On a Nonlocal Reaction-Diffusion Problem Arising from the Modeling of Phytoplankton Growth

Du, Yihong; Hsu, Sze-Bi

doi:10.1137/090775105

Cited by 78 publications

(74 citation statements)

References 26 publications

Supporting

Mentioning

Contrasting

Unclassified

Order By: Relevance

“…The proof of Theorem 3.1 is similar to that of case v = 0, which was studied in [8], with some modifications. For the sake of completeness we give the proof here in detail.…”

Section: Proof Of Theorem 31mentioning

confidence: 92%

“…They also analyzed in depth the phase transition curve for the case g(I) = aI γ , 0 < γ ≤ 1, by means of reducing the equation to a Bessel equation. In [25] the authors studied the asymptotic behaviors of the eigenvalues and eigenfunctions associated with the linearized operator of (2.1) when D is small and v > 0 is of the order √ D. In [8] the authors study both single species and two species competing for light in a eutrophic ecosystem with no advection, and the dynamics of single species growth is also completely analyzed in [8]. In this paper, we will use several critical rates to give a complete classification of the phase transition from bloom to no bloom for the general single phytoplankton species model (2.1)-(2.5).…”

Section: P (S T)ds mentioning

confidence: 99%

“…The proof of the uniqueness of a positive solution of (4.1) basically follows from the argument in [8] applying to (4.10). By the strong maximum principle [21], all nonnegative and not identically zero solutions of (4.8) must be strictly positive in [0, L].…”

Section: Proof Of Theorem 31mentioning

confidence: 99%

See 2 more Smart Citations

Single Phytoplankton Species Growth with Light and Advection in a Water Column

Hsu¹,

Lou²

2010

SIAM J. Appl. Math.

Self Cite

View full text Add to dashboard Cite

Abstract. We investigate a nonlocal reaction-diffusion-advection equation which models the growth of a single phytoplankton species in a water column where the species depends solely on light for its metabolism. We study the combined effect of death rate, sinking or buoyant coefficient, water column depth, and vertical turbulent diffusion rate on the persistence of a single phytoplankton species. Under a general reproductive rate which is an increasing function of light intensity, we establish the existence of a critical death rate; i.e., the phytoplankton survives if and only if its death rate is less than the critical death rate. The critical death rate is a strictly monotone decreasing function of the sinking or buoyant coefficient and water column depth, and it is also a strictly monotone decreasing function of the turbulent diffusion rate for buoyant species. In contrast to the critical death rate, a critical sinking or buoyant velocity, a critical water column depth, and a critical turbulent diffusion rate may or may not exist. For instance, if the death rate is suitably small with respect to the water column depth, the phytoplankton can persist for any sinking or buoyant velocity; i.e., there is no critical sinking or buoyant velocity under such a situation. We further show that a critical water column depth, a critical sinking or buoyant velocity, and a critical turbulent diffusion rate for both buoyant species and species with large sinking rates can exist for some intermediate range of phytoplankton death rates and, whenever they exist, are always unique. In strong contrast, there may exist two critical turbulent diffusion rates for species with small sinking rates. The phytoplankton forms a thin layer at the surface of the water column for large buoyant rates, and it forms a thin layer at the bottom of the water column for large sinking rates. Precise characterizations of these thin layers are also given.

show abstract

“…The proof of Theorem 3.1 is similar to that of case v = 0, which was studied in [8], with some modifications. For the sake of completeness we give the proof here in detail.…”

Section: Proof Of Theorem 31mentioning

confidence: 92%

Section: P (S T)ds mentioning

confidence: 99%

See 1 more Smart Citation

Single Phytoplankton Species Growth with Light and Advection in a Water Column

Hsu¹,

Lou²

2010

SIAM J. Appl. Math.

Self Cite

View full text Add to dashboard Cite

show abstract

“…Major theoretical results include photoacclimation (increase in chlorophyll per cell) (Steele, 1964;Fennel and Boss, 2003), bistability (Yoshiyama and Nakajima, 2002;Ryabov et al, 2010), oscillating SCM (Huisman et al, 2006), hysteresis conditions (Kiefer and Kremer, 1981;Navarro and Ruiz, 2013) and the ESS (evolutionary stable strategy) depth obtained by gametheory approach (Klausmeier and Litchman, 2001;Mellard et al, 2011). Recent mathematical studies solved the persistence and uniqueness of the steady-state solution (Du and Hsu, 2010;Hsu and Yuan, 2010;Du and Mei, 2011) and gave rigorous proofs for the abovementioned ESS depth and the game-theory approach (Du and Hsu, 2008a, b). Additionally, several modeling studies have been conducted to quantitatively assess the importance of different physical-biological processes leading to the SCML (Jamart et al, 1977(Jamart et al, , 1979Varela et al, 1994;Klausmeier and Litchman, 2001;Hodges and Rudnick, 2004;Beckmann and Hense, 2007).…”

mentioning

confidence: 99%

Analytical solution of the nitracline with the evolution of subsurface chlorophyll maximum in stratified water columns

et al. 2017

View full text Add to dashboard Cite

Abstract. In a stratified water column, the nitracline is a layer where the nitrate concentration increases below the nutrient-depleted upper layer, exhibiting a strong vertical gradient in the euphotic zone. The subsurface chlorophyll maximum layer (SCML) forms near the bottom of the euphotic zone, acting as a trap to diminish the upward nutrient supply. Depth and steepness of the nitracline are important measurable parameters related to the vertical transport of nitrate into the euphotic zone. The correlation between the SCML and the nitracline has been widely reported in the literature, but the analytic solution for the relationship between them is not well established. By incorporating a piecewise function for the approximate Gaussian vertical profile of chlorophyll, we derive analytical solutions of a specified nutrient-phytoplankton model. The model is well suited to explain basic dependencies between a nitracline and an SCML. The analytical solution shows that the nitracline depth is deeper than the depth of the SCML, shoaling with an increase in the light attenuation coefficient and with a decrease in surface light intensity. The inverse proportional relationship between the light level at the nitracline depth and the maximum rate of new primary production is derived. Analytic solutions also show that a thinner SCML corresponds to a steeper nitracline. The nitracline steepness is positively related to the light attenuation coefficient but independent of surface light intensity. The derived equations of the nitracline in relation to the SCML provide further insight into the important role of the nitracline in marine pelagic ecosystems.

show abstract

“…[3], [5], [6], [7], [21], [22], [25], [26], [29], [31], [35], [42], [50], [56], [57], [60], [67], [68]. We also recall the related problems faced in [23] and [24] also for higher order operators, and in [19] for p = 2 and N = 1.…”

Section: +mentioning

confidence: 99%

Nontrivial, nonnegative periodic solutions of a system of singular-degenerate parabolic equations with nonlocal terms

Fragnelli

Mugnai

Nistri

et al. 2015

Commun. Contemp. Math.

View full text Add to dashboard Cite

We study the existence of non-trivial, non-negative periodic solutions for systems of singulardegenerate parabolic equations with nonlocal terms and satisfying Dirichlet boundary conditions. The method employed in this paper is based on the Leray-Schauder topological degree theory. However, verifying the conditions under which such a theory applies is more involved due to the presence of the singularity. The system can be regarded as a possible model of the interactions of two biological species sharing the same isolated territory, and our results give conditions that ensure the coexistence of the two species.

show abstract

On a Nonlocal Reaction-Diffusion Problem Arising from the Modeling of Phytoplankton Growth

Cited by 78 publications

References 26 publications

Single Phytoplankton Species Growth with Light and Advection in a Water Column

Single Phytoplankton Species Growth with Light and Advection in a Water Column

Analytical solution of the nitracline with the evolution of subsurface chlorophyll maximum in stratified water columns

Nontrivial, nonnegative periodic solutions of a system of singular-degenerate parabolic equations with nonlocal terms

Contact Info

Product

Resources

About