Water quality parameters response to temperature change in small shallow lakes

Effects of temperature (T) on water quality of three small shallow lakes in Taihu Lake region of China were investigated. The annual temperature was classified into three levels: low temperature (LT, 4 °C < T ⩽ 10 °C), middle temperature (MT, 10 °C < T ⩽ 20 °C), and high temperature (HT, 20 °C < T ⩽ 30 °C). Results showed that total nitrogen (TN) and total phosphorus (TP) concentrations might go to a fixed value (or range) in small shallow lakes receiving domestic sewage and farm drainage water. Nitrogen concentrations in the lakes were mainly in the form of nitrate (${\text{NO}}_3^{-}$) at above concerned three temperature levels, and nitrogen concentrations in the forms of TN, TIN, and ${\text{NO}}_3^{-}$ were increased with the increase of nutrient input. At the LT and MT levels, there was a series of good cubic curve relationships between temperatures and three N forms (TN, ${\text{NO}}_3^{-}$ and ${\text{NH}}_4^{+}$). The temperatural inflexion change points in the curves were nearly at 7 °C and 14 °C, respectively. However, no significant relationship between temperature and any water quality parameter was observed at the HT level. The significant relationship of TIN to TN, ${\text{NO}}_3^{-}$ to TN and ${\text{NH}}_4^{+}$ to dissolve oxygen (DO) was exist in three temperature portions, and TP to Chemical oxygen demand (COD, determined by potassium permanganate oxidation methods) in LT and MT, TP to pH or DO in HT also exist. COD were less than 6 mg L⁻¹ at each temperature level, and pH values were the largest in HT than it in LT or MT. Thus, changes between temperature and water quality parameters (TN, ${\text{NO}}_3^{-}$, ${\text{NH}}_4^{+}$ and TP) obviously nearly in 7 °C or 14 °C in lakes show that water self-purification of natural small shallow lakes were obviously with temperature changed.     

Combined effect of rheology and confining boundaries on spreading of gravity currents in porous media

One-dimensional flows of gravity currents within horizontal and inclined porous channels are investigated combining theoretical and experimental analysis to evaluate the joint effects of channel shape and fluid rheology. The parameter $\beta$ governs the shape of the channel cross section, while the fluid rheology is characterised by a power-law model with behaviour index n. Self-similar scalings for current length and height are obtained for horizontal and inclined channels when the current volume increases with time as $t^{\alpha }$.For horizontal channels, the interplay of model parameters $\alpha \text{,}n$, and $\beta$ governs the front speed, height, and aspect ratio of the current (ratio between the average height and the length). The dependency is modulated by two critical values of $\alpha \text{,}{\alpha }_{\beta }=n/(n+1)$ and ${\alpha }_n=(2\beta +1)/\beta$. For all channel shapes, ${\alpha }_{\beta }$ discriminates between currents whose height decreases ($\alpha <{\alpha }_{\beta }$) or increases ($\alpha >{\alpha }_{\beta }$) with time at a particular point. For all power-law fluids, ${\alpha }_n$ discriminates between decelerated currents, with time-decreasing aspect ratio ($\alpha <{\alpha }_n$), and accelerated currents, with time-increasing aspect ratio ($\alpha >{\alpha }_n$). Only currents with time-decreasing height ($\alpha <{\alpha }_{\beta }$) and aspect ratio ($\alpha <{\alpha }_n$) respect model assumptions asymptotically; the former constraint is more restrictive than the latter.For inclined channels, a numerical solution in self-similar form is obtained under the hypothesis that the product of the channel inclination $\theta$ and the slope of the free-surface is much smaller than unity; this produces a negligible error for $\theta >2°$, and is acceptable for $\theta >0.5°$. The action of gravity in inclined channels is modulated by both the behaviour index n and the shape factor $\beta$. For constant flux, the current reaches at long times a steady state condition with a uniform thickness profile. In steep channels and for sufficiently long currents, the free-surface slope becomes entirely negligible with respect to channel inclination, and the constant thickness profile depends only on n.Theoretical results are validated by comparison with experiments (i) in horizontal and inclined channels with triangular or semicircular cross-section, (ii) with different shear-thinning fluids, and (iii) for constant volume and constant flux conditions. The experimental results show good agreement with theoretical predictions in the long-time regime.Our analysis demonstrates that self-similar solutions are able to capture the essential long-term behaviour of gravity currents in porous media, accounting for diverse effects such as non-Newtonian rheology, presence of boundaries, and channel inclination. This provides a relatively simple framework for sensitivity analysis, and a convenient benchmark for numerical studies.