for setting realistic expectations and calculating compensatory restoration requirements (e.g., Fonseca et al. 2000; Strange et al. 2002). Better understanding the trajectories associated with the restoration project development may also help restoration practitioners identify project features or approaches that speed the development of important functions and services (e.g., Karp et al. 2018; Madrid et al. 2012; Reynolds et al. 2012; Silliman et al. 2015). It can also help identify when to directly restore specific lost ecosystem functions (McCay et al. 2003) or prioritize the conservation of existing high function habitats (e.g., Beck and Odaya 2001; Levin and Stunz 2005), rather than conduct habitat restoration.

Extensive restoration of estuarine habitats will occur in the northern Gulf of Mexico (GOM), USA region over the next several decades through over $16 billion in funding provided by penalties and settlement agreements associated with the 2010 Deepwater Horizon oil spill (Deepwater Horizon Natural Resource Damage Assessment Trustees 2016; Gulf Coast Ecosystem Restoration Council 2016). This substantial investment in coastal habitat restoration is intended to provide broad ecosystem benefits, including provision of food, shelter, and spawning and nursery areas, to help restore the wide range of species and life stages that were injured by the spill. A better understanding of the ecological benefits of coastal habitat restoration projects can help managers compare projects and project designs and assist with the selection of projects that maximize benefits to the range of species and habitats targeted for restoration. With these goals in mind, this theme section presents seven papers that synthesize the existing data on the restoration of coastal habitats in the GOM. The papers identify gaps where additional data collection would improve the understanding of functional development and benefits to associated faunal resources, providing a foundation for future restoration work in the region and an approach that could be applied in other regions.

How Do Restored Coastal Habitats Compare with Natural Habitats?

For restored coastal marshes, habitat structure can develop quickly following restoration (Armitage et al. 2014; Cui et al. 2009; Edwards and Proffitt 2003; Virgin et al. 2020). Structure, however, does not always correlate with functions such as organic matter accumulation, nutrient transformation, or benthic invertebrate community characteristics (Cole 2002; Meli et al. 2014). Soil properties, including organic matter and nutrients, are particularly slow to develop in restored wetlands (Armitage et al. 2014; Craft et al. 2002; Cui et al. 2009; Edwards and Proffitt 2003; Llewellyn and La Peyre 2011; Morgan and Short 2002; Yu et al. 2017). In this issue, Ebbets et al. (2020) corroborate these findings, suggesting that for marsh restoration projects in the GOM, average belowground biomass and soil organic matter do not reach reference levels until more than 30 years after restoration is complete. The slow accumulation of soil organic matter may drive differences in benthic communities observed between restored and reference marshes, which can persist for decades following restoration (Craft et al. 1999, 2003; Craft and Sacco 2003; Levin et al. 1996; Minello and Webb 1997; Staszak and Armitage 2013; Streever 2000; Swamy et al. 2002; Zimmerman et al. 1979). The relatively slow development of salt marsh invertebrate communities in restored marshes is highlighted by the results of Baumann et al. (2020), who found that amphipod communities do not fully recover until more than 20 years following restoration.

Coastal marshes provide important functions for fish and invertebrate species, serving as spawning and nursery habitat, providing refuge from predators, foraging habitat, and environmental conditions that enhance survival and/or growth (e.g., overwintering habitat) (Beck et al. 2001; Boesch and Turner 1984; Deegan et al. 2002; Lefcheck et al. 2019; Rountree and Able 2006). These functions may not develop at the same rate at restored marsh sites (Meli et al. 2014). Gut content analyses and correlations between nekton density and soil organic content and benthic invertebrate densities suggest that trophic support functions may sometimes develop more slowly than other nekton habitat functions, driven by slow development of benthic infauna and epifauna communities (Allen et al. 1994; Minello and Zimmerman 1992; Warren et al. 2002; Zeug et al. 2007). Some studies suggest that it takes longer to achieve comparable nekton sizes, growth rates, and/or diet compared with reference marshes (Allen et al. 1994; Moy and Levin 1991; Warren et al. 2002; Weinstein et al. 2019; Zeug et al. 2007), but there are also conflicting examples (Llewellyn and La Peyre 2011; Rozas and Minello 2009; Simenstad and Thom 1996). Such delays are observed more often in marshes created using dredged material with low organic content. By contrast, many tidally restricted marshes show rapid development of sediment organic content, benthic invertebrates, and nekton feeding patterns and growth once flooding has been re-established (Able et al. 2008; James-Pirri et al. 2001; Lechene et al. 2018; Miller and Able 2002; Nemerson and Able 2005; Teo and Able 2003a, b; Tupper and Able 2000; Weinstein et al. 2019).

In general, nekton communities establish rapidly at restored marsh sites, with restored marshes capable of supporting nekton densities and community compositions similar to natural marshes as quickly as 1 to 2 years following restoration (Able et al. 2008; Dionne et al. 1999; Jivoff and Able 2003; Konisky et al. 2006; Lechêne et al. 2018; Nemerson and Able 2005; Raposa and Talley 2012; Roman et al. 2002; Simenstad and Thom 1996; Williams and Zedler 1999). However, this is not always the case for restored marshes or all species (Havens et al. 2002; Minello 2000; Minello and Webb 1997; Moy and Levin 1991; Streever 2000). In this issue, Hollweg et al. (2020b) use a meta-analysis approach to re-examine data from paired restoration and reference sites in the northern GOM region. They find that mean nekton densities at restored sites do not achieve equivalence with reference sites until 13 years after restoration, a trend that is strongly driven by lower crustacean densities at restored sites (Hollweg et al. 2020b). Some of the variability observed in nekton community establishment at created marshes may be attributed to factors such as the type of dredged sediments used, marsh elevations, rates of sediment organic matter accumulation, and benthic community development (Minello and Webb 1997; Thom et al. 2004; Zeug et al. 2007). Project-specific features such as tidal connectivity, substrate variability, shallow ponds, and the amount of marsh edge habitat can also have a strong influence on the functions of restored wetlands (Larkin et al. 2008; Minello and Webb 1997; Weinstein et al. 2005; Zeug et al. 2007).

Restoration outcomes for submerged aquatic vegetation (SAV) beds have been variable. Recent reviews of SAV restoration outcomes from Chesapeake Bay and Europe and a global meta-analysis of SAV restoration found that few restored sites survive beyond 1 year (Cunha et al. 2012; Luckenbach et al. 2011; van Katwijk et al. 2016). The results of these reviews contrast with numerous individual studies over the past few decades that have documented examples of successful SAV restoration (Bell et al. 2014; Fonseca et al. 1996a; Kenworthy et al. 1980; McSkimming et al. 2016; Sheridan 2004). In some cases, monitoring timeframes much longer than 3 years may be necessary to fully capture the restoration trajectories of SAV beds ( Bell et al. 2008, 2014; McGlathery et al. 2012).

Appropriate site selection is particularly important for SAV restoration, as water quality and water clarity are important drivers of restoration outcomes (Golden et al. 2010; Luckenbach et al. 2011; Orth et al. 2010; van Katwijk et al. 2016). Loss of historic SAV beds can create feedbacks with water flow velocity that can increase turbidity and make it difficult for SAV to re-establish, potentially explaining the high failure rate for SAV restoration attempts (van der Heide et al. 2007). The range of techniques that have been used for SAV restoration complicates the development of restoration trajectories for SAV beds. For example, seeding can result in different outcomes from transplanting (Fonseca et al. 1990; van Katwijk et al. 2016) and the timing of planting, interannual variability in environmental conditions, use of fertilization, and genetics of the donor stock can also influence outcomes (Bologna and Sinnema 2012; Jahnke et al. 2015; Kenworthy et al. 2018; Orth et al. 2009; Powell et al. 1991; Reynolds et al. 2012). However, nekton and epifauna can respond rapidly to successful SAV restoration, with abundance/density, species composition, and size at restored sites resembling those of natural SAV beds within a couple of years (Fonseca et al. 1990, 1996b; McSkimming et al. 2016; Scapin et al. 2016; for exceptions, see Sheridan et al. 2003). Colonization by resident epibenthic fauna may be dependent on the restored bed first reaching a minimum shoot density (Fonseca et al. 1990, 1996b).

By contrast, restored oyster reefs tend to demonstrate rapid development of both ecosystem structure and function, as long as they are located in environmental settings with suitable salinity, water quality, and oyster larval transport (Beseres Pollack et al. 2012; Powers et al. 2009). Under the right conditions, restored eastern oyster (Crassostrea virginica) reefs have been shown to support similar oyster densities as natural oyster reefs within just a few years, with examples from the GOM (Chambers et al. 2017; Dillon et al. 2015; Frederick et al. 2016; La Peyre et al. 2014; Rezek et al. 2017), South Carolina (Hadley et al. 2010), North Carolina (Hanke et al. 2017; Keller et al. 2019; Meyer and Townsend 2000), and Chesapeake Bay (Schulte et al. 2009). Similar outcomes have also recently been reported for other oyster species in Australia (Shelamoff et al. 2019).

Many restored oyster reefs support similar resident macrofauna abundance, species richness/diversity, and biomass as natural oyster reefs within a few years following construction (Hadley et al. 2010; Harwell et al. 2011; Karp et al. 2018; Meyer and Townsend 2000; Rezek et al. 2017). While few published studies have compared the nekton communities of constructed oyster reefs with natural reference reefs, studies in North Carolina found similar nekton community characteristics between created and natural reference reefs (Harwell et al. 2011; Meyer and Townsend 2000; Rutledge et al. 2018). Numerous studies have demonstrated enhanced nekton abundance on restored oyster reefs compared with unstructured control sites (Chowdhury et al. 2020; Gilby et al. 2019; Humphries and La Peyre 2015; La Peyre et al. 2014; Scyphers et al. 2011). Food web characteristics such as food chain length, food web complexity, and consumer stable isotope values have also been demonstrated to be similar between restored oyster reefs and natural reef communities within 2 years following restoration in some cases (Dillon et al. 2015; Rezek et al. 2017).

It has been well established that each of these coastal habitats (marsh, SAV, oyster reefs) individually provide important benefits to estuarine resident and transient nekton species, as well as to other species that benefit from exported prey (Able 2005; Blandon and zu Ermgassen 2014; Boesch and Turner 1984; Deegan 1993; Jänes et al. 2020; Nelson et al. 2011; Odum 1980; Weinstein et al. 2005, 2014; zu Ermgassen et al. 2016). In this issue, Hollweg et al. (2020a) reinforce that these structured habitats support higher nekton densities than unstructured habitat, with oyster reefs generally supporting different nekton communities than marsh and SAV. There is also evidence that restoration of multiple habitat types in close proximity to each other can result in higher nekton biodiversity and production than the restoration of each individual habitat in isolation (Baillie et al. 2015; Irlandi and Crawford 1997; Meynecke et al. 2008; Zeug et al. 2007). While some studies suggest that restored oyster reef habitat can be functionally redundant to other structured habitats (Geraldi et al. 2009; Grabowski et al. 2005; La Peyre et al. 2014), the presence of patchy oyster substrate along the marsh edge may enhance marsh habitat value for some species (Zeug et al. 2007).

Given that different habitats are used by different nekton species and life stages (Glancy et al. 2003; Rozas and Minello 1998; Rozas and Zimmerman 2000; Stunz et al. 2002, 2010), protecting and/or restoring a heterogeneous mosaic of coastal habitats within estuaries should support successful niche partitioning. Heterogeneity within habitats can also contribute to enhanced ecological function and service flows. For example, microhabitats within coastal marshes (e.g., interior marsh surface, marsh edge, tidal creeks, shallow ponds, and adjacent non-vegetated bottom) support different nekton densities and species compositions (Baltz et al. 1993; Breitburg et al. 1995; Minello and Rozas 2002; Minello et al. 1994; Peterson and Turner 1994). In this issue, Hollweg et al. (2020a) support these findings for marshes in the northern GOM, with total nekton density highest in marsh edge habitat and differing nekton community composition between marsh edge, marsh interior, and non-vegetated bottom habitats.

Applying Restoration Trajectories to Compensatory Restoration

Trajectories describing the rate of development of ecological functions can be used to quantify the scale of restoration needed to offset habitat injuries in regulatory contexts. Habitat equivalency analysis (HEA) and resource equivalency analysis (REA) are approaches that have been developed to assist with calculating the amount of restoration needed to compensate for injuries to natural resources (English et al. 2009; NOAA 1995, 1997). The main distinction between HEA and REA is that HEA is usually applied to habitat types (e.g., tidal marsh or oyster reefs) while REA is applied to specific living resources (e.g., number of injured birds or biomass of injured fish). These methods were originally developed in the USA for use in Natural Resource Damage Assessments (NRDAs) for oil spills, but they have also been applied to chemical spills, vessel groundings, forest fires, and habitat conversion (Desvousges et al. 2018; Fonseca et al. 2000; Kirsch et al. 2005). The European Union has also adopted HEA and REA for calculating environmental mitigation requirements (Desvousges et al. 2018; Lipton et al. 2018), and the United Nations relied on HEA to determine compensation for environmental damages in Kuwait from the 1990 to 1991 Gulf War (United Nations Security Council 2005).

Past HEA and REA models have incorporated the time needed for habitat functions to develop and the risk that restored habitats may never provide the same level of functions and services as the injured natural habitats. These models incorporate change in the level of resources or services provided by a restoration action over time, often included in models simply as a percentage of total ecosystem service provided by restored habitat (e.g., Lavaca Bay, NOAA 2000) However, HEA and REA models are only as strong as the data that support them. The restoration trajectories (often called “recovery trajectories” in HEA and REA applications) used in many previous HEA and REA models have frequently relied on data from only a handful of restoration projects or expert opinion (Strange et al. 2002). The meta-analyses presented in this theme section provide an opportunity to leverage larger, synthesized datasets to support the development of HEA and REA models for GOM coastal habitats that can more accurately estimate restoration project benefits over time. The REA model presented by Fricano et al. (2020) in this issue provides an example for how restoration trajectories derived through meta-analysis of regionally focused datasets can be used along with other regionally specific input parameters to develop more robust estimates of restoration benefits.

Many environmental mitigation scenarios require out-of-kind compensation for damages, such as restoring salt marsh to mitigate for injury to soft-sediment benthic habitat (English et al. 2009; Wickham et al. 1993). Another common scenario is a “benefits cascade,” where a single restoration project benefits multiple trophic levels (Heinrich et al. 2014). For example, a marsh restoration project may be constructed to restore for fish that were killed by an oil spill. The marsh is an appropriate restoration option based on the assumption that the marsh will provide ecological services to the injured fish species. A common metric is needed when calculating compensatory restoration requirements in situations that involve out-of-kind restoration or benefits cascades. In this issue, Cebrian et al. (2020) present a novel protocol for quantifying biomass at recruitment (for species with life history tables available) or productivity (for species without life history tables available) supported by different coastal habitats, which can be applied to help calculate out-of-kind restoration requirements.

Restoration trade-off scenarios have evolved from fairly straightforward trade-offs between similar habitats or resources to more complex applications. Prior approaches include the development of conversion factors based on productivity ratios for the same trophic level between habitat types (e.g., M/V Athos, French McCay et al. 2002), the development of equivalencies between trophic levels, and the application of simple food chain models using energy transfer efficiencies to scale across trophic levels (see, e.g., French McCay et al. 2002, 2003b; French McCay and Rowe 2003; Peterson et al. 2003, 2007). Recent advancements in ecosystem modeling approaches provide a means to integrate multiple components of the ecosystem, facilitating the consideration of different restoration scenarios (e.g., Ainsworth et al. 2018; de Mutsert et al. 2017). Robust estimates for the broadest possible array of various ecological functions of coastal habitats, such as those provided by the meta-analysis studies included in this theme section, can improve certainty in ecosystem model outputs by providing more robust values for model parameterization.

Overview of the Theme Section

This collection of papers provides insights into the quantification of benefits and the rate at which benefits develop for coastal habitat restoration projects in the northern GOM, USA region. The authors of the papers included in this collection conducted systematic reviews of the existing literature on coastal habitat restoration and utilization of coastal habitats by species impacted by the Deepwater Horizon oil spill. Meta-analysis was used to synthesize existing data related to marsh vegetation and soils; marsh resident fauna; and nekton abundance across marsh, oyster reef, submerged aquatic vegetation (SAV), and open-water non-vegetated bottom (NVB) habitats. The authors used the results of the meta-analyses to develop quantitative relationships describing the restoration of key structural characteristics and ecological functions and services over time in restored coastal habitats. Approaches are also presented to estimate the productivity of estuarine habitats, model the benefits associated with a hypothetical marsh restoration project, and quantify the benefits of removing derelict crab traps from estuaries. The synthesized datasets can be used to compare benefits associated with different types of restoration projects, serve as a reference for setting appropriate targets and performance criteria, and be applied to scale up the measured benefits of individual restoration projects to evaluate the longer-term, cumulative outcomes of restoration in the GOM. While this synthesis of existing data focuses specifically on the northern GOM, USA region, the results contribute to an overall better understanding of the ecological benefits of estuarine habitat restoration and can serve as a valuable reference for managers implementing restoration projects in other regions.

Ebbets et al. (2020) conducted a systematic literature review and meta-analysis to evaluate whether vegetation and soil parameters at fresh, brackish, and saline marsh sites restored using dredged sediment placement and thin layer sediment addition recover to levels found at paired reference sites. On average, belowground parameters (root biomass and soil organic matter) were 44 to 92% lower at restored sites younger than 15 years compared with the reference sites. Percent vegetation cover was 50% lower at restored sites compared with the reference sites over the first 5 years of restoration; in contrast, aboveground biomass was 25% higher at restored sites. Mean recovery trajectories for belowground biomass and productivity, vegetation cover, and soil parameters indicated that mean values for restored sites reached reference site conditions within 30 years following restoration. However, the recovery curve for the 20th percentile of site data suggests slower recovery for some sites.

Baumann et al. (2020) examined recovery of the epifaunal gastropod periwinkle snail (Littorina irrorata) and a broad grouping of amphipod crustaceans (order Amphipoda) following salt marsh restoration in the northern GOM. Faunal recovery trajectories were developed using data from restored and reference marshes extracted from published, unpublished, and gray literature related to marsh structure and function following marsh creation, marsh rehabilitation, or experimental treatments that closely mimic marsh restoration. The results of the analysis indicate progressive recovery of periwinkle function to equivalence with reference by year six, while amphipods do not fully recover in the first 20 years following restoration. Although periwinkle function in terms of annual biomass addition reaches equivalence by year six, the development of a population structure characteristic of reference marshes would likely take longer because of the relatively long lifespan for this species.

Hollweg et al. (2020a) conducted a systematic literature search and meta-analysis to evaluate nekton densities across estuarine habitat types, including marsh, oyster reefs, SAV, and open-water NVB in the northern GOM. They corrected nekton densities for gear efficiencies to allow for comparisons across sites, studies, and habitats. Higher nekton densities were associated with structured estuarine habitats (i.e., marsh, oyster reefs, SAV) than with open-water NVB habitats. Marsh and SAV community assemblages were relatively similar to each other but different from those associated with open-water NVB and oyster habitats. Densities of recreationally and commercially important crustacean and fish species were highest in saline marshes, thus demonstrating the importance of these habitats in the northern GOM.

Hollweg et al. (2020b) conducted a meta-analysis of nekton densities measured at restored marsh sites in the GOM compared with the reference (i.e., natural) sites to describe general patterns of nekton recovery following restoration. Overall, total nekton densities at restored sites were generally lower than those at reference sites during the first decade following restoration. They found variations in restored versus reference densities when examining specific fish and crustacean taxa; densities of many crustacean taxa (e.g., penaeid shrimp Penaeidae spp., grass shrimp Palaemonidae spp.) and some fish taxa (e.g., gobies Gobiidae spp.) were generally lower at the restored sites, while restored densities of other crustacean taxa (e.g., portunid crabs Portunidae spp.) were similar to the reference densities. Nekton densities—and constituent crustacean densities—appeared to increase with the age of the restored sites and were comparable with densities at the reference sites by approximately year 13, although the specific response varied for different species groups.

Cebrian et al. (2020) propose a method to standardize estimates of biomass at recruitment and nekton productivity that can be used to inform coastal habitat conservation or restoration actions in the northern GOM region, including efforts to restore coastal wetlands, SAV beds, and oyster reefs. The objective of their study was to develop a new protocol that, building upon existing methods, derives nekton biomass and productivity from density values. The method also allows for the quantification of the uncertainty around the derived biomass and productivity values, thereby allowing end users to obtain an accurate understanding of the value and variability of coastal ecosystems as habitat for nekton as well as developing effective strategies for the conservation and restoration of nekton coastal habitat.

Fricano et al. (2020) present a method for quantifying anticipated ecological benefits associated with marsh restoration projects, particularly marsh creation, in the northern GOM. Using salt marsh vegetation (percent cover, aboveground biomass, and belowground biomass), periwinkle snails, and amphipods as representative ecological components, they modeled anticipated ecological functioning over time and quantified total net project benefits for a hypothetical marsh creation project in Barataria Bay, Louisiana. They applied a rigorous approach to the development of input values, mining the scientific literature, Coastal Wetlands Planning, Protection and Restoration Act (CWPPRA) data, and other sources. They also demonstrate how model inputs can be varied to accommodate different marsh restoration techniques, salinity regimes, and geographic regions.

Arthur et al. (2020) present a method for determining the potential benefits of crab trap removal projects in northern GOM bays and estuaries. Recent stock assessments of blue crabs (Callinectes sapidus) in the GOM are discouraging, indicating the stock is in waning health (West et al. 2016). The authors conducted a synthesis of data made available by state natural resource management agencies and provide a novel approach to handling large uncertainties regarding trap loss rates. The outcomes of this analysis could serves as inputs for REA, including applying concepts of production forgone (French McCay et al. 2003a). An estimate of lost crab and finfish biomass is determined based upon rates of ghost fishing by derelict traps. The authors estimate that a 5-year program would result in a benefit of 391,000 kg of crab and 300,000 kg of finfish not killed due to ghost fishing, for a combined benefit of 691,000 kg across the GOM. The approach used could be extended to estimate other measures of ecosystem performance, including reduced marine mammal entanglement, improved esthetics, and economic benefits to fishing communities. The article also brings attention to other persistent threats and stressors in estuaries such as marine debris. For certain ecosystems, habitat restoration alone may be less effective than approaches that also address other stressors to the system. This begs the question of how portfolios of restoration projects can be designed to address multiple stressors to a system.

Key Take-Aways

Coastal habitat restoration has been conducted for decades in the northern GOM region through existing programs such as the Coastal Wetlands Planning, Protection, and Restoration Act (CWPPRA) program, NOAA’s Community-based Restoration Program, and the USFWS Coastal Program, with much more restoration planned or already underway as a result of the Deepwater Horizon settlements. However, many restoration projects are only monitored for a few years after construction, with most monitoring focused on meeting specific construction targets (e.g., marsh elevation, volume of constructed oyster reefs) and the development of structural habitat features (e.g., vegetation percent cover). The papers included in this theme section reveal the limited amount of long-term monitoring information currently available for coastal habitat restoration projects in the GOM (Table 1). Without more long-term monitoring data, natural variability makes it difficult to accurately predict restoration trajectories for some characteristics of restored marshes, particularly the extent to which slower developing functions might emerge over time (Callaway 2005; Zedler 2000). Larger, combined datasets, such as those derived in these papers, improve understanding of the ecological services and the rate of development of restored habitats.

Table 1 Summary of the number of restoration projects by age analyzed by the papers included in this theme section

While the papers in this volume draw on the best currently available data from the GOM region, combining data from numerous sites inherently introduces additional variability and requires large sample sizes. Increased long-term monitoring of individual projects combined with strategic re-sampling of older restoration projects could further improve the power of meta-analysis for developing restoration trajectories. Collecting longer-term monitoring data for a variety of different types of restoration projects and restoration projects with specific design features would help clarify which restoration actions are most effective at increasing the rate of development of desired functions. As the number of restoration projects with long-term monitoring data increases, it should become possible to distinguish differences between restoration techniques and shed more light on the drivers behind the differences in the rate of development of some habitat functions seen in individual studies. Additional data collection related to soil development, benthic community composition, and faunal habitat utilization would further improve understanding of the ecological services provided by restored habitats, the length of time required to achieve full functional equivalence with natural habitats, whether equivalence is ever achieved for all functions, and how to set appropriate performance expectations for restoration projects.