Study region and stands

Our modelling approach explores stands that one could encounter in a typical private hardwood forest of eastern North America. Stands of SM, SID and WSP were selected for the simulation of various forest management scenarios.

Stands from the Forest Inventory and Analysis (FIA) database of the state of New York (2012 survey) were used to make the simulation as realistic as possible. To simplify the number of simulations to be made and render all scenarios more easily comparable, we decided to select stands that were ready to harvest, resulting in a bank of suitable stands from which to draw five stands randomly. The criteria for stand selection are described in Appendix S1 (available online) and their silvicultural characteristics are shown in Table S1.

Forest simulation model

The Northeast Variant of FVS, a well-known growth model (Crookston & Dixon Reference Crookston and Dixon2005), was used to simulate three management scenarios, with different harvest types and cycles, applied on the stands described above. FVS simulates the dynamics of each tree in a stand in a non-spatially explicit context.

Management scenarios and simulation parameters

Management scenarios were simulated over a 70-year horizon using 10-year time steps. The first three scenarios were designed to replicate management that is typical of Northeast American forests. An ecosystem (Grumbine Reference Grumbine1994) and intensive management scenario that differed depending on forest type was compared to a no-management scenario (where no timber is cut) for each of the three different forest types (scenarios hereafter named No-management, Ecosystem, and Intensive; see Table 1). The scenarios and the rotation lengths were developed in order to reflect the current thinking in terms of silvicultural practices for these kinds of stand in private woodlots.

Table 1 Management scenarios for the 70-year simulations (2012–2082). Retention harvesting refers to 80% of the basal area being removed from below. Commercial thinning refers to 35% of the basal area being removed from above. Pre-commercial thinning refers to 10% of the basal area being removed from below. DBH = Diameter at breast height; ITS = Individual tree selection.

Harvesting parameters for the individual tree selection (ITS) used for Ecosystem in SM stands were set in order to allow for initial basal area recovery in a 20-year harvest cycle. The merchantable volume of a tree was calculated from 15-cm stump height trees with a minimal diameter at breast height (DBH) of 9 cm. The maximum basal area was set at 35 m² ha^–1 in the SM stands, representative of forests dominated by sugar maple and beech (McCune & Menges Reference McCune and Menges1986), at 40 m² ha^–1 for the denser SID stands and at 50 m² ha^–1 for the WSP. Setting a maximum basal area ensured that the stands would not grow to exceed what is sustainable for the site, which has been recommended for FVS (Dixon Reference Dixon2002).

TRIAD forest management scenarios consisted of simultaneously applying the three simulated management scenarios (shown in Table 1 for SM and SID) within one single stand of a particular forest type. The mean of the five stands under each single-management scenario was used for this single stand in order to simulate the various TRIAD scenarios. Spatial components were not considered. The ‘wood production’ zone corresponded to our Intensive, which was divided into two sub-zones: the original stand under Intensive and a WSP under Intensive. The latter was implemented following a clearcut in the SM and SID stands. Following Côté et al. (Reference Côté, Tittler, Messier, Kneeshaw, Fall and Fortin2010), we investigated five different zoning proportions (Table 2). The numbering in the names of the TRIAD scenarios reflects the percentage of the land set aside for conservation, increasing from T12 to T50. The zoning proportions of T12 and T20 have been tested by Côté et al. (Reference Côté, Tittler, Messier, Kneeshaw, Fall and Fortin2010) and T50 is currently demanded in boreal forests by some environmental groups (Badiou et al. Reference Badiou, Baldwin, Carlson, Darveau, Drapeau and Gaston2013).

Table 2 Proportions (%) allocated to each TRIAD management scenario (modified from Côté et al. (Reference Côté, Tittler, Messier, Kneeshaw, Fall and Fortin2010)).

FVS simulation cycles and regeneration sub-model

There is a fixed processing sequence of operations in a FVS simulation (Dixon Reference Dixon2002): the model first reads and computes the initial stand characteristics, then processes the thinning if requested, grows trees, allows some mortality that generates snags and finally establishes new trees (regeneration). As mortality is density dependent, parameters of new seedling regeneration must be computed in order to ensure proper forest dynamics (see Table S2) (Nunery & Keeton Reference Nunery and Keeton2010). The parameter selection and adjustment for the model are described in Appendix S1.

Ecosystem service measurements and utility analysis

We limited our analyses to three services that could be easily assessed using only the variables included in FVS. Timber, habitat quality and stored carbon were calculated based on the FVS outputs for the different stands (Table 3). Timber is a common source of revenue for forest owners, habitat quality is an expected requirement of many certification programmes and carbon is increasing in importance and value. All merchantable volumes that were removed were summed over the 70-year simulation for the timber service. It was equal to zero in No-management, as no merchantable volume was extracted. We used the sub-model Fire and Fuels Extension of FVS in order to evaluate carbon storage. The default 10-year time step was used for all of the simulation outputs (Wykoff & Crookston Reference Wykoff, Crookston and Stage1982). We considered only the carbon stored in the aboveground live tree biomass and followed the carbon calculation of Jenkins et al. (Reference Jenkins, Chojnacky, Heath and Birdsey2003).

Table 3 Measures of ecosystem services on 70-year simulation results. DBH = Diameter at breast height; FVS: Forest Vegetation Simulator.

Habitat quality was quantified with a HSI (Schamberger & Krohn Reference Schamberger and Krohn1982) based on measurable structural components of a forest stand (Ferris & Humphrey Reference Ferris and Humphrey1999). Three characteristics of old-growth forests were considered as optimal in the calculation of the HSI for each stand (Bauhus et al. Reference Bauhus, Puettmann and Messier2009). The densities of large trees (DBH ≥40 cm) and large snags (DBH ≥30.5 cm) were averaged over the simulation. Furthermore, since tree diameter distribution is a good indicator of stand biodiversity (Buongiorno et al. Reference Buongiorno, Dahir, Lu and Lin1994), it was calculated using the Gini index (Gini Reference Gini1921) on DBH classes of 2 inches (5.08 cm). This coefficient has been found to be particularly appropriate for discriminating diverse stand parameters, such as its vertical structure (e.g., Bílek et al. Reference Bílek, Remeš, Švec and Zahradník2013).

The MCDA approach allows for the determination of which alternative scenario performs best considering multiple services, as well as for visualizing the trade-offs and benefits among them (Diaz-Balteiro & Romero Reference Diaz-Balteiro and Romero2008; Ananda & Herath Reference Ananda and Herath2009). Each service was designated as a partial utility scaled to 1, or 100%, to allow for comparison among them. Partial utilities can be weighted depending on the priorities and values of the manager. Among the many multiple-criteria decision-making techniques available (Tamiz et al. Reference Tamiz, Jones and Romero1998; Romero Reference Romero2001; Belton Reference Belton and Stewart2002), we used a simple methodology fit for a discrete-choice problem like ours. The overall performance of a scenario was quantified by the sum of the service levels transformed into partial utilities.

In this study, we gave services equal weights. For each of the three stand types, partial utilities were calculated as:

(1) $$\begin{equation} {U_{\ P,i,j}} = \frac{{{P_{i,j}}}}{{{P_{max}}}} \end{equation}$$

for all three services P, five stands i and three management scenarios j. To obtain the carbon stock utility, U _{Cstock, i, j} , every carbon stock annual mean for an i,j combination, Cstock _{i, j} , was divided by the maximum value of the annual mean carbon stock, Cstock_max , found among the five stands i, across all three management scenarios j. Likewise, for the timber utility U _{T, i, j} , the value of the total harvested volume after 70 years of every i,j combination, T _{i, j} , was divided by the maximum value showed by any combination i,j, T_max .

Habitat quality was measured with a HSI, H_i,j :

(2) $$\begin{equation} {H_{i,j}} = {U_{LT,\ i,j}} + {U_{LS,\ i,j}} + {U_{G,\ i,j}} \end{equation}$$

where sub-utilities (density of large trees U _{LT, i, j} , density of large snags U _{LS, i, j} and Gini coefficient U _{G, i, j} ) were obtained with eqn (1) using HSI components instead of P services. Following eqn (2), the partial utility of habitat quality, U _{H, i, j} , was then calculated with eqn (1).

Finally, for every management scenario j, the partial utilities of the five stands i of a specific type (SM, SID or WSP) for a service P were averaged, giving a mean utility U _{P, j} :

(3) $$\begin{equation} {U_{\ P,j}} = \frac{{\mathop \sum \nolimits_{i = 1}^5 {U_{P,\ i,j}}}}{5} \end{equation}$$

The TRIAD management scenarios were evaluated with eqn (3) in the SM and SID stands. The calculation of a total score U _{P Tot} for a given service P was realized by using the proportions p found in Table 2 to weight each mean utilityU_j :

(4) $$\begin{eqnarray} {U_{P\ Tot}} &=& {p_{NM}}{U_{P,\ j = NM}} + {p_{ECO}}{U_{P,j = ECO}}\nonumber\\ &&+ {p_{INT}}{U_{P,\ j = INT}} + {p_{PI}}{U_{WSP,\ P,j = INT}} \end{eqnarray}$$

where p_NM , p_ECO and p_INT are the proportions of the utility value U for No-management, Ecosystem and Intensive, respectively. In eqn (4), p_PI refers to the proportion of the partial utility found for the most timber-productive WSP stand under Intensive.

Simulation outputs were analysed by first computing utilities for single-management scenarios. All TRIAD scenarios and single-management scenarios were then compared with respect to every utility using MCDA. A non-parametric Kruskal–Wallis test (α = 0.05) was used in order to test the differences between single-management scenarios within a forest type. Post hoc contrasts were performed when necessary with pairwise comparisons using a multiple comparison test after Kruskal–Wallis testing (R package ‘pgirmess’). All of the FVS output data analyses were conducted with R (R Development Core Team 2010).