Data collection and analysis

Vegetation data for carbon and plant diversity were collected through the International Centre for Integrated Mountain Development (ICIMOD) database, which was compiled from forest inventories conducted in February–April 2013. These data included the height and diameter at breast height (dbh) of trees and saplings, the number of seedlings and shrubs and grasses (not including ferns, mosses and lichens) collected from 112 composite plots of 250 m² distributed across 19 CFs. A stratified random sampling design was used, whereby forests were stratified into dense (≥70% canopy density) and sparse (<70% canopy density) strata, using a geographic information system (ArcGIS) with Geo-eye satellite images captured in November 2009 (Subedi et al. Reference Subedi, Pandey, Pandey, Rana, Bhattarai and Banskota2010).

Forest products (i.e. annual harvest of timber [m³], fuelwood [kg] and fodder [kg]) data for 2013 were collected from the logbooks and meeting minutes of CF groups during field visits to Nepal in July–October 2013. We reviewed annual data on the extraction of forest products from the start of the REDD+ project (i.e. 2009–2013), and we used data from 2013 as this represented the change in forest characteristics over a 4-year period and coincided with the end of the REDD+ pilot in the study area. These data were verified through meetings with key members of the executive committee.

Carbon stock, plant diversity and forest product extraction

Per ha carbon included five carbon pools: above- and below-ground tree carbon; saplings and shrubs; herbs and grasses; leaf litter; and soil organic carbon. Aboveground tree and sapling carbon levels were calculated using the equation from Chave et al. (Reference Chave, Andalo, Brown, Cairns, Chambers and Eamus2005, p. 92) for moist forest types (Supplementary Material 1; available online).

We used a Nepal-specific biomass equation developed by Tamrakar (Reference Tamrakar2000) to estimate the aboveground sapling (1–5 cm dbh) biomass (eqn (1)):

(1) $$\begin{equation} {\rm{log}}\left( {{\rm{AGSB}}} \right) = {\rm{a}} + {\rm{b}}\left( {{\rm{log}}\left[ {\rm{D}} \right]} \right) \end{equation}$$

where AGSB = aboveground sapling biomass (kg), log = natural log, a = intercept of the allometric relationship for saplings, b = slope of the allometric relationship for saplings and D = overbark dbh (cm).

The biomass of herbs, litter and grasses was calculated using eqn (2):

(2) $$\begin{equation} \ \ {\rm{LHG = }}\frac{{{{\rm{W}}_{field}}}}{{\rm{A}}}\,\,\frac{{{{\rm{W}}_{subsample,{\rm{ }}dry}}}}{{\ {{\rm{W}}_{subsample,{\rm{ }}wet}}}} \times {\rm{ }}10 \end{equation}$$

where LHG = biomass of litter, herbs and grasses (tonnes ha^–1), W _field = weight of fresh field sample of litter, herbs and grasses (g) within an area of size A (m²), W _{subsample, dry} = weight of oven-dried subsample of litter, herbs and grasses (g) and W _{subsample, wet} = weight of fresh field sample of litter, herbs and grasses (g).

We calculated belowground biomass using a root:shoot ratio, whereby root parts are estimated to contain 20% of total aboveground biomass (MacDicken Reference MacDicken1997, p. 84). Total biomass was converted into carbon by multiplying the biomass by the standard value of 0.47 (IPCC Reference Eggleston, Buendia, Miwa, Nagara and Tanabe2006). The soil carbon data we used were calculated by ICIMOD in 2010, and we assume that this is representative of 2013 values given that soil carbon does not change substantially over such a short period under the same land-use practices (MacDicken Reference MacDicken1997; Martin et al. Reference Martin, Newton and Bullock2013).

Per ha timber (m³) harvested was calculated from the total quantity of timber harvested from each CF divided by the area of the CF. Timber in CFs is generally harvested using selective logging of standing trees and from fallen trees. The location, tree species to harvest, annual harvestable quantity and the quantity assigned to local forest users are defined in the CF group's forest operational plans. Most of the harvested tree is used for timber, while tree tops and branches are used for fuelwood. Fuelwood is generally extracted from a combination of non-merchantable green and dried wood products such as fallen twigs, stumps and branches. Fodder contains leaves, branches and grass. The per ha annual harvest of fuelwood or fodder (kg) for each CF was calculated by dividing the total quantity of fuelwood and fodder harvested (total number of full and half-head loads [a full head-load is considered to be 35 kg]) by the area of the respective CF.

Plant species diversity was estimated using the Shannon–Wiener diversity index (H’) (Magurran Reference Magurran2004). We calculated stem density by counting the number of trees, saplings and seedlings in the survey plots, whereby the average number of stems per plot in each CF was calculated by dividing the total number of stems by the total number of plots. The per ha stem density in each CF was then calculated by multiplying the density of stems in plots by 40.

Trade-offs and synergies between carbon, plant diversity and forest products

We aimed to identify CFs that had high or low values for multiple ESs or between an ES and plant diversity (positive or negative synergies, respectively), or had low values for one ES and high values for another, or a high/low outcome for an ES and plant diversity (i.e. a trade-off). We first analysed pair-wise associations among variables using Spearman's rank order correlation. The strengths of association between variables were classified into five categories based on the correlation coefficient following Dancey and Reidy (Reference Dancey and Reidy2007): zero (0), weak (0.01–0.3), moderate (0.31–0.60), strong (0.61–0.90) and perfect (0.91–1.00).

The purpose of this initial analysis was to determine if, when examining trends across all forests, there were strong synergies (large positive correlation coefficients) or trade-offs (large negative correlation coefficients) across the CFs; that is, for example, did forests with large carbon values consistently have large plant diversity values (positive synergies) or did forests with large carbon values consistently have small plant diversity values (trade-offs)? Importantly, weak correlation coefficients in this analysis are indicative of a much more complex relationship between forest characteristics, suggesting that only some individual forests may have mutually high values of, for example, carbon and forest products, while other forests may have low values of one characteristic, but high values of the other. Hence, weak and strong correlation coefficients uncover fundamentally different, but equally important, dynamics across the group of forests.

We then analysed trade-offs and synergies in ESs and plant diversity using methods described in Luck et al. (Reference Luck, Chan and Fay2009). First, we standardized the numerical values (Supplementary Material 2) of carbon, plant diversity and forest products using Z-scores so that the values of each attribute had a mean of zero and a standard deviation of one. Then we calculated the median value for each attribute, which was used as the threshold value to determine if values were ‘high’ or ‘low’ (i.e. above or below the median value, respectively). Finally, we plotted values in pair-wise comparisons to identify trade-offs or synergies for any given CF. For example, in a pair-wise comparison of values for carbon and plant diversity, a given forest may have high values for both (positive synergy), low values for both (negative synergy), a high value for carbon but a low value for plant diversity (a trade-off favouring carbon) or a low value for carbon but a high value for plant diversity (a trade-off favouring plant diversity) (Fig. 2). A number from 1 to 19 was assigned to each CF (Table 1), and these numbers were used as labels in the scatter plots showing trade-offs and synergies.

Figure 2 Framework for assessing the trade-offs or synergies between two variables in the context of carbon and plant species diversity. Solid black lines represent the median values. The top left quadrant represents forests with high carbon values (above the median value for carbon) but low values for plant species diversity (below the median value for plant species diversity).