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The authors have declared that no competing interests exist.

In recent years, the Asian gall wasp

The Asian chestnut gall wasp,

Solving this phytosanitary problem by adopting the most effective pest management options is very important for the economy of this sector, specially for countries that are big producers, like Portugal, with an estimate of 30,000 to 35,000 tons of annual chestnut production. Biological control is considered the most effective method of control of

A mathematical model of the biological control of the chestnut Asian gall wasp by

Paparella et al. [

The mortality of

In northwestern Portugal, a high number of native parasitoids were reported parasitizing

The diffusive ratio, defined as the quotient between the diffusion coefficient of the parasitoid over that of the gall wasp, reflects the relative dispersion capacity of the two species. This coefficient is taken to be less than one because

A previous preliminary study suggested that the reinjection of the parasitoid can contribute to the reduction of the number of years during which

These dispersion parameters, along with different gall wasp overwintering survival rates, are used in the model to simulate biological control scenarios applicable to the chestnut–producing regions in Portugal, whose chestnut–cultivated areas are characterized by having surfaces less than 25 km^{2}. Simulations of simultaneous releases of the parasitoid are made in various places and at different times. The effects of the dimension of the forest area, the periodic repetition of the releases and the distance between them are studied. The results obtained allow us to draw important conclusions about the factors that enhance biological control and help to define effective strategies for achieving it in Portugal.

The paper is organized as follows. In Section

The life cycle of

Depending on locality (altitude, exposure) and chestnut cultivar, pupation occurs from mid-May until mid-July [

The life span of a

In this Section, mathematical models that take into account the separate evolution of

Let _{n} be the population of adult gall wasps carrying eggs during the summer of the year _{n} be the density of eggs laid in the chestnut buds.

Considering the density _{max} of chestnut buds and

Let _{d} be the length (days) of the egg deposition season. Assuming, for simplicity, a rate independent of time, emergence rate is:

Let _{d}), in days, and

Finally, let _{d} = _{d}/_{d} being the maximum number of eggs that can be laid by an adult female. The laying rate is proportional to the product of the density of eggs that can be laid in a given location, which in the model is expressed as _{max} − _{n}(

The combination of all these quantities results in the following formulation that describes the evolution of _{n} and _{n} during the season of the year

In _{n}, also appears in the equation for _{n} with a minus sign and divided by _{d}. This term thus represents female individuals who have already laid all their eggs (_{d}) and, as such, are no longer part of the population that carries eggs (_{n}).

Non-dimensional field variables are used in the following. They are defined as: _{n} = _{n}/(_{max}), _{n} = _{n}/_{max}. Moreover, we define the non–dimensional time as _{d}/_{d} = _{d}. Consequently, the non-dimensional model for

Note that these ordinary differential equations, valid for the _{n−1}(1). The initial conditions simply state that at the beginning of the season there are no adults of

To obtain the mathematical model for the evolution of _{n} as the population of the egg-carrying _{n} as the density of eggs laid in the same year.

To estimate the egg deposition rate, as in the case of _{t} be the number of eggs laid by each _{t} ≈ _{t}/_{t}, with _{t} being the maximum number of eggs that can be laid by an adult female during its lifespan _{t}. Thus, the egg laying rate is given by the product of egg-carrying

In _{n−1}(_{d})) and the density of

Once combined, these quantities yield a set of equations describing the evolution of _{n} and _{n} during the year

In _{n} with a minus sign and divided by _{t}. This term thus represents individuals who have already laid all their eggs (_{d}) and, as such, are no longer part of the population of _{n}). Contrary to the wasp model, the parasitoid model does not include any terms related either to the emergence or to the mortality of adult parasitoids. The reason is that _{t} [

While a mortality term for the adult phase appears to be unnecessary,

Defining the non-dimensional variables _{n} = _{n}/(_{max}), _{n} = _{n}/(_{max}), _{t}/(_{d}) we obtain, for _{t} = _{t} and _{n−1}(_{n}(0) = _{n−1}(_{n}.

To have a complete model, it is necessary to introduce the effect of

This results in the complete model described by

The system of ordinary differential equations, described by

The model parameters are _{d} = _{d}, _{t} = _{t}, _{t}/(_{d}) and _{d}/

Regarding the number of eggs laid by _{d} = 150 and _{t} = 71, respectively. These values are similar to those obtained in studies carried out in America and Japan, from wasps emerging from galls collected in chestnut orchards [_{d} = 40 and

_{n} = 1 and _{n} = 10^{−9}). Note that actual release protocols dictate much higher densities (e.g. 40 pairs/ha), localized on restricted gall-rich areas, rather than uniformly spread in all of a chestnut-producing area [

A logarithmic scale is used to highlight the low density reached by the two insect species.

Additionally, in ^{6} (_{max} ≈ 2 × 10^{6} buds ha^{−1}). This number assumes that a full-grown chestnut tree in spring produces about 10^{4} buds and that typical production orchards have a density of 100-200 trees per hectare. Although these values are characteristic of Italian chestnut orchards [^{7} (_{max} ≈ 10^{7} eggs ha^{−1}). Therefore, nondimensional densities _{n} = 10^{−7} corresponds to less than one insect per hectare. For an isolated, hectare-wide orchard, this would be the extinction threshold. For a chestnut woodland spanning ^{−7}/

The dynamic of the evolution observed in

_{n} approaches 1, then _{n} begins to decline. Then, in the turn of 1 − 3 years ^{−9}.

On the other hand, ^{−30} (

Comparing ^{−50} in the case of

^{−7}. The subsequent recovery of

Comparing ^{−9} for ^{−9} for

The spatially-homogeneous model predicts the local extinction of the pest. However, this mathematical model is deterministic and as such does not take into account the random events that occur especially when population densities are low. Under these circumstances, the gall wasp is more likely to survive than the parasitoid, because the probabilities finding chestnut buds is much higher than the probability of the parasitoid finding the wasp galls. More generally, we must stress that our model does not take into account the presence of refugia, which, by the nature of the trophic relationships under study, appear to be more likely to exist for

On the other hand, the model assumes populations homogeneously distributed in space, which is unlikely to occur in the field, except in small orchards, due mainly to the different dispersion capacities of the two species.

Adding a spatial dependence to the previous homogeneous model will take into account the fact that the two species move over time from one area to another. To accomplish that we add diffusion terms to the adult populations in the model described by

We assume that the random motion of individual insects within a wood at spatial scales large enough that the population density may be approximated by a continuous, smooth field, will produce a Fourier–Fick flux, that is, a flux proportional to the gradient of the insect population density. This gives rise in the equations for the _{n} and _{n} to terms proportional to the Laplacian of these two fields [_{d} and _{t}, respectively for the flux of _{t}/_{d}, we may bring the new terms to non–dimensional form, resulting in the following spatially–dependent system of equations:

In each season _{n}). This quantity will influence the amount of adult gall wasps that will hatch, so it goes into the _{n} equation. Then the gall wasp equations are solved, allowing to determine the distribution of laid eggs (_{n}) during the season _{n}, through the term _{n−1}. The computational algorithm repeats this procedure each year and, consequentially, enables to look at the spatial evolution of the density of

The two sets of partial differential equations, described by

The algorithm implemented in built-in Matlab function

The diffusivity ratio between the two species (_{t}/_{d}) is, jointly with the overwintering survival rates (_{d} = 0.889 km^{2/}d.

Regarding _{t} ≈ 0.016 km^{2/}d giving a diffusivity ratio of

The results of the numerical solution of the space-dependent model given by ^{2}), completely infested by

As shown in

The local evolution of the two species, considering their dispersion capacities, makes it possible to make a comparison with the results obtained with the homogeneous model, illustrated in

^{−4} which is well above the extinction threshold.

Comparing the results obtained with the non-dimensional areas 4 × 4 (s

The observation of ^{−6} despite the mesh refinement. This result shows that there is no point in increasing the number of

_{r} = 6,7,8,9. In all these simulations the overwintering survival rate is set to

The results observed in the ^{−2} (level of infestation is 1%), the maximum

It is possible to think that the periodic release of _{r} years, considering

In all the cases illustrated in

Comparing

A spatially-homogeneous model shows that biological control, under optimal conditions, can be successful. This result suggests that for small, isolated chestnut orchards, biological control should be effective. For this, it is necessary that the release of

The presence of an important number of native parasitoids that parasitize

On the other hand, the results obtained with the spatially–dependent version of the model shows that in large, or heterogeneous, areas biological control is likely to fail in achieving the desired goal of eradicating the pest. This occurs because

This allows

This procedure does not succeed in fully eradicating

In Portugal, vast chestnut–trees woods are not very frequent. However, there are regions with extensive chestnut production (Bragança, Vila Real, Viseu, Guarda and Portalegre), in many small orchards next to each other. In these regions it is preferable to follow a collective strategy for the entire region, otherwise the gall wasp will move between chestnut orchards and reconstruct its population uninterruptedly.

^{™}User’s Guide—Matlab R2020a; 2020.