Figure 5: Spawner – recruits relationship, blue line with density shape parameter 1 and black line with density shape parameter 10

Data on the fecundity of Murray cod have changed little since the early 1990’s. Studies by Rowland (1988a; b) and Koehn and O’Connor (1990) form the best knowledge on fecundity (Table 1). Additional data for large Murray cod are currently being collected (J.D. Koehn and I. Stewart unpubl. data) and may be incorporated at a later date. Some data have been collected by DPI Victoria on size at sexual maturity and when they become available it may also be included at a later date. Other studies, such as the rehabilitation of the Murray River (Hume to Yarrawonga reach) will be analysing fish frames collected from some fishers, and where possible, fecundity data will be collected (J. Lyon pers. comm.). This remains an area of poor understanding for Murray cod and some simple studies would greatly improve our understanding of Murray cod fecundity. Assuming a one to one sex ratio, the following fecundity estimates are expressed as female eggs only (Table 1).

The parameter fec_i is the number of eggs produced per fish in age class i and forms part of the parameterisation of F_i in equation 7, such as F_i = fec_i x egg survival x larval survival x fingerling survival.

Mark-recapture is considered to be the best method for the estimation of the parameters required for structured population models (White and Burnham 1999; Todd et al. 2001). There is only one known

Age data obtained through analysing otoliths can be used to generate estimates of age specific survival (Fig. 9 and Table 2). Survival rates are calculated as the ratio between consecutive predicted relative frequencies, for example Nfreq(Age₄) = 0.1468 and Nfreq(Age₃) = 0.2081 and therefore the proportion of three year old fish that survive to become four year old fish is 0.7054. Coefficients of variation are inestimable through this technique, and have been assumed to decrease with age (Table 2). Age data are available from numerous researchers around the Murray-Darling Basin. So far this study has obtained age data from 220 Murray cod collected from the Murray River and tributaries (Morrison and Gooley unpublished data). Other age data were obtained from SARDI (Qifeng Ye and Brenton Zampatti unpublished data) and taxidermists (Appendix 5).

4.2.1 Other survival parameters

Once eggs are laid they must survive to hatch into larvae. Larvae must survive to become free swimming young-of-the-year juvenile fish (fingerlings) and fingerlings must survive to become one year olds in the case of the aged based model or survive to enter the first size class in the size based model. In the case of the aged based model, this leaves 3 survival parameters to be estimated; egg, larval and fingerling survival,where F₅ = G_EG_LG₀fec₅. Todd et al. (2004) estimated egg survival to be 0.5 for trout cod and in the absence of any other data it is reasonable to assume the same for Murray cod, i.e. G_E = 0.5 (annual survival rate). There are no means by which to estimate larval and fingerling survival directly, however, solving the characteristic equation 3.9 and substituting in all other parameter estimates (Tables 2 and 3) provides a growth rate as a function of the two survival rates combined, i.e. G_LG₀. The population growth rate for Murray cod is unknown, however it is reasonable to examine three cases of the product G_LG₀: 1) G_LG₀ = 0.0005; 2) G_LG₀ = 0.0015; and G_LG₀ = 0.0025. case 1) returns a lower growth rate,  = 1.0910; case 2) a moderate growth rate,  = 1.1981; and case 3) a higher growth rate,  = 1.2630. Todd et al. (2004) postulated that larvae were the most vulnerable life stage and that fingerling survival was likely to be an order of magnitude higher than larval survival for trout cod. Estimates of larval and fingerling survival for Murray cod in the absence of external mortality impacts such as thermal pollution, are presented in Table 3. Particular scenarios that may impact on either egg or larval survival, or both, will reduce the underlying growth rate and may produce growth rates less than 1. These scenarios will be individually manipulated within the model.