Conservation limits

Conservation limits were established during 2007–2009 for 439 Norwegian populations (all of the known self-reproducing populations). The limits were set by a group of scientists from research institutions in Norway, coordinated by the Norwegian Institute of Nature Research. Local county governor fisheries managers reviewed the suggested limits before final approval by the Directorate for Nature Management. Except for the county governor managers, there was no local involvement in the process.

The conservation limits were based on stock-recruitment relationships from nine Norwegian rivers. Both Shepherd (Reference Shepherd1982) and Hockey-Stick (Barrowman & Myers Reference Barrowman and Myers2000) models were used (Fig. 1), and several parametric and non-parametric spawning stock reference levels were tested (see review in Potter Reference Potter, Prévost and Chaput2001, and box 12.2 in Hindar et al. Reference Hindar, Hutchings, Diserud, Fiske, Aas, Einum, Klemetsen and Skurdal2011). The estimated optimal egg densities (eggs m⁻² wetted area) with respect to recruitment (the average maximum number of recruits at the peak or derived from the asymptote of the relationships) ranged (excluding outliers) from approximately 1 egg m⁻² to more than 6 eggs m⁻² (Fig. 1; Hindar et al. Reference Hindar, Diserud, Fiske, Forseth, Jensen, Ugedal, Jonsson, Sloreid, Saltveit, Sægrov and Sættem2007, Reference Hindar, Hutchings, Diserud, Fiske, Aas, Einum, Klemetsen and Skurdal2011). To transfer conservation limits from these nine data-rich rivers to the remaining 430 populations, the populations were placed according to their productivity in one of the following categories of conservation limits: 0.5–1.5, 1.5–3, 3–5 and 5–7 eggs m⁻², with respective modal values at 1, 2, 4 and 6 eggs m⁻². Assessment of productivity was based on catch per wetted area, smolt (the life stage at which the juveniles migrate to sea, typically 2–4 years after hatching) age distribution, sea-age distribution and other information about each population and watercourse (Hindar et al. Reference Hindar, Hutchings, Diserud, Fiske, Aas, Einum, Klemetsen and Skurdal2011). Once the egg density category was determined (eggs m⁻²), total necessary egg deposition was estimated from the wetted area (using standardized geographic information system [GIS] methods; Erikstad et al. Reference Erikstad, Sloreid and Hansen1999) and the conservation limits expressed as biomass of females were calculated assuming female fecundity of 1450 eggs kg⁻¹, representative for many of the Norwegian populations (Hindar et al. Reference Hindar, Hutchings, Diserud, Fiske, Aas, Einum, Klemetsen and Skurdal2011). Mass specific fecundity shows relative low inter- and intra-population variation (Klemetsen et al. Reference Klemetsen, Amundsen, Dempson, Jonsson, Jonsson, O'Connell and Mortensen2003).

Figure 1 (a) An example of stock-recruitment relationships based on the Shepherd (Reference Shepherd1982) (solid line), the original hockey-stick (dotted line) and logistic hockey-stick (Barrowman & Myers Reference Barrowman and Myers2000) (dashed line) models fitted to stock (S, egg deposition, n eggs m⁻²) and recruitment (R, n 1+ juveniles 100 m⁻²) data from the River Alta, northern Norway, and (b) different parametric and non-parametric spawning stock reference measures (see Potter Reference Potter, Prévost and Chaput2001 for an overview) that could be derived from the stock-recruitment relationships for the River Alta and similar relationships from seven other Norwegian Rivers. Shep = the stock value at the peak of the Shepherd curve, or the maximum observed stock in cases when no peak were observed, HS = the break point of the hockey-stick model, Max5R = average stock for the five highest recruitments observed, and 90.90 = the intersection of the 90th percentile of the survival rate (R/S) and the 90th percentile of the recruitment. Data for the river Imsa (one of the nine rivers with stock-recruitment relationships in Norway) were obtained from Jonsson et al. (Reference Jonsson, Jonsson and Hansen1998) and are not shown because of the very high values for some of the stock reference measures (for example Shep = 66 eggs m⁻²). Note that the rankings among rivers were generally similar across the different spawning stock reference measures and that most fell within the 0–5 eggs m⁻² range. Figure courtesy of Hindar et al. (Reference Hindar, Diserud, Fiske, Forseth, Jensen, Ugedal, Jonsson, Sloreid, Saltveit, Sægrov and Sættem2007).

Assessment of attainment of conservation limits

The procedures described below were developed by the Salmon Committee, of which the main authors are also members.

The only information available from all river systems were the catch statistics, which thus was the foundation for the assessment. Catch statistics are collected annually both from the marine fisheries and from each of the rivers. The catch is reported in three weight groups (<3 kg, 3–7 kg and >7 kg) that roughly represent three sea-age-classes at maturity (one-sea-winter 1SW, two-sea-winter 2SW and three-sea-winter 3SW; Otero et al. Reference Otero, Jensen, L'Abe´e-Lund, Stenseth, Storvik and Vøllestad2012). By combining the reported catch with estimates of exploitation rates the spawning population can be estimated. Nominal catches were used, whereas the relative small but growing practice of catch and release fishing in the rivers was accounted for by reducing the exploitation rates according to the reported level of catch and release in each river.

The proportion of females in each of the three size groups in the statistics and their average weights were used to estimate female spawning biomass. To account for uncertainties in the estimates of female spawning biomass, Monte Carlo simulations based on triangular distributions of all the involved parameters were used (see below). Because the conservation limits (biomass females) were also given as ranges (minimum, modal and maximum), reflecting the uncertainty of the limits, the simulations were run using triangular distributed conservation limits. Triangular distributions are commonly used in risk assessments (Williams Reference Williams1992, Johnson Reference Johnson1997), and are useful when a modal (most likely value) has been determined and the two extreme percentiles (typically 5 and 95%) can be set by expert judgements.

Estimates of spawning female biomass

The biomass of spawning females in each river system was estimated as: [(total weight nominal catch in river) ÷ (exploitation rate) – (total weight nominal catch in river)] × (proportion females). Since both the proportion of females and the exploitation rate varies among weight groups, this was done separately for each of three weight groups and the biomasses were then summed.

In 2011, 58 of the 135 exploitation rates used for simulations in the subsample analysed here were based on one of the following methods: (1) counts of upward migrating adult salmon in fish ladders or other counting facilities, (2) counts of the spawning population in the autumn after termination of the fishing season by drift snorkelling or observations from the shore, and (3) capture-mark-recapture studies. In most cases, exploitation was estimated for each of the size groups. To account for uncertainty in the estimated exploitation rates (Hansen Reference Hansen1990; Orell et al. Reference Orell, Erkinaro and Karppinen2011), they were given as a range (minimum, modal and maximum) with triangular distributions. For the remaining populations no local estimates of exploitation rates were available and exploitation was assigned to one of 12 categories of exploitation for each size group (Table 1), using general and seasonal local information on fishing pressure (such as number of anglers, organization of the fishery, quotas, length of the season, allowed gear, protected zones or catch and release) and fishing conditions (favourable/unfavourable discharge or temperature conditions). The categories were developed from analyses of 214 historical estimates of exploitation rates from 40 river systems that revealed a pattern of different exploitation rates among the three sea-age classes (Anon. 2009), and among rivers of different size (average annual discharge; grouped into small, medium and large). Within each of the resulting nine groups (three size classes × three river sizes), exploitation rates were categorized into four groups from very low to high, yielding a system with a total of 36 categories. To account for the uncertainty, the exploitation rates were given as relatively large ranges due to the uncertainty of the procedure. Local information for categorization of exploitation level (from very low to high) was obtained from a standardized questionnaire submitted annually to the county governor fisheries managers.

Table 1 Lower, modal and upper exploitation rates (%) for small, medium and large salmon in small, medium and large rivers used in the simulation of attainment of conservation limits when local estimates of exploitation were not available. Exploitation is categorized and ranked as very low to high.

The next component in the estimate of spawning biomass is the proportion of females in the different size/sea-age classes. 1SW salmon are typically dominated by males, whereas 2SW salmon are female dominated and 3SW salmon often have a 1:1 sex ratio. This general pattern, however, is not consistent among populations (see for example Fleming Reference Fleming1996; Niemelä et al. Reference Niemelä, Mäkinen, Moen, Hassinen, Erkinaro, Lansman and Julkunen2000), and rivers where most of the salmon return as 1SW fish often have a slight numerical dominance of females (Fleming Reference Fleming1996). For many rivers, anglers provide information about the gender of the fish as part of a scale-sampling programme. This information was combined with general knowledge about the sex distribution in the different size groups to provide estimates for each population. To account for uncertainty, the proportion of females was given as triangular distributions.

Finally, to ensure that the estimates of spawning biomass were based on wild salmon, escaped farmed salmon were removed from the reported catch. Spawning of farmed salmon in the wild is considered a major threat to the genetic integrity and productivity of the wild populations (Fleming et al. Reference Fleming, Hindar, Mjølnerød, Jonsson, Balstad and Lamberg2000; McGinnity et al. Reference McGinnity, Prodöhl, Ferguson, Hynes, Maoiléidigh, Baker, Cotter, O'Hea, Cooke, Rogan, Taggart and Cross2003; Glover et al. Reference Glover, Quintela, Wennevik, Besnier, Sørvik and Skaala2012), and Norwegian management aims at minimizing interbreeding of wild and farmed salmon. During recent years, farmed salmon has constituted, on average, 4–9% of the river catch (in terms of number of fish). For many rivers, there are annual estimates of the proportion of farmed salmon based on analyses of scale samples (Lund et al. Reference Lund, Økland and Hansen1991; Fiske et al. Reference Fiske, Lund and Hansen2006), whereas for other rivers, estimates are scarce or lacking. In the latter cases, proportion of farmed salmon from neighbouring rivers was used as a proxy. Proportion of farmed salmon within each weight group was drawn from triangular distributions.

Simulation procedure

One thousand simulations were conducted for each population and year, according to the following procedure:

For each of three weight groups (i):

\begin{equation*} \begin{array}{l} Nw_i \,\, = N_i \times (1 - pf_i ) \\ Ww_i \, = Nw_i \times (W_i /N_i ) \\ WSf_i = [(Ww_i /e_i ) - Ww_i ] \times p_i , \\ \end{array} \end{equation*}

and then:

\begin{equation*} WSf_{tot} = WSf_1 + WSf_2 + WSf_3 , \end{equation*}

where pf_i = proportion of farmed salmon in weight group i, N_i = nominal catch (numbers) in weight group i, Nw_i = nominal catch (numbers) of wild salmon in weight group i, W_i = nominal catch (weight) in weight group i, Ww_i = nominal catch (weight) of wild salmon in weight group i, WSf_i = weight of spawning females in weight group i, e_i = exploitation rate in weight group i, p_i = proportion females in weight group i, and WSf_tot = total weight of spawning females summed over all three weight groups.

Next, the conservation limits (CL) for the simulations were drawn from triangular distributions and compared to WSf_tot. If WSf_tot > CL, the conservation limit was considered as reached and attainment = 1. If WSf_tot < CL, the conservation limit was not reached, and attainment = 0.

Finally, the percentage attainment was computed as WSf_tot × 100/CL and if per cent attainment was > 100 then truncated per cent attainment was set as 100; otherwise truncated per cent attainment = per cent attainment.

After 1000 simulations, the following three estimates were computed: (1) average probability of attaining the conservation limit, (2) average truncated percentage attainment of the conservation limit and (3) average percentage attainment of the conservation limit (non-truncated). The average of these estimates over the last four years were then used to evaluate attainment of the management targets and as the foundation for management advice following pre-decided procedures (as described later).

In 22 small rivers, where the catches were highly variable and strongly influenced by discharge conditions, it was very difficult to assign reasonable estimates of exploitation rates and an alternative simulation approach was used. We will not describe this approach in detail here, but it was based on estimating adults return at maximum smolt production and regional estimates of sea survival. Adult returns minus the catch provided an estimate of the spawning population.

The management targets and advice

Based on the assessment procedures described above, standardized advice has been provided annually since 2009. In 2008, the Directorate for Nature Management defined the management targets for each population as attainment of the conservation limit in three out of four years. The Salmon Committee operationalized this target by defining a threshold at 75% average probability of attaining the conservation limit over four years. Deviation from the conservation limit may however be small or large, and per cent attainment was also used as criterion for the advice. Each population was given one of five standardized recommendations for exploitation, ranging from increased exploitation to substantially reduced exploitation. The thresholds were set by expert opinion from the committee and under the precautionary approach adopted for salmon management by Norwegian authorities, assuming that small deviations from the conservation limits have small effects on recruitment, but effects may escalate at larger deviations. The five recommendations and their criteria were:

1. (1) This population can probably be more heavily exploited given that marine survival remains at current levels. Average probability for attainment of conservation limits during the last four years >75%, and average attainment (non-truncated) during the same period >140%.

2. (2) The management target is attained for this population and no additional restrictions on exploitation are necessary. Average probability for attainment of conservation limits during the last four years ≥75%.

3. (3) The management target may not have been attained for this population and exploitation should be reduced moderately to ensure attainment of the conservation limit. Average probability for attainment of conservation limits during the last four years is between 40 and 74%, and average attainment during the same period >75%.

4. (4) The management target is likely not attained for this population and exploitation should be significantly reduced to ensure attainment of the conservation limit. Average probability for attainment of conservation limits during the last four years is between 20 and 39%, and average attainment during the same period >60%.

5. (5) The management target is not attained for this population and exploitation should be reduced substantially to ensure attainment of the conservation limit. Average probability for attainment of conservation limits during the last four years <20%.

The recommendations are hierarchically structured so that if one of the two criteria (where there are two criteria) was not met, a more restrictive recommendation was applied. While the catch advice was given on a river basis, the catch recommendations address all fishing on the population, in the river, the fjord or along the coast. A separate system, not described here, has been developed for aggregated advice for the mixed population fishery in the fjords and along the coast.

The recommendations were based on historical evaluation of attainment of conservation limits (over the last four years) and were thus given under the assumption that survival conditions at sea remain the same. This is not likely to be true, as survival at sea varies substantially among years (Friedland et al. Reference Friedland, Hansen, Dunkley and MacLean2000). Current forecast models only provide large scale predictions for salmon abundance in the North Atlantic (see ICES 2012b), and the ability of the models to predict shifts in survival conditions (for example from low to high) is likely limited. However, because survival conditions have been generally poor during recent years (Windsor et al. Reference Windsor, Hutchinson, Hansen and Reddin2012; ICES 2012b), assuming that conditions will not change is probably a conservative approach.

Assessment of effects

For the assessment of effects of the new management scheme, only populations where attainment of the limits were evaluated with the method described above throughout the period (2005–2011) were included (for a variety of reasons, some were excluded and others added during the period). The largest salmon river system in Norway, the River Tana (18% of the total conservation limit in Norway), was also excluded from the analyses because the fisheries management is regulated through a long-term agreement with Finland, and no major new restrictions have been implemented during recent years. All analyses were thus based on results from 135 rivers, representing 61% of the total conservation limits. However, we also present the recommendations provided for all assessed populations (154–176 populations).

The effect of management according to conservation limits and management targets was primarily assessed by comparing the estimated attainment of the limits before (2005–2008) and after (2009–2011) the new scheme was implemented. However, changes may be due to changes in the abundance of fish or changes in exploitation rates. We thus also compare estimates of exploitation rates both in marine and river fisheries in the two periods. The abundance of salmon each year was estimated from a revised ‘run-reconstruction’ pre-fishery abundance (PFA) model (Potter et al. Reference Potter, Crozier, Schon, Nicholson, Maxwell, Prevost, Erkinaro, Gudbergsson, Karlsson, Hansen, MacLean, Maoileidigh and Prusov2004). In contrast to the original model, where total catch was the starting point (Potter et al. Reference Potter, Crozier, Schon, Nicholson, Maxwell, Prevost, Erkinaro, Gudbergsson, Karlsson, Hansen, MacLean, Maoileidigh and Prusov2004), the Norwegian model uses the river catch statistics as the starting point. The number of salmon that ascend all rivers was estimated from the reported river fisheries catch and estimates of exploitation rates. Next, the reported catch in the marine fishery was added, and after removing farmed escapees (based on monitoring programmes) and adjustment for unreported catch (as proportion of the reported), the total PFA for Norway was estimated. The estimates were based on Monte Carlo simulations using uniform distributions reflecting uncertainty in model parameters (unreported catch, proportion farmed salmon). PFA in number of fish was transformed to total biomass and biomass of females, by using average size and proportion females in each of the three size groups. Because no independent estimates of exploitation rates in the marine fisheries for the relevant period were available in the literature, changes in marine exploitation after implementation of the new management scheme were assessed using estimates from the PFA-model. In addition, estimates of fishing effort (bag-net and bend-nets days) was used as index of marine exploitation.

Some more indirect effects were also described. Changes in the quality of the catch statistics were assessed based on categorization in the questionnaire to the county governor fisheries managers. Changes in the number of the rivers with local estimates of exploitation rates were also assessed.